MORTIERELLACEAE PHYLOGENOMICS AND TRIPARTITE PLANT-FUNGAL-BACTERIAL SYMBIOSIS OF MORTIERELLA ELONGATA By Natalie Vandepol A DISSERTATION Submitted to Michigan State University in partial fulfillment of the requirements for the degree of Microbiology & Molecular Genetics – Doctor of Philosophy 2020 MORTIERELLACEAE PHYLOGENOMICS AND TRIPARTITE PLANT-FUNGAL-BACTERIAL SYMBIOSIS OF MORTIERELLA ELONGATA ABSTRACT By Natalie Vandepol Microbial promotion of plant growth has great potential to improve agricultural yields and protect plants against pathogens and/or abiotic stresses. Soil fungi in Mortierellaceae are non- mycorrhizal plant associates that frequently harbor bacterial endosymbionts. My research focused on resolving the Mortierellaceae phylogeny and on characterizing the effect of Mortierella elongata and its bacterial symbionts on Arabidopsis thaliana growth and molecular functioning. Early efforts to classify Mortierellaceae were based on morphology, but phylogenetic studies with ribosomal DNA (rDNA) markers have demonstrated conflicting taxonomic groupings and polyphyletic genera. In this study, I applied two approaches: low coverage genome (LCG) sequencing and high-throughput targeted amplicon sequencing to generate multi-locus sequence data. I combined these datasets to generate a well-supported genome-based phylogeny having broad sampling depth from the amplicon dataset. Resolving the Mortierellaceae phylogeny into monophyletic groups led to the definition of 14 genera, 7 of which are newly proposed. Mortierellaceae are broadly considered plant associates, but the underlying mechanisms of association are not well understood. In this study, I focused on the symbiosis between M. elongata, its endobacteria, and A. thaliana. I measured aerial plant growth and seed production and used transcriptomics to characterize differentially expressed plant genes (DEGs) while varying fungal treatments. M. elongata was shown to promote aerial plant growth and affect seed production independent of endobacteria. A. thaliana DEGs were related to hormone signaling, immune responses, root development, abiotic stress, and metabolism. These data suggest that the mechanism of plant-fungal symbiosis involves fungal manipulation and stimulation of the auxin, ethylene, and ROS response pathways. Future experiments are proposed that could test these hypotheses and further characterize the fungal side of this symbiosis. ACKNOWLEDGEMENTS I would like to thank my supervisor and mentor, Dr. Gregory Bonito, for his guidance and support through this process. I would like to thank my committee, Dr. Ashley Shade, Dr. Hideki Takahashi, Dr. Frances Trail, and Dr. Sheng-Yang He, for their guidance, constructive criticism, and support throughout my research and professional development. I would like to thank my labmates for their time, support, community, and invaluable assistance in designing, conducting, and surviving my research, especially Dr. Nico Benucci, Dr. Pedro Beschoren, Abigail E Bryson, Julian Liber, Bryan Rennick, and Xinxin Wang. I am grateful to Amy McGovern and Gail Doehring for assistance in performing DNA extractions, the MLST library preparation and sequencing, and metadata collection in Chapter 2. I am grateful to Dr Marty Chilvers, Dr. Andrea Porras-Alfaro, Dr Matthew E Smith, Dr. Matt Kasson and the ZyGoLife project for contributing isolates that were used in my phylogenetic analyses. The collection of Modicella provided by Dr. M.E. Smith added significant value to my phylogenetic study. I thank Dr. Kevin Liu for advice on phylogenetic analyses, as well as Bryan Rennick and Alicja Okrasińska for proofreading Chapter 2 and helpful discussions. I would like to thank Abigail Bryson and Bryan Rennick for their extensive assistance with setting up plant-fungal interaction experiments, Xinxin Wang for her tireless and inexplicably enthusiastic assistance collecting Arabidopsis seeds from plant material, and Natalie Golematis for her help with antibiotic passaging to cure fungal strains and DNA extractions for qPCR analyses. I would like to thank Dr. Zsofia Szendrei for generously providing access to her lab microbalance for weighing seeds and plants. I am grateful to Dr. Pat Edger for his advice on RNA- seq experimental design and data analysis and to Keith Koonter and Dr. Matthew Greishop for sharing their automated image analysis pipeline. I am endlessly grateful to my friends and family for their love and understanding throughout my academic training, despite my preoccupation, stress, and distance, especially Diane iv Vandepol, Katherine Vandepol, Karen Matlock, and Dr. Amanda Lorenz. I would not have completed this dissertation research without the love, advice, and steadfast support of my partner, Dr. Jason Matlock. I would also like to acknowledge the companionship and unconditional love of Arthur Vandepol, who stayed by my side every day and through every all-nighter. v TABLE OF CONTENTS LIST OF TABLES ..................................................................................................................... viii LIST OF FIGURES .................................................................................................................... ix KEY TO ABBREVIATIONS ........................................................................................................ xi CHAPTER 1. INTRODUCTION .................................................................................................. 1 Problem Statement ................................................................................................................. 1 Background ............................................................................................................................ 2 Mortierellaceae Phylogeny .................................................................................................. 2 Plant-Fungal Symbiosis .....................................................................................................10 Mortierellaceae-Plant Symbiosis ........................................................................................18 Research Focus ....................................................................................................................23 Value of this research ........................................................................................................24 CHAPTER 2. RESOLVING THE MORTIERELLACEAE PHYLOGENY THROUGH SYNTHESIS OF MULTI-GENE PHYLOGENETICS AND PHYLOGENOMICS ..............................................25 Authors & Contributions .........................................................................................................25 Introduction ...........................................................................................................................25 Materials & Methods ..............................................................................................................28 Sampling, Isolation, & Culture Conditions ..........................................................................28 Preliminary Isolate Identification .........................................................................................30 Genomic DNA Extraction ...................................................................................................30 Low Coverage Genome (LCG) Library Preparation & Sequencing .....................................30 Low-Coverage Genome (LCG) Sequence Analysis ...........................................................31 PHYling methods for genome analysis ...............................................................................32 Multi-Gene Phylogenetic (MGP) Primer Design & Validation .............................................33 MGP Multiplex Amplification, Library Preparation, & Sequencing .......................................34 MGP Sequence Analysis ...................................................................................................34 Results ..................................................................................................................................36 Geographic and Biodiversity Sampling ...............................................................................36 The Low Coverage Genome Approach ..............................................................................38 The Multi-Gene Phylogenetics Approach ...........................................................................39 Taxonomy .............................................................................................................................44 Accepted Genera ...............................................................................................................45 Novel Genera .....................................................................................................................51 Discussion .............................................................................................................................61 Conclusions ...........................................................................................................................66 Figures & Tables ...................................................................................................................68 CHAPTER 3. MORTIERELLA ELONGATA STIMULATES AERIAL GROWTH, SEED PRODUCTION, AND RESPONSES TO AUXIN, ETHYLENE, AND REACTIVE OXYGEN SPECIES IN ARABIDOPSIS THALIANA................................................................................. 170 Authors & Contributions ....................................................................................................... 170 Introduction ......................................................................................................................... 170 Materials & Methods ............................................................................................................ 172 Plant and fungal culturing ................................................................................................. 172 vi Potting Mix Experiments .................................................................................................. 174 Agar-Based Experiments ................................................................................................. 176 RNA Sequencing & Differential Gene Expression ............................................................ 179 Results ................................................................................................................................ 182 Potting Mix Experiments .................................................................................................. 182 Agar Experiments ............................................................................................................ 183 Differential Gene Expression............................................................................................ 185 Discussion ........................................................................................................................... 190 Mortierella elongata promotes Arabidopsis growth independent of endobacteria ............. 190 Mortierella elongata may regulate Arabidopsis defense and abiotic stress responses ..... 192 Phytohormones in fungi ................................................................................................... 197 Future Directions .............................................................................................................. 197 Conclusions ......................................................................................................................... 199 Figures & Tables ................................................................................................................. 200 CHAPTER 4. SYNTHESIS ...................................................................................................... 241 Objectives............................................................................................................................ 241 Mortierellaceae Phylogeny & Taxonomy .............................................................................. 241 Mortierella elongata - Arabidopsis thaliana symbiosis .......................................................... 243 Conclusions ......................................................................................................................... 246 APPENDICES ......................................................................................................................... 248 APPENDIX A: PLANT-FUNGAL EXPERIMENTS ................................................................ 248 APPENDIX B: MORTIERELLA ELONGATA TRANSFORMATION SYSTEM ...................... 258 APPENDIX C: MORTIERELLA ELONGATA MATING SYSTEM ......................................... 275 APPENDIX D: SUPPLEMENTARY METHODS ................................................................... 284 BIBLIOGRAPHY ..................................................................................................................... 287 vii LIST OF TABLES Table 2.1 – Mortierellaceae species not included in this study .................................................. 81 Table 2.2 – Isolate metadata ..................................................................................................... 89 Table 2.3 – LCG assembly statistics ....................................................................................... 114 Table 2.4 – Primer sets produced by the MLST locus selection pipeline ................................. 120 Table 2.5 – Raw sequences per locus .................................................................................... 125 Table 2.6 – Rejected Strains ................................................................................................... 126 Table 2.7 – MLST Sequences by Isolate ................................................................................. 128 Table 2.8 – Primer mismatch .................................................................................................. 145 Table 2.9 – Locus sequence variability at the species level..................................................... 146 Table 2.10 – Locus sequence variability at the genus level ..................................................... 154 Table 2.11 – Mortierellaceae speceis chatacteristics .............................................................. 157 Table 2.12 – A comparison of historic Mortierellaceae phylogenies ........................................ 167 Table 3.1 – A map of the light levels in the growth chamber.................................................... 201 Table 3.2 – qPCR primer sets ................................................................................................. 205 Table 3.3 – Linear modeling of Arabidopsis aerial dry weight as a function of light level ......... 211 Table 3.4 – Linear modeling of Arabidopsis aerial dry weight as a function of treatment and medium ................................................................................................................................... 212 Table 3.5 – Linear modeling of Arabidopsis aerial dry weight as a function of starting seedling root length ...................................................................................................................................... 213 Table 3.6 – Linear mixed modeling of Arabidopsis aerial dry weight ....................................... 214 Table 3.7 – qPCR of plant, fungal, and endobacterial genes from RNA .................................. 216 Table 3.8 – Molecular results of RNA sequencing run ............................................................. 218 Table 3.9 – Arabidopsis genes differentially expressed in response to Mortierella elongata .... 221 Table B.1 – Primers for constructing and screening pRFHUE_eGFP_CBX ............................. 274 Table C.1 – Mortierella elongata mating strains ...................................................................... 283 viii LIST OF FIGURES Figure 2.1 – Divseristy of Mortierellaceae macromorphologies ................................................ 68 Figure 2.2 – Common Mortierellaceae spore forms ................................................................... 69 Figure 2.3 – Media-dependent macromorphology ..................................................................... 70 Figure 2.4 – Maximum likelihood analysis of LCG dataset ........................................................ 71 Figure 2.5 – Unconstrained maximum likelihood analysis of the concatenated MGP dataset .... 72 Figure 2.6 – MrBayes multi-gene Mortierellaceae phylogeny .................................................... 75 Figure 2.7 – Constrained Maximum Likelihood analysis of the MGP dataset ............................ 78 Figure 3.1 – Arabidopsis seedlings used in plant-fungal interaction assays ............................ 200 Figure 3.2 – Agar plates with Arabidopsis plants in the growth chamber ................................. 202 Figure 3.3 – Bolting phenotype ............................................................................................... 203 Figure 3.4 – Arabidopsis plants at the time of harvest for aerial biomass assay ...................... 204 Figure 3.5 – Aerial dry biomass of Arabidopsis plants grown in sterile potting mix .................. 206 Figure 3.6 – Total mass of Arabidopsis seed .......................................................................... 207 Figure 3.7 – Average Arabidopsis seed mass ......................................................................... 208 Figure 3.8 – Density histogram of Arabidopsis seed image area ............................................. 209 Figure 3.9 – Total seed number produced by Arabidopsis ...................................................... 210 Figure 3.10 – Mortierella elongata colonization of Arabidopsis increased aerial dry weight in agar- based interaction experiments ................................................................................................ 215 Figure 3.11 – Mortierella elongata strains equivalently colonized Arabidopsis roots ................ 217 Figure 3.12 – Principal component analysis of differential Arabidopsis gene expression ......... 219 Figure 3.13 – Volcano plots of differential gene expression .................................................... 220 Figure 3.14 – Abundance of differentially expressed Arabidopsis genes (DEGs) .................... 240 Figure A.1 – 23 day old Arabidopsis plants on 0.5xMS+suc, 12 DPI ....................................... 254 Figure A.2 – Plates from the Fungal Exudate pilot study ......................................................... 255 ix Figure A.3 – Estimated marginal mean of Arabidopsis aerial dry weight (agar pilot study) ...... 256 Figure A.4 – Aerial dry biomass of Arabidopsis grown in sterile potting mix (species panel) ... 257 Figure B.1 – Alignment of the sdhB amino acid sequences of Mortierella elongata AG77, M. alpina 1S-4, and Botrytis cinerea BQ-3 .............................................................................................. 270 Figure B.2 – A map of plasmid pDS23_eGFP_CBX-HygB ...................................................... 271 Figure B.3 – A map of plasmid pRFHUE-eGFP....................................................................... 272 Figure B.4 – A map of plasmid pRFHUE-eGFP_CBX ............................................................. 273 Figure C.1 – Macromorphology of Mortierella elongata mating on HAY1 ................................ 281 Figure C.2 – Micromorphology of Mortierella elongata zygospores ......................................... 282 x KEY TO ABBREVIATIONS PGP Plant Growth Promotion DPI Days Post Inoculation AM EM Arbuscular Mycorrhizal Ectomycorrhizal NM Non-Mycorrhizal BRE Burkholderia-related Endobacteria MRE Mycoplasma-related Endobacteria, or Mollicute-related endobacteria NRRL Agricultural Research Service Culture Collection CBS Westerdijk Fungal Biodiversity Institute (Centraalbureau voor Schimmelcultures) MRCA most recent common ancestor DEG Differentially expressed gene JA SA Jasmonic acid Salicylic acid IAA indole-3-acetic acid IBA Indole-3-butyric acid GA CK BR Gibberellic acid cytokinin brassinosteroid ABA abscisic acid ET ethylene PCR polymerase chain reaction rDNA ribosomal DNA ITS Internal Transcribed Spacer SSU Small Subunit xi LSU Large Subunit MLST multi-locus sequence typing LCG low-coverage genome BLAST Basic Local Alignment Search Tool (https://blast.ncbi.nlm.nih.gov/) RAxML Randomized Axelerated Maximum Likelihood EMM estimated marginal mean LM linear model LMM linear mixed model MEA Malt Extract Agar PDA Potato Dextrose Agar PNM Plant Nutrient Medium KM Kaefer Medium SDA Sabouraud's Dextrose Agar DI deionized TAE Tris base Acetic acid and EDTA xii CHAPTER 1. INTRODUCTION Problem Statement Microbial promotion of plant growth has great potential to improve agricultural yields and protect plants against pathogens and/or abiotic stresses, while also relieving economic and environmental costs of crop production (Li, Chen, et al. 2018; Bedini et al. 2018). Agriculturally important metrics pertaining to plant growth promotion include aerial biomass, root biomass, root architecture, seed number, seed size, and flowering time. One group of plant beneficial microbes is early-diverging filamentous fungi, which have been implicated in assisting plants in the colonization of land (Field et al. 2015). There are three main guilds of plant mutualistic fungi relevant to this study: arbuscular mycorrhizal (AM) fungi, ectomycorrhizal (EM) fungi, and non- mycorrhizal (NM) endophytic fungi. For the purpose of this study, NM root endophytes are defined as fungi that are found inside healthy plant roots but do not make any characteristic mycorrhizal structures. Most of these fungi are thought to promote plant growth primarily by providing water and mineral nutrients, and sometimes secondarily by precluding infection by pathogens and/or priming and regulating plant defense responses (Hooker, Jaizme-Vega, & Atkinson, 1994). However, the mechanisms of symbiosis can be very distinct between and within these functional guilds, largely because EM and NM associations represent convergent evolution on a phenotype, rather than a shared evolutionary mechanism of interaction (Tedersoo, May, & Smith 2010). Mortierellaceae are early diverging soil fungi belonging to the subphylum Mortierellomycotina. They are closely related to Glomeromycotina (the AM fungi) and Mucoromycotina, some of which are EM fungi (James et al. 2006; Spatafora et al. 2016). Plant associations with Mortierella have been recorded since the early 1900s and these fungi are broadly considered NM plant associates (Stiles, 1915; Bisby, Timonin, & James, 1935). Mortierellaceae are commonly detected and isolated from soils, plant debris, insect guts, mosses and roots of living plant roots (Dixon-Stewart, 1 1932; Gams, 1977; Domsch et al. 1980), and have been found on every continent, including Antarctica (Gams, 1977; GBIF.org, 2019). However, the extent of the plant growth promotion (PGP) phenotype(s) and the underlying mechanism(s) of association are still not well understood. Moreover, the inability to resolve phylogenetic relationships within Mortierellaceae limits their classification and the ability to make inferences pertaining to species distributions and diversity, or the conservation of functional ecologies across Mortierellaceae species (Gams, 1977; Petkovits et al. 2011; Wagner et al. 2013). Soil fungi in the Mortierellaceae also frequently harbor intracellular bacterial endosymbionts, making them an engaging research system for studying plant-fungal-bacterial symbioses. There are two lineages of endobacteria found in Mortierella species: Mycoplasma-related endobacteria (MRE) and Burkholderia-related endobacteria (BRE), which includes Mycoavidus cysteinexigens (Ohshima et al. 2016; Uehling et al. 2017; Desirò et al. 2018; Takashima et al. 2018). MRE are also found in Mucoromycotina, including EM species of Endogonales, and in the Glomeromycotina, which form AM (Bonfante & Desirò, 2017). The BRE in Mortierellaceae are closely related to the BRE in Glomeromycotina, Ca. Glomeribacter (Ohshima et al. 2016). Although the impact of Glomeromycotina MRE and BRE on the AM fungal-plant symbiosis has been characterized in one study, it remains unknown whether Mortierellomycotina endobacteria impact the Mortierellaceae-plant symbiosis (Lumini et al. 2007; Bonfante & Desirò, 2017). Background Mortierellaceae Phylogeny The Mortierellaceae are a family of fungi whose diversity, global distribution, and phylogenetic structure remain poorly characterized (Nagy et al. 2011; Tedersoo et al. 2014). These challenges limit inferences of total Mortierellaceae diversity and species relationships, both of which are key to identifying functional groups or genetic patterns. This is especially important in the context of 2 plant symbioses, given that Mortierellomycotina is phylogenetically related to the AM fungi (Glomeromycotina) and to a lineage of EM fungi (Endogonales). There are well over 100 species in Mortierellaceae, which were estimated to have split from its most recent common ancestor (MRCA) with the Glomeromycotina 358-508 million years ago (Wagner et al. 2013; Uehling et al. 2017). It is possible that the MRCA were plant associated, a trait that may have been lost through their evolution. Alternatively, the trait for associating with plants may have been gained in some species from a MRCA that had shared potential for plant association, but was not necessarily dedicated to that lifestyle (Uehling et al. 2017; Bonfante & Venice, 2020). Resolution of the Mortierellaceae and subsequent plant growth promotion (PGP) bioassays of representative species is necessary to elucidate which of these hypotheses is better supported. Early efforts to classify Mortierellaceae were based on macro- and micromorphology, including growth patterns, coenocytic hyphae, and asexual spore production (Gams, 1977). Most species within Mortierellaceae have macromorphological growth patterns on agar media and can produce three types of spores: asexual sporangiospores, asexual chlamydospores that can be produced terminally or intercalary, and sexual zygospores. One or more spore types may be absent in some species, such as M. chlamydospora which lacks sporangiospores and M. parvispora which lacks chlamydospores (Gams, 1977). Sexual reproduction is either heterothallic, where strains are required to out-cross with a compatible partner to mate, or homothallic, where a single strain possesses both mating types and is able to complete the sexual process without another individual. Macromorphology, micromorphology, and the production of all three spore types may vary considerably between growth media and conditions, which can complicate morphological species identifications (Petkovits et al. 2011). Mortierellaceae species and their groupings were morphologically redefined throughout the mid and late 1900s by mycologists including Gams, Linnemann, Mil’ko, Zycha, and Turner (Gams, 1976; Domsch et al. 1980). By 1970, a total of 9 genera had been described in the family: 3 Mortierella Coemans 1863, Carnoya Dewèvre 1893, Dissophora Thaxter 1914, Haplosporangium Thaxter 1914, Azygozygum Chesters 1933, Naumoviella Novotelnova 1950, Aquamortierella Embree & Indoh 1967, Echinosporangium Malloch 1967, and Actinomortierella Chalabuda 1968. In 1976, the monotypic Azygozygum chlamydosporum was redefined as Mortierella chlamydospora (Plaats-Niterink et al. 1976). Carnoya and Naumoviella were also synonymized with Mortierella around this time, though few records exist for these changes, which have not yet been digitized or translated from the original German texts (Gams, 1977). From 1969-1977, Gams performed comprehensive revisions of Mortierellaceae species and genera (Gams 1976; Gams 1977). He combined Actinomortierella and Haplosporangium into the genus Mortierella and then divided Mortierella into two subgenera: Micromucor and Mortierella. Within Mortierella subgenus Mortierella, Gams recognized 9 sections and at least 73 species: Alpina, Actinomortierella, Haplosporangium, Hygrophila, Schmuckeri, Simplex, Spinosa, Stylospora, and Mortierella (Gams, 1977). This arrangement was the final major revision of Mortierella based on morphological characteristics. In the early 1990s, with the advent of PCR and Sanger sequencing technologies, molecular systematics provided novel approaches that use variations in genome sequences to determine phylogenetic relationship between sampled taxa. Early phylogenies focused on rDNA and mitochondrial genes because they are ubiquitous among living organisms and have both highly conserved and hyper variable regions (Olsen & Woese, 1993). Highly conserved regions evolve very slowly and can be compared across extremely distantly related organisms, while the hyper variable regions generally evolve sufficiently to distinguish between species (Olsen & Woese, 1993). In fungi, the hyper variable region is the Internal Transcribed Spacer (ITS) region, between the highly conserved 18S (SSU) and 28S (LSU) coding regions (Schoch et al. 2012). DNA sequence analyses have permitted the rearrangement and definition of several Mortierellaceae genera. Mortierella subgenus Micromucor was reclassified to belong within 4 Mucoromycota in the genus Umbelopsis (Meyer & Gams, 2003). Mortierella subgen. Gamsiella was elevated to generic status and Echinosporangium was renamed Lobosporangium to resolve a nomenclature conflict with a red alga also named Echinosporangium (Benny & Blackwell, 2004). Echinochlamydosporium was recently described as a novel Mortierellaceae genus basal to all previously described genera, but cultures are not readily available for corroborating studies (Jiang et al. 2011). The genus Modicella was reassigned from the Mucoromycotina to the Mortierellaceae (Smith et al. 2013). Therefore, the most current molecular-based Mortierellaceae classification divides species into seven recognized genera: Lobosporangium, Dissophora, Mortierella, Modicella, Gamsiella, Aquamortierella, and the enigmatic Echinochlamydosporium (Benny, 2009; Jiang et al. 2011; Wagner et al. 2013). The first modern revision of the Mortierellaceae at the species level analyzed the ITS, SSU, and LSU rDNA regions across 85 strains representing 65 taxa (Petkovits et al. 2011). The authors established that the historic morphological classification system was largely unsupported by DNA sequence data and defined 12 new clades (Petkovits et al. 2011). The composition and general arrangement of the clades had strong statistical support, though the authors noted that placement of two clades (represented by Mortierella strangulata and M. selenospora, clades denoted /strangulata and /selenospora, respectively) did shift within the phylogenetic tree if ambiguously aligned sites in the ITS region were excluded from the analyses. It was also noted that several strains seemed to be misidentified. The authors concluded that species should be represented by multiple strains and/or identified on a genetic basis in order to increase confidence in their phylogenetic placement (Petkovits et al. 2011). A second rDNA phylogenetic study shortly thereafter expanded the diversity of sequenced species to over 400 specimens, including 63 type strains (Wagner et al. 2013). The authors used morphology and sequence data to confirm the identities of included specimens. Recognizing that the ITS region is too divergent to align across the entire lineage without significant indel gaps, 5 they generated a preliminary tree using the LSU region to define clades within the Mortierellaceae. They then aligned and analyzed the ITS region within each clade to define finer relationships between species. Wagner et al. (2013) reorganized and combined several of the Petkovits et al (2011) clades into a total of seven rDNA-based clades. The study by Wagner et al. (2013) has remained the most comprehensive and useful revision of the Mortierellaceae. Undiscovered fungi represent potential sources for biocontrol agents, pharmaceutical compounds, and agriculturally important plant symbionts (Hawksworth & Rossman, 1997). Detecting, isolating, and characterizing novel species is important to understanding the members of ecosystems, the complex interactions taking place, and how these ecological contexts drive the processes relevant to our interests. There is considerable variation in estimates of Mortierellaceae species diversity that remains unsampled (Hibbett & Glotzer, 2011; Nagy et al. 2011). Nagy et al. (2011) estimated the rate of novel species discovery in Mortierellaceae by comparing the total diversity of over 800 Mortierellaceae ITS sequences deposited to GenBank to the sequence diversity within 102 reference sequences from 78 described species. Since most of the sequence diversity in the GenBank dataset was already represented in culture and sequence repositories, they concluded that most Mortierellaceae diversity was already discovered and redetected, due to unsequenced type specimens. Nagy et al. (2011) estimated a total of approximately 127 species in the family. Given that 102 of the 125 currently accepted species in Mortierellaceae were described prior to 1980, and only 11 more between 1990 and 2011, this might seem to be a reasonable conclusion. However, this estimate was based only on well sampled areas, and did not take into account that vast regions of the world are still poorly sampled. Further, it should be noted that ITS and/or 28S rDNA regions have limited resolution at the species level, which may lead to underestimates of diversity (Nagy et al. 2011; Wagner et al. 2013). Hibbett & Glotzer (2011) countered the findings of Nagy et al. (2011), pointing out that type or authenticated material is unavailable for about half of the described Mortierellaceae species. 6 Further, Hibbett & Glotzer (2011) noted that most of the unidentifiable molecular operational taxonomic units (mOTUs) identified by Nagy et al. (2011) did not include sequences from cultures, having been generated from environmental metagenomic studies. In fact, there are currently close to 125 accepted Mortierellaceae species, and new species continue to be described at a steady, if not increasing, rate (Gams, 1977; Smith et al. 2013; Wagner et al. 2013; Degawa, 2014; Takashima, Degawa, Ohta & Narisawa, 2018). Some taxonomists caution that recent species descriptions may be established as redundant because the phylogenetic markers used to establish novelty of the culture sequence were not compared to a complete reference dataset (Wagner et al. 2013). Such oversights are entirely possible since a variety of rDNA markers are available and studies select among them for whichever is most suited to their study conditions (Bazzicalupo et al. 2013; Kohout et al. 2014). A comprehensive library of Mortierellaceae reference sequences for all possible described species, whether from type or authenticated strains, is not available yet. Of the 125 currently described species, at least 119 are classified as belonging to the genus Mortierella (Smith et al. 2013; Wagner et al. 2013). This is predominantly because the other accepted genera were described based on morphological distinctions that are not shared with the novel species. Therefore, Mortierella has largely become a catch-all genus for anything that belongs in the Mortierellomycotina. Further, modern taxonomic studies have established that Mortierella is polyphyletic with respect to the other genera in the family. One option for resolving this polyphyly by collapsing all Mortierellaceae species and genera into Mortierella, in order to circumvent the extensive revision of species and genus descriptions necessary to fully resolve species relationships and establish monophyletic genera (Petkovits et al. 2011). However, this solution would exacerbate the already poor resolution of species in this genus by rendering the genus-level identification equally as informative as the sub-phylum level classification and is generally not endorsed (Petkovits et al. 2011; Wagner et al. 2013). 7 DNA sequencing and phylogenetic methods have the ability to provide a framework that can guide classification and taxonomy decisions (Petkovits et al. 2011; Wagner et al. 2013). However, it has become clear that neither ribosomal data nor morphological characterizations are sufficient by themselves to resolve phylogenetic relationships within Mortierellaceae (Petkovits et al. 2011; Wagner et al. 2013). Thus, additional non-ribosomal markers are needed to identify monophyletic clades and describe novel genera to increase genus-level taxonomic resolution. Criteria for choosing non-ribosomal (nuclear) phylogenetic markers include genes that are single-copy and not under selective pressure; they should also contain sufficient sequence variation to make phylogenetic inferences. Identification of nuclear markers has historically been done manually, starting from protein sequence and characteristics, as in the case of RPB1 (Jokerst, Weeks, Zehring, & Greenleaf, 1989; Sidow & Thomas, 1994). Even with the advent of genome sequencing, discovery and evaluation of novel nuclear markers has been a largely manual process (Blair, Coffey, Park, Geiser, & Kang, 2008). There has been at least one effort to automate the discovery and evaluation of nuclear markers, a program called DIscoMark, which analyzes orthologous gene datasets to identify candidate loci (Detering, Rutschmann, Simon, Fredslund, & Monaghan, 2016). Both approaches are dependent on the availability of high-quality input genomes, of which there were only three for Mortierellaceae species at the start of the present work. Another approach used to resolve phylogenies relies upon genomic data to perform comparative phylogenomics and thus circumvent the challenges of amplicon sequencing of individual markers (Spatafora et al. 2016; Zhang et al. 2017). There are two approaches for genome sequencing: high-coverage de novo genome sequencing and low-coverage genome (LCG) sequencing. High-coverage genomes allow higher quality assembly and annotation (Sims et al. 2014). The LCG approach recovers less data and lower confidence assemblies, which must be guided by a reference de novo genome. These two approaches represent a tradeoff between 8 data and confidence vs. per-sample cost and sample throughput. The de novo sequencing approach was recently used to perform a comprehensive molecular review of zygomyceteous fungi, wherein 192 protein coding genes were used to resolve phylum-level relationships between 43 taxa across 7 phyla in the Kingdom Fungi and 3 outgroup taxa (Spatafora et al. 2016). The LCG approach has been applied successfully in insects and olive tree systems, from both low and high quality specimens and genome coverage between 0.5-30X (Olofsson et al. 2019; Zhang et al. 2019). These LCG phylogenomic approaches have relied on first identifying existing phylogenetic markers in assembled whole genome sequence data and mining them from the LCG dataset, rather than discovering novel markers. Olofsson et al. (2019) also demonstrated the capability of an LCG approach to extract phylogenetic information from degraded herbarium specimens with extremely low coverage (<0.5X), which encourages LCG sequencing of fungal herbarium specimens (Olofsson et al. 2019). These studies together suggest that estimations of Mortierellaceae species diversity and phylogeny remain uncertain, largely due to confused and inadequate morphological definitions, inadequate phylogenetic markers for molecular identification, and a dearth of reference sequences for type material. The genus Mortierella is polyphyletic with respect to the other Mortierellaceae genera and has become a catch-all genus for novel Mortierellaceae species. Further taxonomic revisions likely need to include non-ribosomal phylogenetic markers. A combination of high- and low-coverage genome sequencing may be suitable for recovery of sequence information from both fresh cultures and degraded herbarium specimens. Phylogenomics may serve as a framework for amplicon-based studies and identification of candidate non-ribosomal markers. The application of non-ribosomal marker discovery for amplicon-based phylogenetics and low-coverage genome sequencing for phylogenomics to resolving the Mortierellaceae phylogeny is discussed further in Chapter 2. 9 Plant-Fungal Symbiosis Plant microbiomes are dynamic and complex, and consist of bacteria, archaea, fungi, protists, and viruses. The effect that each member of the microbiome has on the host plant occurs on a spectrum from beneficial to pathogenic, and can shift along that spectrum depending on interactions with other members of the microbiome or abiotic changes in the plant environment (Zeilinger et al. 2015). Microbial protection against biotic and/or abiotic stresses and promotion of plant growth has great potential to naturally improve agricultural yields while also relieving economic and environmental costs of crop production (Rodriguez et al. 2008). Understanding the mechanisms of plant-microbe symbiosis could provide insight into what triggers shifts in the microbial behavior toward the plant. It could also enable us to also adjust land management, plant breeding, and agricultural practices to capitalize on beneficial plant interactions. Plant-associated fungi have extensive mycelial networks which efficiently scavenge and transport minerals, nutrients and water to host plants. There are three main guilds of plant mutualistic fungi relevant to this study: arbuscular mycorrhizal fungi (AM), ectomycorrhizal (EM) fungi, and non-mycorrhizal (NM) root endophytic fungi. Both AM and EM fungi promote plant growth primarily by providing water and mineral nutrients and often secondarily by niche occupation precluding infection by pathogens (Hooker et al. 1994). However, the signaling mechanisms and fungal symbiotic structures are very distinct between these two functional guilds. The term NM fungal endophyte encompasses an extremely diverse group of fungi, including representatives from Ascomycota, Basidiomycota, and Mucoromycota. Focusing on root endophytes narrows the diversity considerably within each phylum, but the range of species, lifestyles, and mechanisms of plant association are still extremely broad. In all of these associations, the fungus receives or derives nutrients from the plant host. In mycorrhizal associations, plants actively transfer photosynthates to the fungus. NM fungi may also penetrate into the root and receive photosynthates, as with the mycorrhizae, but NM fungi are also able to 10 degrade and utilize general root exudates and sloughed off plant root cells (Buée et al. 2009). As mentioned above, plant-microbe interactions are complex and can often involve multiple symbionts. Fungal endobacteria are known to have a crucial role in how their host fungus interacts with plant partners in many tripartite symbioses (Vannini et al. 2016). In plant pathogen Rhizopus microsporus, endobacteria are necessary for fungal sporulation and for production of a toxin that kills plant cells, releasing nutrients to the fungus (Partida-Martinez & Hertweck, 2005; Lackner et al. 2011). In AM fungus Gigaspora margarita, endobacteria Candidatus Glomeribacter provides additional defenses to environmental stress, as demonstrated by increased carbonylation of proteins in response to oxidative stress, which accumulate in cured AM fungi and are transmitted to host plant roots (Salvioli et al. 2016; Vannini et al. 2016). Endobacteria are also found in some EM fungi, but their impact on those plant-fungal associations is still unknown. Ectomycorrhizal (EM) Fungi Ectomycorrhizal associations are classically defined on the basis of symbiotic morphology (Tedersoo & Brundrett, 2017). The first characteristic is clusters of short, highly branched lateral plant roots wrapped in a thick fungal mantle. The second is the Hartig net, a web of fungal hyphae seen in the cross-section of the short, lateral EM root, where the hyphae have penetrated around and between, but not into root epidermal and cortex cells. Recent studies have expanded this definition to include phylogenetic relatedness to other EM fungi and/or demonstrably mutualistic, since some EM associations have poorly formed EM structures (Tedersoo & Brundrett, 2017). Only about 2% of known plant species are capable of supporting an EM symbiosis; these are predominantly woody shrub and tree species (Tedersoo et al. 2010). Most commercial and academic research interest in EM fungi is focused on applications in forestry and agriculture, e.g. habitat restoration, Christmas tree farms, and timer plantations (Peterson et al. 1984; Jeffries & Rhodes, 1987). However, in addition to the benefits that EM fungi confer to plants, many EM fungi are also studied and farmed for production of their fruiting bodies, e.g., truffles, porcini 11 mushrooms, and chanterelles (Hall et al. 2003). EM symbiosis has arisen and persisted through convergent evolution of both the plant and fungal partners. In fungi, EM capacity has evolved over 60 times, arising from saprotrophic fungi mostly in Basidiomycota, but also Ascomycota and Mucoromycotina, with current estimates of diversity at 20,000-25,000 species (Tedersoo et al. 2010). In plants, it is estimated that 250–300 genera and 6000–7000 species are consistently EM hosts (Tedersoo & Brundrett, 2017). Most EM plants seem to have evolved EM capacity from a pre-existing AM capacity, though there are some exceptions to this generalization (Tedersoo & Brundrett, 2017). Each plant host may interact with hundreds of EM fungi throughout their lifecycle, possibly selecting for different fungal partners at each life stage and/or season (Courty et al. 2010). Each individual fungus can also interact with many different plant hosts simultaneously, serving as a means of plant-plant communication, though the range of compatible plant host species for each fungal species is generally limited (Bruns et al. 2002; Courty et al. 2010). EM fungi can live independent of their plant hosts as saprotrophs and are therefore usually culturable and amenable to experimental manipulation, though they generally grow slowly (Jeffries & Rhodes, 1987). However, EM plant hosts have long generation times, more intense growth requirements, and larger genomes than many model plants, such as the Brassicaceae (Tedersoo et al. 2010). In addition to helping to physically exclude pathogens from roots, EM fungi benefit plants by obtaining and transferring minerals and simple organic nutrients to plant roots. They scavenge these nutrients by secreting enzymes from their hyphae and absorbing the digested products. There are differences in the key enzyme functions of different EM fungal lineages and species therein (Tedersoo et al. 2012). It has been suggested that these differences are also due to differences in the substrates and environmental conditions in which each EM fungal lineage or species evolved (Courty et al. 2010). This environmental specificity, combined with the high abundance of indigenous EM fungi in soils, means that it is often difficult to “transplant” EM fungi 12 onto established plants, rather is often more effective to simply rely on the extant fungi when relocating plants, an issue particularly challenging for truffle growers that are focused on growing a single EM species rather than the whole community. The signals exchanged in EM fungi symbioses are highly variable between different combinations of plants and fungi (Garcia et al. 2015). This has restricted the ability to translate research into the mechanism of EM symbiosis from one system to another. However, some commonalities can be observed. First, it appears to be critical that the EM fungus has lost most of the cell-wall degrading enzymes commonly found in saprotrophic fungi, particularly cellulases, to avoid production of plant cell damage-associated compounds that trigger the plant immune system (Clear & Hom, 2019). The initiation of EM symbiosis appears to involve fungal detection of plant root exudates (often flavonoids in particular) (Daguerre et al. 2017; Clear & Hom, 2019). In some EM fungi, the fungus responds to plant stimulus by producing a class of volatile organic compounds called sesquiterpenes that induce characteristic root branching independent of cell contact, others are known to produce auxins (Daguerre et al. 2017). In order to increase plant cell plasticity and promote hyphal penetration between plant root cells, EM fungi secrete glucanases, chitinases, aquaporins, and small secreted effector proteins (SSPs) (Clear & Hom, 2019). However, the identity of the crucial SSPs appears to vary between species and only one has been well characterized (Clear & Hom, 2019). A well characterized SSP is MiSSP7, produced by Laccaria bicolor during the early stages of symbiosis with Populus trichocarpa. This mycorrhizal secreted protein blocks jasmonic acid (JA) defense signaling and thereby promotes fungal colonization (Plett et al. 2014). However, there are over 10,000 EM symbiotic genes in the L. bicolor genome, few of which have functional characterizations (Kaur & Reddy, 2019). MiSSP7 has no homologs in close relatives, thus, while the underlying mechanisms may be conserved (e.g. use of SSPs), the specifics appear to vary between fungal species and plant hosts. Several species of EM fungi Endogonales have been confirmed to host obligate Mycoplasma- 13 related endobacteria (MRE), both from microscopic examination and by 16S rDNA sequencing. MRE genomes have been recovered from the sequenced metagenomes of some colonized Endogonales species. However, these MRE genomes are very difficult to analyze or characterize, particularly as a single fungal strain may host multiple, relatively diverse MRE populations (Bonfante & Desirò, 2017). The impact of MRE on EM fungal hosts is still unknown (Bonfante & Venice, 2020). Arbuscular Mycorrhizal (AM) Fungi Similar to EM fungi, AM fungi are typically defined morphologically. Unlike EM fungi, AM fungi penetrate plant cortical cells and form arbuscules, which are highly branched/coiled fungal structures within the plant cell. AM fungi do not produce fruiting bodies, but they do form very large spores containing hundreds of nuclei. The benefit of AM fungi to plants has long been of interest and use in agriculture to improve plant survivability, growth, and disease resistance, even though the primary mechanisms of interaction have only recently been formally described (Jeffries & Rhodes, 1987; Hooker et al. 1994; Gutjahr & Parniske, 2013). In contrast to the convergent evolution of EM symbiosis, AM fungi compose a monophyletic lineage (Glomeromycotina), which are estimated to have arisen between 358-558 million years ago (Uehling et al. 2017). The AM fungi are an ancient plant-fungal association and have been implicated in assisting plants in the colonization of land (Taylor et al. 1995). AM fungi are obligate biotrophs and spores only germinate after detecting exudates from a nearby plant root and they have limited resources with which to grow to the plant root. Unlike the EM fungi, AM fungi have low host specificity and have been found in about 80% of vascular plant species and some non- vascular plants (Smith & Read, 2010). AM fungal spores have hundreds of nuclei, which in combination with the requirement for a living plant host, make experimental manipulation of AM fungi very difficult. Arbuscular mycorrhizal fungi associate with many common model plants, including legumes 14 used to study legume-rhizobia symbioses. It was discovered very early on that many of the plant symbiotic genes necessary for legume-rhizobia symbiosis were also necessary for successful AM symbiosis (Duc et al. 1989). Moreover, the obligate biotrophism of AM fungi was useful for characterizing the early stages of symbiotic signaling. AM fungal spores germinate when they detect constitutively produced plant root hormones called strigolactones (Gutjahr & Parniske, 2013). Prior to contact with the plant root, the fungus responds to the plant root by producing and secreting a mixture of chitooligosaccharides, referred to as Myc factors. These Myc factors stimulate plant symbiotic genes by much the same mechanism as Nod factors in the legume- rhizobia symbiosis (Gutjahr & Parniske, 2013). Indeed, many of the plant genes involved in initiating AM symbiosis are also involved in legume-rhizobia symbiosis, though the common proteins are part of distinct plant signaling receptor protein complexes (Genre & Russo, 2016). The Myc factors trigger a signaling cascade from the receptor protein complex that initiates transduction of the AM signal between plant cells via calcium spiking. AM fungi also secrete an effector protein (SP7) that suppresses plant ethylene signaling (Mukherjee & Ané, 2011). Ethylene has been found to inhibit the root architectural changes required for AM colonization. Once established, individual arbuscules persist in root cells for 24-72 hours, before the plant initiates senescence and turnover of the arbuscule. The mechanism for this plant regulation of AM symbiosis is unknown, but is predicted to be a mechanism by which plants can select for and reward AM partners providing the most nutrients to the plant, particularly nitrogen and phosphorus (Gutjahr & Parniske, 2013). There are two lineages of obligate endobacteria found to live within tissues of AM fungi: Mycoplasma-related endobacteria (MRE) and Burkholderia-related endobacteria (BRE). The MRE in AM fungi are closely related to those found in the EM Endogonales. The effect of MRE on the metabolism and plant symbiosis of their fungal hosts is unknown, but the relationship appears to be facultative for the fungus, which can complete its life cycle without either 15 endobacteria. Both endobacteria are transmitted vertically by bacterial vesicles into AM spores (Bianciotto et al. 2004). One study examined the effect of BRE Ca. Glomeribacter gigasporum on the fitness and plant association of its fungal host Gigaspora margarita (Lumini et al. 2007). The authors found that G. margarita strains cured of their BRE were still able to colonize plant roots, but were significantly impaired in the pre-symbiotic distance that germinating spores could traverse to make contact with roots, likely due to reduced lipid and protein reserves compared to BRE-colonized spores (Lumini et al. 2007). This suggests that AM fungal BRE do not impact the AM symbiosis directly, other than increasing pre-symbiotic fungal fitness. Non-Mycorrhizal (NM) Root Endophytic Fungi For the purpose of this study, NM root endophytes are defined as fungi found inside living, healthy plant roots that do not make any characteristic mycorrhizal structures. Similar to EM fungi, NM root associated fungi have evolved in Mucoromycota, Ascomycota, and Basidiomycota. Many NM fungi have a broad host range, most importantly including plants that cannot support other mycorrhizal symbioses, such as Brassicaceae (Tester et al. 1987, Buée et al. 2009). In general, NM fungi live in soil as saprotrophs and associate with plants opportunistically as plants recruit and select soil microbes to colonize the rhizosphere by tailoring their root exudates (Zeilinger et al. 2016). In some cases, such as Fusarium oxysporum, different isolates within a species may be plant beneficial or plant pathogenic, which is thought to be controlled by biosynthetic gene clusters on supernumerary chromosomes (Validov et al. 2011; van Dam et a, 2017; Hoogendoorn et al. 2018). The primary benefits of fungal saprotrophs to plants are nutrient provision, secretion of competitive antifungal compounds, consumption of root exudates that would attract pathogens, and physical exclusion of pathogens (Buée et al. 2009). It has been suggested that plant root exudates stimulate the growth and activity of saprotrophic NM fungi, which then also degrade complex organic compounds in the surrounding soil, some of which may be transferred to or 16 directly absorbed by the plant (Subke et al. 2004). It is also possible that NM fungi interact with mycorrhizal fungi to indirectly associate with plants (Buée et al. 2009). Some NM endophytes are also mycophiles and feed on would-be fungal competitors and plant pathogens, as in the case of many Trichoderma spp. (Harman et al. 2004). Very few NM associations have been studied closely, but these fungi represent potential sources of biocontrol agents, producers of novel pharmaceutical compounds, and scavengers of plant nutrients. The most thoroughly characterized plant beneficial NM fungus is Serendipita (=Piriformospora) indica, a Basidiomycete, which has unusually strong plant growth promoting (PGP) activity on a wide variety of plants, such as tobacco, Arabidopsis thaliana, barley, and legumes (Peškan‐Berghöfer et al. 2004). S. indica has been shown to confer resistance to pathogens and abiotic stress by priming the plant immune system, transmitting nutrients, and manipulating plant hormone signaling (del Barrio-Duque et al. 2019). The benefits conferred by S. indica in pure-culture experimental conditions are similar to those of AM fungi, but with the benefit of an axenically culturable fungus (del Barrio-Duque et al. 2019). Interestingly, S. indica was found to have no PGP effect on mycorrhizae-deificent pea and soybean mutants, which implicates a symbiotic mechanism similar to that of the AM fungi (Varma et al. 2001). Prior to contact with the root, S. indica secretes effectors that stimulate a systemic stress and defense response (Vahabi et al. 2015). In general, once hyphae make contact with the root, this response is shut off and the plant shifts over to a mutualistic interaction (Vahabi et al. 2015). However, the timing of this shift and the role of plant hormones jasmonic acids (JA) and gibberellic acid (GA) differ considerably between plant species (Liu et al. 2019). Similar to AM fungi, S. indica colonizes root cells progressively along the growing root length and over time the colonized cells are turned over (Jacobs et al. 2011). However, unlike the AM fungi, where the root cell survives this turnover, S. indica kills the colonized plant cells to release and absorb the cell contents (Jacobs et al. 2011). Arabidopsis secretes defensive proteins that regulate the extent of 17 S. indica colonization, balancing the benefit and cost of the symbiosis (Thürich et al. 2018). While the mechanism of S. indica-plant interaction may be highly variable, significant improvement of plant health, growth, and performance is universal under research conditions (Lie et al. 2019). Unfortunately, S. indica is not commonly found in soils, necessitating inoculating fields with non-native microbes, which has ethical and ecological implications (Rabiey et al. 2017). Therefore, it could be highly beneficial to explore globally cosmopolitan NM fungi and determine how to promote their selection and plant association using plant genotype and land management. Mortierellaceae-Plant Symbiosis Mortierellaceae have been isolated from living, healthy plant roots for over 100 years and from roots and soils across multiple continents and habitats (Stiles, 1915; Bisby et al. 1935; Domsch et al. 1980). Some Mortierellaceae species appear to be globally cosmopolitan. Because the Mortierellomycotina are closely related to both AM fungi and the Endogonales, research into the mechanism of PGP activity may provide insight into the evolution of plant symbiosis in this highly diverse phylum. Moreover, Mortierellaceae are easily isolated and cultured and can be studied on both mycorrhizal and non-mycorrhizal plants. Many Mortierellaceae species host both MRE and BRE. The lineage of BRE associated with Mortierellaceae, named Mycoavidus cysteinexigens, are distinct from, but form a sister clade to Ca. Glomeribacter found within Glomeromycotina (Ohshima et al. 2016; Uehling et al. 2017). Multiple phylotypes of both lineages have been found in different fungal isolates and species (Desirò et al. 2018; Takashima et al. 2018). Metabolic studies with isolates of M. elongata which have been “cured” of their endobacteria through the use of antibiotic passaging, indicate that the endobacteria restrict fungal growth rates and upregulate cellular respiration (Uehling et al. 2017). Moreover, preliminary data show a strong effect of the endobacteria on the lipid and secondary metabolite profiles of Mortierella isolates (Uehling et al. 2017). Genome sequence analysis of Mortierella and BRE has also shown that Mortierella lacks genes to synthesize many secondary 18 metabolites and that this is potentially complemented by the endobacteria (Uehling et al. 2017). It is uncertain whether endobacteria confer a functional advantage to Mortierellaceae. It is possible that any functional advantage may be restricted to environmental conditions that have not yet been replicated in experimental conditions. Until the present study, Mortierellaceae-plant interaction studies did not include endobacteria as a factor. In both controlled research conditions and in field soils, Mortierella species have demonstrated a wide variety of benefits to their host plants, which can include protection against nematodes, pathogenic fungi, and abiotic stresses, as well as plant growth promotion under controlled conditions (Al-Shammari et al. 2013; Wani et al. 2017; Shemshura et al. 2018; Johnson et al. 2019). In addition, Mortierella species also interact with other fungi and bacteria in the root microbiome, some of which have been isolated and shown to work cooperatively with Mortierella (Moreno et al. 2016; Tamayo-Velez & Osorio, 2017; Liao et al. 2019; Uehling et al. 2019). Root-knot nematodes cause severe damage to agricultural plants by feeding on plant roots and vectoring both bacterial and viral plant diseases (DiLegge et al. 2019). Mortierella alpina inhibits the hatching of root-knot nematode Meloidogyne javanica eggs and reduced the severity of the nematode pathogenicity on tomato plants in vivo, which significantly increased plant growth compared to the uninoculated, nematode infected controls (Al-Shammari et al. 2013). The closely related Mortierella globalpina had a similar inhibitory effect on Meloidogyne chitwoodi, also tested on tomato (DiLegge et al. 2019). Interestingly, the latter study compared tomato plant growth in control, nematode-only, fungus-only, and nematode+fungus treatments and found that any treatment including the fungus (Mortierella globalpina) had increased root and shoot biomass (DiLegge et al. 2019). This demonstrates that M. globalpina, and potentially M. alpina, promote plant growth and protect plants from nematode pathogens. Recent research into natural biocontrol of phytopathogenic fungi has found that M. alpina produces a suite of mycotoxic compounds (Shemshura et al. 2018). Culture exudates and 19 extracted lipids from M. alpina were found to inhibit the growth of three plant pathogenic fungi: Purpureocillium lilacinum, Fusarium tricinctum, and F. oxysporum (Shemshura et al. 2018). Arachidonic acid composed up to 40% of the lipids and 11% of the total dry biomass produced by M. alpina. Purified arachidonic acid strongly inhibited the growth of all three pathogens and also inhibited their production of mycotoxins that diffuse into the food products of infected crops and cause severe diseases in mammals (Shemshura et al. 2018). This finding is particularly important when taken in combination with another study that found exogenously applied phytohormones increased the production of arachidonic acid by M. alpina (Zhang et al. 2019). The screened plant hormones included cytokinins (6-benzyl adenine (BA) & furfuryl adenine (KT)), auxin, gibberellin, and abscisic acid. Each hormone had different stimulatory effects and required an optimized concentration. However, Zhang et al. (2019) also noted that combining both cytokinins had no synergy and cytokinin+auxin inhibited M. alpina growth and production of arachidonic acid. This suggests a potential mechanism by which plants can employ M. alpina to produce metabolites to protect themselves against pathogenic fungi and simultaneously regulate M. alpina colonization of the rhizosphere. A study of M. alpina on saffron crocus also demonstrated agriculturally important corm rot disease protection via arachidonic acid and disease effect mitigation through the jasmonic acid pathway (Wani et al. 2017). Mortierellaceae interact cooperatively with other microbiome species in the plant rhizosphere. Liao et al. (2019) found that M. elongata structures the Populus fungal rhizobiome selected from forest soil, slightly reducing the activity of AM fungi and increasing that of EM fungi and other NM root endophytes. M. elongata also promoted Populus growth in a cultivar-dependent manner (Liao et al. 2019). Transcriptome analysis indicated that M. elongata inoculation resulted in up- regulation of Populus genes related to lipid signaling, nutrient uptake, and growth promotion. Liao et al. (2019) aslo found alteration of gene expression related to gibberellin, jasmonic acid, salicylic acid, and ethylene signaling, suggesting that M. elongata manipulated plant defense responses. 20 Another study of M. elongata and the Populus microbiome identified a free-living Burkholderia strain that exchanges metabolites with M. elongata in a multi-phased interaction that increases the growth of both partners (Uehling et al. 2019). It is yet unknown whether this association occurs naturally in the Populus rhizosphere and/or affects the M. elongata-Populus interaction. Two studies co-inoculated a phosphate-solubilizing Mortierella sp. with AM fungus Rhizoglomus fasciculatum onto four different species of nursery trees (Moreno et al. 2016; Tamayo-Velez & Osorio, 2017). The first study found that while R. fasciculatum did increase growth of three tree species 16-37% compared to uninoculated controls, co-inoculation with Mortierella sp. increased growth promotion to 108-116% compared to the uninoculated controls (Moreno et al. 2016). The second study examined the growth of avocado with applications of R. fasciculatum and Mortierella sp. individually and together (Tamayo-Velez & Osorio, 2017). They found that neither fungus significantly increased plant growth individually, but co-inoculation increased plant height, biomass, and phosphorous content (Tamayo-Velez & Osorio, 2017). Ozimek et al. (2018) studied the microbiome of winter wheat to identify important winter-active plant associates. Two such symbionts were identified as M. verticillata & M. antarctica. M. verticillata produced high levels of auxin indoleacetic acid (IAA) when supplied with the precursor compound tryptophan and increased wheat root and shoot fresh weight by 40% (Ozimek et al. 2018). M. antarctica produced IAA independent of tryptophan amendment and increased root fresh weight by 40% and shoot fresh weight by 24%. Both strains were found to produce gibberellic acid and M. antarctica produced ACC (1-aminocyclopropane-1-carboxylate) deaminase, which degrades ethylene to ammonia, simultaneously reducing the concentration of a growth-inhibitory hormone and providing a nitrogen source to the plant root (Ozimek et al. 2018). Two studies recently explored symbiosis between Arabidopsis and M. hyalina (Johnson et al. 2019; Meents et al. 2019). Johnson et al. (2019) found that M. hyalina increases Arabidopsis aerial growth and inhibits Alternaria brassicae disease development. They found that M. hyalina 21 exudes induced calcium spiking in Arabidopsis roots, much as AM fungi induce during early symbiotic signaling with legumes (Genre & Russo, 2016; Johnson et al. 2019). An Arabidopsis mutant deficient in the calcium spiking response was also insensitive to M. hyalina disease protection and could not regulate M. hyalina colonization (Johnson et al. 2019). Meents et al. (2019) found that M. hyalina produces IAA in pure culture and colonized Arabidopsis roots had increased IAA levels, but that auxin-responsive Arabidopsis genes were not differentially expressed compared to uninoculated Arabidopsis roots. However, Meents et al. (2019) did observe a significant increase in jasmonates in colonized roots after 1 day of interaction, which was not produced by M. hyalina in pure culture. This elevated phytohormone level was not observed by Johnson et al. (2019) in Arabidopsis roots 12 days post inoculation (DPI), suggesting that the elevated hormone levels are important for establishing, but not maintaining the Arabidopsis-M. hyalina symbiosis. Both studies also quantified ABA levels in Arabidopsis roots with and without M. hyalina and together found that ABA was unaffected at 1 DPI but reduced at 12 DPI (Johnson et al. 2019; Meents et al. 2019). Salicylic acid concentrations were not different in colonized roots at either stage of interaction, which the authors concluded was consistent with high IAA levels and antagonism between the IAA and SA signaling pathways (Johnson et al. 2019; Meents et al. 2019). Li et al. (2018) explored the effect of organic fertilizer applications on the maize rhizobiome and found that the abundance of M. elongata significantly increased in response to organic amendments. The authors isolated M. elongata from the rhizosphere and inoculated unfertilized maize seedlings in bulk soil (Li et al. 2018). They found that plants inoculated with M. elongata had increased growth, increased phosphate, IAA and ABA concentrations, and an altered rhizosphere community. They suggested that M. elongata promoted plant growth by solubilizing and supplying phosphate to the plant, suppressing plant stress and defense responses and optimizing root architecture (Li et al. 2018). 22 In summary, Mortierellaceae is a highly diverse, globally distributed fungal lineage. Some species are known to have PGP activity, and a variety of mechanisms have been proposed. These fungi have a broad host range, including non-mycorrhizal plants, and are easily cultured, allowing for simplified research design compared to mycorrhizal fungi. M. elongata has been detected on all continents except Antarctica, precluding the need to inoculate agricultural or forest ecosystems with a non-native microbe. Moreover, M. elongata frequently hosts both BRE and MRE and has been shown to interact with free living soil microbiota (Desirò et al. 2018; Takashima et al. 2018; Uehling et al. 2019). These characteristics make M. elongata an excellent model system for studying tripartite plant-fungal- bacterial interactions, as will be explored in Chapter 3. Research Focus The goals of this dissertation research were to: 1. Resolve the phylogeny of the Mortierellaceae Hypotheses: (H1) There are phylogenetically informative single-copy loci conserved across the Mortierellaceae for which family-specific primers can be developed from the genome sequences of a few species. (H2) Low-coverage genome sequencing of species across the Mortierellaceae will yield sufficient genetic loci to construct a highly supported Mortierellaceae phylogeny. (H3) Combining the LCG and amplicon datasets will provide sufficient data across sufficient species diversity to resolve the Mortierellaceae phylogeny. 2. Confirm and characterize the symbiosis phenotype. Hypotheses: (H4) Mortierella elongata will promote the growth and seed production of Arabidopsis thaliana. (H5) M. elongata BRE and MRE impact the fungal-plant symbiosis. 3. Elucidate the genetic basis of Mortierella-plant association. Hypotheses: (H6) Plant and fungal genes are differentially expressed in co-culture as 23 compared to individual cultures. (H7) Genes that are differentially expressed during symbiosis are involved in maintaining a stable plant-fungal symbiotic interaction. Value of this research Existing ribosomal markers are insufficient to classify Mortierellaceae isolates to the species level. Identification of superior phylogenetic loci would improve identification of Mortierellaceae isolates both from pure culture and in environmental studies, which would clarify species diversity and geographical distribution. The genus Mortierella currently contains nearly all of the recognized species in the Mortierellomycotina. This renders the current genus-level taxonomy equally as informative as the subphylum-level classification. Defining novel genera will improve the informative value of genus-level identification for novel species. As traits and ecological functions are determined for representative members of each group, conserved features might become apparent as definitive of that taxonomic group. This will enable inferences about the ecological function of new species or isolates classified within those groups. Finally, as the functions of each group become defined, the evolution of those traits within Mortierellaceae and the fungal tree of life can be studied. Many studies have explored the impact of a variety of Mortierellaceae species in different environmental and experimental conditions. However, the role of Mortierellaceae bacterial endosymbionts in the plant-fungal symbiosis is unexplored. The Mortierellaceae are emerging as an extremely tractable research system. The Mortierella species reported to be plant-beneficial are distributed across several Mortierellaceae clades. It is valuable to understand the mechanism of interaction in each of these representative species to determine whether the Mortierellaceae have a conserved mechanism of plant association and how each functional group interacts with plants. If the Mortierellaceae do have a conserved approach, it can be compared to that of the Glomeromycotina and Endogonales to infer characteristics of their most recent common ancestor. 24 CHAPTER 2. RESOLVING THE MORTIERELLACEAE PHYLOGENY THROUGH SYNTHESIS OF MULTI-GENE PHYLOGENETICS AND PHYLOGENOMICS Authors & Contributions 1. Natalie Vandepol - primer design & validation, MGP PCR, MGP sequence analysis, & writing 2. Julian Liber - microscopy, photography, species & genus description, isolate troubleshooting 3. Alessandro Desirò - DNA extraction & strain isolations 4. Hyunsoo Na - LCG sequencing 5. Megan Kennedy - LCG sequencing 6. Kerrie Barry - LCG sequencing coordination 7. Igor V Grigoriev - LCG sequencing coordination 8. Andy Miller - metadata for shared strains, proofreading, taxonomy & nomenclature 9. Kerry O’Donnell - idea, strains, research support, MGP sequencing, & proofreading 10. Jason Stajich - idea, software development, Low Coverage genome sequence assembly, annotation, analysis & writing, data deposition. 11. Gregory Bonito - idea, research support, & writing Introduction Early diverging fungi belonging to Mortierellomycotina are diverse in ecology and species richness and are classified within a single order (Mortierellales) and as belonging to a single family (Mortierellaceae). Phylogenetically, this lineage is closely related to arbuscular mycorrhizal fungi (Glomeromycotina) and Mucoromycotina, and are among the earliest diverging lineages of fungi to have independently evolved differentiated macroscopic fruiting body structures, in the form of ~1cm sporocarps (Smith et al. 2013; Spatafora et al. 2016; Chang et al. 2019). Several species of Mortierella are prolific producers of polyunsaturated fatty acids and have relevance to nutraceutical industries and bioenergy research (Goyzueta et al. 2019). Mortierellaceae are 25 commonly detected and isolated from soils, plant debris, insect guts, mosses and living plant roots (Dixon-Stewart, 1932; Gams, 1977; Domsch et al. 1980), and have been found on every continent, including Antarctica (Gams, 1977; GBIF.org, 2019). Yet, the inability to resolve phylogenetic relationships within Mortierellaceae has limited inferences pertaining to species distributions, diversity, and functional ecology of Mortierellaceae (Gams, 1977; Petkovits et al. 2011; Wagner et al. 2013). Early efforts to classify Mortierellaceae were based on macro- and micromorphology, including colony growth patterns, hyphal branching, and spore production (Gams, 1977). Most species within Mortierellaceae have distinct macromorphological growth patterns on agar media, with colonies forming rounded to slightly pointed rosette “petals”, although some species grow in simple rings and others are completely devoid of visible growth rings (Fig. 2.1). Mortierellaceae fungi can produce three types of spores: asexual sporangiospores born in sporangia, asexual chlamydospores that can be terminal or intercalary, and sexual zygospores (Fig. 2.2). One or more spore types may be absent in some species, such as M. chlamydospora which lacks sporangiospores and M. parvispora which lacks chlamydospores (Gams, 1977). In some species, chlamydospores may be decorated with spines or other ornamentations and are referred to as stylospores (Chien, Kuhlman, and Gams 1974). Both heterothallism and homothallism have been observed in Mortierellaceae and sexuality varies by species, although mating is not commonly observed. Macromorphology, micromorphology, and the production of all three spore types may vary considerably between growth media and conditions, which can complicate morphological species identifications. (Fig. 2.3). Species and their groupings were repeatedly redefined in the mid 1900s, which was concluded by Gams in 1977, who divided the lineage into two subgenera: Micromucor and Mortierella. Within Mortierella subgenus Mortierella, Gams recognized 9 sections: Alpina, Actinomortierella, Haplosporangium, Hygrophila, Schmuckeri, Simplex, Spinosa, Stylospora, and Mortierella, the last of which contained the type genus and species for the Mortierellaceae, 26 Mortierella polycephala (Gams, 1977). Micromucor was later reclassified to belong within Mucoromycota in the genus Umbelopsis (Meyer & Gams, 2003). Additional genera, Gamsiella, Dissophora, Modicella, and Lobosporangium were subsequently described and accepted as Mortierellaceae, but remained polyphyletic with respect to Mortierella (Thaxter, 1914; Benjamin, 1978; Benny & Blackwell, 2004; Petkovits et al. 2011; Smith et al. 2013). The genus Haplosporangium was retired by Gams (1977) and all included species, including the type species H. bisporale, have been transferred to Mortierella, in various clades. The first modern sequencing- based revision of the Mortierellaceae established that the morphological classification system was largely unsupported and defined 12 new clades (Petkovits et al. 2011). Only sect. Schmuckeri, sect. Actinomortierella, and sect. Mortierella were retained in the new clades. A second rDNA sequencing effort expanded the diversity of sequenced species and reorganized and combined several of the Petkovits et al (2011) clades into a total of seven clades: selenospora, verticillata- humilis, lignicola, dissophora, capitata, alpina, and gamsii (Wagner et al. 2013). Currently, there are close to 125 accepted Mortierellaceae species, and new species continue to be formally described each year (Table 2.1). Estimates based on environmental sequencing predict there to be more than 170 Mortierellaceae species worldwide, indicating at least one quarter of the species in this family remain to be described (Gams, 1977; Benny, 2009; Nagy et al. 2011; Smith et al. 2013; Wagner et al. 2013; Degawa, 2014; Takashima et al. 2018). The current Mortierellaceae classification divides species into six genera: Aquamortierella, Dissophora, Gamsiella, Lobosporangium, Mortierella, and Modicella (Benny, 2009). However, most of these genera are monotypic or ditypic and nearly all of the species in the family are classified as belonging to the polyphyletic genus Mortierella (Smith et al. 2013; Wagner et al. 2013). Broad sampling of taxa, combined with robust phylogenetic analysis, and detailed morphological examinations, will underlie a phylogenetically-informed revision of Mortierellaceae classification and taxonomy. However, ribosomal data are unable to resolve phylogenetic 27 relationships within Mortierellaceae (Wagner et al. 2013). That is because the Internal Transcribed Spacer (ITS) rDNA is too divergent to align across the family for phylogenetic reconstruction, though it can be useful as a DNA barcode for classifying isolates to ITS-based clades and is sometimes sufficient for species determinations. Conversely, large subunit (LSU) and small subunit (SSU) rDNA regions are too highly conserved to sufficiently resolve higher order phylogenetic relationships (Wagner et al. 2013). Thus, additional non-ribosomal markers are needed in order to identify monophyletic genera and increase genus-level taxonomic resolution. In this study we applied two parallel approaches to resolve the Mortierellaceae phylogeny. In the first approach, we generated low-coverage genomes (LCG) from a phylogenetically diverse set of ingroup taxa to generate a robust and fully resolved phylogeny, which is a relatively new approach for phylogenomics (Olofsson et al. 2019; Zhang et al. 2019). We tested whether the LCG approach was suitable for fungi as a high-throughput method of genome sequencing to efficiently recover sequence data for phylogenomics. In the second approach, we developed and tested an automated pipeline to identify multiple lineage-specific markers for phylogenetic applications from a small number of representative genomes, and used multiplexed targeted amplicon sequencing to generate multi-gene sequence data across several hundred taxa. This allowed for an improved taxon sampling in terms of breadth and depth of as compared to the LCG approach. We then combined the concordant LCG and multi-gene phylogenetic (MGP) datasets to generate a resolved phylogeny and taxonomy for Mortierellaceae. Materials & Methods Sampling, Isolation, & Culture Conditions Diverse isolates were obtained from established culture collections including the Agricultural Research Service Culture Collection (NRRL) and Westerdijk Fungal Biodiversity Institute (CBS - Centraalbureau voor Schimmelcultures) and from collaborators to broaden geographic and 28 biodiversity sampling. Fresh isolates for this study were also obtained from roots, soils and plant substrates collected across Australia, Fiji, New Zealand, Uganda, and the United States (Table 2.2). Isolates were obtained using three methods: soil baiting, shrimp baiting, and soil dilution plating or swabbing (Finkelstein, 2013; Nampally et al. 2015). Soil baiting involved placing substrates in squares of water agar (10 g/L BactoAgar (Difco)) supplemented with antibiotics (i.e. streptomycin, chloramphenicol) on the lid of an inverted water agar dish. Aerial hyphae able to colonize the upper plate were then transferred to new 1% malt extract agar (MEA: 10 g/L Malt extract, 1 g/L Yeast extract, and 10 g/L BactoAgar (Difco)) plates. Shrimp baiting refers to incubating soils with shrimp exoskeletons, which have been washed and sterilized (Nampally et al. 2015). This substrate is enriched in chitin and selects for chitinolytic fungi, which includes many Mortierella species (Nampally et al. 2015). After 1-week, colonized exoskeletons were surface sterilized with 3% hydrogen peroxide for 1 minute, quenched with sterile water, and plated on squares of MEA or 1.2% potato dextrose agar (PDA: 12 g/L Potato dextrose broth and 10 g/L BactoAgar (Difco) on the lid of an inverted petri dish. Isolates whose macromorphology were consistent with Mortierella spp. were collected from the edge of growing colonies and transferred to new PDA or MEA plates until the cultures appeared to be pure. Soil dilution or swabbing involved either serial dilutions (1:100 and 1:1000) of soil in DI water plated on Saborauds Dextrose Agar (SDA (Thermo Scientific), or swabs streaked onto SDA. Individual isolates were picked at 1 day and 7 days and transferred to SDA. In total, 318 isolates were studied with the aim of resolving the Mortierellaceae phylogeny (Table 2.2). We included 59 strains from the ARS Culture Collection (NRRL) and 4 from the CBS strain repository selected to increase geographic diversity in our dataset. Sixteen of these were type strains. These included 21 isolates from across the United States, 12 from Europe, 3 from India, 2 from Mexico, 2 from Antarctica, and 1 each from Australia, Canada, Colombia, New Zealand, and Russia. We were unable to obtain metadata for 15 NRRL strains. In total, the NRRL and CBS isolates comprised 36 previously identified species and 5 strains unidentified to species. 29 Preliminary Isolate Identification To generate preliminary isolate identifications, DNA was extracted from mycelium using an alkaline extraction buffer (see Appendix D for details). We PCR-amplified the ITS region and the 5’ portion of the LSU using the universal fungal primers ITS1-F and LR3 (Vigalys & Hester, 1990; Gardes & Bruns, 1993). PCR products were separated by gel electrophoresis on a 1% agarose TAE gel containing ethidium bromide and visualized under ultraviolet illumination. The sizes of DNA fragments were estimated using a 100-bp ladder (ThermoFisher). Products with bands of the expected size were purified and template DNA was used in 10μL sequencing reactions with BigDye® Terminator v3.1 (Applied Biosystems), using the primers ITS1-F and LR3 (Vigalys & Hester, 1990; Gardes & Bruns, 1993). Sequences were generated on an Applied Biosystems 3730XL high throughput capillary sequencer at the Michigan State University Research Technology Support Facility Genomics Core. Sequences were de novo assembled with Geneious 8.1.3 and analyzed using the NCBI BLASTn tool (Johnson et al. 2008). Preliminary identifications were assigned based on sequence similarities and E-values. In the case of multiple equally high- quality BLAST hits to multiple Mortierellaceae species, the isolate was designated at the genus level (e.g. ‘Mortierella sp.’), with an indication of the clade to which it likely belonged as defined by Wagner et al. (2013). Genomic DNA Extraction To prepare high-quality genomic DNA, isolates were grown in liquid 1% malt extract broth culture for 1-2 weeks. Mycelium was harvested by vacuum filtration and genomic DNA was extracted following a CTAB-based chloroform extraction protocol (Doyle, 1991). DNA quality and concentration were estimated by gel electrophoresis and NanoDrop. Low Coverage Genome (LCG) Library Preparation & Sequencing Plate-based DNA library preparation for Illumina sequencing was performed on the PerkinElmer Sciclone NGS robotic liquid handling system using Kapa Biosystems library preparation kit. 200ng of sample DNA was sheared to 600bp using a Covaris LE220 focused- 30 ultrasonicator. The sheared DNA fragments were size-selected by double-SPRI and the selected fragments were end-repaired, A-tailed, and ligated with Illumina compatible sequencing adaptors from IDT containing a unique molecular index barcode for each sample library. The prepared libraries were quantified using KAPA Biosystem’s next-generation sequencing library qPCR kit and run on a Roche LightCycler 480 real-time PCR instrument. The quantified libraries were then multiplexed with other libraries, and the pool of libraries was then prepared for sequencing on the Illumina HiSeq sequencing platform utilizing a TruSeq paired-end cluster kit, v4, and Illumina’s cBot instrument to generate a clustered flow cell for sequencing. Sequencing of the flow cell was performed on the Illumina HiSeq 2500 sequencer using HiSeq TruSeq SBS sequencing kits, v4, following a 2x100 indexed run recipe. Low-Coverage Genome (LCG) Sequence Analysis Automated genome assembly was performed with the tool Automatic Assembly For The Fungi (AAFTF) which performs read trimming and filtering against PhiX and other contaminants using BBMap v38.16 followed by genome assembly with SPAdes v3.13.1 (Bankevich et al. 2012; Bushnell, 2014; Stajich & Palmer, 2018; Stajich & Palmer, 2019). Assemblies were further cleaned of vector sequences, screened for contaminant bacteria with sourmash using database Genbank Microbes 2018.03.29 (Pierce et al. 2019). Duplicated small contigs were removed using minimap2 v2.17 alignment of contigs smaller than the assembly N50 (Li, 2018). Contigs were further polished for the total Illumina read set with Pilon v1.10 and sorted by length and renamed (Walker et al. 2014). Each set of paired-end sequence reads for an isolate was automatically processed with AAFTF to produce a polished, vector screened, de-duplicated, polished, and sorted genome assembly. Genomes were annotated with funannotate v1.7.0, which used a combination of evidence from ab initio gene prediction and protein alignments to produce a predicted gene set (Palmer & Stajich, 2017; Love et al. 2019). For each genome, the funannotate prediction step was run and allowed to train the augustus v3.3.2 gene predictor with BUSCO aligned core genes from the 31 fungi_odb9 data set (Stanke et al. 2006; Palmer & Stajich, 2017). Genemark.hmm-ES was run in self-training mode to produce additional predictions (Ter-Hovhannisyan et al. 2008). These ab initio predictions were combined with exon locations inferred by aligning proteins from the SwissProt database to the genome first with BLASTX v2.2.31+, followed by exonerate v2.4.0 to produce splice site-aware alignments. These data combined into consensus gene models for each genome using EVidenceModeler (NCBI & Camacho, 2008; Slater & Birney, 2005; Haas et al. 2008). All these analysis steps are run as part of the funannotate ‘predict’ procedure. The predicted gene models in each genome were further annotated with putative functional information using eggNOG v1.03, CAZY, MEROPs, and Pfam databases searched with HMMER and DIAMOND (Eddy, 1998; Buchfink, Xie, & Huson, 2015). These annotated draft genomes were deposited in NCBI GenBank along with the primary Illumina sequences in NCBI SRA (Table 2.3). PHYling methods for genome analysis To examine the phylogenetic relationships of the strains using these sequenced, assembled, and annotated genomes, the PHYling pipeline was applied to a set of conserved, typically single- copy markers that were previously developed (Spatafora et al. 2016; Beaudet et al. 2017; Stajich 2020). The predicted protein set from each strain was searched for each of the 434 single-copy markers in the “JGI_1086” set, which was developed from Joint Genome Institute’s orthologous clusters from genomes in 2015. The best hits from each strain for each marker were aligned to the original HMM using hmmalign and the resulting alignments were trimmed with trimAL (Eddy, 1998; Capella-Gutiérrez, Silla-Martínez, & Gabaldón, 2009). Codon alignments were generated by back translating the protein alignments using the input coding sequences for each gene with the script bp_mrtrans.pl from BioPerl (Stajich et al. 2002) incorporated into PHYling. These individual alignments were concatenated together by PHYling using the script combine_multiseq_aln.py, recording the start/end of the alignment into a partition file. The concatenated protein and codon alignments were each used for phylogenetic analyses, initially in 32 FastTree and later in RAxML (Price, Dehal, & Arkin, 2010; JTT substitution model, Stamatakis, 2014). In addition, individual gene alignments were subjected to phylogenetic analyses to estimate gene trees. All the gene trees were combined and processed with ASTRAL v5.14.3 to infer a coalescent species tree from the individual gene trees (Mirarab et al. 2014). Multi-Gene Phylogenetic (MGP) Primer Design & Validation We used a series of custom Python scripts to extract all exon sequences from the annotated de novo genome of Mortierella elongata AG77 (Uehling et al. 2017; https://github.com/natalie- vandepol/mortierellaceae_mlst). We then conducted a BLAST search for these exon sequences in the de novo M. alpina B6842 and M. verticillata NRRL6337 genomes (Wang et al. 2011; Spatafora et al. 2016). We filtered the results for high-identity, single-copy hits and used MUSCLE to align the sequences (Edgar, 2014). From these, loci were selected based upon sequence identity and primers were manually designed using MEGA6 and OligoCalc (Kibbe, 2007; Tamura et al. 2013). Primer sequences were tested in silico with iPCRess against several Mortierella, Umbelopsis, and Mucor genomes to estimate the likelihood of off-target amplification (Slater, 2007; Table 2.4). Primer sets were selected for testing based on melting temperature compatibility. Primer sets were tested using genomic DNA from a panel of Mortierella isolates and DreamTaq Master Mix (MM) (ThermoFisher Scientific). PCR products were visualized through gel electrophoresis, as previously described, using a 1.2% agarose gel. Product sizes were estimated using a 100-bp ladder (ThermoFisher). Amplicons were Sanger sequenced and aligned in Mesquite 3.6. Thirteen loci showed primer specificity, robust amplification, and good alignment of sequences across the panel of Mortierellaceae diversity (Table 2.4). These loci, together with the fungal ribosomal primers ITS1-F and LR5, were tested for multiplex compatibility (Hopple & Vilgalys, 1994). Four sets of primer pairs were identified for multiplexed amplification of 3-4 loci in a single reaction. These sets were composed as follows: 1) RPB1, EF1a, 615, and 1870; 2) 370, 4955, and 10927; 3) 5401, 4121, and ITS1-F/LR5; and 4) 5512, 2175, 5491, and 2451. 33 MGP Multiplex Amplification, Library Preparation, & Sequencing Multiplex PCR was performed using Platinum Multiplex PCR Master Mix (Applied Biosystems). 2.5μl aliquots of the products were mixed with loading dye and subjected to electrophoresis on a 1.2% agarose gel and DNA was visualized by ethidium bromide staining. PCR products and their sizes were estimated based on a 100bp ladder (ThermoFisher). Primer sets that failed to amplify in the MultiPlex reactions were amplified individually with DreamTaq MM and screened using gel electrophoresis. Amplicons were pooled and sent to NCAUR (USDA- ARS, Peoria, IL) for library preparation using the Nextera DNA Library Preparation and Nextera Index Kits (Illumina) and sequenced on a MiSeq platform instrument. MGP Sequence Analysis Demultiplexed paired-end sequences were filtered for PhiX using the filter_phix tool in the USEARCH pipeline and assembled using SPAdes v3.7.1 (Edgar, 2010; Bankevich et al. 2012). The resulting contigs were identified to locus through a BLAST search against the genome sequences used for primer design and representative fungal and bacterial ribosomal sequences. A custom python script parsed the BLAST results to group contigs by locus. To minimize missing data, we defined “full-length” sequences as being at least 80% of the expected length for the locus. The count of full and partial length sequences for each sample and locus are summarized in Table 2.5. Loci were selected for further analysis based on the frequency of duplicate full-length sequences by comparing the total number of sequences for that locus to the number of samples (hereafter isolates represented by DNA sequence data) with at least one sequence. Loci with a sequence:sample ratio higher than 1.2:1 were excluded from the dataset, since this degree of over-representation would require extensive manual analysis to resolve, if possible, and could represent genuine paralogs or gene duplication events rather than barcode migration or cross- contamination between samples (Table 2.5). Resolution of duplicate sequences in the case of a gene duplication or paralogs would likely result in different copies being retained for a given sample and the locus still being unusable. 34 The filtered contigs were aligned using MUSCLE and trimmed to conserved regions in Mesquite 3.6 (Edgar, 2004; Maddison and Maddison, 2007). Additional loci were excluded if they had distinct sequence variants that could not be aligned. For the remaining 6 loci that were not excluded for the reasons described above, informative regions were identified using Gblocks 0.19b and analyzed with PartitionFinder 2 to determine the appropriate nucleotide substitution model (Castresana, 2000; Lanfear, Frandsen, Wright, Senfeld, & Calcott, 2016). Phylogenetic trees for each marker were generated with RAxML using the CIPRES gateway (RAxML-HPC2 on XSEDE (8.2.12)) (Ronquist & Huelsenbeck, 2003; Miller, Pfeiffer, & Schwartz, 2010; Stamatakis, 2014). Taxonomic identification of isolates was verified through BLAST searches of ITS sequences and considered valid if the best hits were to the expected or closely related species. When the best hits were consistently to species in a different ITS-based clade, the isolate was indicated as “Mortierella sp.”. Isolates were removed from the dataset if sequence data was only present for one locus or if they consisted of multiple copies for the majority of the loci. The remaining isolates were screened for multiple copies of any locus. In cases of multiple copies, if one sequence was clearly consistent in phylogenetic placement compared to other loci, that sequence copy was assumed to be the orthologue and was kept, and any paralogues were deleted. Otherwise, all sequences for that locus were removed for that sample. To improve the data matrix by increasing the number and diversity of isolates having four or more of the six loci, missing loci of several isolates were individually amplified with DreamTaq, screened via agarose gel electrophoresis, and Sanger sequenced. In addition, when genome sequences were available for a sample with missing loci, sequences from close relatives were used in a BLAST search against the raw genome sequencing reads to search for the target loci. This process was also used to construct MGP loci for LCG samples that had not been included in the MGP dataset. Matching reads were assembled and aligned to the query sequence in Geneious. 35 Three outgroup taxa were selected from published genomes available on JGI Mycocosm Portal: Mucor circinelloides CBS277, Umbelopsis ramanniana AG#, and Lichtheimia corymbifera FSU9682. The MGP loci were identified in these genomes using BLAST analyses in the MycoCosm portal and the sequences downloaded for inclusion in the alignments. After finalizing the dataset and alignments, Gblocks 0.91b and PartitionFinder 2 were used to exclude characters (type = DNA, allowed gaps = with half) and identify the optimal model of evolution for phylogenetics for each locus (GTR+G+I) (Castresana, 2000; Lanfear et al. 2016). SequenceMatrix 1.8 was used to generate a concatenated nucleotide matrix of the 6 loci (Vaidya, Lohman, & Meier, 2011). Four different phylogenetic tree building approaches were carried out. These included both constrained and unconstrained RAxML analyses of the concatenated matrix, a partially constrained MrBayes analysis of the concatenated matrix, and RAxML analyses of constrained and unconstrained single-gene alignments. A custom R script was used to prune the LCG tree to remove isolates not included in our concatenated and single gene datasets. The pruned genome tree provided a guide tree to constrain RAxML phylogenetic analyses. Key nodes were used to define partial constraints for MrBayes phylogenetic analyses. We did explore using ASTRAL to generate a consensus phylogeny as a counterpoint to our concatenated matrix analyses (Mirarab et al. 2014). However, we elected to not use this approach for our six gene dataset since this program was intended for datasets of several hundred genes. Results Geographic and Biodiversity Sampling We improved geographic sampling of Mortierellaceae with our own isolates obtained from soils collected in Italy (1), Australia (32), Fiji (1), New Zealand (8), Uganda (13), and across the United States (53). These new isolates account for 110 cultures representing 14 previously described species and 44 strains that could not be resolved to species, 26 of which represent 4 putatively novel species. In most cases, isolates that could not be identified to species by ITS 36 sequence could still be assigned to one of the ITS-based clades established by Wagner et al. (2013). An additional 145 isolates were contributed by collaborators. Of those, 141 were from the United States, 1 from Argentina, and 3 where metadata was missing. The 145 contributed isolates represented 25 previously described species and 46 isolates that could not be identified to species. The LCG dataset included 73 strains representing 28 described species and 21 isolates unidentified to species by ITS sequence analysis. Representatives were included from all seven ITS-based clades defined by Wagner et al. (2013) and 11 of the 12 clades defined by Petkovits et al. (2011), the exception being the strangulata clade. For the MGP approach, we PCR-amplified and sequenced the initial 13 loci across 332 isolates. Thirty-two isolates were excluded on the basis of quality filtering as described in detail later. These 32 excluded isolates are not reported in the sampling and metadata to avoid confusion about included versus excluded diversity, but are listed in Table 2.6. We added 14 LCG isolates by mining the genomes for the MGP loci. Therefore, the final MGP dataset contained 314 isolates that represent 48 distinct Mortierellaceae taxa and three outgroup species (Table 2.2). In this dataset, the gamsii, verticillata-humilis, and alpina clades were over-represented. Indeed, these are often the most commonly isolated Mortierellaceae. In addition, we specifically oversampled M. elongata and M. alpina isolates from disparate geographic regions in an attempt to better resolve these species complexes. In total, we included 117 isolates representing 11 of the 22 described species and one putative novel species from the gamsii clade, 69 isolates representing 7 of the 8 described species from the verticillata-humilis clade, and 70 isolates representing 7 of the 10 described species from the alpina clade. By comparison, the lignicola, dissophora, capitata, and selenospora clades were relatively undersampled. In the lignicola clade, we included 13 isolates representing 4 of the 8 described species, and 7 that were not previously identified to species. From the dissophora clade, we included 22 isolates representing 5 of the 7 37 described species and three putative novel species. For the capitata clade, 9 isolates represented 4 of the 9 described species and one unidentified species. For the selenospora clade, our dataset included 16 isolates, which represent 6 of the 12 described species. This study is the first modern phylogenetic analysis to include Modicella, represented by M. reniformis MES-2146. For the 81 described Mortierellaceae species that were not included in this study, we have summarized the current classification and, when possible, estimated their likely placement in our proposed classification based on high ITS sequence similarity to the species included in this study (Table 2.1). The Low Coverage Genome Approach Molecular Results For two samples, the sequencing coverage was too low to assemble and be included in the study. One sample was found to be contaminated. On average, Illumina sequencing returned 588 (316-1217) GB of sequence data per isolate, which were assembled into ~3,700 (1,100-12,500) contigs (Table 2.3). The average depth of genome coverage was 14.8X (8.5X-38.5X). Genome annotation identified an average of ~12,000 predicted proteins (7,338-16,572) in each genome. Our search for the 434 phylogenetic markers in the annotated protein set for each isolate identified between 354-419 markers in each genome (Table 2.3). Altogether there were a total of 109,439 characters in the concatenated LCG nucleotide matrix, which has been uploaded to TreeBase (submission 25806). LCG Dataset & Phylogeny There are 9 main branches in the LCG tree (Fig. 2.4). The wolfii-capitata clade is sister to the rest of the lineages and includes the taxa Mortierella ambigua, M. aff. ambigua, and M. wolfii. The next diverging lineage is M. selenospora. The third branch contains all representatives of the verticillata-humilis clade (17 isolates, 7 species). The single M. cystojenkinii isolate appears as a monotypic lineage. The fifth branch contains all included representatives of the gamsii clade (19 isolates, 7 described species) and a putative novel species that does not cluster with any known 38 taxon in either ITS or phylogenomic analyses, represented by Mortierella sp. GBAus35, NVP41, and AD031. The sixth branch includes all representatives of the alpina clade (11 isolates, 2 species), and is divided into two subgroups containing predominantly M. polycephala and M. alpina, respectively, the former of which is the type species for Mortierella. The seventh branch is represented by the lignicola clade and the eight branch is the monotypic Lobosporangium transversale. The ninth and final branch contains Gamsiella multidivaricata, Modicella reniformis, Dissophora ornata, Mortierella globulifera, and several putative novel species that are sister to Modicella. The Multi-Gene Phylogenetics Approach Primer Design From the three reference genomes, 1269 exons met initial quality criteria related to length, copy number, and sequence similarity. Of those, 130 were classified as suitable candidates for primer design due to their internal moderate variability flanked at each end by highly conserved areas. Further analysis yielded 74 primer sets meeting target amplicon length, GC content, primer length, ambiguity, and self-compatibility criteria (Table 2.4). Of those, 55 passed in silico PCR. As a positive control for this locus selection process, we checked our primer sets for exons from RNA polymerase subunit B (RPB1) and elongation factor 1-alpha (EF1a), which have been used successfully as fungal phylogenetic markers. We found both RPB1 and EF1a among the 55 primer sets that had passed in silico PCR. We selected 22 loci, including RPB1 and EF1a, for in vitro testing based on similar annealing temperatures (Table 2.4). Thirteen were selected for continued use based on consistent amplification across a panel of Mortierellaceae isolates and alignment of the amplicon sequences. Molecular Results Illumina sequencing generated a total of 711.5 GB of sequence data (2.8 million reads) that were demultiplexed into our initial 333 samples. Sequences were assembled into 7905 contigs across 329 isolates for a total of 7.6 GB unfiltered, assembled contigs having an average 39 coverage of about 100x. Three isolates and the PCR negative control had little or no sequence data, could not be assembled, and were excluded from further analyses. Filtering Loci, Sequences, and Isolates Further quality control steps were taken to assess the consistency and validity of each locus as a phylogenetic marker. Loci 4121 (hypothetical protein, predicted amino acid transporter), 2175 (CTP synthase), and 615 (chitin synthase) were found to exceed the 120% sequence over- representation cutoff described in the methods and were therefore excluded (Tables 2.4 & 2.5). Loci 10927 (hypothetical protein, class V myosin motor head), 5401 (adenosylmethionine-8- amino-7-oxononanoate transaminase, biotin/cofactor biosynthesis), and 5491 (delta-12 fatty acid desaturase) each had two very distinct sequence variants that could not be aligned, so these loci were excluded from further analysis. Locus 370 (acyl-CoA oxidase) was found to be a member of a gene family, with no one homologue consistently amplified across sampled taxa. Therefore, this locus was excluded from further analysis. Some isolates had more than one full-length sequence for a given locus, referred to here as duplicates (Tables 2.5 & 2.7). In most cases, we attribute this to cross-contamination of isolates during post-PCR sample handling. Duplicate sequences were resolved by identifying where the sample was placed phylogenetically by other loci, and then determining which of the duplicate sequences were congruent. We resolved 2 of 5 duplicates in locus 1870 (xanthine dehydrogenase), 1 of 1 in locus 2451 (calcium-translocating P-type ATPase), 4 of 7 in locus 4955 (hypothetical protein, DNA replication licensing factor), 2 of 5 in locus EF1a (elongation factor 1- alpha), and 11 of 13 in locus RPB1 (RNA polymerase II subunit RPB1). Locus 5512 (glycosyltransferase Family 21 protein) had no duplicates. Thirty-two isolates were completely excluded from further analysis for various reasons detailed here and summarised in Table 2.6. Four isolates were completely excluded from the dataset because all but one locus had duplicate sequences, therefore no trends could be used to resolve duplicated sequences. Eleven isolates were removed for having zero full length 40 sequences or only ITS sequences. Five isolates were removed because only one locus amplified and there was no corroboration from other loci to verify the placement of the sample. Two isolates were excluded because they were contaminated by Umbelopsis and the loci were strongly incongruent. Five additional isolates were removed because placement according to the non- ribosomal loci radically disagreed with the species identification by ITS sequence. Four isolates were found to be duplicated in our dataset, due to having been assigned new isolate ID numbers after having been shared between labs. One isolate was excluded because the only loci for which it had sequences were deleted loci. We mined reference genomes and the unassembled LCG dataset for MGP loci and were able to fill in several “holes” in the dataset from loci that had failed to amplify/sequence. We also added 15 new isolates that were not included in the initial MGP dataset by successfully recovering at least two full-length MGP loci from genome sequences. Primer Performance Many isolates did not have all 6 loci represented in the final dataset. This was particularly true for isolates that were not closely related to the species from which the primers were designed. We attribute this result to sequence mismatch preventing the primer from binding, hereafter referred to as “primer mismatch”, rather than absence of the target genes. Sequence reads for all of the loci were detected in genome sequences of isolates across all clades of the Mortierellaceae, although incomplete sequencing often meant that the assembled reads did not meet the minimum sequence length and therefore could not be included in our analyses (Table 2.8). The effect of primer mismatch varied by loci (e.g., 1870, 5512 had lower recovery; EF1a, RPB1 had higher recovery), as seen by inconsistent percentages of isolates amplified across the clades. In contrast, locus 2451 amplified poorly across all clades. Unconstrained MGP Phylogeny The MGP dataset included 314 isolates representing 48 unique Mortierellaceae taxa and three outgroup species. These included 69 of the 73 Mortierellaceae LCG isolates, the exceptions being Mortierella wolfii NRRL 66265, Mortierella sp. GBAus43, M. chlamydospora NRRL 2769, 41 and Mortierella sp. NRRL A-10996. The final 6 gene concatenated matrix contained a total of 8181 characters, which has been uploaded to TreeBase (submission 25806). No strong incongruence was observed between the unconstrained MGP phylogeny and the LCG tree, but some weak incongruences were evident (Fig. 2.5). For instance, in the MGP phylogeny, the wolfii- capitata clade was split into several basal branches. The verticillata-humilis, gamsii, and alpina clades were still internally cohesive and consistently placed along the backbone. However, the alpina clade was split between two separate branches. Mortierella dichotoma was not represented in the LCG dataset. Our analyses place it apart from the other “clade 1” species, as defined by Wagner et al. (2013), where it comprised a monotypic branch between the verticillata-humilis and cystojenkinii clades. The MGP phylogeny also placed the selenospora clade within the second alpina branch and M. parvispora and M. beljakovae were grouped with M. dichotoma, rather than the rest of the lignicola clade. The lignicola clade, Gamsiella, Dissophora, Modicella, Lobosporangium, and the novel group detected in this study were still clustered together. All together, the internal group structure was generally consistent with the LCG analysis, although Lobosporangium was placed within the lignicola clade, possibly due to long branch attraction with Mortierella sp. NRRL3175. There were several weakly supported nodes (40-71%) along the backbone of the unconstrained MGP phylogeny, indicating that (similar to rDNA) the MGP loci were generally able to resolve relationships within, but not between, the major groups. LCG-Constrained MGP Phylogeny Since the unconstrained MGP phylogeny was unable to resolve the backbone placement of the major clade of Mortierellaceae, we synthesized our datasets to leverage the high confidence of the LCG phylogeny with the sampling depth of the MGP dataset. To obtain a constraint tree, we “pruned” the LCG tree to remove the 4 isolates not represented in the MGP dataset. Since MrBayes does not accept a constraint tree as a direct input, we defined major nodes of the LCG tree as partial constraints. However, the resulting tree topology was clearly inconsistent with the genome tree, though somewhat consistent with the unconstrained RAxML tree (Fig. 2.6). We 42 then generated an LCG-constrained RAxML phylogeny from the concatenated MGP matrix. This phylogeny had strong support (74-100% at major nodes), was congruent with the LCG phylogeny, and will be used henceforth as our best estimate of the Mortierellaceae phylogeny (Fig. 2.7). Resolving the Mortierellaceae phylogeny into monophyletic lineages resulted in a total of 14 clades. (Fig. 2.7). To help stabilize Mortierellaceae taxonomy we have resurrected Actinomortierella and erected seven novel monophyletic genera to accommodate supported clades: Benniella, Entomortierella, Gryganskiella, Linnemannia, Lunasporangiospora, Necromortierella, and Podila. We erected the genus Linnemannia to include the monophyletic gamsii clade, which contains the L. elongata complex, L. gamsii, L. amoeboidea and related species. L. elongata isolates do not appear to cluster by geographic origin, indicating that L. elongata may be cosmopolitan globally. Different genotypes of isolates within the L. elongata complex could not be distinguished using the ITS sequence data, and even with a global sampling provide poor resolution of the species within this complex. L. gamsii isolates were split between two branches: one monophyletic and the other shared with L. zychae, L. exigua, and L. acrotona. Lastly, L. amoeboidea originally clustered with M. alpina in ITS-based studies but consistently was resolved in Linnemannia in our analyses (Wagner et al, 2013; Petkovits et al. 2011). Since M. polycephala is the type species for Mortierella, the genus Mortierella is conserved for the alpina clade, which was split into two main groups. The first included M. polycephala, M. bisporalis, M. reticulata, and M. indohii. The other branch was composed of the M. alpina complex and M. antarctica. Podila includes species within the verticillata-humilis clade, which contains P. verticillata, P. minutissima, and related species. Podila species have historically been difficult to resolve or identify by ITS analysis, as the ITS sequences of species within this group usually share 98-99% identity. Although P. horticola and P. minutissima ITS sequences share 99% identity, they were distinguished in our analyses. 43 The deeply diverged clade in the Mortierellaceae phylogeny that includes Lobosporangium, Dissophora, Gamsiella, Modicella, and the newly erected genera Entomortierella and Benniella also has the highest diversity of ecologies and morphologies in the family. Entomortierella includes the lignicola clade and E. parvispora. Lobosporangium was placed between Entomortierella and the deepest branch with Gamsiella, Dissophora, Modicella, and Benniella. The MGP Loci as Phylogenetic Markers In this study, we found EF1a to be the least informative of the tested loci, as even the constrained gene tree had extremely low support (1-50% at most major nodes) and many misplaced taxa (e.g., Mortierella alpina KOD1046 grouped with Podila and M. alpina NRRL 6302 grouped with Entomortierella, both separate from the dominant M. alpina cluster). However, EF1a and RPB1 had the highest recovery rate across all isolates, including for outgroup taxa. RPB1 was the best performing individual locus of the MGP dataset, both in terms of its consistent amplification and ability to distinguish species. For example, the ITS1f-LR5 sequences of Linnemannia elongata NVP64 and L. gamsii NVP61 shared 98% similarity and 97% similarity with L. hyalina. However, RPB1 sequences of these species showed 85-96% interspecific sequence similarity, with intraspecific sequence similarity usually 98-99% (Tables 2.9 & 2.10). The other loci provided additional resolution of species within other genera. For example, locus 2451 provided the best resolution of species in Podila, with generally 96-99% sequence similarity within species and 89-94% similarity between species. P. epicladia and P. minutissima shared the highest sequence similarity (96-98% similarity within, 95-96% similarity between). For more reliable separation of these two species, locus 5512 could be used, where P. epicladia and P. minutissima were each 98-99% similar within species and 96% similar between species. Taxonomy The proposed classification for Mortierellaceae follows general principles promoted in the Hibbett et al. (2007) phylogenetic classification of Kingdom Fungi and followed by Spatafora et 44 al. (2016) in their reclassification of zygomyceteous fungi. Below are the accepted and proposed genera, each in alphabetical order, a brief discussion of each genus, and the species included in this study. Following each genus description are any comb. nov. descriptions for each species transferred to that genus. Species characteristics, synonyms, basionyms, and MycoBank numbers are also summarized in Table 2.11. Accepted Genera Actinomortierella Chalab. 1968 ≡ Mortierella Coem., Bulletin de l'Académie Royale des Sciences de Belgique Classe des Sciences 15: 536 (1863) ≡ Carnoya Dewèvre, Grevillea 22 (101): 4 (1893) [MB#20101] ≡ Naumoviella Novot., Chung-kuo Ti Chen-chun [Fungi of China]: 155 (1950) [MB#20362] MycoBank No: MB#20012 Type species: Actinomortierella capitata (Marchal) Vandepol & Bonito Description: Phylogenetically basal within the Mortierellaceae. Sporangiophores have an apical inflation in the uppermost portion from which short branches arise. The main sporangiophore and branches may or may not form terminal sporangia. Sporangiospores are globose to ellipsoid; chlamydospores are absent. Habitat: Isolates of this genus have been reported from Fiji, India, New Zealand, across North America, and the United Kingdom. A. ambigua and A. capitata are most commonly isolated from soil and dung. Actinomortierella. sp. aff ambigua BC1065 was isolated from decaying wood and fungivorous millipedes (Macias et al. 2019). In contrast, A. wolfii is generally isolated from compost, decaying hay and the lungs of diseased animals, usually cattle, where it causes mycotic pneumonia and abortion. A. wolfii is the only Mortierellaceae species known to be pathogenic to mammals and thus grows well at unusually high temperatures (Seviour, Cooper, and Skilbeck 1987). 45 Species in this study: Actinomortierella ambigua (B.S. Mehrotra) Vandepol & Bonito comb. nov. MycoBank No.: MB#835795 Type specimen: M-80 Basionym: Mortierella ambigua B.S. Mehrotra (1963) Actinomortierella capitata (Marchal) Vandepol & Bonito comb. nov. MycoBank No.: MB#835796 Type specimen: No type known Basionym: Mortierella capitata Marchal, Bull. Soc. R. Bot. Belg.: 134 (1891) Synonym: Mortierella vesiculosa Mehrotra, Baijal & B.R. Mehrotra (1963); Carnoya capitata (Marchal) Dewèvre (1893) Actinomortierella wolfii (B.S. Mehrotra & Baijal) Vandepol & Bonito comb. nov. MycoBank No.: MB#835797 Type specimen: M-82 Basionym: Mortierella wolfii B.S. Mehrotra & Baijal, Mycopathologia et Mycologia Applicata 20 (1-2): 51 (1963) Notes: Mortierella capitata Marchal (1891) was reassigned to Carnoya by Dewèvre (1893) and then transferred to Actinomortierella by Chalab (1968) along with several other Mortierellaceae species. The genus Actinomortierella was subsequently reduced to a subsection of Mortierella by Gams (1977). Since all but one of the species formerly in Actinomortierella were clustered together in our analyses (the exception being Lunasporangiospora chienii as Actinomortierella umbellata), we are resurrecting Actinomortierella. However, while Actinomortierella was validly described by Chalabuda in Griby Roda Mortierella (1968), the novel combinations for A. ambigua, A. capitata, and A. wolfii were in violation of Article 41.5 of the Shenzhen Code. Therefore, we provide valid combinations for each of these species. 46 Aquamortierella Embree & Indoh 1967 MycoBank No: MB#20047 Type species: Aquamortierella elegans Embree & Indoh Description: Hyphae highly branched. Sporangiospores uniquely reniform (kidney-shaped) to allantoid (sausage-shaped). Zygospores unknown and chlamydospores not mentioned. Suggested to be the only known member of the Mucorales, wherein the Mortierellaceae were then presumed to belong, to normally form sporangia and discharge spores under water. Habitat: Initially isolated from midge larvae in a freshwater stream in New Zealand. It was also found in Japan. Notes: No living material of this taxon currently exists. Dissophora Thaxter 1914 MycoBank No: MB#20187 Type species: Dissophora decumbens Thaxter Description: Fertile, septate aerial stolons are abruptly differentiated from fine vegetative hyphae. Sporangiophores arise as buds from these stolons in intervals behind the advancing apex. D. globulifera comb. nov., was not originally described in this genus, but it does produce sporangiophores from aerial stolons, in accordance with the original diagnostic characteristic. Unlike the other Dissophora species, D. globulifera sporangiophores appear as outgrowths from the bases of older sporangiophores, forming “tufts”, rather than singly along the length of the fertile aerial stolon. Habitat: All Dissophora species have been isolated from forest litter and soil. D. globulifera has also been isolated from agricultural soil. D. decumbens isolates are from North America, D. ornata isolates are from South America, and D. globulifera has been isolated from Europe and Japan. 47 Species in this study: Dissophora decumbens Thaxt. (1914) [MB#160412] Dissophora globulifera (Rostr.) Vandepol & Bonito comb. nov. MycoBank No: MB#833727 Type specimen: MBT#8101 (Neotype) Basionym: Mortierella globulifera O. Rostr., Dansk botanisk Arkiv 2 (5): 2 (1916) Synonym: Mortierella ericetorum Linnem. (1953) Dissophora ornata (Gams) Gams [MB#135572] ≡ Mortierella ornata W. Gams (1983) Gamsiella Benny & M. Blackwell 2004 ≡ Mortierella subgen. Gamsiella R.K. Benj., Aliso 9: 157 (1978) [MB#530804] MycoBank No: MB#28820 Type species: Gamsiella multidivaricata (R.K. Benj.) Benny & Blackwell Description: This genus was originally monotypic and defined based on the sporangiophore morphology of G. multidivaricta: “branched aerial hyphae form intercalary, lateral enlargements which become several times successively di- or tridivaricately branched, the ultimate branches forming two-spored sporangia on slender, elongate, attenuated pedicels” (Benjamin, 1978). G. stylospora, does not form sporangiospores, instead making stylospores. As Dixon-Stewart described (1932) “Stylospores very well developed on Czapek's medium, borne on fine aerial upright hyphae. No sporangia have been seen”. Habitat: Isolates have been reported from soil, decaying wood, and dung in Australia and Russia. Species in this study: Gamsiella multidivaricata (R.K. Benj.) Benny & Blackwell [MB#488121] ≡ Mortierella multidivaricata R.K. Benj. (1978) 48 Gamsiella stylospora (Dixon-Stew) Vandepol & Bonito comb. nov. MycoBank No: MB#833728 Type specimen: CBS 211.32 [MBT#8202] Basionym: Mortierella stylospora Dixon-Stew., Transactions of the British Mycological Society 17 (3): 218 (1932) Lobosporangium M. Blackwell & Benny 2004 MycoBank No: MB#28819 Type species: Lobosporangium transversale (Malloch) Blackwell & Benny Description: Sporangiophores are branched, sporangia transversely elongate with 1-5 spines at the apex. Sporangiospores are irregularly shaped. Zygospores are absent. Habitat: The type strain of this monotypic genus was isolated from Nevada soil in 1964. It has only been reported since from soils in Texas and the Sonoran Desert. Species in this study: Lobosporangium transversale (Malloch) Blackwell & Benny [MB#488122] ≡ Echinosporangium transversale Malloch [as 'transversalis'] (1967) Modicella Kanouse 1936 MycoBank No: MB#20336 Type species: Modicella malleola (Harkn.) Gerd. & Trappe Description: Species in this genus are the only Mortierellaceae known to produce macroscopic fruiting bodies, in the form of small, whitish, round sporocarps. Spores can be germinated on artificial media and grown axenically. They are morphologically Mortierellaceae-like in their acolumellate sporangium and garlic-like odor that is similar to that of other Mortierellaceae species. 49 Habitat: Modicella specimens are found growing saprotrophically on soils and decaying plant matter. M. malleola has been recorded in Europe, New Zealand, North America, and Taiwan, whereas M. reniformis has only been found in South America. Species in this study: Modicella reniformis (Bres.) Gerd. & Trappe [MB#317772] ≡ Endogone reniformis Bres. (1896) Mortierella Coemans 1863 MycoBank No: MB#20345 Type species: Mortierella polycephala Coemans Description: Sporangiospores are absent in some species, when present they can range from smooth and ellipsoid to reticulated and/or irregular, depending on the species. Chlamydospores, where present, are scarce and either smooth or spiny. When known, zygospore production is by heterothallic mating, though some homothallic M. polycephala isolates have been reported (de Hoog et al. 2000). Habitat: Most Mortierella species prefer to grow at cooler temperatures. Several species of Mortierella are known to be mycoparasitic to varying degrees. The type species of this genus, M. polycephala, was originally isolated from a mushroom. One strain in the present study was isolated from the surface of a truffle. M. bisporalis is a facultative biotrophic mycophile that first competes with its host for substrate, then causes lysis of the host mycelium and penetrates the host to live biotrophically (Rudakov, 1978). Mortierella alpina has also been shown to parasitize oospores of members of Oomycota (Phylum Heterokontophyta) (Willoughby, 1988). Species in this study: Mortierella alpina Peyronel (1913) [MB#170280] ≡ Mortierella oblatispora W. Gams & G.J. Bollen (?) ≡ Mortierella acuminata Linnem. (1941) 50 ≡ Mortierella renispora Dixon-Stew.(1932) ≡ Mortierella monospora Linnem. (1936) ≡ Mortierella thaxteri Björl. (1941) Mortierella antarctica Linnem. (1969) [MB#317880] Mortierella bisporalis (Thaxt.) Björl. (1936) [MB#258541] ≡ Haplosporangium bisporale Thaxt. (1914) Mortierella indohii C.Y. Chien (1974) [MB#317900] Mortierella polycephala Coem. (1863) [MB#145769] ≡ Mortierella vantieghemi Bachm. (1900) ≡ Mortierella vantieghemii Bachm. (1900) ≡ Mortierella raphani Dauphin (1908) ≡ Mortierella vantieghemi var. raphani (Dauphin) Linnem. (1941) Mortierella reticulata Tiegh. & G. Le Monn. (1873) [MB#236117] Novel Genera Benniella Vandepol & Bonito, gen. nov. MycoBank No: MB#833778 Etymology: In honor of Gerald Benny, an American mycologist who has dedicated his career to the study of zygomyceteous fungi. Dr. Benny made significant contributions to Mortierellaceae taxonomy, among others. This included establishing the subphylum Mortierellomycotina, elevating Gamsiella to generic level, and renaming Echinosporangium as Lobosporangium. Type species: Benniella erionia Liber & Bonito Description: Colonies on MEA or PDA are pure white to off white in color and do not produce rosette or colony patterns when young. With age, some slight growth rings may develop in the mycelium along the agar surface. Aerial mycelium is very abundant, over 1 cm thick. Hyphae are sterile, without observed sporangiophores or zygospores. 51 Habitat: These fungi have been isolated from dried soils collected in the United States (Indiana and Ohio), Australia, and Uganda. Isolates were baited from soils using sterilized shrimp exoskeletons. Benniella erionia Liber & Bonito, sp. nov. MycoBank No: MB#833779 Etymology: “erionia” - from the Greek “erion” meaning “wool”. This describes the appearance of the mycelium as unpatterned, light colored, and wooly. Type specimen: Australia, Western Australia, Camballan, sub-humid upland forest woodlands dominated by Eucalyptus marginata and Corymbia calophylla. 24 Sept. 2014, G.M. Bonito, FLAS- F-66497 (holotype) [MBT#392648]. Description: Colonies on MEA are pure white, and do not produce rosettes or patterning. Hyphae are sterile, without observed sporangiophores or zygospores, and are 3.63 ± 0.09 μm (mean ± SEM) in diameter. Terminal structures borne on axillary hyphae are swollen and irregularly branched, and in older cultures, these become darkened and resemble chains of spherical chlamydospores, each spore 10.7 ± 1.89 μm. Growth rates on PDA ½ + YE are 6.6-9.5 μm/min (min and max of 3 replicates) at room temperature (RT), and 5.0-8.5 μm/min at 30°C. On MEA + YE, growth rates are 4.9-8.4 μm/min at RT, and 4.9-5.2 μm/min at 30°C. Habitat: The type specimen (isolate GBAus27B) was cultured from soils collected in woodland of Eucalyptus marginata and Corymbia calophylla in Australia, on sandy gravels on low divides in the subhumid zones. Isolates were baited from soils using sterilized arthropod exoskeletons. The other B. erionia isolate in this study, INSO1-46B2, was isolated from soybean field soil in Indiana, USA. Entomortierella Vandepol & Bonito, gen. nov. MycoBank No: MB#833613 52 Etymology: entomon- (insect) refers to the insect association common to the species in this genus. Type species: Entomortierella lignicola (Martin; Gams & Moreau) Vandepol & Bonito Description: Most of the species produce sporangiospores, usually globose and smooth, but spiny in the case of E. lignicola. Entomortierella beljackovae, E. chlamydospora, and E. echinosphaera produce chlamydospores, the latter two of which are usually spiny. Almost all of the species are known to produce zygospores, but are divided between hetero- and homothallic sexual lifestyles. Habitat: Species in this genus appear to be arthropod and/or worm associates, as they are commonly isolated from ant pellets, termite nests, and vermicompost. They are also frequently isolated from soil, roots, and rotting plant matter. Species in this study: Entomortierella beljakovae (Milko) Vandepol & Bonito comb. nov. MycoBank No: MB#833729 Type specimen: CBS 123.72 [MBT#8042] Basionym: Mortierella beljakovae Milko (1973) Entomortierella chlamydospora (Chesters) Vandepol & Bonito comb. nov. MycoBank No: MB#835762 Type specimen: MBT#8049 (Syntype) Basionym: Azygozygum chlamydosporum Chesters, Transactions of the British Mycological Society 18 (3): 213 (1933) Synonyms: Mortierella chlamydospora (Chesters) Plaats-Niterink (1976) Entomortierella echinosphaera (Plaats-Niterink) Vandepol & Bonito comb. nov. MycoBank No: MB#835750 Type specimen: CBS575.75 (Holotype) Basionym: Mortierella echinosphaera Plaats-Niterink, Persoonia 9 (1): 91 (1976) Entomortierella lignicola (G.W. Martin) Vandepol & Bonito comb. nov. 53 MycoBank No: MB#835763 Type specimen: CBS 207.37 [MBT#15136] Basionym: Haplosporangium lignicola G.W. Martin (1941) Synonyms: Mortierella lignicola (G.W. Martin) W. Gams & R. Moreau (1960); Mortierella sepedonioides Linnem. (1941) Entomortierella parvispora (Linnem.) Vandepol & Bonito comb. nov. MycoBank No: MB#835751 Type specimen: MBT#8163 (Syntype) Basionym: Mortierella parvispora Linnem., Pflanzenforschung 23: 53 (1941) Synonyms: Mortierella gracilis Linnem. (1941) Gryganskiella Vandepol, Stajich & Bonito, gen. nov. MycoBank No: MB#833857 Etymology: In honor of Andrii Gryanskyi, a Ukrainian-American mycologist, for his contributions in research, training and genomics of fungi in Mucoromycota. Type species: Gryganskiella cystojenkinii (W. Gams & Veenb.-Rijks) Vandepol & Bonito Description: Sporangiospores are smooth and elliptical to cylindrical. Chlamydospores are lightly pigmented, light brown or ochre/orange. While this characteristic is not unique to this genus, it is conserved within this group. Habitat: These species have been reported from agricultural soil & moss in the Netherlands & South America. Species in this study: Gryganskiella cystojenkinii (Gams & Veenb.-Rijks) Vandepol & Bonito comb. nov. MycoBank No: MB#833858 Type specimen: CBS 456.71 [MBT#8054] Basionym: Mortierella cystojenkinii W. Gams & Veenb.-Rijks, Persoonia 9 (1): 137 (1976) 54 Gryganskiella fimbricystis (Gams) Vandepol & Bonito comb. nov. MycoBank No: MB#833859 Type specimen: CBS 943.70 [MBT#8084] Basionym: Mortierella fimbricystis W. Gams, Persoonia 9 (1): 138 (1976) Linnemannia Vandepol & Bonito, gen. nov. MycoBank No: MB#833612 Etymology: In honor of Germaine Linnemann, a German mycologist who contributed many Mortierellaceae species descriptions and early hypotheses on their evolutionary relationships. Type species: Linnemannia hyalina (Harz; Gams) Vandepol & Bonito Description: Nearly all known species of Linnemannia produce sporangiospores, with the exception of L. acrotona. When produced, sporangiospores are usually ellipsoid, but can also be spherical to cylindrical. Production of chlamydospores is irregular between species. When produced, most chlamydospores are various shades of brown. L. amoeboidea makes irregular amoeba-like chlamydospores. The species for which the sexual reproductive mode is known are heterothallic. Habitat: This genus contains some of the most widely distributed Mortierellaceae species. L. elongata, L. hyalina and L. gamsii, are especially common in neutral or calcareous soils. Most of the species in this genus are isolated from soils and are usually associated with plant rhizospheres or decaying plant matter. Species in this study: Linnemannia acrotona (Gams) Vandepol & Bonito comb. nov. MycoBank No: MB#833769 Type specimen: CBS 386.71 [MBT#8005] Basionym: Mortierella acrotona W. Gams, Persoonia 9 (1): 133 (1976) 55 Linnemannia amoeboidea (Gams) Vandepol & Bonito comb. nov. MycoBank No: MB#833770 Type specimen: CBS 889.72 [MBT#8022] Basionym: Mortierella amoeboidea W. Gams, Persoonia 9 (1): 116 (1976) Linnemannia camargensis (Gams & Moreau) Vandepol & Bonito comb. nov. MycoBank No: MB#835745 Type specimen: CBS 221.58 [MBT#18848] Basionym: Mortierella camargensis W. Gams & R. Moreau, Annales Scientifiques Université Besançon 3: 103 (1960) Synonyms: Haplosporangium gracile Nicot (1957) Linnemannia elongata (Linnem.) Vandepol & Bonito comb. nov. MycoBank No: MB#833768 Type specimen: MBT#140592 Basionym: Mortierella elongata Linnem., Pflanzenforschung 23: 43 (1941) Synonyms: Mortierella debilis E. Wolf (1954) Linnemannia exigua (Linnem.) Vandepol & Bonito comb. nov. MycoBank No: MB#835752 Type specimen: MBT#140594 Basionym: Mortierella exigua Linnem., Pflanzenforschung 23: 44 (1941) Synonyms: Mortierella indica B.S. Mehrotra (1960); Mortierella sterilis B.S. Mehrotra & B.R. Mehrotra (1964) Linnemannia gamsii (Milko) Vandepol & Bonito comb. nov. MycoBank No: MB#835747 Type specimen: CBS 749.68 [MBT#8087] Basionym: Mortierella gamsii Milko, Opredelitel mukoralnykh gribov [Key to the identification of Mucorales]: 76 (1974) 56 Synonyms: Mortierella spinosa Linnem. (1936) Linnemannia hyalina (Gams) Vandepol & Bonito comb. nov. MycoBank No: MB#833682 Type specimen: MBT#56360 (Isotype) Basionym: Mortierella hyalina (Harz) W. Gams, Nova Hedwigia 18: 13 (1970) Synonyms: Hydrophora hyalina Harz (1871); Mortierella candelabrum var. minor Grove (1885); Mortierella hygrophila Linnem. (1941); Mortierella hygrophila var. minuta Linnem. (1941) Linnemannia nantahalensis (C.Y. Chien) Vandepol & Bonito comb. nov. MycoBank No: MB#835746 Type specimen: CBS 610.70 [MBT#8154] Basionym: Mortierella nantahalensis C.Y. Chien, Mycologia 63 (4): 826 (1971) Linnemannia schmuckeri (Linnem.) Vandepol & Bonito comb. nov. MycoBank No: MB#835748 Type specimen: MBT#8193 (Syntype) Basionym: Mortierella schmuckeri Linnem., Archiv für Mikrobiologie 30: 263 (1958) Linnemannia sclerotiella (Milko) Vandepol & Bonito comb. nov. MycoBank No: MB#835749 Type specimen: CBS 529.68 [MBT#8195] Basionym: Mortierella sclerotiella Milko, Novosti Sistematiki Nizshikh Rastenii 4: 160 (1967) Linnemannia zychae (Linnem.) Vandepol & Bonito comb. nov. MycoBank No: MB#835753 Type specimen: CBS 316.52 [MBT#8235] Basionym: Mortierella zychae Linnem., Pflanzenforschung 23: 46 (1941) 57 Synonyms: Mortierella brachyrhiza E. Wolf (1954); Mortierella zychae var. japonica J.Y. Lee (1972); Mortierella zychae var. simplex Linnem. (1941) Lunasporangiospora Vandepol & Bonito, gen. nov. MycoBank No: MB#833611 Etymology: luna- (crescent) refers to the lunate sporangiospores unique to the two species in this genus. Type species: Lunasporangiospora chienii (P.M. Kirk) Vandepol & Bonito Description: Sporangiospores are smooth and characteristically lunate. Chlamydospores are terminal and scarce in L. selenospora and absent in L. chienii. Mating and zygospores are unknown in both species. Habitat: Isolates of this genus have been reported from mushroom compost and forest soil from North America, Europe, and Asia. Species in this study: Lunasporangiospora chienii (P.M. Kirk) Vandepol & Bonito, comb. nov. MycoBank No: MB#833681 Type specimen: CBS 124.71 [MBT#8211] Basionym: Mortierella chienii P.M. Kirk, Index Fungorum 2: 1 (2012) Synonyms: Mortierella umbellata C.Y. Chien (1972); Actinomortierella umbellata (C.Y. Chien) Chalab. (1973) Lunasporangiospora selenospora (W. Gams) Vandepol & Bonito, comb. nov. MycoBank No: MB#833724 Type specimen: CBS 811.68 [MBT#8196] Basionym: Mortierella selenospora W. Gams, Persoonia 9 (1): 128 (1976) 58 Necromortierella Vandepol & Bonito, gen. nov. MycoBank No: MB#833725 Etymology: necro- (death) refers to the necrotrophic mycophilic lifestyle of the type species, in that it kills and consumes the cells of other fungi. Type species: Necromortierella dichotoma (Linnem. ex W. Gams) Vandepol & Bonito Description: Sporangiophore narrow, tapering quickly to a narrower apex with irregular dichotomous branching. Sporangiospores are ellipsoidal to cylindrical. Chlamydospores are elongated or irregular. Habitat: N. dichotoma is the only known necrotrophic mycophile (kills fungal cells and feeds saprotrophically on the dead tissue) in Mortierellaceae. This species has only been reported from mouse dung in Germany. Notes: There may be additional species in this genus that were not included in this study. Additional work must be done to determine whether related species are also necrotrophic mycophiles. Species in this study: Necromortierella dichotoma (Gams) Vandepol & Bonito comb. nov. MycoBank No: MB#833726 Type specimen: MBT#8056 (Syntype) Basionym: Mortierella dichotoma W. Gams, Persoonia 9 (1): 128 (1976) Podila Stajich, Vandepol & Bonito, gen. nov. MycoBank No: MB#833766 Etymology: In honor of Gopi Podila (1957-2010), an Indian American biologist who advanced the fields of plant-microbe interactions, plant genetics and biotechnology in bioenergy crops. In particular, Podila researched the genetic basis of the poplar microbiome and metabolome. Type species: Podila minutissima (Tiegh.) Vandepol & Bonito 59 Description: All species produce sporangiospores, though with variable morphologies: globose to fusoid, smooth to spinulose or verrucose. Chlamydospores are absent in some species and scarce or unknown in the others. When known, zygospore morphology ranges from naked to smooth and globose and mating is usually heterothallic, though at least one species is homothallic. Habitat: Species of Podila are frequently isolated from forest and agricultural soil, compost, dung, and municipal waste. P. minutissima has been isolated from Populus roots (Bonito et al. 2016). They have been reported from Europe, New Zealand, and North America. P. minutissima is a semi-saprotrophic mycophile (saprotrophically consumes dead fungal tissue) it is possible that additional species in this genus are also mycophilic/mycoparasitic to some degree (Rudakov, 1978). Species in this study: Podila clonocysits (Gams) Vandepol & Bonito comb. nov. MycoBank No: MB#835720 Type specimen: CBS 357.76 [MBT#8053] Basionym: Mortierella clonocysits W. Gams, Persoonia 9 (1): 132 (1976) Podila epicladia (Gams) Vandepol & Bonito comb. nov. MycoBank No: MB#835721 Type specimen: CBS 355.76 [MBT#8074] Basionym: Mortierella epicladia W. Gams & Emden, Persoonia 9 (1): 133 (1976) Podila epigama (Gams & Domsch) Vandepol & Bonito comb. nov. MycoBank No: MB#835722 Type specimen: CBS 489.70 [MBT#8076] Basionym: Mortierella epigama W. Gams & Domsch, Transactions of the British Mycological Society 58 (1): 11 (1972) 60 Podila horticola (Linnem.) Vandepol & Bonito comb. nov. MycoBank No: MB#835723 Type specimen: MBT#8105 (Syntype) Basionym: Mortierella horticola Linnem., Pflanzenforschung 23: 21 (1941) Podila humilis (Linnem. ex W. Gams) Vandepol & Bonito comb. nov. MycoBank No: MB#835724 Type specimen: MBT#8109 (Syntype) Basionym: Mortierella humilis Linnem. ex W. Gams, Beitrag zu einer Flora der Mucorineae Marburgs, Diss. (1963) Podila minutissima (Tiegh.) Vandepol & Bonito comb. nov. MycoBank No: MB#833767 Type specimen: no type known Basionym: Mortierella minutissima Tiegh., Annales des Sciences Naturelles Botanique 4: 385 (1878) Synonym: Mortierella minutissima var. dubia Linnem. (1941) Podila verticillata (Linnem.) Vandepol & Bonito comb. nov. MycoBank No: MB#835725 Type specimen: MBT#140598 Basionym: Mortierella verticillata Linnem., Pflanzenforschung 23: 22 (1941) Synonyms: Mortierella marburgensis Linnem. (1936); Haplosporangium fasciculatum Nicot (1957); H. attenuatissimum F.J. Chen (1992) Discussion To our knowledge, this study provides the most extensive and in-depth sampling of Mortierellaceae diversity to date, that extends to new isolates from Africa, Australia, and the United States, where several novel species and lineages were discovered. We also included 61 Modicella, sampled from a sporocarp, in the first application of low coverage genome sequencing to large-scale fungal phylogenetic systematics (Petkovits et al. 2011; Smith et al. 2013; Wagner et al. 2013). We further developed and tested a pipeline for identifying non-ribosomal phylogenetic markers. By combining these approaches, we were successful in resolving the phylogeny of Mortierellaceae to provide a phylogenetic-based framework for their taxonomy. There is considerable uncertainty concerning Mortierellaceae species diversity that remains to be sampled (Hibbett & Glotzer, 2011; Nagy et al. 2011). Nagy et al. (2011) estimated the rate of novel species discovery in Mortierellaceae by comparing the diversity represented in sequence repositories to diversity within putatively novel sequences and those of described species. They concluded that most Mortierellaceae diversity was already discovered and they estimated a total of approximately 126 species in the family. Given that 102 of the 125 currently accepted species in Mortierellaceae were described prior to 1980, and only 9 more between 1990 and 2000, this might seem to be a reasonable conclusion (Tables 2.1 & 2.11). However, taking into account that vast regions of the world are still unsampled, and the limited resolution of ITS and/or 28S rDNA regions in metabarcoding diversity studies, this estimate may be low. There are several examples of distinct species of Mortierella that have very similar ITS sequence similarity, e.g. Podila horticola and P. minutissima. The rate of species discovery in Mortierellaceae has increased in the last decade, with at least seven new species being described in the family between 2011 and 2019 from Poland, Japan, Taiwan, and Korea (Hibbett & Glotzer, 2011; Ariyawansa et al. 2015; Li et al. 2016; Table 2.1). Moreover, our sampling efforts in Africa and Australia for this study yielded multiple novel species an entirely novel lineage at the generic level. From our deep sampling efforts in Illinois caves, we recovered 119 isolates. These represented 8 genera and 9 under-represented species, which include isolates of L. amoeboidea and N. dichotoma. These species are rarely isolated and the collection of new strains is inherently valuable to understanding the ecology, genetics, and distribution of these fungi (Gams, 1977). For the purposes of exploring 62 the diversity and distribution of Mortierellaceae, we expect more species to be discovered in undersampled locations such as South America, Africa, and Asia. We found low coverage genome sequencing is a relatively cost-effective means of generating a high-confidence fungal phylogeny. Further, it requires fewer assumptions, and less upstream handling and preparation time than traditional genome sequencing or multi-locus sequence typing, as only a single high quality, high concentration DNA preparation is needed. The approximately 15X sequencing coverage we achieved was sufficient to recover several hundred orthologous genes for our phylogenomic analyses. Occasional misassembly of target loci necessitated mining MGP loci from the raw genome reads, rather than the assembled contigs. Nonetheless, we were still able to detect and recover full length MGP loci from 15 isolates entirely from genome sequences. The LCG approach has been applied successfully in other systems as well, including insects and olive trees, with both low and high quality specimens and genome coverage between 0.5-30X (Olofsson et al. 2019; Zhang et al. 2019). All LCG phylogenomic approaches have relied on first identifying existing phylogenetic markers in assembled whole genome sequence data. Olofsson et al. (2019) built phylogenies with two classical markers and compared these to phylogenies based on SNPs obtained from additional orthologous gene sets. They also demonstrated the capability of an LCG approach to extract phylogenetic information from degraded herbarium specimens with extremely low coverage (<0.5X), which encourages LCG sequencing of fungal herbarium specimens as well (Olofsson et al. 2019). The approach used by Zhang et al. (2019) was more similar to the LCG approach described here, including the breadth of phylogenetic diversity represented in their Hexapoda dataset, but with higher genome coverage than our dataset (20x-30x vs. 15X) and with fewer genomes (21 vs. 73). Non-ribosomal (nuclear) phylogenetic markers should be single-copy genes that are not under selective pressure and contain sufficient sequence variation to make phylogenetic inferences. Identification of nuclear markers has historically been done manually, starting from protein sequence and characteristics, as in the case of RPB1 (Jokerst et al. 1989; Sidow & Thomas, 63 1994). Even with the advent of genome sequencing, discovery and evaluation of novel nuclear markers has been a largely manual process (Blair et al. 2008). There has been at least one other effort to automate the discovery and evaluation of nuclear markers, a program called DIscoMark, which uses a similar approach to the unbiased MGP locus identification method developed here but starting with orthologous genes instead of raw genomes (Deteringet al. 2016). Both approaches are dependent on the availability of high-quality input genomes. In this study, our pipeline did successfully identify single-copy loci, some of which were phylogenetically informative that we used to improve DNA-based species identification. Elongation Factor 1 alpha (EF1ɑ) and RNA polymerase II large subunit (RPB1) have previously been used as phylogenetic markers in Fungi (James et al. 2006; Stockinger et al. 2014). The six MGP markers were sufficient to sort Mortierellaceae species into clades and provide structure at the species level, however, the 6 loci were insufficient to resolve the higher-level organization of clades along the Mortierellaceae backbone. The limited number of high-quality genomes available for the locus selection pipeline made it difficult to screen loci and primers in silico for off-target amplification or gene paralogs prior to in vivo use. Additional reference genomes would also inform the primer design process, reducing primer mismatch, locus bias and off-target amplification. The main trade-off between the LCG and MGP approaches is sampling depth versus breadth. The high capacity of Illumina sequencing platforms meant that there was a minimum sample number needed for the MGP approach to be cost-effective. Therefore, we were able to include “lower priority/higher risk” isolates than in the genome sequencing project, including a high proportion of isolates that could not be identified by ITS sequence data. However, even with multiplex PCRs, there was significantly more sample handling and bench time required for the MGP protocol compared to the LCG. In light of these issues, we suggest that the LCG approach is a superior method for resolving the broad phylogeny of such a diverse lineage. By combining LCG and MGP approaches, we were able to resolve higher-level phylogenetic relationships using 64 the LCG-derived data, while improving sampling depth and breadth with the MGP approach to place taxa and improve diversity sampling within the phylogeny. This study upheld the majority of the modern rDNA clades defined by Petkovits et al. (2011) and Wagner et al. (2013) (Table 2.12). To resolve the polyphyly of Mortierella, we have erected seven novel genera in Mortierellaceae. These include Podila (verticillata-humilis clade), Mortierella (alpina-polycephala clade), and Linnemannia (gamsii clade) (Petkovits et al. 2011; Wagner et al. 2013). However, ITS-clades 1 (selenospora-parvispora), and 5 (strangulata & wolfii) as described by Wagner et al. (2013) are not supported. Lunasporangiospora, Actinomortierella, Gryganskiella, and Necromortierella more closely correspond to the selenospora, wolfii, and parvispora clades as described by Petkovits et al. (2011). The MGP dataset places E. parvispora, originally part of selenospora-parvispora, in the newly erected genus Entomortierella with the retained lignicola clade. The LCG dataset places Actinomortierella species (Petkovits /wolfii) at the base of the tree, apart from Lobosporangium transversale (strangulata clade), which is still near the middle of the phylogeny. The composition of clade 4 (globulifera, angusta, and mutabilis) was retained, although the species were resolved as separate genera, Dissophora and Gamsiella. The monophyletic genus Mortierella has two main subgroups, the previously defined alpina and polycephala clades (Petkovits et al. 2011). These two clades were widely separated in the Bayesian analyses of Petkovits et al. (2011) and distinct groups within clade 6 as defined by Wagner et al. (2013). Some of the new genera described here have loosely conserved ecological niches (Table 2.11). For example, taxa now classified as Entomortierella have almost all been isolated from insect nests or bodies (Gams, 1977; Watanabe et al. 1998). Several members of the re-defined genus Mortierella are known to be mycophilic and/or have been isolated from mushrooms and truffles (Domsch et al. 1980). These associations are not unique to these genera, as demonstrated by Actinomortierella capitata, Actinomortierella aff. ambigua, and Necromortierella dichotoma, but genus-level conservation may represent specialization and evolution of an 65 ancestral trait (Gams, 1977; Macias et al. 2019). While much remains unknown about the ecological function of most Mortierellaceae, these trends inspire some additional confidence in the groupings defined by our phylogenetic analyses. Existing ITS-based species identifications, or lack thereof due to highly similar ITS sequences, are not fully resolved by this study, as this will require the inclusion of type specimens to confidently identify correct ITS classifications. This is most notable in Podila, Mortierella, and Linnemannia due to extensive sampling, high species number, and ITS sequence similarity. Rather, we provide a genus-level framework that will empower future studies to thoroughly resolve individual genera. Conclusions Previous research has estimated that the majority of Mortierellaceae diversity has already been discovered and may reside in culture collections (Nagy et al. 2011). However, our research reveals novel species and genera in both thoroughly sampled and historically undersampled regions, including Michigan, USA and Uganda, respectively. Based on these results, we believe that there is a need for continued geographic sampling efforts to identify new species and to establish the ranges and ecological niches of recognized species of Mortierellaceae, including L. elongata (Ozimek et al. 2018; Liao et al. 2019). While greatly improved by our study, ecological data to accompany sequence data are still scarce for Mortierellaceae. One of the valuable contributions of this work is the curation of reference sequences with updated taxonomy, supported by multiple independent loci, that will be integrated into NCBI and UNITE reference sequence database. These vouchered sequence data could also be used to seed non-ITS reference databases. Together, these data will improve the ability to accurately identify taxa and novel species and thereby improve understanding of the diversity and ecology of these fungi. Further consolidation of global geographic and environmental records of Mortierellaceae isolates would help resolve the range and ecology of these species. 66 We recommend future efforts prioritize sequencing of non-ribosomal markers from type isolates, additional culture collections, and isolates from under-sampled regions. 67 Figures & Tables Figure 2.1 – Divseristy of Mortierellaceae macromorphologies a) Mortierella sp. JL58 on MEA+YE, 11 days; b-d) Mortierella sp. JL29, AP5, and JL1 on MEA+YE, 11 days; e) Mortierella elongata NVP64- on PDA/2+YE, 6 days; f-h) M. alpina NVP153, JL109, and KOD1002 on PDA/2+YE, 6 days; i) M. humilis PMI1414- on PDA/2+YE, 6 days. 68 Figure 2.2 – Common Mortierellaceae spore forms Mortierella elongata NVP64 a) sporangiospores and bent sporangiophores on agar surface; b) intercalary chlamydospore and septate, evacuated hyphae; c) branched sporangiophore bearing sporangiospores; and d) sexual zygospore from heterothallic mating with M. elongata NVP5. Scale bars – a, 100 µm; b, 10 µm; c, 200 µm; d, 20 µm. 69 Figure 2.3 – Media-dependent macromorphology Mortierella sp. aff ambigua JL86, 10 days, on three media a) PDA/2+YE, b) MEA+YE, c) CZA. 70 Figure 2.4 – Maximum likelihood analysis of LCG dataset Maximum likelihood analysis of a concatenated matrix of 109,439 nucleotide characters of protein-coding sequences from 434 genes. Clade colors indicate monophyletic groupings, lines and clade names denote previously defined clades for the purpose of discussion. Node numbers indicate bootstrap support. 71 Figure 2.5 – Unconstrained Maximum Likelihood analysis of the concatenated MGP dataset Taxa are named according to the initial ITS-based species identification and current taxonomy. Clade colors indicate monophyletic groupings according to the proposed taxonomy, lines and names denote previously defined clades. 72 Figure 2.5 (cont’d) 73 Figure 2.5 (cont’d) 74 Figure 2.6 – MrBayes muilt-gene Mortierellaceae phylogeny A Bayesian analysis of the concatenated MGP dataset using a series of partial constraints defined by major nodes in the LCG phylogeny. Clade colors indicate groupings according to the Constrained RAxML MGP phylogeny. 75 Figure 2.6 (cont’d) 76 Figure 2.6 (cont’d) 77 Figure 2.7 – Constrained Maximum Likelihood analysis of the MGP dataset Maximum Likelihood analysis of the concatenated 6-gene MGP dataset composed of 8181 nucleotide characters and constrained by the LCG phylogeny. Taxa are named according to the initial ITS-based species identification and proposed genus-level taxonomy. Clade colors indicate monophyletic groupings according to the proposed taxonomy, lines and names denote previously defined clades for the purpose of discussion. 78 Figure 2.7 (cont’d) 79 Figure 2.7 (cont’d) 80 Table 2.1 – Mortierellaceae species not included in this study A summary of the described species not included in this study, the estimated placement under the proposed taxonomy, the basis for the estimation, and the reference for the original species definition. Current Name Aquamortierella elegans Echinochlamydo- sporium variabile Closest included species by ITS Justification Predicted Genus NCBI BLAST (EU688962) Modicella malleola Modicella reniformis Wagner et al. (2013) Modicella Mortierella alliaceae Sepiachlamydospori um fimbricystis Wagner et al. (2013) Sepiachlamy- dosporium Mortierella angusta = Mortierella polycephala var. angusta = Mortierella simplex Dissophora ornata Wagner et al. (2013) NCBI BLAST (MH858055.1) at 86% Dissophora Mortierella apiculata Mortierella arachnoides Mortierella arcuata 81 Species Description Embree & Indoh, Bulletin of the Torrey Botanical Club 94: 464 (1967) X.Z. Jiang, H.Y. Yu, M.C. Xiang, X.Y. Liu & X.Z. Liu, Fungal Diversity 46: 46 (2011) Harkn., Proceedings of the California Academy of Sciences 1 (8): 280 (1899) Linnem., ZentBl. Bakt. ParasitKde, Abt. 2: 225 (1953) Linnem., Mucorales, eine Beschreibung aller Gattungen und Arten dieser Pilzgruppe: 172 (1969) Linnem., Mucor.- Gatt. Mortierella Coem.: 29 (1941) Marchal, Bull. Soc. R. Bot. Belg. 30(no. 2): 135 (1891) Therry & Thierry, Revue mycol., Toulouse 4(no. 15): 161 (1882) E. Wolf, Zentbl. Bakt. ParasitKde, Abt. II 107: 530 (1954) Table 2.1 (cont’d) Mortierella armillariicola Linnemannia acrotona Wagner et al. (2013) Linnemannia Mortierella baccata Mortierella bainieri Linnemannia exigua Wagner et al. (2013) Linnemannia Mortierella basiparvispora Entomortierella parvispora Wagner et al. (2013) Entomortierella Mortierella biramosa = Mortierella wuyishanensis Linnemannia nantahalensis Wagner et al. (2013) Linnemannia Mortierella calciphila Entomortierella beljakovae Mortierella cephalosporina NCBI BLAST (KT964845.1) at 84% Entomortierella Mortierella claussenii Linnemannia camargensis Wagner et al. (2013) Linnemannia Mortierella cotigans Linnemannia exigua Wagner et al. (2013) Linnemannia Mortierella decipens = Haplosporangium decipiens Mortierella bisporalis Wagner et al. (2013) Mortierella Mortierella delamerensis Mortierella diffluens 82 W. Gams, Persoonia 9 (1): 128 (1976) E. Wolf, Zentbl. Bakt. ParasitKde, Abt. II 107: 530 (1954) Costantin, Bulletin de la Société Mycologique de France 4: 152 (1889) W. Gams & Grinb., Persoonia 9 (1): 130 (1976) Tiegh., Annales des Sciences Naturelles Botanique sér. 6, 1: 110 (1875) F.J. Chen, Mycosystema 5: 57 (1992) Li et al., Fungal Diversity 78: 201 (2016) Chalab., Mikrobiol. Zh. 27: 31 (1965) Linnem., Archiv für Mikrobiologie 30: 265 (1958) Degawa, Mycologia 90: 1040 (1998) Björl., Botaniska Notiser 1936: 126 (1936) Thaxt., Botanical Gazette Crawfordsville 58: 363 (1914) W.Gams in GBIF Secretariat (2019) Sorokin (1873) Table 2.1 (cont’d) Mortierella echinula - Mortierella elasson Dissophora decumbens Mortierella elongatula Sepiachlamydo- sporium fimbricystis NCBI BLAST (MH860124.1) NCBI BLAST (HQ630368.1) at 99% Wagner et al. (2013) NCBI BLAST (NR_111582.1) at 96% Dissophora Sepiachlamy- dosporium Mortierella fatshederae Linnemannia exigua Wagner et al. (2013) Linnemannia Mortierella ficariae Mortierella fimbriata Mortierella fluviae Linnemannia exigua NCBI BLAST (KX227756.1) at 99% Linnemannia Mortierella formicae Entomortierella beljakovae NCBI BLAST (KY793000.1) at 84% Entomortierella Mortierella formicicola Mortierella formosana Entomortierella beljakovae Wagner et al. (2013) Entomortierella Linnemannia gamsii NCBI BLAST (KP744428.1) at 86% Linnemannia Mortierella formosensis Mortierella fusispora 83 Linnem., Zentbl. Bakt. ParasitKde, Abt. II 107: 229 (1953) Sideris & G.E. Paxton, Mycologia 21(4): 176 (1929) W. Gams & Domsch, Persoonia 9(1): 119 (1976) Hyang B. Lee, K. Voigt & T.T.T. Nguyen, in Hyde et al., Fungal Diversity 80: 255 (2016) Therry & Thierry, Revue mycol., Toulouse 4(no. 15): 161 (1882) S.H. Ou, Sinensia, Shanghai 1: 442 (1940) Hyang B. Lee, K. Voigt & T.T.T. Nguyen, Fungal Diversity 80: 255 (2016) Siedlecki, in Hyde et al., Fungal Diversity 87: 222 (2017) D.S. Clark & W. Gams (?) Ariyawansa et al., Fungal Diversity 75: 254 (2015) C.Y.Chien in GBIF Secretariat (2019) Tiegh., Annls Sci. Nat., Bot., sér. 6 4(4): 385 (1878) [1876] Table 2.1 (cont’d) Mortierella gemmifera Entomortierella lignicola Wagner et al. (2013) Entomortierella Mortierella globalpina Thaxteriella minutissima Wagner et al. (2013) Thaxteriella Mortierella hepiali Mortierella heterospora Mortierella histoplasmatoides Linnemannia hyalina Wagner et al. (2013) Linnemannia Mortierella humicola Mortierella humilissima Mortierella hypsicladia Mortierella reticulata NCBI BLAST (MH802523.1) at 93% Mortierella Mortierella insignis Mortierella jenkinii = Mortierella bainieri var. jenkinii Entomortierella parvispora Wagner et al. (2013) Entomortierella Mortierella kuhlmanii Entomortierella echinosphaera Wagner et al. (2013) Entomortierella M. Ellis, Transactions of the British Mycological Society 24: 95 (1940) W. Gams & Veenb.-Rijks, Persoonia 9 (1): 113 (1976) Q.T. Chen & B. Liu, in Chen, Wang & Liu, Journal of Shanxi University, Natural Science 4: 70 (1986) W.Gams in GBIF Secretariat (2019) W. Gams, Boletus 15: 35 (1991) Oudem., Archives Néerlandaises 7: 276 (1902) Pišpek, Acta bot. Inst. bot., Zagreb 4: 99 (1929) Degawa & W. Gams, Stud. Mycol. 50(2): 567 (2004) Linnem., Mucor.- Gatt. Mortierella Coem.: 34 (1941) (A.L. Sm.) Naumov, Opredelitel Mukorovykh (Mucorales): 97 (1935) W. Gams, Persoonia 9 (1): 122 (1976) 84 Table 2.1 (cont’d) Mortierella longigemmata Linnemannia hyalina NCBI BLAST (JX976055.1) at 94% Linnemannia Mortierella macrocystis = Mortierella microspora var. macrocystis Mortierella macrocystopsis Mortierella mairei Mortierella mehrotraensis Mortierella microspora Mortierella microzygospora Mortierella mundensis Mortierella niveovelutina Sepiachlamydo- sporium cystojenkinii Sepiachlamyd- osporium cystojenkinii Wagner et al. (2013) Sepiachlamy- dosporium Wagner et al. (2013) Sepiachlamy- dosporium - Wagner et al. (2013) NCBI BLAST (MH862681.1) Mortierella oliogospora Mortierella polycephala Wagner et al. (2013) Mortierella Mortierella ovalispora Mortierella paraensis Entomortierella beljakovae Wagner et al. (2013) Entomortierella Linnem., Mucorales, eine Beschreibung aller Gattungen und Arten dieser Pilzgruppe: 199 (1969) W. Gams, Nova Hedwigia 3: 69 (1961) W. Gams & Carreiro, Studies in Mycology 31: 85 (1989) Vuill., Bull. Soc. mycol. Fr. 34(1- 2): 46 (1918) Baijal, Sydowia 21: 269 (1968) [1967] E. Wolf, Zentbl. Bakt. ParasitKde, Abt. II 107: 528 (1954) Degawa, Mycologia 90: 1041 (1998) Linnem., Mucor.- Gatt. Mortierella Coem.: 48 (1941) Cif. & Ashford, Porto Rico J. Publ. Health Trop. Med. 5(2): 142 (1929) Björl., Botaniska Notiser 1936: 121 (1936) Chalab., Mikrobiol. Zh. 27: 28 (1965) Pfenning & W. Gams, Mycotaxon 46: 287 (1993) 85 Table 2.1 (cont’d) Mortierella parazychae Mortierella pilulifera Mortierella pisiformis Entomortierella echinosphaera NCBI BLAST (KP744416.1) at 87% Entomortierella Mortierella plectoconfusa Mortierella pseudozygospora - Wagner et al. (2013) NCBI BLAST (JX975880.1) Mortierella pulchella Sepiachlamydo- sporium fimbricystis Wagner et al. (2013) Sepiachlamy- dosporium Mortierella pusilla = Mortierella nodosa = Mortierella stricta Mortierella pygmaea Mortierella repens Mortierella rhizogena Mortierella rostafinskii - Wagner et al. (2013) NCBI BLAST (JX975885.1) 86 Degawa, in Degawa & Tokumasu, Mycologia 90(6): 1041 (1998) Tiegh., Annls Sci. Nat., Bot., sér. 6 1: 105 (1875) H.M. Ho, S.F. Wei & K. Voigt, in Ariyawansa et al., Fungal Diversity 75: 252 (2015) E. Wolf, Zentbl. Bakt. ParasitKde, Abt. II 107: 527 (1954) W. Gams & Carreiro, Studies in Mycology 31: 87 (1989) W. Gams & Domsch, Persoonia 9(1): 119 (1976) Oudem., Arch. néerl. Sci., Sér. 2 7: 277 (1902) E. Wolf, Zentbl. Bakt. ParasitKde, Abt. II 107: 531 (1954) Chalab., Mikrobiol. Zh. 27: 30 (1965) A.L. Sm., J. Bot., Lond. 36: 180 (1898) Dasz., Bull. Soc. bot. Genève, 2 sér. 4: 310 (1912) Bref., Untersuchungen aus dem Gesammtgebiete der Mykologie 4: 81 (1881) Table 2.1 (cont’d) Mortierella sarnyensis Linnemannia nantahalensis Wagner et al. (2013) Linnemannia Mortierella signyensis Linnemannia schmuckeri NCBI BLAST (JQ693160.1) at 98% Linnemannia Mortierella simplex (= Mortierella angusta) Dissophora ornata Wagner et al. (2013) NCBI BLAST (JX975870.1) at 86% Dissophora Mortierella sossauensis Necromyco- mortierella dichotoma Wagner et al. (2013) Necromyco- mortierella Mortierella strangulata - Mortierella striospora Mortierella subtilissima Mortierella sugadairana Mortierella thereuopodae - Milko, Novosti Sistematiki Nizshikh Rastenii 10: 87 (1973) K. Voigt, P.M. Kirk & Bridge, in Bridge & Hughes, Index Fungorum 7: 1 (2012) Tiegh. & G. Le Monn., Annales des Sciences Naturelles Botanique 17: 350 (1873) E. Wolf, Zentralblatt für Bakteriologie und Parasitenkunde, Abteilung 2 107: 533 (1954) Tiegh., Annales des Sciences Naturelles Botanique sér. 6, 1: 102 (1875) K.B. Deshp. & Mantri, Mycopath. Mycol. appl. 20: 223 (1963) Oudem., in Oudemans & Koning, Arch. néerl. Sci., Sér. 2 7: 277 (1902) Y. Takash., Degawa & K. Narisawa, Mycoscience 59(3): 201 (2018) Linnem., Mucorales (Lehre): 199 (1969) Wagner et al. (2013) NCBI BLAST (JX975997.1) NCBI BLAST (MF510830.1) Linnemannia hyalina NCBI BLAST (AB862879.1) at 83% Linnemannia 87 Table 2.1 (cont’d) Mortierella tirolensis Mortierella traversoana Mortierella tsukubaensis Mortierella tuberosa Mortierella verrucosa Linnemannia hyalina NCBI BLAST (MH878485.1) at 98% Linnemannia Mortierella zonata Linnemannia hyalina Wagner et al. (2013) Linnemannia Linnem., Mucorales (Lehre): 192 (1969) Peyronel [as 'traversiana'], I germi astmosferici dei fungi con micelio, Diss. (Padova): 17 (1913) Ts. Watan., in Watanabe, Watanabe, Fukatsu & Kurane, Mycol. Res. 105(4): 506 (2001) Tiegh., Annls Sci. Nat., Bot., sér. 6 1: 106 (1875) Linnem., Zentbl. Bakt. ParasitKde, Abt. II 107: 227 (1953) Linnem., Flora (Regensburg) 130: 210 (1936) 88 Table 2.2 – Isolate metadata The substrate, geographic origin, collector, collection year, vouchered by, and synonymous isolate identification numbers known Status Isolated From Geographic Origin Year Collected By Vouchered By Alternate IDs M. Carreiro NRRL CBS 592.88 for each isolate used in this study. Isolate ID Preliminary Identification NRRL_22416 Dissophora decumbens NRRL_22417 Dissophora ornata NRRL_2682 NRRL_3175 NRRL_A- 10739 NRRL_A- 10996 Haplosporangium sp. Haplosporangium sp. Haplosporangium sp. Haplosporangium sp. FSU9682 Lichtheimia corymbifera plant, ground-up Quercus (Oak) and Acer (Maple) leaves USA: Rhode Island soil, in mountain forest under Weinmannia, Clusia etc., alt. 3100 m. Dog dung Colombia: Cordillera Central, Cauca en Huila, Parque Nacional del Puracé USA: Palo Verde, California Greenhouse soil Pack rat dung USA: Vidal Junction, California T. van der Hammen & R. Jaramillo Soil Afghanistan J.J. Curtis 89 NRRL NRRL NRRL NRRL CBS or NRRL CBS 348.77, IMI 287528 NRRL A- 7647 NRRL A- 13808 CBS 429.75, ATCC 46771, NRRL 2981 Table 2.2 (cont’d) NRRL_3116 Lobosporangium transversale ISOTYPE Soil beneath Purshia tridentata USA: Virginia City, Nevada ATCC 16960, CBS 357.67, IMI 130776, NRRL A- 12901, VKM F- 1384 ATCC 18036 NRRL NRRL NRRL_5525 MES-2146 C-ARSO24-5 Lobosporangium transversale Modicella reniformis Mortierella acrotona 14Py14W Mortierella alpina AD021 Mortierella alpina AD062 Mortierella alpina AD071 Mortierella alpina AD072 Mortierella alpina B6842 Mortierella alpina Soil Soil Soil USA: Texas Argentina USA: Arkansas USA: Illinois Matthew Smith Martin Chilvers Martin Chilvers Rhizosphere of Pinus sp. USA: Bryce Canyon, UT Rhizosphere/Roots of Spruce and Pine USA: Sleepy Hollow State Park, Laingsburg, MI 2015 Alessandro Desirò 2015 Alessandro Desirò Rhizosphere/Roots of Spruce and Pine Rhizosphere/Roots of Spruce and Pine USA: Sleepy Hollow State Park, Laingsburg, MI USA: Sleepy Hollow State Park, Laingsburg, MI 2015 Alessandro Desirò 2015 Alessandro Desirò human leg lesion USA: Minnesota 2011 Andrii Gryganskyi & Greg Bonito 90 Martin Chilvers Martin Chilvers Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Table 2.2 (cont’d) C-ARSO21-9 Mortierella alpina C-ILSO26-18 Mortierella alpina C-INSO22-22 Mortierella alpina CK1227 Mortierella alpina CK1249 Mortierella alpina CK1268 Mortierella alpina CK202 Mortierella alpina C-MICO24- 19 Mortierella alpina GBAus31 Mortierella alpina KOD1002 Mortierella alpina KOD1005 Mortierella alpina KOD1012 Mortierella alpina KOD1016 Mortierella alpina KOD1017 Mortierella alpina KOD1018 Mortierella alpina Soil Soil Soil USA: Arkansas USA: Illinois Martin Chilvers Martin Chilvers USA: Indiana Martin Chilvers biological soil crust USA: Utah 2014 C. Kuske biological soil crust USA: Utah 2014 C. Kuske biological soil crust USA: Utah 2014 C. Kuske biological soil crust USA: Utah 2014 C. Kuske Soil Soil USA: Michigan Martin Chilvers Australia Gregory Bonito Cave wall USA: Illinois 2013 Andrew Miller Boot Mud USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller 91 Martin Chilvers Martin Chilvers Martin Chilvers Andrea Porras- Alfaro Andrea Porras- Alfaro Andrea Porras- Alfaro Andrea Porras- Alfaro Martin Chilvers Gregory Bonito Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller 2155-1 2178-1 2203-2 2242-2 2242-3 2244-1 Table 2.2 (cont’d) KOD1019 Mortierella alpina KOD1021 Mortierella alpina KOD1022 Mortierella alpina KOD1026 Mortierella alpina KOD1027 Mortierella alpina KOD1028 Mortierella alpina KOD1045 Mortierella alpina KOD1046 Mortierella alpina KOD1047 Mortierella alpina KOD1054 Mortierella alpina KOD1055 Mortierella alpina KOD957 Mortierella alpina KOD958 Mortierella alpina KOD967 Mortierella alpina KOD983 Mortierella alpina KOD990 Mortierella alpina KOD994 Mortierella alpina Cave wall USA: Illinois 2013 Andrew Miller Soil Soil Bat Soil Soil USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Leaf Litter USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2012 Andrew Miller Soil Soil USA: Illinois 2012 Andrew Miller USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2013 Andrew Miller 92 Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller 2244-3 2253-2 2253-3 2305-1 2313-3 2327-3 2624-1 2642-2 2645-1 1064-11 1210-11 1650-1 1690-1 1908-1 1979-2 2052-2 2093-2 Soil Soil USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Soil Cropfield Soil, CR700 Fescue hay Truffle Fruiting Body Soil fungivorous millipedes USA: North Dakota USA: Kilbourne, Illinois USA: San Nicolas Island, California USA: Kentucky USA: Traverse City, Michigan USA: Ouachita Mountains, Arkansas Italy 2015 Natalie Vandepol 2015 Natalie Vandepol 2011 Andrii Gryganskyi Martin Chilvers D.T. Wicklow NRRL G. Linnemann NRRL Andrew Miller Andrew Miller Andrew Miller Martin Chilvers NRRL NRRL Gregory Bonito Gregory Bonito Table 2.2 (cont’d) KOD995 Mortierella alpina KOD998 Mortierella alpina KOD999 Mortierella alpina NDSO1-48 Mortierella alpina NRRL_62971 Mortierella alpina NRRL_6302 Mortierella alpina NRRL_66262 Mortierella alpina NRRL_A- 15043 Mortierella alpina NVP17b Mortierella alpina NVP47 Mortierella alpina BC1065 Mortierella ambigua NRRL_28271 KOD1051 KOD1053 KOD1030 NRRL_28267 Mortierella ambigua Mortierella amoeboidea Mortierella amoeboidea Mortierella antarctica Mortierella antarctica U. Schulz, Bayer NRRL Cave wall USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Andrew Miller Andrew Miller Andrew Miller ISOTYPE Soil, rock crevice near glacier Antarctica: Hallett Station 1966 O.L. Lange NRRL 93 2093-3 2136-1 2147-2 ENDO 3847 CBS 250.53 NRRL A- 10995 CBS 450.88 1031-12 1059-11 2344-1 CBS 609.70 Soil Antarctica: Hallett Station 1966 G. Linnemann & O.L. Lange CBS Aspergillus flavus sclerotium buried in soil USA: Tifton, Georgia 1996 DT Wicklow NRRL Soil USA: Illinois 2013 Andrew Miller Rotted Populus log with dung pellets mixed with litter Soil under sugar maple tree USA: Gull Lake, Michigan USA: Massachusetts Andrew Miller NRRL NRRL NRRL Table 2.2 (cont’d) NVP157 Mortierella antarctica NRRL_25716 Mortierella aplina KOD1040 NRRL_2493 Mortierella beljakovae Mortierella bisporalis NRRL_A- 12553 NRRL_2610 Mortierella bisporalis Mortierella camargensis NRRL_28260 Mortierella camargensis WISO4-30 Mortierella camargensis NRRL_22892 Mortierella capitata 2448-3 NRRL A- 7266 CBS 221.58 NRRL A- 12039, CBS 648.68 CBS 648.68, NRRL A- 12039 ATCC 22481, CBS 124.71, IMI 158112, NRRL A- 18233 ISOTYPE Sandy soil Soil ISOTYPE of M. forest soil vesiculosa France: Bois de Rièges, Camargue USA: Wisconsin India: Rishikesh 1951 J. Nicot NRRL Martin Chilvers Martin Chilvers NRRL B.S. Mehrotra NRRL NRRL_28257 Mortierella capitata Forest soil India NRRL_5217 Mortierella chienii M. Forest soil umbellata TYPE of USA: Athens, Georgia 1970 C.-Y. Chien NRRL 94 Table 2.2 (cont’d) AD033 NRRL_2769 Mortierella chlamydospora Mortierella chlamydospora Soil NRRL_2760 Mortierella claussenii SYNTYPE Soil under Castanea sativa, pH 4.7, alt. 300 m. Switzerland: Ticino, Cavigliano, Centovalli USA: East Lansing, MI 2015 Alessandro Desirò, Shelby Hughey Gregory Bonito NRRL G. Linnemann NRRL ATCC 42541 CBS 294.59, NRRL A- 16564, NRRL A- 9140 2148-1 1040-1 2379-1 2395-1 2104-1 IMI 242503, CBS H- 7365 (holotype); CBS H- 7366 (isotype) KOD1000 KOD947 CBS456.71 KOD1035 KOD1036 KOD996 Mortierella clonocystis Mortierella clonocystis Mortierella cystojenkinii Mortierella dichotoma Mortierella dichotoma Mortierella dichotoma Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2012 Andrew Miller Andrew Miller Andrew Miller TYPE Soil Netherlands: Wageningen J.W. Veenbaas- Rijks CBS Soil Bat USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Andrew Miller Andrew Miller Andrew Miller CBS575.75 Mortierella echinosphaera HOLOTYPE Begonia Netherlands: Aalsmeer A.J. van der Plaats-Niterink CBS AD022 AD035 Mortierella elongata Mortierella elongata Rhizosphere of Pine Soil USA: Bryce Canyon, UT USA: Seattle, WA 2015 Alessandro Desirò 2015 Alessandro Desirò, Shelby Hughey Gregory Bonito Gregory Bonito 95 Table 2.2 (cont’d) AD050 AD093 AG77 C-ARSO25- 24 C-MISO21- 18 GBAus21 GBAus23 GBAus24 GBAus25 GBAus32 GBAus33 GBAus34 GBAus36 GBAus37 GBAus38 Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Rhizosphere of poplar Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil USA: Kellogg Biological Station, KBS, Michigan USA: Coatesville, PA USA: Duke Forest, Korstian Div., North Carolina USA: Arkansas Martin Chilvers USA: Michigan Martin Chilvers Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Australia Australia Australia Australia Australia Australia Australia Australia Australia Australia 96 2015 Alessandro Desirò, Gian Maria Niccolò Benucci Gregory Bonito 2015 Alessandro Desirò, Andrii Griganski, Zhen Hao Gregory Bonito Gregory Bonito Martin Chilvers Martin Chilvers Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Soil Soil Soil Soil Australia USA: Iowa USA: Illinois Gregory Bonito Martin Chilvers Martin Chilvers USA: Indiana Martin Chilvers Boot Mud USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller Table 2.2 (cont’d) GBAus40 IASO10-42- 45rt ILSO2-38 INSO1-46B2 KOD1006 KOD1007 KOD980 KOD981 KOD982 KOD984 KOD993 NRRL_5513 NVP112 NVP113 NVP123 NVP128 Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Gregory Bonito Martin Chilvers Martin Chilvers Martin Chilvers Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller 2179-1 2184-3 1976-3 1976-4 1979-1 1979-3 2089-1 ATCC 42661, CBS 121.71 USA: Monroe, Georgia C.-Y. Chien NRRL Uganda 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito 97 Table 2.2 (cont’d) NVP156 NVP4 NVP5 NVP64 NVP65 NVP66 NVP67 NVP71 NVP79 NVP90 WISO4-29 AD058 KOD1059 NRRL_5512 Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella epicladia Mortierella epicladia Mortierella epigama Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Uganda 2016 Natalie Vandepol USA: Hart, Michigan USA: Hart, Michigan USA: Jackson, Michigan USA: Jackson, Michigan USA: Grand Junction, Michigan USA: Grand Junction, Michigan USA: Brighton, Michigan USA: Jackson, Michigan 2015 Natalie Vandepol 2015 Natalie Vandepol 2015 Natalie Vandepol 2015 Natalie Vandepol 2015 Natalie Vandepol 2015 Natalie Vandepol 2015 Natalie Vandepol 2015 Natalie Vandepol USA: Michigan 2015 Natalie Vandepol USA: Wisconsin USA: Sleepy Hollow State Park, Laingsburg, MI Martin Chilvers 2015 Alessandro Desirò Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Martin Chilvers Gregory Bonito Andrew Miller Rhizosphere/Roots of Spruce and Pine Leaf Litter USA: Illinois 2012 Andrew Miller ISOTYPE Composted refuse Germany K.H. Domsch NRRL 98 1274-13 ATCC 24027, CBS 489.70 Table 2.2 (cont’d) NRRL_28262 KOD991 Mortierella exigua Mortierella fimbricystis 14Py25W Mortierella gamsii AD045 Mortierella gamsii AD070 Mortierella gamsii C-INSO22-17 Mortierella gamsii C-MNSO24- 13 Mortierella gamsii GBAus22 Mortierella gamsii KOD1032 Mortierella gamsii KOD1034 Mortierella gamsii NVP60 Mortierella gamsii NVP61 Mortierella gamsii NRRL_66264 Mortierella geracilis AD054 Mortierella globulifera Wheat field soil Germany: Kiel- Kitzeberg W. Gams Procyon Latrine USA: Illinois 2013 Andrew Miller Soil USA: Illinois Martin Chilvers Rhizosphere/Roots of Spruce, Pine and Oak Rhizosphere/Roots of Spruce and Pine USA: Lake Lansing, East Lansing, MI USA: Sleepy Hollow State Park, Laingsburg, MI 2015 Alessandro Desirò 2015 Alessandro Desirò Soil Soil Soil USA: Indiana Martin Chilvers USA: Minnesota Australia Martin Chilvers Gregory Bonito Cave wall USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller Soil Soil Soil Pyrenomycete on wood Rhizosphere/Roots of Spruce and Pine USA: Cassopolis, Michigan USA: Cassopolis, Michigan USA: Massachusetts USA: Sleepy Hollow State Park, Laingsburg, MI 2015 Natalie Vandepol 2015 Natalie Vandepol NRRL Andrew Miller Martin Chilvers Gregory Bonito Gregory Bonito Martin Chilvers Martin Chilvers Gregory Bonito Andrew Miller Andrew Miller Gregory Bonito Gregory Bonito NRRL CBS 870.68 2063-1 2345-2 2348-3 NRRL A- 12637 2015 Alessandro Desirò Gregory Bonito 99 Table 2.2 (cont’d) REB-010B Mortierella globulifera AD008 AD009 AD012 AD013 AD055 CK413 MICO2-9 Mortierella horticola Mortierella horticola Mortierella horticola Mortierella horticola Mortierella horticola Mortierella horticola Mortierella horticola REB-025A Mortierella horticola KOD1050 PMI1414 Mortierella humilis Mortierella humilis Soil Rhizosphere of Allisonia sp. Rhizosphere of Allisonia sp. Rhizosphere of Allisonia sp. Rhizosphere of Allisonia sp. Rhizosphere/Roots of Spruce and Pine USA: Loblolly Pine Plantation, Duke Forest, North Carolina New Zealand: Kelly Creek, South Island New Zealand: Kelly Creek, South Island New Zealand: Kelly Creek, South Island New Zealand: Kelly Creek, South Island USA: Sleepy Hollow State Park, Laingsburg, MI 2013 C. Kuske 2015 Alessandro Desirò 2015 Alessandro Desirò 2015 Alessandro Desirò 2015 Alessandro Desirò 2015 Alessandro Desirò biological soil crust USA: Utah 2014 C. Kuske Soil Soil USA: Michigan Martin Chilvers USA: Loblolly Pine Plantation, Duke Forest, North Carolina 2013 C. Kuske Cave wall USA: Illinois 2012 Andrew Miller Soil USA: Massachusetts 2009 Brantlee Sprakes- Richter 100 Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Andrea Porras- Alfaro Martin Chilvers Gregory Bonito Andrew Miller Gregory Bonito 1023-11 Table 2.2 (cont’d) AD068 JES103 KOD1020 KOD1023 KOD1037 KOD1067 KOD1068 KOD949 KOD965 NRRL_2591 Mortierella hyalina Mortierella hyalina Mortierella hyalina Mortierella hyalina Mortierella hyalina Mortierella hyalina Mortierella hyalina Mortierella hyalina Mortierella hyalina Mortierella hyalina NRRL_6427 Mortierella hyalina NRRL_A- 12040 Mortierella hyalina NRRL_5248 Mortierella indohii Rhizosphere/Roots of Spruce and Pine USA: Sleepy Hollow State Park, Laingsburg, MI 2015 Alessandro Desirò Soil USA: Illinois 2013 Andrew Miller Woody Debris USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2012 Andrew Miller Woody Debris USA: Illinois 2012 Andrew Miller Procyon Latrine USA: Illinois 2012 Andrew Miller Soil USA: Illinois 2013 Andrew Miller Sewage Gregory Bonito Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller NRRL Hypoxylon deustum soil Dung USA: Schoharie County, New York 1969 C.T. Rogerson NRRL India NRRL USA: Athens, Georgia 1971 C.-Y. Chien NRRL 101 2246-1 2262-1 2429-1 1643-11 1670-12 1145-2 1898-2 NRRL A- 7162 ATCC 42665, CBS 100563, C.T.R. 69- 229, NRRL A-17771 CBS 650.68 CBS 460.75, IMI 242505 Table 2.2 (cont’d) NRRL_2525 NRRL_6425 AD034 AD041 Mortierella lignicola Mortierella lignicola Mortierella minutissima Mortierella minutissima AD051 Mortierella minutissima AD065 Mortierella minutissima AD069 Mortierella minutissima AD077A KOD944 KOD959 Mortierella minutissima Mortierella minutissima Mortierella minutissima NRRL_6424 Mortierella minutissima Soil Soil NRRL NRRL NRRL A- 16362 NRRL A- 16560, ATCC 42664 2015 Alessandro Desirò & Shelby Hughey Gregory Bonito Rhizosphere/Roots of Spruce, Pine and Oak Rhizosphere/Roots of Spruce and Pine Rhizosphere/Roots of Spruce and Pine Rhizosphere/Roots of Spruce and Pine Rhizosphere/Roots of Spruce and Pine USA: East Lansing, MI USA: Lake Lansing, East Lansing, MI USA: Sleepy Hollow State Park, Laingsburg, MI USA: Sleepy Hollow State Park, Laingsburg, MI USA: Sleepy Hollow State Park, Laingsburg, MI USA: Sleepy Hollow State Park, Laingsburg, MI 2015 Alessandro Desirò 2015 Alessandro Desirò 2015 Alessandro Desirò 2015 Alessandro Desirò 2015 Alessandro Desirò Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Andrew Miller Andrew Miller 1029-1 1695-1 CBS 226.35, NRRL A- 16546 Cave wall USA: Illinois 2012 Andrew Miller USA: Illinois 2012 Andrew Miller Germany G. Linnemann NRRL 102 2015 Natalie Vandepol Gregory Bonito Table 2.2 (cont’d) NVP1 Mortierella minutissima NRRL_6456 Mortierella multidivaricata RSA2512 AD085 Mortierella multidivaricata Mortierella nantahalensis Soil ISOTYPE decaying stump Soil NRRL_5842 Mortierella nantahalensis ISOTYPE Soil USA: Cincinnati, Ohio Russia: Sokolniki Park, Moskva NRRL USA: Coatesville, PA 2015 Alessandro Desirò, Andrii Griganski, & Zhen Hao Gregory Bonito USA: Joyce Kilmer Memorial Forest, Nantahala National Forest, North Carolina 1970 C.-Y. Chien NRRL CBS 227.78, IMI 236322, RSA 2152 ATCC 22480, CBS 610.70, IMI 158113, NRRL 5216, NRRL A- 18051 AD039 KOD1056 KOD1061 KOD1062 KOD1069 NRRL_2942 Mortierella parvispora Mortierella parvispora Mortierella parvispora Mortierella parvispora Mortierella parvispora Mortierella parvispora Rhizosphere/Roots of Spruce, Pine and Oak USA: Lake Lansing, East Lansing, MI 2015 Alessandro Desirò Gregory Bonito Soil Bat Bat USA: Illinois 2012 Andrew Miller USA: Illinois 2012 Andrew Miller USA: Illinois 2012 Andrew Miller Boot Mud USA: Illinois 2012 Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller NRRL 1240-11 1422-11 1455-11 1777-12 NRRL A- 10895 103 Table 2.2 (cont’d) KOD1052 KOD948 KOD968 KOD975 NRRL_22890 NRRL_22891 NRRL_28261 MISO4-46 Mortierella polycephala Mortierella polycephala Mortierella polycephala Mortierella polycephala Mortierella polycephala Mortierella polycephala Mortierella reticulata Mortierella rishikesha Soil Soil Soil Soil USA: Illinois 2012 Andrew Miller USA: Illinois 2012 Andrew Miller USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller UK Andrew Miller Andrew Miller Andrew Miller Andrew Miller NRRL NRRL 1033-12 1044-1 1913-1 1948-3 NRRL A- 18178 NRRL A- 18179 CBS 859.68 Soil USA: Michigan Martin Chilvers Martin Chilvers M. Turner NRRL NRRL_2761 Mortierella schmuckeri SYNTYPE Soil under Opuntia sp., pH 6.7 Mexico: Queretaro G. Linnemann NRRL ATCC 42658, CBS 295.59, NRRL A- 16570, NRRL A- 9141, NRRL 6426 104 Table 2.2 (cont’d) NRRL_6426 Mortierella schmuckeri SYNTYPE Soil under Opuntia sp., pH 6.7 Mexico: Queretaro G. Linnemann NRRL NRRL_5841 Mortierella sclerotiella ISOTYPE Mouse dung Ukraine NRRL ATCC 42658, CBS 295.59, NRRL 2761, NRRL A- 16570, NRRL A- 9141 ATCC 18732, CBS 529.68, IMI 133978, VKM F- 1099 CBS811.68 Mortierella selenospora TYPE mushroom compost with Entomophthora coronata & Aphanocladium album Netherlands: Horst 1968 Proefstation v.d. Champignoncultuur CBS KOD1015 Mortierella selenospora 14Py07W Mortierella sp. 14Py31W Mortierella sp. 14Py45W Mortierella sp. 14UC Mortierella sp. AD010 Mortierella sp. Cave wall USA: Illinois 2013 Andrew Miller Soil Soil Soil Rhizosphere of Allisonia sp. USA: Illinois USA: Illinois USA: Illinois New Zealand: Kelly Creek, South Island 105 Martin Chilvers Martin Chilvers Martin Chilvers 2015 Alessandro Desirò Andrew Miller Martin Chilvers Martin Chilvers Martin Chilvers Gregory Bonito 2229-1 Table 2.2 (cont’d) AD011 Mortierella sp. AD014 Mortierella sp. AD031 Mortierella sp. AD032 Mortierella sp. AD060 Mortierella sp. AD078 Mortierella sp. AD084 Mortierella sp. AD094 Mortierella sp. Rhizosphere of Allisonia sp. Rhizosphere of Allisonia sp. Soil Soil Rhizosphere/Roots of Spruce and Pine Soil Soil Soil New Zealand: Kelly Creek, South Island New Zealand: Kelly Creek, South Island USA: Belleville- Woods, MI USA: Chandler Crossing, MI USA: Sleepy Hollow State Park, Laingsburg, MI USA: Coatesville, PA USA: Coatesville, PA USA: Coatesville, PA GBAus27B Mortierella sp. TYPE Soil GBAus30 Mortierella sp. GBAus35 Mortierella sp. GBAus39 Mortierella sp. GBAus41 Mortierella sp. Soil Soil Soil Soil Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Australia Australia Australia Australia Australia 106 2015 Alessandro Desirò 2015 Alessandro Desirò Gregory Bonito Gregory Bonito 2015 Alessandro Desirò, Shelby Hughey Gregory Bonito 2015 Alessandro Desirò, Shelby Hughey Gregory Bonito 2015 Alessandro Desirò 2015 Alessandro Desirò, Andrii Griganski, Zhen Hao Alessandro Desirò, Andrii Griganski, Zhen Hao Alessandro Desirò, Andrii Griganski, Zhen Hao 2015 2015 Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Table 2.2 (cont’d) GBAus42 Mortierella sp. GBAus43 Mortierella sp. KOD1001 Mortierella sp. KOD1003 Mortierella sp. KOD1004 Mortierella sp. KOD1008 Mortierella sp. KOD1009 Mortierella sp. KOD1010 Mortierella sp. KOD1013 Mortierella sp. KOD1014 Mortierella sp. KOD1024 Mortierella sp. KOD1025 Mortierella sp. KOD1029 Mortierella sp. KOD1033 Mortierella sp. KOD1038 Mortierella sp. KOD1039 Mortierella sp. KOD1041 Mortierella sp. Soil Soil Australia Australia Gregory Bonito Gregory Bonito Cave wall USA: Illinois 2013 Andrew Miller Woody Debris USA: Illinois 2013 Andrew Miller Leaf Litter USA: Illinois 2013 Andrew Miller Soil Bat USA: Illinois 2013 Andrew Miller USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2013 Andrew Miller Boot Mud USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Woody Debris USA: Illinois 2013 Andrew Miller Gregory Bonito Gregory Bonito Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller 2148-2 2159-1 2166-1 2188-1 2192-1 2200-1 2215-1 2217-1 2272-1 2283-2 2339-1 2348-1 2429-3 2430-1 2474-1 107 Table 2.2 (cont’d) KOD1042 Mortierella sp. KOD1043 Mortierella sp. KOD1044 Mortierella sp. KOD1048 Mortierella sp. KOD1049 Mortierella sp. KOD1057 Mortierella sp. KOD1063 Mortierella sp. KOD1064 Mortierella sp. KOD1065 Mortierella sp. KOD943 Mortierella sp. KOD945 Mortierella sp. KOD950 Mortierella sp. KOD951 Mortierella sp. KOD954 Mortierella sp. KOD955 Mortierella sp. KOD956 Mortierella sp. KOD960 Mortierella sp. Woody Debris USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Bat Bat USA: Illinois 2012 Andrew Miller USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2012 Andrew Miller Bat Soil USA: Illinois 2012 Andrew Miller USA: Illinois 2012 Andrew Miller Leaf Litter USA: Illinois 2012 Andrew Miller Leaf Litter USA: Illinois 2012 Andrew Miller Soil Soil USA: Illinois 2012 Andrew Miller USA: Illinois 2012 Andrew Miller Cave wall USA: Illinois 2012 Andrew Miller Soil USA: Illinois 2012 Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller 2474-2 2511-1 2548-1 1012-11 1012-13 1252-11 1518-11 1518-13 1562-12 1014-2 1033-2 1274-2 1274-3 1479-3 1550-1 1611-3 1695-2 108 Table 2.2 (cont’d) KOD963 Mortierella sp. KOD964 Mortierella sp. KOD969 Mortierella sp. KOD971 Mortierella sp. KOD972 Mortierella sp. KOD979 Mortierella sp. KOD988 Mortierella sp. KOD989 Mortierella sp. KOD992 Mortierella sp. NRRL_1458 Mortierella sp. NRRL_1617 Mortierella sp. NRRL_22995 Mortierella sp. NRRL_25721 Mortierella sp. NRRL_A- 12867 Mortierella sp. NVP103 Mortierella sp. Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2013 Andrew Miller Cave wall USA: Illinois 2013 Andrew Miller Soil USA: Illinois 2013 Andrew Miller Woody Debris USA: Illinois 2013 Andrew Miller Plant leaf Sclerotium of Aspergillus flavus buried in cornfield soil Aspergillus flavus sclerotium buried in field soil Soil Soil USA: IRVSF, Kilbourne, Illinois USA: IRVSF, Kilbourne, Illinois USA: Austin, Texas Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller Andrew Miller NRRL NRRL NRRL Gregory Bonito 1894-2 1897-1 1922-3 1929-1 1930-1 1976-1 2035-1 2039-3 2066-3 ATCC 56653, Blakeslee C1066 1994 DT Wicklow NRRL 1996 DT Wicklow NRRL Uganda 2016 Natalie Vandepol 109 Table 2.2 (cont’d) NVP105 Mortierella sp. NVP106 Mortierella sp. NVP125 Mortierella sp. NVP130 Mortierella sp. NVP131 Mortierella sp. NVP132 Mortierella sp. NVP133 Mortierella sp. NVP134 Mortierella sp. NVP137 Mortierella sp. NVP138 Mortierella sp. NVP139 Mortierella sp. NVP144 Mortierella sp. NVP145 Mortierella sp. NVP146 Mortierella sp. NVP147 Mortierella sp. NVP148 Mortierella sp. NVP149 Mortierella sp. Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Soil Uganda 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Fiji 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Uganda 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito 110 Table 2.2 (cont’d) NVP150 Mortierella sp. NVP151 Mortierella sp. NVP153 Mortierella sp. NVP154 Mortierella sp. NVP3 Mortierella sp. NVP41 Mortierella sp. NVP85 Mortierella sp. NVP8B Mortierella sp. PMI86 Mortierella sp. 14Py58W Mortierella sp. NRRL_28272 Mortierella stylospora AD003 AD079 AD086 Mortierella verticillata Mortierella verticillata Mortierella verticillata Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Gregory Bonito Martin Chilvers NRRL Gregory Bonito Gregory Bonito Gregory Bonito CBS 211.32, IMI 038599 2015 Natalie Vandepol 2015 Natalie Vandepol 2015 Natalie Vandepol 2015 Natalie Vandepol 2011 Khalid Hameed & Gregory Bonito Martin Chilvers 2015 Alessandro Desirò 2015 2015 Alessandro Desirò, Andrii Griganski, Zhen Hao Alessandro Desirò, Andrii Griganski, Zhen Hao Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Australia 2016 Natalie Vandepol Soil Soil Soil Soil Soil Soil Soil Soil Populus deltoides roots USA: Cincinnati, Ohio USA: Detroit, Michigan USA: Hamilton, Ohio USA: Los Gatos, California USA: North Carolina Soil USA: Illinois ISOTYPE Soil, sandy loam Rhizosphere of Allisonia sp. Soil Soil Australia: Victoria New Zealand: Kelly Creek, South Island USA: Coatesville, PA USA: Coatesville, PA 111 Table 2.2 (cont’d) AD092 Mortierella verticillata CK281 KOD952 NRRL_2611 NRRL_6337 Mortierella verticillata Mortierella verticillata Mortierella verticillata Mortierella verticillata NRRL_6338 Mortierella verticillata NRRL_6369 Mortierella verticillata TTC192 Mortierella verticillata NRRL_6351 Mortierella wolfii NRRL_66265 Mortierella wolfii USA: Coatesville, PA USA: Loblolly Pine Plantation, Duke Forest, North Carolina England: Freshfield, Lancashire England: Freshfield, Lancashire Canada: Great Bear Lake, Northwest Territories USA: Loblolly Pine Plantation, Duke Forest, North Carolina Soil Soil Soil Sandy forest soil Sandy forest soil Soil Soil Lung from cow dying of mycotic pneumonia New Zealand NRRL B.S. Mehrotra NRRL 112 2015 Alessandro Desirò, Andrii Griganski, Zhen Hao Gregory Bonito 2014 C. Kuske Andrea Porras- Alfaro Andrew Miller NRRL USA: Illinois 2012 Andrew Miller S.T. Williams NRRL S.T. Williams NRRL 1969 E.E. Butler NRRL 2013 C. Kuske Gregory Bonito 1476-3 NRRL A- 7267 CBS 131.66, NRRL A- 16547 CBS 130.66, NRRL A- 16548 CBS 100561, NRRL A- 6111 NRRL A- 18027 NRRL A- 12631 Table 2.2 (cont’d) NRRL_2592 Mortierella zychae Dead wood USA: Brownfield Wood, Urbana, Illinois NRRL CBS277.49 Mucor circinelloides AG13-4 Umbelopsis sp. AG# Umbelopsis ramanniana Soil USA: North Carolina A.F. Blakeslee CBS Gregory Bonito Andrii Gryganskyi NRRL A- 7087 ATCC 1216b, MUCL 15438, NRRL 3631 113 Table 2.3 – LCG assembly statistics The LCG assembly statistics, BUSCO analysis on the fungi_odb9 dataset which contained 290 single-copy marker genes, protein ortholog detection, number of markers used out of 434 total, and assembly deposition/accession details. Sample identifications were adjusted to correct misidentified samples or outdated taxonomy. “REF” indicates reference de novo genomes that were used to guide LCG sequence analysis, which are best accessed by BioSample number. Contig BUSCO Marker Percentage Assembly # Mbp Min Max Med- ian L50 N50 Full Sin- gle Dup- licate Frag- ment Cov- erage Mark- ers Used BioSample Assembly Accession 4002 38.4 500 123321 3612 467 23711 94.5 82.4 12.1 4.8 14.9 408 SAMN05720457 JAAAUD000000000 3523 36.0 500 118702 4952 469 23035 91.4 79.7 11.7 6.6 11.7 404 SAMN05720499 JAAAIT000000000 6585 35.4 500 70116 2722 895 10948 81.4 75.2 6.2 12.1 15.1 417 SAMN05720431 Superceded by REF genome 6418 35.6 500 128939 2737 864 11602 79.7 71.4 8.3 12.8 16.3 388 SAMN06281768 JAAAHT000000000 12478 43.6 500 267961 2062 2102 5999 81.7 75.5 6.2 14.5 17.2 368 SAMN05720516 JAAAHW000000000 1601 35.1 499 336245 5760 164 64418 96.8 83.4 13.4 2.1 13.2 416 SAMN05720461 JAAAHX000000000 2684 37.3 500 174171 6707 352 30823 95.2 82.8 12.4 3.4 11.1 411 SAMN05720462 JAAAUT000000000 4026 36.3 500 92935 4968 605 18393 94.4 83.4 11 4.5 8.5 403 SAMN05720518 JAAAHY000000000 2501 37.2 500 216994 5988 311 36335 96.8 83.4 13.4 1.7 12.2 416 SAMN05720773 JAAAHZ000000000 Sample Name Dissophora ornata NRRL_22417 Gamsiella multidivaricata NRRL_6456 Lobos- porangium transversale NRRL_3116 Lobos- porangium transversale NRRL_5525 Modicella reniformis MES-2146 Mortierella alpina AD071 Mortierella alpina AD072 Mortierella alpina CK1249 Mortierella alpina GBAus31 114 1181 37.7 500 458088 5288 114 101414 98 81.4 16.6 2186 35.5 500 272146 4268 226 47442 96.5 83.1 13.4 2284 37.9 498 238780 3660 243 48912 97.9 96.2 1.7 2279 37.6 500 252519 4804 262 44814 97.3 95.9 1.4 2034 35.1 500 259283 5340 227 47393 96.9 94.5 2.4 4906 37.8 500 114383 3110 598 18574 93.7 83.4 10.3 2797 44.9 491 271031 7635 377 36446 96.2 83.1 13.1 3653 39.0 499 149264 5051 479 24358 94.5 82.4 12.1 5304 38.2 500 76672 4037 810 14167 93.4 83.4 10 2928 41.4 500 208146 6033 376 33105 94.8 83.4 11.4 3048 39.5 500 157240 5381 392 31100 96.5 85.5 11 3044 42.9 291 200391 4581 346 37152 95.2 83.8 11.4 3514 46.9 501 111933 7016 494 28149 95.9 83.8 12.1 Table 2.3 (cont’d) Mortierella alpina NRRL_66262 Mortierella alpina NVP157 Mortierella ambigua BC1065 Mortierella ambigua BC1291 Mortierella ambigua NRRL_28271 Mortierella beljakovae KOD1040 Mortierella camargensis NRRL_2610 Mortierella chlamydospora AD033 Mortierella chlamydospora NRRL_2769 Mortierella clonocystis AM1000 Mortierella clonocystis KOD947 Mortierella cystojenkinii CBS456.71 Mortierella elongata GBAus34 0.7 34 415 SAMN10361219 JAABKD000000000 2.1 11 409 SAMN05720774 JAAAIB000000000 1 25.7 415 SAMN09074672 JAAAJB000000000 2.4 22.6 414 SAMN09074671 JAAAUS000000000 2.4 12.7 411 SAMN05720519 JAAAIA000000000 3.8 13.1 407 SAMN05720775 JAAAVF000000000 2.1 15.6 414 SAMN05727885 JAAAUF000000000 3.4 16.9 408 SAMN05720793 JAAAIC000000000 4.8 10.7 400 SAMN05720521 JAAAID000000000 3.4 13.8 408 SAMN05720794 JAAAIE000000000 2.8 13.3 410 SAMN05720795 JAAAIF000000000 3.8 14.6 411 SAMN05720522 JAAAIG000000000 2.8 12.6 415 SAMN05720796 JAAAUV000000000 115 Table 2.3 (cont’d) Mortierella elongata GBAus40 Mortierella elongata NVP5 Mortierella elongata NVP71 Mortierella epicladia AD058 Mortierella epicladia KOD1059 Mortierella epigama NRRL_5512 Mortierella exigua NRRL_28262 Mortierella gamsii AD045 Mortierella gamsii NVP60 Mortierella globulifera AD054 Mortierella globulifera REB-010B Mortierella horticola AD009 Mortierella horticola CK413 3610 40.8 500 181942 6369 543 22197 92.7 85.5 7.2 2579 38.1 500 152774 7478 363 31490 91.4 79.7 11.7 3903 32.9 500 81695 5327 649 15510 94.4 87.2 7.2 5084 48.1 500 123319 4776 732 19879 94.5 84.8 9.7 3359 49.3 500 305885 6658 430 33479 95.5 81 14.5 6418 49.5 500 166065 4282 967 15258 93.8 85.9 7.9 4204 38.2 500 114911 4447 560 19603 93.5 80.7 12.8 2632 39.2 500 200293 5893 303 37013 95.9 83.1 12.8 3587 40.0 500 118901 5989 510 23161 92.4 83.8 8.6 2108 40.4 500 256907 5327 222 56369 96.9 85.5 11.4 4256 46.8 500 122649 6079 611 22018 94.8 84.8 10 3.8 10.8 405 SAMN05720440 JAAAIH000000000 5336 46.0 500 123362 5213 884 15830 92.1 83.1 9 5.9 10.1 404 SAMN05720527 JAAAII000000000 6092 45.6 500 89460 4818 1061 13229 91 83.4 7.6 6.2 10.8 391 SAMN05720528 JAAAUW000000000 5.5 11.6 406 SAMN05720441 JAAAIJ000000000 6.2 12.1 410 SAMN05720442 JAAAIK000000000 3.1 12.6 408 SAMN05720443 JAAAVE000000000 3.8 9.5 398 SAMN05720535 JAAAIL000000000 2.4 12.2 412 SAMN05720529 JAAAIM000000000 4.1 10.3 400 SAMN05720530 JAAAIN000000000 4.1 10 400 SAMN05720444 JAAAIO000000000 3.1 15.5 410 SAMN05720531 JAAAIP000000000 6.9 10.2 395 SAMN05720532 JAAAIQ000000000 1.4 14.9 409 SAMN05720445 JAAAUX000000000 116 2079 29.2 554 102834 10992 551 16383 79 72.8 6.2 3.8 12.5 354 SAMN05720536 JAAAIR000000000 1564 46.1 500 535183 2879 102 128808 97.3 82.1 15.2 4029 35.3 501 100968 4138 530 19168 92.8 82.8 10 1 38.5 416 SAMN10361082 JAAAXW000000000 5.2 16.3 403 SAMN05720451 JAAAUG000000000 Table 2.3 (cont’d) Mortierella humilis KOD1050 Mortierella hyalina NRRL_2591 Mortierella lignicola NRRL_2525 Mortierella minutissima AD069 Mortierella minutissima NVP1 Mortierella polycephala KOD948 Mortierella schmuckeri NRRL_6426 Mortierella selenospora KOD1015 Mortierella sp. 14UC Mortierella sp. AD010 Mortierella sp. AD011 Mortierella sp. AD031 Mortierella sp. AD032 Mortierella sp. AD094 Mortierella sp. AM989 3215 39.4 500 134544 4516 389 30349 95.6 86.6 9 3.1 14.5 416 SAMN05720476 JAAAIS000000000 3345 39.0 477 132954 4234 410 29770 96.2 85.9 10.3 2595 32.6 500 148289 4233 303 31731 95.1 83.4 11.7 3515 46.1 500 124421 7322 542 25996 96.6 85.2 11.4 8632 40.5 500 66104 2780 1396 8341 87.9 81.7 6.2 2793 45.2 500 223587 6512 341 39533 95.5 84.1 11.4 4436 38.6 500 105019 4067 581 18859 94.8 83.1 11.7 4450 38.6 500 120180 4019 592 19053 94.8 84.5 10.3 3076 44.8 500 176793 5604 364 37102 95.5 85.5 10 4189 49.3 500 108262 5304 568 26892 95.2 86.9 8.3 5229 43.8 500 149436 3238 609 20836 93.4 81.7 11.7 4302 40.2 498 192044 2533 404 28934 94.1 80.3 13.8 2.1 14.2 412 SAMN05720446 JAAAUY000000000 2.4 12.3 408 SAMN05720452 JAAAJA000000000 2.1 11.3 405 SAMN05720483 JAAAUQ000000000 11.7 9.5 389 SAMN05720454 JAABOA000000000 2.4 12.4 411 SAMN05720455 JAAAUP000000000 4.5 14.4 407 SAMN05720791 JAAAUR000000000 4.5 13.5 411 SAMN05720798 JAAAVD000000000 2.8 12.5 416 SAMN05720799 JAAAUL000000000 3.1 10.4 411 SAMN05720491 JAAAIU000000000 5.2 13.5 414 SAMN05720438 JAAAUZ000000000 3.8 17.8 406 SAMN05720439 JAAAUM000000000 117 1938 37.0 497 204409 6156 222 51412 95.9 79.3 16.6 3099 44.8 500 165087 5608 382 35220 95.2 85.5 9.7 4038 50.9 499 190274 4665 455 32930 95.8 85.5 10.3 4063 39.2 500 149293 2139 343 33168 96.9 85.2 11.7 3767 38.8 500 159479 3974 457 25173 94.5 85.2 9.3 3995 36.1 500 91252 4133 515 20648 93.8 85.2 8.6 1697 33.5 500 216595 5245 182 56943 96.2 82.4 13.8 1626 33.5 500 304264 5338 170 59832 95.9 81.4 14.5 11106 39.0 500 105785 1297 1162 8506 81.7 74.1 7.6 2509 45.1 500 353893 4783 266 51498 97.2 84.8 12.4 5178 42.8 490 199404 2911 548 21933 95.2 83.8 11.4 3481 39.7 500 131992 5436 475 24790 94.8 84.1 10.7 2.4 18.6 409 SAMN05720448 JAAAIV000000000 3.4 11.3 411 SAMN05720449 JAAAUN000000000 2.8 10.6 414 SAMN05720493 JAAAUO000000000 1.7 12.6 404 SAMN05720494 JAAAIW000000000 4.1 13.2 411 SAMN05720520 JAAAUU000000000 4.8 16.8 406 SAMN05727888 JAAAUH000000000 2.8 17.6 410 SAMN05727889 JAAAUI000000000 3.1 17.1 412 SAMN05727887 JAAAUJ000000000 15.2 13.5 382 SAMN05727890 JAAAUE000000000 1.4 14.3 419 SAMN05720450 JAAAIX000000000 3.8 13.2 405 SAMN05720496 JAAAVA000000000 3.8 14.9 407 SAMN07687489 JAAAVB000000000 2.4 11.9 410 SAMN05720458 JAAAUK000000000 5.5 13.1 408 SAMN07687234 JAAAVC000000000 1.4 16.8 406 SAMN05720778 JAAAIZ000000000 Table 2.3 (cont’d) Mortierella sp. GBAus30 Mortierella sp. GBAus35 Mortierella sp. GBAus39 Mortierella sp. GBAus43 Mortierella sp. KOD1030 Mortierella sp. NRRL_3175 Mortierella sp. NRRL_A- 10739 Mortierella sp. NRRL_A- 10996 Mortierella sp. NRRL_A- 12553 Mortierella sp. NVP41 Mortierella sp. NVP85 Mortierella verticillata AD079 Mortierella verticillata NRRL 2611 Mortierella verticillata TTC192 Mortierella wolfii NRRL 66265 3118 39.9 500 185175 5614 402 29432 96.9 85.5 11.4 3609 42.1 500 260596 5928 509 24172 93.4 83.1 10.3 1088 34.1 500 432786 7590 110 90211 98.3 96.2 2.1 118 Table 2.3 (cont’d) Mortierella wolfii NRRL_6351 Mortierella zychae NRRL_2592 Mortierella zychae PUST_F9C REF: Lobo- sporangium transversale NRRL_3116 REF: Mortierella alpina B6842 REF: Mortierella elongata AG-77 REF: Mortierella humilis PMI1414 REF: Mortierella sp. GBAus27b REF: Mortierella verticillata NRRL 6337 838 39.3 1000 745939 9779 473 50.0 1003 1529192 5302 82 144249 96.2 78.3 17.9 1.4 31 518384 96.9 81 15.9 2.1 - - 416 SAMN02370960 N/A 418 SAMN02745706 N/A 523 36.2 1152 456461 49981 99 118088 87.6 75.2 12.4 140 45.0 1029 2979878 118251 15 820600 97.9 83.8 14.1 1.7 - 376 SAMN06266088 N/A 0.3 - 413 SAMN06310397 N/A 1180 34.2 493 534714 5458 113 93672 98.3 96.2 2.1 1260 45.7 500 611785 5298 120 120966 97.3 82.1 15.2 2068 44.8 1002 257400 10265 282 46863 93.8 79.7 14.1 138 42.8 1957 1854208 182234 22 672590 92 80.3 11.7 1.4 14.7 403 SAMN05720777 JAAAIY000000000 1.4 33.5 412 SAMN10361244 JAAAHU000000000 4.8 17.4 410 SAMN11510820 JAAAHV000000000 3.8 - 417 SAMN05421885 N/A 56 41.9 5293 5074928 17244 6 2912254 96.2 83.1 13.1 1.4 - 417 SAMN00699802 N/A 119 Table 2.4 – Primer sets produced by the MGP locus selection pipeline All primer sets produced by the MGP locus selection pipeline. Status indicates which tests the primer set has passed: in silico = simulated PCR in IPCRESS; in vitro = amplification & sequencing of each independent primer set using genomic DNA from a panel of isolates; in vivo = multiplex PCR and sequencing to generate mutli-gene phylogenetic data. Failure at each stage came in the form of 1) non-specific in silico “amplification”, 2) off target in vitro amplification or failure to amplify across the panel of isolates, and 3) in vivo MGP sequence data analysis revealing selective pressure or potential gene duplication of that locus. Primer Set Status ExonID in M. elongata AG77 (gene_ exon) Size (bp) Putative Gene Identification Sequence (5' to 3') Len (bp) GC % Tm °C Sequence (5' to 3') Len (bp) GC % Tm °C Forward Primer Reverse Primer 11759_6 1481 RPB1 largest subunit 1870_4_ 1 1693 Xanthine dehydrogenase 2451_3 1932 Calcium-translocating P- type ATPase Used 3770_1 1320 EF-1alpha 5512_3 1606 4955_7 747 10927_4 2000 Glycosyltransferase Family 21 protein Hypothetical protein, DNA replication licensing factor, MCM5 component Class V Myosin motor head 2175_2 1400 CTP synthase 370_5 980 Acyl-CoA oxidase Passed in silico Passed in vitro Failed in vivo 4121_2 950 Hypothetical protein, Amino acid transporters ACAAAGATCAASGW GCAGTTGCC 23 48 55.3 120 TCACGWCCTCCCAT GGCGT GTGGTCAGGAGCA GTTCTACC CTGGAACTGCAAGA ACTTGC CTTGCCACCCTTGC CATCG TTCTTCTCRGTCAC AGTCTTGAC ATACGGATRATRGC YTCCAGCTG TCTCGAACGAWCCT GCATCCT TGAACGAYGGTGG WGAGGT ATCAACTACCCCAT GGTCCA 19 63 55.4 21 57 56.3 20 50 51.8 19 63 55.4 53.5- 55.3 23 23 43- 48 43- 57 21 52 54.4 19 53- 58 51.1- 53.2 20 50 51.8 AAGGAGGGTCGTCT TCGTGG ATGCGCTCRGGWG TGGCAG GGYGTSAGTATCTA CGAGGA AACGTCGTCGTTAT CGGACAC TTGAGAGAGAGGTC MGSAGCA 53.5- 58.8 GAAGCTTCGTGGAG ATATCAACG AACAAGGCHCGCAA GGAGCT GCCAWCTCGACAAT CTCCA GCTCAGWCTGRGC CTTRTCC TGGGTGGVTGGATC GGWGTC 20 60 55.9 19 20 63- 68 50- 55 55.4- 57.6 51.8- 53.8 21 52 54.4 21 52- 57 54.4- 56.3 23 48 55.3 20 55- 60 53.8- 55.9 19 53 51.1 20 20 53.8- 57.9 55.9- 57.9 55- 65 60- 65 Table 2.4 (cont’d) Passed in silico Failed in 5401_4 1400 5491_1 944 onanonoxo-7-onima-8- eninoihtemlysoneda delta-12 fatty acid desaturase 615_2 1560 chitin synthase 10616_4 1005 2714_3- _2 1615 4725_7 2020 5489_5 1160 5925_8_ 3 1275 vitro 615_3-_2 730- 820 662_2 800 7496_4 2000 959_4 1317 10278_1 661 1296_2 2000 - 2100 1326_1 1100 Passed in silico Un- tested in vitro 1672_3 725 1777_5 1243 CSAGACGCCAGCAT CCACT GCATGGTAGAAYGG CATCTG TTGGCCATGTTGTG SCGCTTGG TYTCGTTGATRTCG GGCTTGTTG GACATRCCGACYTG CTGGAC TAGTAGTADGGRCG GTCAAAGAC CCTCACAGAGCAGS ACCAGA CTTGKTGATGCGCT TGATACC AGTTGATCCAGCGA CGACGCT GTCTTGACACCRCA YTGGAAYTT ATCTCGGGKGTCTC GAACGA AGAAYCACGGCATC AACTGGT TGGTARACATCRGC RTGCTC GGATGGCTGTTYTG RTGHGCCTG GACTGRATRCMCTT GTAGAA AACATMTACTCGCT CAAYTGGTGG TGGGMTCKGCTATY AAGAACAAGG 121 19 20 63- 65 50- 55 55.4 51.8- 53.8 22 59 58.6 23 20 23 43- 52 55- 65 43- 52 53.5- 57.1 53.8- 57.9 53.5- 57.1 20 60 55.9 21 48- 52 52.4- 54.4 21 57 56 GTSAACAGCCCYAT CATGTC CCCGAGTTCACSAT CAAGGA CGGCATGGGDTACT AYTTCAACG CCTTCAGYAACCAG GACAAGTG CCAAAAGATTGTCA AGAAGCACGAC CTGGTACTTCCCTC TSTGGCA AGCGMGASTGGGA GATTGAC GAGATCAAGMGRTT CGAGGA CCCGGWAACCGWG GAAAGC ACCTCCAAGGAYCT SACCAT CTCGAGGGAAAAGT GGTGGA ACGACTTYTGRGCA GCGTT TCGCCAARTCCTCM AAGGTCGT 53.5- 57.1 53.8- 55.9 52.4- 54.4 49.7- 55.9 23 20 21 20 23 20 24 24 43- 52 55- 60 48- 52 45- 60 52- 65 35- 50 42- 50 42- 54 57.1- 62.4 ATCTGGGACACDGA GCTYGCCTG 45.6- 51.8 54- 57.4 54- 59.1 TGCTGCCCMGGAAT GTTCAA ACTTGSCGCTTGTA YTCSTCGT AGGTACTCCATCGA GAACTCGC 20 50- 55 51.8- 53.8 20 55 53.8 23 22 48- 57 50- 55 55.3- 58.8 54.8- 56.7 25 44 56 21 57 56.3 20 20 55- 60 45- 55 53.8- 55.9 49.7- 53.8 19 63 55.4 20 50- 55 51.8- 53.8 20 55 53.8 19 22 23 20 22 47- 58 50- 55 57- 65 50- 55 50- 55 48.9- 53.2 54.8- 58.6 58.8- 62.4 51.8- 53.8 54.8- 56.7 22 55 56.7 Table 2.4 (cont’d) 180_1 1900 1830_4 763 1870_4_ 2 2281_4 1511 1071 - 1100 2290_4 1170 2463_6- _4 1480 2486_4 2045 2561_2 1200 2575_2 1700 Passed in silico Un- tested in vitro 313_2 890 313_3 840 3998_2 2009 4269_2 1063 4352_3 1600 4352_3_ 2 1500 4690_5 2244 5431_1 1141 GAAGCATCTTYTTG GCMGCRATCAT GACTGGACYAAGAA GGGAGAGG AAGGCCCARTGGTT CCGCC TCATCCTCRTCCAT MGACTC TACCCWTACCTYCA GAAGCG TCCTCMARCCTCYT CCACTC GCRTTGTTCATRTT GGGGAC TGGGGCTCYATCTT TGGWTTCTTG TCDTCAATKCCMGA CCARTACTT CGTCGTCGTACTTG TAGAA TCCTGCRACYTCTC CDGCRACCAT AGCGAAGARGARGA RGAGTC CTGCTCGTCCCGTT ATYTCCGT AAGCAGCCKCGMG TCATCTC AAGCAGCCKCGMG TCATCTC CCTTGGAGATGCAC ATRAAGC ACATYCACTCKCGC ACCTTCTC 122 25 22 19 20 20 20 20 24 23 40- 52 55- 59 63- 68 45- 60 50- 55 50- 65 45- 55 46- 50 35- 52 51.8- 53.8 51.8- 57.9 49.7- 53.8 55.7- 57.4 49.9- 57.1 19 47 48.9 24 20 21 20 20 21 22 50- 63 45- 60 55- 59 55- 65 55- 65 48- 52 50- 59 57.4- 62.5 49.7- 55.9 56.7- 58.6 53.8- 57.9 53.8- 57.9 52.4- 54.4 54.8- 58.6 54.4- 59.3 56.7- 58.6 55.4- 57.6 TCCATCTCGGACYT GACCACAAC TGACWGCRTCCATC TTGTCGCG GTCTGGCCCTCAAA GACCTTG 23 22 52- 57 55- 59 57.1- 58.8 56.7- 58.6 21 57 56.3 49.7- 55.9 TCRTTCTTGACBATT CGCAC 20 40- 50 47.7- 51.8 ACTCATCTTCTTCTT CTCGCG GAACAYASCATGGA GATGCCC GATATYCTGACCAA RCGCGA ACCATGTCGACGGM CTGVGAGCA GCVCCVTTCTGCAT GAAYATG GGMGTCGTCTTTAT CAAGTTC TGGCSCACGACCAY GARATCAT GAGCTGGTATCRAT CTGGAC GTCTTGGGGGCCTT CTTGGCA KGCAAARTCVTCGG GGTC AGVACCTCDGCACG CTC TTTCGATTGTWCGC ACCAAGGA ACCTCGGCCTKGAA GACCTC 21 48 52.4 21 20 23 21 21 22 20 52- 57 45- 55 57- 65 43- 57 43- 48 50- 59 50- 55 54.4- 56.3 49.7- 53.8 58.8- 62.4 50.5- 56.3 50-52 54.8- 58.6 51.8- 53.8 21 62 58.3 18 17 50- 67 59- 71 48- 54.9 49.5- 54.3 22 45 53 20 60- 65 55.9- 57.9 53.8- 57.9 51.8- 55.9 55.9- 60 TACTTCYTKGGHGA YGCCA CCTTGTGSGGCTCG TGCA GAAGATRCCKCCRA TCCAGG 51.8- 53.8 TCAAGGTSATGCGM AAGGTC 56.3- 60.2 CCTAYGTCAAGAAC GGWCCTCA 47.1- 51.9 TGGATCCARAACGC SAC 55.4- 57.6 49.9- 53.5 54.8- 56.7 TCGACAAGTACAAC GAGGAGTGC ACCAACCCWATCAT GGAAGC AAGTAGTTKGADCC WGMCATCC CCTCGATATCACCR ACCATGTAGA 42.2- 44.6 GAGYTCCARATTCC AGTT 21 43 50.5 Table 2.4 (cont’d) 5535_5 665 5557_5- _6 1860 5910_1 812 5925_8_ 1 5925_8_ 2 Passed in silico 6157_7- Un- _5 tested in 2008 - 2047 1630 2000 - 2200 vitro 648_4 1898 7496_4- _3 8603_2- _3 2300 400- 670 957_2 1358 9823_5- _6 10146_1- _2 1550 - 1650 10482_2 900 Failed in 10927_4- silico _3 1600 12903_1 2000 1327_1 1200 AACTTCTCDGGRCG SGTCGA CAGTTYCTSTACCG VCCCTT CCAAGGTCGGYCAG AAYGCC TTGACGATRCGGTA GATGGG GCCTCYTGCTGRCG ACTCTTG GAYGAYTTGCCAGC WCC CTTCAGACGGCGRC GGTTG GTCGAAAGATTTGT TCTGCTG TATGGTCTKTAYTTG ATGGTCGA AGATTCGCTCSGTY ATTGGTGC ATGGCHTACAACGA TCT TCAAGTACGGTTGG GAYTT ARTCAATGCTGTCG CAGGT GATTTGTTCTGCTG ATGCGCCA GCCTCCTCCAAGTA RTTGTC ATCARCTCGGTCAT GWAAGG 123 20 20 20 20 20 17 19 55- 65 50- 60 60- 70 50- 55 57- 67 53- 65 63- 68 23 22 17 19 19 35- 43 50- 55 41- 47 42- 47 47- 53 46.8- 48.9 48.9- 51.1 GCRGGGATCTTGAC YTTG TCCAAGAACGAGAT CCAGTC TCCTTCATCGGTGT CCTCGA ATCGAGAAGCGMAC CTGGC ATCTGCTTYTGCTG CCCMGG 22 50 54.8 20 20 50- 55 45- 50 51.3- 53.8 49.7- 51.8 19 42- 63 46.8- 55.4 18 67 54.9 20 20 22 17 50- 65 50- 55 50- 55 53- 59 51.8- 57.9 51.8- 53.8 54.8- 56.7 47.1- 49.5 23 52 57.1 20 50 51.8 22 24 18 18 41- 55 46- 50 39- 50 50- 61 51.1- 56.7 55.7- 57.4 43.5- 48 48- 52.6 20 50 51.8 20 55 53.8 19 20 58- 63 55- 65 53.2- 55.4 53.8- 57.9 Table 2.4 (cont’d) 13292_2 730 1359_4 650 1412_4 700 14290_2- _1 1300 - 1670 1655_4 1600 2258_3 2200 Failed in silico 2550_2 1543 3484_2 1261 376_2 1400 671_2 1100 730_2 600 819_3 1827 834_4 600 GTCTTGGCCTTGCT CATCA ACATCRCCRAACAT GACGGC CTTCTCCTTCTTRG MCTTCTT 19 53 51.1 20 21 50- 60 38- 48 51.8- 55.9 48.5- 52.4 CACCGCCACATCYT GTC CTTTGARCGYATCC TCTGGAGA AGCTCATYAAGAAC AAGARCGA 17 22 22 59- 65 45- 55 36- 45 49.5- 51.9 53- 56.7 49.2- 53 CTTGATCTTCTTGC GSGCAAT 21 48 52.4 GCCACCACCTGCCC CTC 17 76 56.7 TCWCCRGTCGARG CCATCTC CCATRTCCTTGGAS TCRTCGTGC CCTTGWACTTCTCG GCCTCG AACGASCAGGGTMA CCGTAYCA TCGCTYGCCTACGG WGGYATG GATACCDCCCAAGT TCTG TBCGCCTKTTGATC TCBCAC ATCTTGTTCTGCTCA CGRGCCT TGTYTGCCTGGMTG CTTCT 20 23 55- 65 52- 61 53.8- 57.9 57.1- 60.6 20 60 55.9 22 21 18 2 21 19 50- 59 57- 67 50- 56 45- 60 50- 55 47- 58 54.8- 58.6 56.3- 60.2 48- 50.3 49.7- 55.9 54.8- 56.7 48.9- 53.2 AGTCKGTYGGHGAG GTCATG GTCTCGTTCGGCCC CAAGCA ACCTACTCBTGCGT TGCCGTCT TCATGGSACGCTCW CCCTCGTA TAGTTDGTRGGYTC GTCCAG CTTCTGCTGCCCHG GYATGT ACAATRGTGAACAT GCGCTC GGGYATGCCCCATC GTGGT GAARTCGTCAAAGT GCCAG 20 50- 65 51.8- 57.9 20 65 57.9 22 55- 59 56.7- 58.6 22 59 58.6 20 20 20 19 19 45- 60 55- 65 45- 50 63- 68 47- 53 49.7- 55.9 53.8- 57.9 47.9- 51.8 55.4- 57.6 48.9- 51.1 124 Table 2.5 – Raw sequences per locus The total number of sequences recovered, the total number of isolates represented, and the ratio between the number of sequences and isolates, full and partial length, for each locus 5512 370 1870 2175 5491 2451 4121 Full Part Full Part Full Part Full Part Full Part Full Part Full Part Sequences 214 39 238 61 295 70 353 201 334 63 170 81 370 119 214 32 205 57 283 38 289 119 301 53 169 55 269 50 1 1.22 1.16 1.07 1.04 1.84 1.22 1.69 1.11 1.19 1.01 1.47 1.38 2.38 Samples Ratio 4955 5401 EF1a RPB1 615 10927 ITS Full Part Full Part Full Part Full Part Full Part Full Part Full Part Sequences 299 44 253 77 298 698 335 110 305 92 175 89 307 42 282 40 246 54 287 110 307 78 253 60 171 61 303 28 1.06 1.1 1.03 1.43 1.04 6.35 1.09 1.41 1.21 1.53 1.02 1.46 1.01 1.5 Samples Ratio 125 Table 2.6 – Rejected Strains The strain number, preliminary identification, ITS-based identification, number of full-length sequences for each locus, and reason the strain was excluded from the final MGP analyses. Reason Strain ID Preliminary ID ITS ID 5512 1870 2451 4955 EF1a RPB1 ITS NRRL_5247 Mortierella elongata Mortierella elongata NRRL_28263 Mortierella rostafinskii NRRL_2665 Mortierella sp. Mortierella sp. clade5 Erratic placement(s) NRRL_A-16826 Mortierella sp. NRRL_A-13231 Umbelopsis vinacea NRRL_28259 Umbelopsis vinacea wolfii, clade 5 Mortierella sp. clade6 & Umbelopsis Umbelopsis vinacea Sequence Duplication Only one MGP locus AD030 NVP93 NRRL_22986 Umbelopsis vinacea NVP39 Mortierella minutissima Mortierella sp. clade7 NRRL_28270 Mortierella echinula NRRL_28640 Mortierella wolfii Mortierella sp. Mortierella minutissima Mortierella minutissima NRRL_A-17819 Mortierella rostafinskii Mortierella rostafinskii AD036 Mortierella chlamydospora Mortierella chlamydospora KOD1061 Mortierella sp. Mortierella parvispora C-SDSO22-35 Mortierella elongata Mortierella elongata KSSO1-41 Mortierella gamsii KSSO2-49 Mortierella elongata C-MISO26-28 Mortierella alpina No MGP loci C-MNSO23-21 Mortierella alpina AG14-9 AG18-7 AG24-3 AG69 Umbelopsis Mortierella sp. clade7 Umbelopsis Umbelopsis 126 1 1 1 1 1 1 1 1 5 2 3 1 1 1 1 1 5 2 2 3 1 1 1 1 1 1 1 5 2 1 1 1 1 1 1 1 1 7 1 2 2 1 1 1 1 2 1 1 1 1 1 1 1 1 2 1 1 1 partial Table 2.6 (cont’d) No MGP loci AG6-9 AG12 Umbelopsis Umbelopsis 1 1 127 Table 2.7 – MGP Sequences by Isolate Values indicate the Genbank reference number for the sequence included in the final dataset. Numbers in parentheses indicate the initial degree of sequence duplication for that sample at that locus. “0.5” indicates at least one partial sequence was detected but could not be included due to insufficient length. Asterisks indicate sequences obtained from a low coverage or de novo genome sequence, rather than PCR amplification. Isolate ID Preliminary Identification Updated Identification In LCG Locus 1870 Locus 2451 Locus 4955 Locus 5512 Locus EF1a Locus RPB1 14Py07W Mortierella sp. Linnemannia sp 14Py14W 14Py25W Mortierella alpina Mortierella gamsii Linnemannia sp Linnemannia gamsii 14Py31W Mortierella sp. Linnemannia elongata 14Py45W Mortierella sp. Mortierella alpina 14Py58W Mortierella alpina 14UC Mortierella sp. Linnemannia sp Mortierella verticillata Mortierella horticola Mortierella horticola Podila horticola Podila horticola Podila verticillata MN878503 MN878497 MN878963 MN879069 MN878222 MN744146 MN878964 MN879070 MN878223 MN744147 MN878490 MN878859 MN879036 MN878114 MN744033 MN878434 MN883114 MN878965 MN879071 MN878224 MN744148 MN878549 MN878713 MN878751 MN879072 MN878017 MN743921 MN878518 MN878701 MN878752 MN879073 MN878018 MN743922 Y MN878286* MN878175* MN743903* MN878332 MN883115 MN879004 MN879037 MN878269 MN744194 MN878747* 0.5* 0.5* MN878350 MN883116 MN878870 MN879074 MN878125 MN744044 Y MN878349 MN878651 MN878871 MN879075 MN878126 MN744045 AD010 Mortierella sp. Entomortierella sp Y MN878453 0.5* MN878954 (2) 0.5* Y MN878348 0.5* MN878955 0.5 MN878872 MN879076 MN878127 MN744046 MN878212 MN744134 (2) MN879018 MN744135 AD003 AD008 AD009 AD011 AD012 AD013 AD014 AD021 AD022 Podila horticola Podila horticola Mortierella sp. Entomortierella sp Mortierella horticola Mortierella horticola Mortierella sp. Entomortierella sp Mortierella alpina Mortierella elongata Mortierella alpina Linnemannia elongata MN878351 MN878650 MN878873 MN879077 MN878128 MN744047 MN878213 MN744136 MN878516 MN878706 MN878753 MN879078 MN878019 MN743923 MN878956 0.5 0.5 MN878462 MN878629 MN878810 MN879079 MN878067 MN743983 128 Table 2.7 (cont’d) AD031 AD032 AD033 AD034 AD035 AD039 AD041 AD045 AD050 AD051 AD054 AD055 AD058 AD060 AD062 AD065 AD068 AD069 Podila minutissima Linnemannia elongata Podila minutissima Linnemannia gamsii Entomortierella parvispora Mortierella sp. Linnemannia sp nov Mortierella sp. Linnemannia sp Entomortierella Mortierella chlamydospora chlamydospora Mortierella minutissima Mortierella elongata Mortierella parvispora Mortierella minutissima Mortierella gamsii Mortierella elongata Mortierella minutissima Mortierella globulifera Mortierella horticola Mortierella epicladia Mortierella sp. Linnemannia sp Mortierella alpina Mortierella minutissima Mortierella hyalina Mortierella minutissima Podila minutissima Podila minutissima Podila horticola Podila epicladia Linnemannia elongata Podila minutissima Mortierella alpina Linnemannia hyalina Dissophora globulifera Y MN878297 MN878682 MN878868 MN879086 MN878124 MN744042 Y MN878406 MN883117 MN878966 Y MN878504 MN878225 MN744149 MN878967 MN879080 MN878226 MN744150 0.5* Y MN878059* MN879017* MN878360 MN878664 MN878892 MN879081 MN878150 MN744069 MN878456 MN878605 MN878811 MN879082 MN878068 MN743984 MN878383 MN878903 MN878163 MN744080 MN878893 MN879083 MN878151 MN744070 Y MN878495 MN878632 MN878860 0.5* MN878115 MN744034 MN878432 MN878598 MN878812 MN879084 MN878069 MN743985 MN878384 MN878894 MN879085 MN878152 MN744071 0.5 MN878653 MN878874 MN879087 MN878129 MN744048 Y MN878358 MN878659 MN878854 MN879088 MN878110 MN744028 MN878501 MN878968 MN879089 MN878227 MN744151 MN878526 MN878729 MN878754 MN879090 MN878020 MN743924 0.5 MN878382 0.5 MN878895 MN879091 MN878153 MN744072 MN878488 MN878625 MN878880 MN879092 MN878135 MN744054 Y MN878288* MN878564* MN878745* MN879093* MN878154* MN743905* 129 MN878496 0.5 MN878861 MN879038 MN878116 MN744035 Y MN878523 MN878735 MN878755 MN879094 MN878021 MN743925 Y MN878289* 0.5* MN878744* 0.5* MN878022* MN743906* MN878364 MN878666 MN878896 MN879095 MN878155 MN744073 MN878214 MN744137 MN878678 Y MN878270* MN743902* MN878489 MN878626 MN878969 MN879096 MN878228 MN744152 MN878327 MN878578 MN878902 MN879097 MN878162 MN744079 MN878741* MN878334 MN878642 MN879005 MN879039 MN878271 MN744195 MN878335 MN878641 MN879006 MN879040 MN878272 MN744196 MN878431 MN878602 MN878813 MN879098 MN878070 MN743986 Umbelopsis ramanniana Linnemannia elongata MN883129* MN878425 0.5* MN878679 MN878918 Y MN878176 MN744096 MN879019* MN743913* MN878229 MN744153 Table 2.7 (cont’d) AD070 AD071 AD072 AD077A AD078 AD079 AD084 AD085 AD086 AD092 AD093 AD094 AG# AG13-4 AG77 B6842 BC1065 C- ARSO21-9 C- ARSO24-5 Podila verticillata Mortierella alpina Mortierella alpina Podila minutissima Linnemannia gamsii Linnemannia nantahalensis Mortierella gamsii Mortierella alpina Mortierella alpina Mortierella minutissima Mortierella sp. Entomortierella sp Mortierella verticillata Mortierella sp. Linnemannia hyalina Mortierella nantahalensis Mortierella verticillata Mortierella verticillata Mortierella elongata Mortierella sp. Entomortierella sp Umbelopsis ramanniana Umbelopsis Mortierella elongata Mortierella alpina Mortierella ambigua Mortierella alpina Mortierella acrotona Actinomortierella ambigua Mortierella alpina Mortierella alpina Podila verticillata Podila verticillata Linnemannia elongata Linnemannia acrotona Linnemannia elongata Y MN878282* MN878561* MN878737* MN879099* MN878071* MN743897* Y MN878283* MN878562* MN878738* MN879100* MN878023* MN743898* MN878740* MN743900* MN878531 MN878699 MN878756 MN879101 0.5 MN743926 MN878498 MN878750 MN879102 MN878016 MN743920 130 Mortierella elongata Table 2.7 (cont’d) C- ARSO25- 24 C-ILSO26- 18 C-INSO22- 17 C-INSO22- 22 C-MICO24- 19 C-MISO21- 18 C- MNSO24- 13 Mortierella alpina Mortierella gamsii Mortierella alpina Mortierella alpina Mortierella elongata Mortierella gamsii CBS277.49 CBS456.71 Mucor circinelloides Mortierella cystojenkinii Mortierella echinosphaera Mortierella selenospora Mortierella alpina Mortierella alpina Mortierella alpina Mortierella alpina Mortierella verticillata CBS575.75 CBS811.68 CK1227 CK1249 CK1268 CK202 CK281 Linnemannia elongata MN878437 MN878604 MN878814 MN879103 MN878072 MN743987 Mortierella alpina MN878546 MN878714 MN878757 MN879105 MN878024 MN743927 Linnemannia gamsii MN878491 MN878862 MN879041 MN878117 MN744036 Mortierella alpina MN878511 MN878709 MN878758 MN879106 MN878025 MN743928 Mortierella alpina MN878515 MN878704 MN878761 MN878027 MN743931 Linnemannia elongata MN878442 MN878592 MN878815 MN879111 MN878073 MN743988 Linnemannia gamsii MN878492 MN878863 MN879042 MN878118 MN744037 Mucor circinelloides Gryganskiella cystojenkinii Entomortierella echinospaera Lunasporangiospora selenospora Y Y 0.5 MN883128* MN879021* MN743912* MN879043 MN878062 MN743978 MN878809 MN878066 MN743982 MN878316 MN878567 MN878917 0.5 0.5 Mortierella alpina MN878517 MN878707 MN878759 MN879107 0.5 MN743929 Mortierella alpina Y MN878290* MN883118* 0.5* 0.5* MN878026* MN743908* Mortierella alpina MN878535 MN878690 MN878760 MN879108 0.5 MN743930 Mortierella sp MN878551 MN878719 MN878919 MN879109 MN878177 MN744097 Podila verticillata MN878333 MN878640 MN879007 MN879044 MN878273 MN744197 131 Podila horticola Y MN878293* 0.5* MN878743* MN879110* 0.5* MN743907* Lichtheimia corymbifera MN879020* MN743911* Linnemannia elongata MN878445 MN878593 MN878816 MN879112 0.5 MN743989 Linnemannia gamsii MN878493 MN878579 MN878864 MN879045 MN878119 MN744038 Linnemannia elongata MN878452 MN878817 MN879113 MN878074 MN743990 Linnemannia elongata Y MN878469 MN878627 MN878818 MN879114 MN878075 MN743991 Linnemannia elongata MN878450 MN878610 MN878819 MN879115 MN878076 MN743992 GBAus27B Mortierella sp. Benniella sp nov 1 GBAus30 Mortierella sp. Mortierella sp Y MN878303 MN878569 MN878998 MN744182 Y MN878320 MN883119 MN878999 MN879046 MN878258 MN744183 Table 2.7 (cont’d) CK413 FSU9682 GBAus21 GBAus22 GBAus23 GBAus24 GBAus25 Mortierella horticola Lichtheimia corymbifera Mortierella elongata Mortierella gamsii Mortierella elongata Mortierella elongata Mortierella elongata GBAus31 GBAus32 GBAus33 GBAus34 Mortierella alpina Mortierella elongata Mortierella elongata Mortierella elongata GBAus36 GBAus37 GBAus38 Mortierella elongata Mortierella elongata Mortierella elongata Mortierella alpina Y MN878534 MN878696 MN878762 MN879116 MN878028 MN743932 Linnemannia elongata MN878443 MN878603 MN878820 MN879117 MN878077 MN743993 Linnemannia elongata MN878451 MN878609 MN878821 MN879118 MN878078 MN743994 Linnemannia elongata Y MN878444 MN878633 MN878822 MN879119 MN878079 MN743995 GBAus35 Mortierella sp. Linnemannia sp nov Linnemannia elongata Y MN878408 MN878634 MN878970 MN878230 MN744154 MN878457 MN878607 MN878823 MN879120 MN878080 MN743996 Linnemannia elongata MN878455 MN878606 MN878824 MN879121 MN878081 MN743997 Linnemannia elongata MN878470 MN878628 MN878825 MN879122 MN878082 MN743998 GBAus39 Mortierella sp. Linnemannia hyalina Y MN878482 MN878619 MN878971 MN879123 MN878231 MN744155 GBAus40 Mortierella elongata Linnemannia elongata Y MN878454 MN878608 MN878826 MN879124 MN878083 MN743999 132 Table 2.7 (cont’d) GBAus41 Mortierella sp. Linnemannia hyalina GBAus42 Mortierella sp. Linnemannia elongata IASO10- 42-45rt Linnemannia elongata MN878483 MN878618 MN878972 MN879125 MN878232 MN744156 MN878423 MN878588 MN878973 MN879126 MN878233 MN744157 MN878447 MN878597 MN878827 MN879127 MN744000 0.5 Linnemannia elongata MN878460 MN878582 MN878828 MN879128 MN878084 MN744001 Benniella sp nov 1 MN878304 0.5 MN878829 MN744002 Linnemannia hyalina Y MN878284* MN878563* MN878739* MN879129* MN878136* MN743899* Mortierella elongata Mortierella elongata Mortierella elongata Mortierella hyalina Mortierella clonocystis ILSO2-38 INSO1- 46B2 JES103 KOD1000 Podila clonocystis KOD1001 Mortierella sp. Linnemannia sp KOD1002 Mortierella alpina Mortierella alpina KOD1003 Mortierella sp. Linnemannia sp KOD1004 Mortierella sp. Podila minutissima Y MN878347 MN878668 MN878923 MN879130 MN878181 MN744102 MN878506 MN878974 MN879131 MN878234 MN744158 0.5 MN878702 MN878763 MN878029 MN743933 MN878505 MN878975 MN879132 MN878235 MN744159 MN878387 MN878924 MN879133 MN878182 MN744103 MN878521 MN878733 MN878764 MN879134 MN878030 MN743934 Linnemannia elongata MN878461 MN878583 MN878830 MN879135 MN878085 MN744003 KOD1005 KOD1006 KOD1007 Mortierella alpina Mortierella elongata Mortierella elongata Mortierella alpina Linnemannia elongata KOD1008 Mortierella sp. Podila horticola KOD1009 Mortierella sp. Podila clonocystis KOD1010 Mortierella sp. Podila minutissima KOD1012 Mortierella alpina Mortierella alpina KOD1013 Mortierella sp. Podila minutissima KOD1014 Mortierella sp. Podila epicladia KOD1015 Mortierella selenospora Lunasporangiospora selenospora 0.5 MN878831 MN879136 MN878086 MN744004 MN878468 MN878388 MN878875 MN879137 MN878130 MN744049 MN878376 MN878672 MN878805 MN879138 MN878060 MN743976 MN878377 MN878673 MN878925 MN879139 MN878183 MN744104 MN878554 MN878722 MN878765 MN879140 MN878031 MN743935 MN878370 MN878926 MN879141 MN878184 MN744105 MN878355 MN878658 MN878927 MN879142 MN878185 MN744106 MN744095* Y MN878317 MN878566 0 (2) MN878174 133 (2) Mortierella alpina MN878527 MN878726 MN878766 MN879143 MN878032 MN743936 Mortierella alpina MN878528 MN878727 MN878767 0.5 MN878033 MN743937 Mortierella alpina MN878529 MN878728 MN878768 MN879144 0.5 MN743938 Mortierella alpina MN878530 MN878730 MN878769 MN879145 MN878034 MN743939 Linnemannia hyalina MN878471 MN878613 MN878881 MN879146 MN878137 MN744055 Mortierella alpina MN878519 MN878725 MN878770 (2) MN879147 MN878035 MN743940 Mortierella alpina MN878542 MN878695 MN878771 MN879148 0.5 MN743941 Table 2.7 (cont’d) KOD1016 KOD1017 KOD1018 KOD1019 KOD1020 KOD1021 KOD1022 KOD1023 Mortierella alpina Mortierella alpina Mortierella alpina Mortierella alpina Mortierella hyalina Mortierella alpina Mortierella alpina Mortierella hyalina KOD1026 KOD1027 KOD1028 Mortierella alpina Mortierella alpina Mortierella alpina KOD1030 KOD1032 Mortierella antarctica Mortierella gamsii Linnemannia hyalina KOD1024 Mortierella sp. Podila minutissima KOD1025 Mortierella sp. Podila minutissima Mortierella alpina MN878480 MN878622 MN878882 MN879149 MN878138 MN744056 MN878393 MN878928 MN879150 MN878186 MN744107 MN878390 MN879151 MN879022 MN744108 MN878544 MN878718 MN878772 MN879152 MN878036 MN743942 0.5 Mortierella alpina MN878555 MN878721 MN878773 MN879153 0.5 MN743943 KOD1029 Mortierella sp. Podila minutissima Mortierella alpina MN878540 MN878694 MN878774 MN879154 MN743944 MN878366 MN878671 MN878929 MN879155 MN878187 MN744109 0.5 Podila minutissima Y MN878371 MN878667 MN878930 MN879156 MN878188 MN744110 Linnemannia sp KOD1033 Mortierella sp. Podila minutissima KOD1034 KOD1035 Mortierella gamsii Mortierella dichotoma Linnemannia sp Necromycomortierella dichotoma MN878507 MN878354 MN878508 MN878365 134 0.5 MN878865 MN879157 MN878120 MN744039 MN878931 MN879158 MN878189 MN744111 MN878866 MN879159 MN878121 MN744040 MN878807 MN878063 MN743979 Necromycomortierella dichotoma 0 (2) 0 (2) MN878064 MN743980 MN878485 MN878614 MN878883 MN879160 MN878139 MN744057 MN878484 MN878616 MN878976 MN879161 MN878236 MN744160 MN878367 MN878178 MN744099 MN878920 0.5 0.5* Y MN878300 MN878053 MN743968 MN878343 MN878655 MN878932 MN879162 MN878190 MN744112 MN878344 MN878656 MN878933 MN879163 MN878191 MN744113 MN744100 0.5* 0 (2) MN878921 0.5 MN878179 (2) MN878487 MN878617 MN878977 MN879164 MN878237 MN744161 MN878556 MN878723 MN878775 MN879165 MN878037 MN743945 Table 2.7 (cont’d) KOD1036 KOD1037 Mortierella dichotoma Mortierella hyalina Linnemannia hyalina KOD1038 Mortierella sp. Linnemannia hyalina KOD1039 Mortierella sp. KOD1040 Mortierella beljakovae Entomortierella parvispora Entomortierella beljakovae KOD1041 Mortierella sp. Podila clonocystis KOD1042 Mortierella sp. Podila clonocystis KOD1043 Mortierella sp. Gryganskiella sp KOD1044 Mortierella sp. Linnemannia hyalina KOD1045 KOD1046 KOD1047 Mortierella alpina Mortierella alpina Mortierella alpina Mortierella alpina Mortierella alpina KOD1048 Mortierella sp. Linnemannia hyalina KOD1049 Mortierella sp. Podila minutissima Mortierella alpina MN878538 MN878697 MN878776 MN879166 MN878038 MN743946 MN878539 MN878692 MN878777 MN879167 MN878486 MN878615 MN878978 MN878386 0.5 MN878238 MN744162 MN878934 MN879168 MN878192 MN744114 0.5 MN743947 Mortierella humilis Mortierella amoeboidea Mortierella polycephala Mortierella amoeboidea Mortierella alpina KOD1050 KOD1051 KOD1052 KOD1053 KOD1054 Podila verticillata Y MN878323 0.5* MN878878 MN879169 MN878133 MN744052 Linnemannia amoedoidea Mortierella polycephala Linnemannia amoedoidea MN878324 0.5 MN878795 MN878050 MN743965 MN878319 0.5 MN878906 MN879047 MN878168 MN744084 MN878325 MN878577 MN878796 MN878051 MN743966 Mortierella alpina MN878520 MN878732 MN878778 MN879170 MN878039 MN743948 135 Mortierella alpina MN878545 MN878716 MN878779 MN879171 0.5 MN743949 KOD1057 Mortierella sp. Podila clonocystis MN878302 MN878346 MN878904 MN878165 MN744081 0.5 MN878935 MN879172 MN878193 MN744115 Podila epicladia Y MN878356 MN878660 MN878855 MN879173 MN878111 MN744029 KOD1063 Mortierella sp. Podila minutissima KOD1064 Mortierella sp. Podila minutissima KOD1065 Mortierella sp. Podila minutissima Linnemannia hyalina MN878164 MN879015 MN878890 MN879048 0.5 MN744064 MN878374 MN878936 MN879174 MN878194 MN744116 MN878372 MN878937 MN879175 MN878195 MN744117 MN878373 MN878897 MN879176 MN878156 MN744074 MN878472 MN883120 MN878884 MN879177 MN878140 MN744058 0.5 Linnemannia hyalina MN878477 MN878623 MN878885 MN879178 MN878141 MN744059 Entomortierella parvispora KOD943 Mortierella sp. Podila epicladia KOD944 Mortierella minutissima Podila minutissima KOD945 Mortierella sp. Mortierella sp MN878905 MN878166 MN744082 MN878353 MN878663 MN878938 MN879179 MN878196 MN744118 MN878385 MN878898 MN879180 MN878157 MN744075 MN878391 MN883121 MN878959 MN879049 MN878217 MN744141 Podila clonocystis Y MN878345 MN878654 MN878806 MN879181 MN878061 MN743977 Entomortierella parvispora Entomortierella parvispora Mortierella polycephala Table 2.7 (cont’d) KOD1055 KOD1056 Mortierella alpina Mortierella parvispora KOD1059 KOD1061 KOD1062 Mortierella epicladia Mortierella parvispora Mortierella parvispora KOD1067 KOD1068 KOD1069 Mortierella hyalina Mortierella hyalina Mortierella parvispora KOD947 KOD948 KOD949 Mortierella clonocystis Mortierella polycephala Mortierella hyalina Mortierella polycephala Linnemannia hyalina KOD950 Mortierella sp. Podila epicladia KOD951 Mortierella sp. Podila minutissima Y MN878318 MN878687 MN878907 MN879050 MN878169 MN744085 MN878479 MN883122 MN878886 MN879068 MN878142 MN744060 MN878357 MN878662 MN878939 MN879182 MN878197 MN744119 MN878361 MN878665 MN878940 MN879183 MN878198 MN744120 136 Table 2.7 (cont’d) KOD952 Mortierella verticillata Podila verticillata MN878331 MN883123 MN879008 MN879051 MN878274 MN744198 KOD954 Mortierella sp. Entomortierella parvispora KOD955 Mortierella sp. Podila minutissima KOD956 Mortierella sp. Podila sp Mortierella alpina MN878922 MN878180 MN744101 MN878375 MN878953 MN879184 MN878211 MN744133 MN878329 MN878649 MN878941 MN879185 MN878199 MN744121 MN878524 MN878731 MN878780 MN879186 MN878040 MN743950 Podila minutissima MN878392 MN878942 MN879187 MN878200 MN744122 Dissophora globulifera KOD960 Mortierella sp. Podila minutissima KOD963 Mortierella sp. Podila minutissima KOD964 Mortierella sp. Podila minutissima Linnemannia hyalina MN878298 MN878394 MN878389 MN878378 MN878481 MN878681 (2) MN878958 MN878215 MN744139 MN878943 MN879188 MN878201 MN744123 MN878952 MN879189 MN878210 MN744132 MN878944 MN879190 MN878202 MN744124 0.5 MN878887 MN879191 MN878143 MN744061 KOD957 KOD958 KOD959 Mortierella alpina Mortierella alpina Mortierella minutissima KOD965 KOD967 KOD968 Mortierella hyalina Mortierella alpina Mortierella polycephala Mortierella polycephala KOD969 Mortierella sp. Podila minutissima KOD971 Mortierella sp. Podila minutissima KOD972 Mortierella sp. Podila minutissima KOD975 Mortierella polycephala Mortierella polycephala KOD979 Mortierella sp. Linnemannia elongata Linnemannia elongata KOD980 KOD981 KOD982 Mortierella elongata Mortierella elongata Mortierella elongata Mortierella alpina MN878553 MN878724 MN878781 MN879192 MN878041 MN743951 0.5 MN878686 MN878908 MN879052 MN878170 MN744086 MN878380 MN878381 MN878379 0 (2) MN878688 MN878945 MN879193 MN878203 MN744125 MN878946 MN879194 MN878204 MN744126 MN878947 MN879195 MN878205 MN744127 MN878909 MN744087 MN879053 MN879023 MN878467 MN878630 MN878979 MN879196 MN878239 MN744163 MN878463 MN878832 MN879197 MN878087 MN744005 0.5 (4) (2) Linnemannia elongata MN878465 MN878635 MN878833 MN879198 MN878088 MN744006 Linnemannia elongata MN878466 MN878631 MN878834 MN879199 MN878089 MN744007 137 Mortierella alpina MN878547 MN878711 MN878782 MN879200 MN878042 MN743952 MN878362 MN878669 MN878948 MN879201 MN878206 MN744128 MN878359 MN878661 MN878949 MN879202 MN878207 MN744129 Y MN878314 MN878677 MN878957 MN879024 MN744138 MN878537 MN878693 MN878783 MN879203 MN879025 MN743953 0.5 MN878301 MN878533 MN878960 MN879054 MN878218 MN744142 MN878419 MN878581 MN878835 MN879205 MN878090 MN744008 MN878858 MN879204 MN879026 MN744032 0.5 Linnemannia elongata Mortierella alpina MN878552 MN878720 MN878793 MN879206 MN878049 MN743963 Mortierella alpina MN878522 MN878734 MN878784 MN879207 MN878043 MN743954 Necromycomortierella dichotoma MN878464 0.5 MN878808 MN879055 MN878065 Mortierella alpina MN878541 MN878691 MN878785 MN879208 MN743981 (2) MN743955 Mortierella alpina MN878543 MN878717 MN878786 MN879209 MN878044 MN743956 Modicella reniformis Y MN878299 MN878568 0.5 0.5* MN878015 MN743919 Podila horticola MN878352 0.5 MN878876 MN879210 MN878131 MN744050 Linnemannia elongata MN878446 MN878595 MN878913 MN879211 MN878171 MN744091 Table 2.7 (cont’d) KOD983 KOD984 Mortierella alpina Mortierella elongata Podila minutissima KOD988 Mortierella sp. Podila epicladia KOD989 Mortierella sp. Entomortierella sp KOD990 KOD991 Mortierella alpina Mortierella fimbricystis Mortierella alpina Gryganskiella fimbricystis KOD992 Mortierella sp. Mortierella sp KOD993 KOD994 KOD995 KOD996 KOD998 KOD999 MES-2146 MICO2-9 MISO4-46 NDSO1-48 Mortierella elongata Mortierella alpina Mortierella alpina Mortierella dichotoma Mortierella alpina Mortierella alpina Modicella reniformis Mortierella horticola Mortierella rishikesha Mortierella alpina Mortierella alpina NRRL 1458 Mortierella sp. Linnemannia hyalina NRRL 1617 Mortierella sp. Linnemannia hyalina MN878512 MN878710 MN878787 MN879212 MN878045 MN743957 MN878475 MN878621 MN878997 MN879213 MN878257 MN744181 MN878473 MN883124 MN878996 MN879214 MN878256 MN744180 138 Table 2.7 (cont’d) NRRL 22416 NRRL 22417 NRRL 22890 NRRL 22891 NRRL 22892 NRRL 22995 Dissophora decumbens Dissophora ornata Mortierella polycephala Mortierella polycephala Mortierella capitata Mortierella bisporalis Mortierella lignicola Mortierella aplina NRRL 2493 NRRL 2525 NRRL 25716 NRRL 25721 Mortierella sp. Linnemannia elongata Dissophora decumbens MN878559 Dissophora ornata Y MN878558 0.5* 0.5 0.5* MN879027 MN743914 MN878010 MN743915 Mortierella polycephala Mortierella polycephala Actinomortierella capitata 0.5 0.5 MN878911 MN879056 MN879028 MN744089 MN883132 MN878689 MN878910 (2) MN879057 MN879029 MN744088 MN883130 (2) MN878560 MN878736 MN879030 MN743896 MN878436 MN878591 MN878853 MN879215 MN878109 MN744027 Mortierella bisporalis MN878557 MN878685 MN879058 MN878054 MN743969 Entomortierella lignicola Y 0.5* MN878676 0.5* Mortierella alpina MN878514 MN878703 MN878792 MN878149 MN744068 MN878048 MN743962 Mortierella sp. Linnemannia elongata MN878459 MN878852 MN879216 MN878108 MN744026 NRRL 2591 NRRL 2592 NRRL 2610 NRRL 2611 NRRL 2682 NRRL 2760 NRRL 2761 Mortierella hyalina Mortierella zychae Mortierella camargensis Mortierella verticillata Haplosporangiu m sp. Mortierella claussenii Mortierella schmuckeri Linnemannia hyalina MN878478 MN878624 MN878889 MN879217 MN878145 MN744063 Linnemannia zychae MN878395 MN879014 MN878281 MN744204 Linnemannia camargensis Y MN878414 MN878638 MN878799 MN879218 MN878056 MN743971 Podila verticillata Y MN878340 MN878646 MN879011 MN879059 MN878278 MN744201 Mortierella sp MN883131 0.5 MN878749 MN879060 MN878012 MN743917 Dissophora sp Linnemannia schmuckeri MN878804 MN879031 MN744093 MN878411 MN878637 MN878915 MN879219 MN879032 MN743975 139 NRRL 28257 NRRL 28260 NRRL 28261 NRRL 28262 NRRL 28267 NRRL 28271 NRRL 28272 NRRL 2942 NRRL 3116 NRRL 3175 NRRL 5217 NRRL 5248 NRRL 5512 NRRL 5513 NRRL 5525 NRRL 5841 Table 2.7 (cont’d) NRRL 2769 Mortierella chlamydospora Mortierella capitata Mortierella camargensis Mortierella reticulata Mortierella exigua Mortierella antarctica Mortierella ambigua Mortierella stylospora Mortierella parvispora Lobosporangiu m transversale Haplosporangiu m sp. Mortierella chienii Mortierella indohii Mortierella epigama Mortierella elongata Lobosporangiu m transversale Mortierella sclerotiella Entomortierella chlamydospora Actinomortierella capitata Linnemannia camargensis Y MN878413 0.5* MN878803* MN879033 0.5* MN878368 (2) MN878801* (2) 0.5 MN879034 MN743973 MN878415 MN878639 MN878800 MN879220 MN878057 MN743972 Mortierella reticulata MN878458 MN878912 0.5 0 (4) MN744090 Linnemannia exigua Y MN878499 0.5* MN878857 MN879221 MN878113 MN744031 Mortierella antarctica MN878509 Actinomortierella ambigua Y 0.5* MN878797 MN878052 MN743967 MN878794 MN879222 MN879035 MN743964 Gamsiella stylospora MN878322 MN878683 MN879003 Entomortierella parvispora Lobosporangium transversale MN878416 Y MN878295 0.5 0.5* Entomortierella sp Y 0.5* MN878675 0.5* Lunasporangiospora chienii Y MN878315 MN878565 MN878802 0.5* 0.5* MN878268 0.5 MN878167 MN744083 MN878014 (2) 0 (2) MN744098 MN878058 MN743974 Mortierella indohii MN878474 Podila epigama Y MN878321 0.5 MN879061 MN878146 MN744065 MN878856 0.5* MN878112 MN744030 Linnemannia elongata MN878448 MN878600 MN878850 MN879223 MN878106 MN744024 Lobosporangium transversale Linnemannia sclerotiella Y MN878294 MN878417 0.5* 0.5* MN878013 MN879016 (2) (3) MN878916 MN879067 MN878173 MN744094 140 Table 2.7 (cont’d) NRRL 5842 NRRL 62971 NRRL 6302 NRRL 6337 NRRL 6338 NRRL 6351 NRRL 6369 NRRL 6424 NRRL 6425 NRRL 6426 NRRL 6427 NRRL 6456 NRRL 66262 NRRL 66264 NRRL A- 10739 NRRL A- 12040 NRRL A- 12553 Mortierella nantahalensis Mortierella alpina Mortierella alpina Mortierella verticillata Mortierella verticillata Mortierella wolfii Mortierella verticillata Mortierella minutissima Mortierella lignicola Mortierella schmuckeri Mortierella hyalina Mortierella multidivaricata Mortierella alpina Mortierella geracilis Haplosporangiu m sp. Mortierella hyalina Mortierella bisporalis Podila sp MN878525 0.5 MN878950 MN879224 MN878208 MN744130 (3) Mortierella alpina MN878550 MN878715 MN878791 MN879225 0.5 MN743961 Mortierella alpina MN878532 MN878700 MN878790 0.5 MN878047 MN743960 Podila verticillata Y MN878342 MN878647 MN879012 MN883111 MN878279 MN744202 Podila verticillata MN878341 MN878648 MN879010 MN883112 MN878277 MN744200 Actinomortierella wolfii Y MN878369 MN879013 0.5* MN878280 MN744203 Podila verticillata MN878336 MN878643 MN879009 MN883113 MN878276 MN744199 Podila minutissima MN878337 MN878657 MN878900 MN879226 MN878159 MN744077 Entomortierella lignicola Linnemannia schmuckeri MN878674 0.5 MN878148 MN744067 (3) Y MN878412 MN878636 MN878914 MN879227 MN878172 MN744092 Linnemannia hyalina MN878476 MN878620 MN878888 MN879228 MN878144 MN744062 Gamsiella multidivaricata Y 0.5* MN878684 MN878901 0.5* MN878161 MN744078 Mortierella alpina MN878510 MN878708 MN878962 MN879229 MN878221 MN744145 Linnemannia gamsii MN878494 MN878580 MN878994 MN878254 MN744178 Mortierella sp Y MN878330 0.5* MN878748 MN879062 MN878011 MN743916 Mortierella sp MN878891 MN879063 MN878147 MN744066 Podila verticillata Y MN878338 MN878645 MN878951 MN879064 MN878209 MN744131 141 Table 2.7 (cont’d) NRRL A- 12867 NRRL A- 15043 Mortierella alpina Mortierella minutissima Mortierella sp. Linnemannia elongata MN878433 MN878601 MN878851 MN879230 MN878107 MN744025 Linnemannia sp MN878502 MN878995 MN879231 MN878255 MN744179 NVP1 Podila minutissima NVP103 Mortierella sp. Benniella sp nov 3 NVP105 Mortierella sp. Benniella sp nov 3 NVP106 Mortierella sp. Benniella sp nov 3 Linnemannia elongata Y MN878363 MN878670 MN878899 MN879232 MN878158 MN744076 MN878310 MN878308 MN878307 MN878439 MN878611 MN878259 MN744184 MN878260 MN744185 MN878261 MN744186 MN879233 MN878091 MN744009 MN879000 0.5 Linnemannia elongata MN878440 MN883125 MN878836 MN879234 MN878092 MN744010 NVP112 NVP113 NVP123 Mortierella elongata Mortierella elongata Mortierella elongata Linnemannia elongata NVP125 Mortierella sp. Actinomortierella sp NVP128 Mortierella elongata Linnemannia elongata NVP130 Mortierella sp. Linnemannia sp nov NVP131 Mortierella sp. Linnemannia sp nov NVP132 Mortierella sp. Linnemannia sp nov NVP133 Mortierella sp. Benniella sp nov 3 NVP134 Mortierella sp. Benniella sp nov 3 NVP137 Mortierella sp. Benniella sp nov 3 NVP138 Mortierella sp. Benniella sp nov 3 NVP139 Mortierella sp. Benniella sp nov 3 NVP144 Mortierella sp. Linnemannia sp nov NVP145 Mortierella sp. Linnemannia sp nov NVP146 Mortierella sp. Linnemannia sp nov NVP147 Mortierella sp. Linnemannia sp nov NVP148 Mortierella sp. Linnemannia sp nov 0.5 MN878438 MN878612 MN878837 MN879235 MN878093 MN744011 MN878216 MN744140 MN878420 MN878584 MN878838 MN879236 MN878094 MN744012 MN878404 MN878980 MN878398 MN878571 MN878981 MN878405 MN878574 MN878982 MN878309 MN879001 MN878306 MN878311 MN878312 MN878313 MN878407 MN878575 MN878983 MN878399 MN878572 MN878984 MN878400 MN878985 MN878401 MN883126 MN878986 MN878402 MN878987 MN878240 MN744164 MN878241 MN744165 MN878242 MN744166 MN878262 MN744187 MN744188 MN878263 MN744189 MN878264 MN744190 MN878265 MN744191 MN878243 MN744167 MN878244 MN744168 MN878245 MN744169 MN878246 MN744170 MN878247 MN744171 0.5 0.5 0.5 142 0.5 0.5 MN878397 MN878248 MN744172 MN878988 MN878409 MN878249 MN744173 MN878989 MN878410 MN878576 MN878990 MN878250 MN744174 MN878548 MN878712 MN878961 MN879237 MN878219 MN744143 MN878500 MN878991 MN879238 MN878251 MN744175 MN878441 MN878839 MN879239 MN878095 MN744013 0.5 Y MN878287* MN878746* MN879104* MN743904* MN878536 MN878698 MN878788 MN879240 MN878396 MN878266 MN744192 MN878427 MN878586 MN878840 MN879241 MN878096 MN744014 MN743958 MN879002 0.5 0.5 Y MN878403 MN878573 MN878992 MN878513 MN878705 MN878789 MN878252 MN744176 MN878046 MN743959 Y MN878292* MN878742* MN879243* MN878122* MN743910* MN878418 MN878570 MN878867 MN878123 MN744041 MN878428 MN878599 MN878842 MN879244 MN878098 MN744016 MN878449 MN878594 MN878843 MN879245 MN878099 MN744017 MN878844 MN878100 MN744018 MN878429 0.5 MN878845 MN879246 MN878101 MN744019 Linnemannia elongata Y MN878422 MN878587 MN878841 MN879242 MN878097 MN744015 Table 2.7 (cont’d) NVP149 Mortierella sp. Linnemannia sp nov NVP150 Mortierella sp. Linnemannia sp nov NVP151 Mortierella sp. Linnemannia sp nov NVP153 Mortierella sp. Mortierella alpina NVP154 Mortierella sp. Linnemannia sp Linnemannia elongata Linnemannia elongata NVP156 NVP157 NVP17b NVP3 NVP4 NVP41 NVP47 NVP5 NVP60 NVP61 NVP64 NVP65 NVP66 NVP67 NVP71 Mortierella alpina Mortierella alpina Mortierella alpina Mortierella elongata Mortierella alpina Mortierella alpina Mortierella sp. Linnemannia sp nov Mortierella elongata Mortierella sp. Linnemannia sp nov Mortierella alpina Mortierella elongata Mortierella gamsii Mortierella gamsii Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Mortierella elongata Linnemannia gamsii Linnemannia gamsii Linnemannia elongata Linnemannia elongata Linnemannia elongata Linnemannia elongata Linnemannia elongata Y MN878426 MN878585 MN878846 MN879247 MN878102 MN744020 143 Table 2.7 (cont’d) Linnemannia elongata Linnemannia elongata Y MN878305 Y MN878339 MN878644 MN878879 MN879066 MN878134 MN744053 MN878435 MN878590 MN878847 MN879248 MN878103 MN744021 MN878267 MN744193 MN879065 MN878220 MN744144 MN878421 MN883127 MN878848 MN879249 MN878104 MN744022 Mortierella elongata Mortierella sp. Benniella sp nov 2 Mortierella sp. Mortierella sp Mortierella elongata Mortierella humilis Mortierella sp. Linnemannia elongata Y MN878430 MN878596 MN878993 MN879250 MN878253 MN744177 Mortierella globulifera Mortierella horticola Mortierella multidivaricata Mortierella verticillata Mortierella elongata Mortierella camargensis MN878424 MN878589 MN878849 MN879253 MN878105 MN744023 MN878328 MN878652 MN878877 MN879252 MN878132 MN744051 Dissophora globulifera Y MN878296 MN878680 MN878869 MN879251 Gamsiella multidivaricata Linnemannia camargensis MN878055 MN743970 Podila verticillata Y MN878291* Linnemannia elongata MN878160* (2*) MN878326 0.5 MN878798 MN743901* MN878275* MN743909* 0.5 Podila verticillata Podila horticola 0 (2) MN744043 NVP79 NVP85 NVP8B NVP90 PMI1414 PMI86 REB-010B REB-025A RSA2512 TTC192 WISO4-29 WISO4-30 Y MN878285* 144 Table 2.8 – Primer mismatch The total number of isolates belonging to each of the ITS-based clades defined by Wagner et al. (2013), the number of those detected in each locus, and the number of usable isolates included in the phylogenetic analyses. The larger the discrepancy between total and detected isolates, the poorer the performance of the primer set on this lineage of Mortierellomycotina. Clade Samp. Num 1870 2451 4955 5512 EF1a RPB1 Found Useable Found Useable Found Useable Found Useable Found Useable Found Useable # % # % # % # % # % # % # % # % # % # % # % # % 13 81.3 11 68.8 8 50.0 5 31.3 12 75.0 11 68.8 5 31.3 4 25.0 13 81.3 13 81.3 16 100 15 93.8 61 95.3 60 93.8 38 59.4 32 50.0 59 92.2 56 87.5 53 82.8 50 78.1 64 100 63 98.4 64 100 64 100 10 76.9 8 61.5 7 53.8 5 38.5 12 92.3 9 69.2 6 46.2 6 46.2 13 100 13 100 13 100 13 100 22 100 21 95.5 17 77.3 12 54.5 21 95.5 18 81.8 7 31.8 5 22.7 21 95.5 21 95.5 22 100 21 95.5 7 100 6 85.7 0 0.0 0 0.0 6 85.7 4 57.1 6 85.7 2 28.6 7 100 7 100 6 85.7 6 85.7 16 64 13 22 7 63 59 93.7 58 92.1 56 88.9 51 81.0 62 98.4 61 96.8 58 92.1 55 87.3 61 96.8 49 77.8 63 100 63 100 110 106 96.4 103 93.6 93 84.5 77 70.0 106 96.4 104 94.5 95 86.4 92 83.6 109 99.1 107 97.3 110 100 110 100 1 2 3 4 5 6 7 NA 2 2 100 2 100 2 100 1 50.0 2 100 2 100 0 0.0 0 0.0 2 100 2 100 2 100 2 100 145 Table 2.9 – Locus sequence variability at the species level Summary statistics from pairwise blastn analyses of the locus sequences as submitted to Genbank. Empty cells indicate that the locus was not recovered for any strains in that species. ‘n’ = the number of non-self pairwise blastn analyses conducted, where ‘0’ indicates that only one sequence was available to represent the species and therefore no intraspecific analyses could be conducted. “Min% - Max%” = the range of percent sequence variability, where ‘0’ means the sequences were identical. Values in bold indicate a meaningful difference between the maximum observed intraspecific variation and the minimum observed interspecific variation. 2451 1870 Intraspecific Min% - Max% n Interspecific Min% - Max% n Intraspecific Min% - Max% n Interspecific n 85 81 Min% - Max% 19.2 - 21.5 19.1 - 22.0 - - 1.6 - 2.0 273 15.8 - 20.2 0.7 179 0 - 21.9 0.1 - 8.4 13.0 - 14.0 0.2 - 14.1 13.0 - 14.1 11.9 - 13.1 271 89 90 83 88 185 11.0 - 12.0 281 2351 0 - 4.3 2485 87 0 - 5.2 812 0 - 3.4 1525 87 185 86 0 - 1.0 1263 87 3.1 - 9.8 0 - 7.6 3.0 - 7.5 4.1 - 8.5 0 - 8.2 8.0 - 9.5 0.1 - 8.4 4.5 - 8.0 6.4 - 8.3 6.9 - 9.6 0 63 341 - 0 - 0 1 0 209 - - 0 89 81 84 183 1681 0 - 14.7 2459 - - - 0 0.6 - 1.7 0 - 5.0 - 0 370 1476 88 185 5 287 0 1 71 15.0 - 18.0 16.8 - 20.3 16.9 - 21.8 4.8 - 20.2 3.1 - 24.6 6.5 - 21.6 3.1 - 23.4 11.7 - 20.8 4.8 - 20.3 146 0 - 1.4 805 14.6 - 21.4 1.3 - 18.0 0 - 10.9 174 85 182 11.6 - 14.0 6.8 - 15.2 77 6.8 - 14.4 719 84 12.7 - 13.3 1.3 - 1.5 274 14.8 - 16.6 12.1 - 13.0 13.8 - 17.3 85 83 0 - 0.7 - - - 88 0.1 - 8.5 0 0 1 0 55 0 5 0 0 0 0 0 0 0 0 1 1 - - 0 - - - - - - - 0 0 0 0 5 1 0 0 0 1 Species Actinomortierella ambigua Actinomortierella capitata Actinomortierella wolfii Benniella erionia Benniella sp nov1 Benniella sp nov2 Dissophora decumbens Dissophora globulifera Dissophora ornata Entomortierella beljakovae Entomortierella chlamydospora Entomortierella echinospaera Entomortierella lignicola Entomortierella parvispora Gamsiella multidivaricata Gamsiella stylospora Gryganskiella cystojenkinii Gryganskiella fimbricystis Linnemannia acrotona Linnemannia amoedoidea Linnemannia camargensis Linnemannia elongata Linnemannia exigua Linnemannia gamsii Linnemannia hyalina Linnemannia nantahalensis Linnemannia schmuckeri Linnemannia sclerotiella Linnemannia sp nov Linnemannia zychae Table 2.9 (cont’d) Lobosporangium transversale Lunasporangiospora chienii Lunasporangiospora selenospora Modicella reniformis Mortierella alpina Mortierella antarctica Mortierella bisporalis Mortierella indohii Mortierella polycephala Mortierella reticulata Necromycomortierella dichotoma Podila clonocystis Podila epicladia Podila epigama Podila horticola Podila minutissima Podila verticillata Lichtheimia corymbifera Mucor circinelloides Umbelopsis ramanniana 1 0 1 0 0 - 180 16.6 - 17.7 82 9.1 - 13.7 2.3 182 9.1 - 13.1 - 80 14.0 - 16.6 0 1 0 - 2.5 - 82 13.8 - 23.1 179 13.8 - 22.7 2161 0 - 12.1 2470 0.3 - 14.8 2132 0 - 11.3 2501 80 - 83 20.2 - 23.9 2.2 - 22.7 11.1 - 21.1 0 - 3.5 367 0.1 - 20.9 0 - 8.6 0 - 4.4 0 - 2.4 0 - 8.3 0 - 5.0 - - 458 550 460 885 884 75 81 0 - 23.0 3.9 - 20.7 6.8 - 21.4 0 - 22.4 8.3 - 21.6 30.4 - 34.9 30.3 - 32.9 0 0 0 5 0 0 - - - 83 89 85 6.2 - 12.0 9.8 - 11.9 0 - 7.8 0.1 - 4.0 272 11.8 - 13.4 85 0 - 7.6 0 11 173 0.1 - 10.3 - - 0 - 5.4 0 - 3.3 - 0 - 11.1 2.8 - 11.1 12.2 - 13.3 549 548 86 0 - 7.7 721 0 - 7.3 2122 29 29 0 0 - 13.5 55 928 0 - 11.8 109 0 - 12.2 1059 0.4 - 13.9 19 29 19 89 89 0 0 147 Table 2.9 (cont’d) Species Actinomortierella ambigua Actinomortierella capitata Actinomortierella wolfii Benniella erionia Benniella sp nov1 Benniella sp nov2 Dissophora decumbens Dissophora globulifera Dissophora ornata Entomortierella beljakovae Entomortierella chlamydospora Entomortierella echinospaera Entomortierella lignicola Entomortierella parvispora Gamsiella multidivaricata Gamsiella stylospora Gryganskiella cystojenkinii Gryganskiella fimbricystis Linnemannia acrotona Linnemannia amoedoidea Linnemannia camargensis Linnemannia elongata Linnemannia exigua Linnemannia gamsii Linnemannia hyalina Linnemannia nantahalensis Linnemannia schmuckeri Linnemannia sclerotiella Linnemannia sp nov Linnemannia zychae Lobosporangium transversale Lunasporangiospora chienii Lunasporangiospora selenospora Modicella reniformis 4955 5512 Intraspecific Min% - Max% n Interspecific Min% - Max% n Intraspecific Min% - Max% n Interspecific Min% - Max% n 1 1 0 1 - 0 - 5 - - 0 0 - 19 0 0 - 0 0 1 5 2255 0 71 341 0 1 0 209 0 0 0 9.1 0 - 0 - - - 2.1 - 2.4 - - - - - 5.9 - 9.6 172 10.3 - 20.4 177 10.3 - 21.1 86 174 14.1 - 16.2 - 182 0.4 - 10.3 - 271 14.0 - 15.5 - - - - - - 85 0 - 10.1 80 1.6 - 16.6 - - - 0 - 11.0 0 - 4.8 - - - - - 0 5.6 - 9.6 0 - 8.5 0.6 - 11.1 450 11.0 - 17.1 84 11.7 - 14.3 83 14.3 - 15.8 - 84 84 183 13.6 - 15.7 276 3.8 - 12.1 0 - 10.2 2481 85 4.2 - 10.9 804 4.5 - 11.3 0 - 10.2 1523 7.2 - 10.6 0 - 10.1 5.3 - 8.3 1262 0.4 - 11.9 3.7 - 11.3 0 - 6.3 0 - 3.0 85 182 84 - 0 - 0 - 0.8 92 - - 0 1 0 0 0 1 2255 0 29 305 0 1 0 - 91 22.9 - 24.8 2.2 183 17.6 - 19.1 82 18.5 - 20.8 86 19.0 - 20.3 87 0.1 - 17.8 - - - 0 - 186 4.6 - 17.5 0 - 6.0 2485 2.8 - 17.2 89 3.7 - 17.2 552 6.0 - 19.7 0 - 8.7 0 - 4.1 1463 2.8 - 17.2 88 10.6 - 17.9 186 4.6 - 16.9 86 7.3 - 15.9 - 0 - - - 81 17.6 - 19.5 84 15.4 - 17.1 148 Table 2.9 (cont’d) Mortierella alpina Mortierella antarctica Mortierella bisporalis Mortierella indohii Mortierella polycephala Mortierella reticulata Necromycomortierella dichotoma Podila clonocystis Podila epicladia Podila epigama Podila horticola Podila minutissima Podila verticillata Lichtheimia corymbifera Mucor circinelloides Umbelopsis ramanniana 2158 0 - 10.4 2476 2.2 - 14.5 1559 0 - 9.8 2384 3.3 - 18.3 86 6.5 - 13.4 632 84 0 - 16.6 7.0 - 16.8 175 0 - 13.9 - 0 - 2.4 - - 0 - 4.6 0 - 3.5 - 545 0 - 15.0 547 2.2 - 15.2 83 15.2 - 17.6 802 2081 0 - 14.5 0 - 3.8 0 - 14.9 0 - 4.5 0 - 13.9 1038 4.1 - 15.0 0 0 41 0 29 29 71 929 109 - - 0 - 2.3 - 84 83 637 10 - 20.1 1.7 - 20.1 0 - 19.7 87 15.5 - 17.5 0 - 4.1 0 - 3.1 551 0 - 18.2 554 0.1 - 17.9 0 - 6.7 808 0.2 - 19.5 0 - 4.2 2126 0 - 18.0 0 - 15.8 961 5.7 - 21.1 0 41 0 0 29 29 0 71 869 129 149 ef1a rpb1 n Interspecific Min% - Max% 1.7 - 4.8 0.3 - 7.4 0.1 - 3.3 2.5 - 7.8 2.5 - 7.2 6.6 - 7.6 5.4 - 6.3 2.9 - 3.8 3.8 - 5.1 173 1.3 - 5.3 79 1.7 - 5.4 Intraspecific Min% - Max% n Interspecific Min% - Max% n 0 1 0 1 0 55 0 5 0 0 0 0 - 0 - 0.2 - 174 10 - 20.1 176 7.6 - 16.6 77 12.4 - 16.1 175 11.0 - 16.0 70 7.0 - 18.0 711 7.0 - 16.1 80 12.8 - 14.6 1.8 - 2.2 266 13.2 - 16.3 80 12.6 - 14.3 0.1 - 14.4 81 0 - 3.3 - - - - - 170 0 - 15.6 78 2.1 - 15.8 Table 2.9 (cont’d) Species Intraspecific Min% - Max% n Actinomortierella ambigua Actinomortierella capitata Actinomortierella wolfii Benniella erionia Benniella sp nov1 Benniella sp nov2 Dissophora decumbens Dissophora globulifera Dissophora ornata Entomortierella beljakovae Entomortierella chlamydospora Entomortierella echinospaera Entomortierella lignicola Entomortierella parvispora Gamsiella multidivaricata Gamsiella stylospora Gryganskiella cystojenkinii Gryganskiella fimbricystis Linnemannia acrotona Linnemannia amoedoidea Linnemannia camargensis Linnemannia elongata Linnemannia exigua Linnemannia gamsii Linnemannia hyalina Linnemannia nantahalensis Linnemannia schmuckeri Linnemannia sclerotiella Linnemannia sp nov Linnemannia zychae Lobosporangium transversale Lunasporangiospora chienii Lunasporangiospora selenospora Modicella reniformis 0 0 0 0 41 0 1 0 0 0 0 1 41 1 0 0 0 0 1 2 1968 0 71 323 0 0 0 209 0 1 0 0 0 - - - - 0 - 2.9 - 3.0 - - - - 1.3 0.1 - 2.9 0.7 - - - - 0 1.4 - 4.2 0 - 2.0 - 0.2 - 1.7 0 - 2.7 - - - 0 - 1.6 - 0.6 - - - 82 173 87 83 630 80 177 84 86 173 630 179 85 84 85 90 178 275 2768 88 803 1546 89 186 87 1256 86 0 - 8.9 0.7 0 - 9.1 0 - - - 1 41 1 0 0 0 1 3 169 11.8 - 17.7 627 0.1 - 15.4 172 13.9 - 16.1 82 12.6 - 13.8 83 13.1 - 15.2 88 3.5 - 5.5 1.7 - 5.3 3.7 - 5.3 3.4 - 4.3 4.2 - 5.1 1.4 - 3.4 0.2 - 2.7 0.2 - 0.2 186 11.1 - 12.8 3.4 - 4.2 0 - 11.6 281 3.8 - 11.7 2.5 - 4.7 2488 2.9 - 10.3 1.2 - 3.2 2449 0 - 5.2 3.9 - 9.8 1.4 - 3.2 88 1.5 - 3.3 4.8 - 9.6 808 1528 2.9 - 9.8 1.6 - 3.9 7.9 - 9.3 1.9 - 2.9 0 - 9.5 2.5 - 4.0 2.5 - 3.9 6.4 - 9.7 1267 7.9 - 9.8 1.8 - 3.4 1.6 - 3.0 7.0 - 10.7 0 - 6.1 0 - 3.5 0 71 341 92 185 89 209 0 - 0.4 - 0 - - 0 1 0 0 88 - 172 7.8 - 9.2 82 87 78 3.3 - 3.9 0.2 - 3.6 7.4 - 8.3 0 0 0 0 - - - - 76 7.7 - 16.6 83 13.8 - 16.0 74 13.2 - 16.4 78 11.6 - 15.9 150 1024 0 - 6.0 2511 - - - 0.2 - 2.1 89 86 77 547 0.4 - 6.0 2115 0 - 7.9 2.3 - 4.3 3.0 - 4.9 0.7 - 5.1 0.4 - 5.7 - - - 0 - 1.2 0 0 0 41 0 - 2615 2.7 - 15.3 87 4.3 - 14.2 69 10.1 - 16.4 75 1.0 - 15.6 628 3.6 - 15.7 79 7.8 - 16.7 Table 2.9 (cont’d) Mortierella alpina Mortierella antarctica Mortierella bisporalis Mortierella indohii Mortierella polycephala Mortierella reticulata Necromycomortierella dichotoma Podila clonocystis Podila epicladia Podila epigama Podila horticola Podila minutissima Podila verticillata Lichtheimia corymbifera Mucor circinelloides Umbelopsis ramanniana 0 0 0 29 5 29 29 0 48 928 135 0 0 0 0 - 0.8 270 3.1 - 4.8 5 0 - 1.2 277 12.3 - 14.5 0.2 - 2.2 0.2 - 1.6 - 0 - 2.5 0 - 1.6 0.2 - 4.2 544 547 83 722 2121 1130 0.1 - 3.8 0.2 - 3.8 2.9 - 4.4 0.2 - 4.1 0.1 - 3.7 1.1 - 4.6 - - - 68 66 77 14.2 - 15.1 14.2 - 15.0 12.6 - 13.5 0 - 6.4 0 - 5.0 0 - 5.2 0 - 2.4 0 - 14.0 0 - 13.8 549 29 547 29 89 12.3 - 15.3 0 799 0.1 - 16.4 71 2122 0 - 14.1 929 146 0 - 15.0 1119 4.1 - 17.6 69 26.5 - 27.7 74 25.2 - 27.1 73 26.1 - 27.7 0 0 0 - - - - 151 Table 2.9 (cont’d) Species Actinomortierella ambigua Actinomortierella capitata Actinomortierella wolfii Benniella erionia Benniella sp nov1 Benniella sp nov2 Dissophora decumbens Dissophora globulifera Dissophora ornata Entomortierella beljakovae Entomortierella chlamydospora Entomortierella echinospaera Entomortierella lignicola Entomortierella parvispora Gamsiella multidivaricata Gamsiella stylospora Gryganskiella cystojenkinii Gryganskiella fimbricystis Linnemannia acrotona Linnemannia amoedoidea Linnemannia camargensis Linnemannia elongata Linnemannia exigua Linnemannia gamsii Linnemannia hyalina Linnemannia nantahalensis Linnemannia schmuckeri Linnemannia sclerotiella Linnemannia sp nov Linnemannia zychae Lobosporangium transversale Lunasporangiospora chienii Lunasporangiospora selenospora Modicella reniformis Mortierella alpina Mortierella antarctica Mortierella bisporalis Mortierella indohii ITS Intraspecific Interspecific - 0 - - - 0 - 0.3 n Min% - Max% 0 1 0 0 0 55 0 1 0 0 0 0 0 19 0 0 0 0 0 1 5 - 0.3 - - - - - - - - - - 0 0.2 - 7.6 0.2 - 4.5 0 - 3.4 - 0 - 3.2 0 - 11.2 - - - 2351 0 55 305 0 0 0 209 0 - 0.2 0 1 0 1 0 - 0.1 - 2.4 - 1559 0 - 6.5 0 0 0 - - - 152 n Min% - Max% 225 500 225 225 225 2108 225 500 225 225 225 225 225 1313 225 225 225 225 225 500 773 11169 225 2108 4628 225 225 225 3893 225 500 225 500 225 9468 225 225 225 1.6 - 18.7 1.3 - 18.9 1.9 - 18.4 2.5 - 21.8 3.0 - 11.9 2.3 - 18.8 2.8 - 19.5 1.7 - 19.6 2.9 - 19.8 2.3 - 18.8 1.6 - 20.8 3.9 - 19.8 3.1 - 19.7 2.9 - 21.7 2.2 - 17.3 2.3 - 19.3 3.5 - 21.5 3.8 - 20.4 0 - 20.8 1.2 - 19.1 1.2 - 19.3 1.2 - 21.2 1.2 - 19.2 2.5 - 19.0 1.9 - 21.8 1.9 - 18.7 1.9 - 19.3 1.9 - 19.0 1.2 - 20.8 1.9 - 20.3 0.6 - 18.2 1.2 - 9.1 1.9 - 8.8 2.3 - 17.8 1.2 - 21.3 3.1 - 19.9 2.5 - 20.3 0.3 - 20.4 Table 2.9 (cont’d) Mortierella polycephala Mortierella reticulata Necromycomortierella dichotoma Podila clonocystis Podila epicladia Podila epigama Podila horticola Podila minutissima Podila verticillata Lichtheimia corymbifera Mucor circinelloides Umbelopsis ramanniana 29 0 5 29 29 55 755 109 0 - 0.8 - 0 - 0.2 0 - 2.7 0 - 2.3 0 - 0.8 0 - 2.5 0 - 14.5 1580 225 773 1580 1580 2108 6948 2885 0 - 21.2 1.6 - 18.3 3.5 - 19.4 0 - 21.2 0.7 - 21.4 0.2 - 21.2 0 - 21.8 1.9 - 21.3 153 Table 2.10 – Locus sequence variability at the genus level Summary statistics from pairwise blastn analyses of the locus sequences as submitted to Genbank. Empty cells indicate that the locus was not recovered for any strains of any species in that genus. ‘n’ = the number of non-self pairwise blastn analyses conducted, where ‘0’ indicates that only one sequence was available to represent the genus and therefore no intrageneric analyses could be conducted. “Min% - Max%” = the range of percent sequence variability, where ‘0’ means the sequences were identical. Values in bold indicate a meaningful difference between the maximum observed intrageneric variation and the minimum observed intergeneric variation. 1870 2451 4955 Intrageneric Intergeneric Intrageneric Intergeneric Intrageneric Intergeneric n Min% - Max% n Min% - Max% n Min% - Max% n Min% - Max% n Min% - Max% Genus Actinomortierella Benniella Dissophora Entomortierella Gamsiella Gryganskiella Linnemannia Lobosporangium Lunasporangiospora Modicella Mortierella Necromycomortierella Podila Lichtheimia Mucor Umbelopsis n 2 109 13 9 0 0 Min% - Max% 2.1 - 2.1 0 - 12.5 1.3 - 15.7 5.5 - 14.0 - - 10700 0 - 12.0 1 5 0 0 2.3 - 9.6 - 287 971 475 676 194 94 582 189 285 90 2639 0 - 14.1 0 - 3927 0 - 13.3 3195 192 2601 0 - 18.0 13.0 - 15.2 10.1 - 16.6 0.1 - 17.3 11.9 - 14.1 13.0 - 14.0 0 0 5 29 1 - - 1.6 - 2.0 0 - 14.7 14.5 93 92 285 557 190 19.1 - 21.5 19.1 - 22.0 15.8 - 20.2 16.1 - 21.9 15.0 - 20.3 11 2 5 59 1 1 0 - 12.3 0 - 10.3 2.1 - 2.4 0 - 16.8 12.8 8 0 - 11.9 4826 0 - 24.3 2988 17.4 - 24.6 10614 0 - 15.7 16.6 - 17.7 11.9 - 13.7 14.0 - 16.6 0 - 14.8 0.1 - 10.3 0 - 13.9 5 0 2.5 - 14.5 - 285 92 2930 0 - 20.5 2508 20.5 - 23.1 20 - 23.9 15.0 - 22.7 1 - 13.1 - 2996 0 - 16.6 0 - 1331 0 - 12.2 2325 17.5 - 23.0 4101 0 - 17.6 474 386 383 1119 190 190 565 188 - 3035 192 2423 3.7 - 21.1 0.4 - 16.2 13.6 - 15.8 0 - 17.3 11.7 - 15.8 0 - 9.6 0 - 15.5 15.4 - 19.5 - 2.9 - 16.8 0 - 13.9 0 - 17.6 0 0 - - 90 90 30.4 - 35.1 30.2 - 32.9 154 n 0 1 1 Min% - Max% - 2.2 14.3 7739 0 - 14.5 n 97 Min% - Max% 22.9 - 24.8 192 17.6 - 19.1 n 5 55 6 Intrageneric Min% - Max% 0.3 - 7.7 0 - 3.6 3.0 - 6.5 0 - 5.6 0.7 - 4.2 136 5 1 192 1068 18.4 - 20.8 15.1 - 19.7 9597 1 0 0 Table 2.10 (cont’d) Genus Actinomortierella Benniella Dissophora Entomortierella Gamsiella Gryganskiella Linnemannia Lobosporangium Lunasporangiospora Modicella Mortierella Necromycomortierella Podila Lichtheimia Mucor Umbelopsis 5512 5512 Intrageneric Intergeneric 2029 0 - 19.2 3411 0 - 96 4159 0 - 16.8 2270 15.9 - 20.1 1697 15.5 - 17.5 15.9 - 21.1 4193 5 0 0 0 ef1a n 480 729 481 1735 286 289 1583 189 192 92 Intergeneric Min% - Max% 0.1 - 8.1 5.8 - 7.8 2.9 - 7.6 1.7 - 5.6 3.3 - 5.3 1.4 - 5.3 2.0 - 4.7 7.8 - 9.2 0.2 - 3.9 7.4 - 8.4 2.0 - 6.0 3.1 - 4.8 0.1 - 4.6 3343 285 2431 88 87 90 14.2 - 15.1 13.4 - 15.0 12.6 - 13.5 rpb1 Intrageneric n 24 107 19 217 1 5 Min% - Max% 0 - 17.6 0 - 12.8 1.8 - 13.5 0 - 17.6 0 10.9 - 11.8 11287 0 - 12.8 0 1 0 3126 5 4486 0 0 0 - 10.4 - 0 - 16.5 0 - 1.2 0 - 16.3 - - - Intergeneric Min% - Max% n 562 974 468 1751 190 287 95 95 190 93 3298 287 2238 90 88 88 7.6 - 20.1 11.6 - 18.0 12.6 - 16.3 0 - 17.7 13.9 - 16.1 12.6 - 15.2 0 - 11.1 0.2 - 16.6 13.2 - 16.4 11.6 - 15.9 1.9 - 16.7 12.3 - 14.5 1.9 - 17.6 25.9 - 27.7 25.1 - 27.1 25.9 - 27.7 2.7 0 - 4.6 0.6 - - 0 - 6.0 0 - 0.8 0 - 4.2 - - - 155 Table 2.10 (cont’d) Genus Actinomortierella Benniella Dissophora Entomortierella Gamsiella Gryganskiella Linnemannia Lobosporangium Lunasporangiospora Modicella Mortierella Necromycomortierella Podila Lichtheimia Mucor Umbelopsis ITS Intrageneric Intergeneric n 19 89 19 209 1 5 12209 1 5 0 3191 5 3659 Min% - Max% 0.0 - 17.7 0.0 - 18.8 0.3 - 18.4 0.0 - 20.2 11.4 7.5 - 8.7 0.0 - 17.1 0.1 2.4 - 6.3 - 0.0 - 20.4 0.0 - 0.2 0.0 - 18.8 n 1353 2668 1353 3933 540 813 18525 540 813 265 12585 813 13225 Min% - Max% 0.0 - 19.1 2.3 - 22.1 0.6 - 20.1 1.6 - 22.0 2.2 - 19.3 3.5 - 22.1 0.0 - 21.8 0.6 - 18.2 1.2 - 9.9 2.3 - 18.8 1.2 - 21.4 3.5 - 19.4 0.5 - 21.8 156 Table 2.11 – Mortierellaceae speceis chatacteristics The current and proposed classification, synonyms, geographic distribution, ecology, endobacteria, and spore morphologies of Mortierellaceae species represented in this study. New Name Basionym/ Synonym Habitat Distribution Sporangio- spores Chlamydo- spores Zygo- Spores/ Mating BRE or MRE Refer- ences Myco- bank # Actinomortierella ambigua Mortierella ambigua Soil & Dung Actinomortierella capitata Mortierella capitata Mortierella vesiculosa Actinomortierella vesiculosa Carnoya capitata Cultivated Soil, Pillbug Gut, & Dung North America, Asia, New Zealand North America, Asia, Europe Hyaline, smooth-walled, oblong Frequent, globose with large oil globule, brown Present, Hetero- thallic BRE Young, 1985 Watanabe, 2002 Takashima et al. 2018 MB308266 Spherical, leaving sporangio- phore as sticky mass Unknown Hyaline (Morpho- logically) Hetero- thallic MRE Degawa & Tokumasu, 1997 MB308267 Actinomortierella wolfii Mortierella wolfii Decaying Hay & Animal Lung North America, Asia, New Zealand Short- cylindrical, double memrane Sometimes abundant, numerous amoeba-like appendages Unknown Gams, 1977 Domsch et al. 1980 MB308269 Lunasporangio- spora selenospora Mortierella selenospora Soil, Mushroom compost Europe, Indonesia Smooth, lunate Scarce, terminal Unknown MRE Gams, 1976 Takashima et al. 2018 MB833724 Lunasporangio- spora chienii Mortierella chienii Mortierella umbellata Actinomortierella umbellata Cultivated & Forest Soil North America, Asia Reniform, smooth, double walled, lunate Absent Unknown BRE Chien, 1972 Takashima et al. 2018 MB833681 157 Table 2.11 (cont’d) Podila clonocystis Mortierella clonocystis Soil Europe Subglobose, smooth Two types: 1) small, globose; 2) consisting of broadened hyphal branches, repeatedly dichotomous Unknown Gams, 1976 Takashima et al. 2018 Podila epicladia Mortierella epicladia Forest Soil Europe, South America Globose, smooth Scarce, lemon- shaped Unknown Podila epigama Moriterella epigama Dung & Compost Europe, Asia, Australia Fusoid with rounded ends Absent Abundant Homo- thallic Podila horticola Mortierella horticola Soil, Roots of herbaceous plants Cosmo- politan Single spored, spinulose sporangia Unknown Unknown BRE Podila humilis Mortierella humilis Forest & Grassland Soil, esp Acidic; Compost Europe, Asia, North America, New Zealand Single spored, finely verrucose sporangia Unknown Naked, Hetero- thallic BRE Gams, 1976 Young, 1985 Watanabe, 2002 Takashima et al. 2018 Gams, 1976 Gams, 1977 Gams, 1977 Domsch et al. 1980 Takashima et al. 2018 Domsch et al. 1980 Takashima et al. 2018 158 Table 2.11 (cont’d) MB833767 Kuhlman, 1969 Kuhlman, 1972 Gams, 1977 Rudakov, 1978 Domsch et al. 1980 Takashima et al. 2018 Kuhlman, 1969 Kuhlman, 1972 Gams, 1977 Domsch et al. 1980 Watanabe, 2002 Takashima et al. 2018 Podila minutissima Mortierella minutissima Agricultural & Forest Soil; Semisaprophy tic mycophile Europe, New Zealand, North America, Australia Hyaline, globose Absent Hyaline, globose, smooth, small, Hetero- thallic Podila verticillata Mortierella verticillata Mortierella marburgensis Haplosporangium fasciculatum Haplosporangium attenuatissimum Soil, root, stump Asia, North America, Europe, Australia Conidia. globose, smooth Unknown Naked, Hetero- thallic MRE BRE MRE Necromortierella dichotoma Mortierella dichotoma Mouse dung; Necrotrophyic mycophile Germany Unknown Unknown Unknown Rudakov, 1978 MB833726 Gryganksiella cystojenkinii Mortierella cystojenkinii Agricultural Soil Europe Ellipsoidal to cylindrical, smooth Abundant, globose, thick-walled, light brown Unknown Gams, 1976 MB833858 159 Table 2.11 (cont’d) Gryganksiella fimbricystis Mortierella fimbricystis Bog South America Ellipsoidal to cylindrical, smooth Abundant, aerial, intercalary, ochre- orange, densely covered with fimbriate appendages Unknown Gams, 1976 Young, 1985 Gams, 1976 Gams, 1976 MB833859 MB833769 MB833770 Linnemannia acrotona Mortierella acrotona Soil India Unknown Unknown Unknown Linnemannia amoeboidea Mortierella amoeboidea Soil North America, Europe Elongate ellipsoidal smooth Abundant, either: large, light brown, blunt appen- dages; small, smooth Unknown Linnemannia camargensis Mortierella camargensis Haplosporangium gracile Linnemannia elongata Moriterella elongata Mortierella rishikesha Mortierella debilis Soil Europe Sporangioles Unknown Unknown Gams, 1977 Agricultural Soil Cosmo- politan Eongated, central oil droplet Brown, thick walled Present, Hetero- thallic BRE MRE MB833768 Kuhlman, 1969 Kuhlman, 1972 Gams, 1977 Rudakov, 1978 Domsch et al. 1980 Takashima et al. 2018 160 Table 2.11 (cont’d) Linnemannia exigua Moriterella exigua Mortierella indica Mortierella sterilis Agricultural & Forest Soil, Crop Plant Rhizosphere Europe, India, New Zealand Cylindrical "Amoeba- like" globose with irregular radiating hyphae Unknown Gams, 1977 Domsch et al. 1980 Watanabe, 2002 Kuhlman, 1975 Gams, 1977 Domsch et al. 1980 Takashima et al. 2018 Linnemannia gamsii Mortierella gamsii Mortierella spinosa Mortierella mutabilis Forest Soil, Bat Carcass Japan, Europe, North America, Australia Globose to slightly ellipsoidal Small, regular Rare, Globose, Hetero- thallic BRE MRE Linnemannia hyalina Mortierella hyalina Hydrophora hyalina Mortierella candelabrum var. minor Mortierella hygrophila Mortierella hygrophila var. minuta Facultative Biotrophic Mycophile; Soil, Roots, Basidiocarp, Decaying Plant Material, Dung Europe, India, China, North America, Antarctica Hyaline, subgolobse or ellispoidal Ellipsoidal, solitary Unknown assumed hetero- thallic Gams, 1977 Rudakov, 1978 Domsch et al. 1980 Young, 1985 Watanabe, 2002 MB833682 Linnemannia nantahalensis Mortierella nantahalensis Linnemannia schmuckeri Mortierella schmuckeri Soil Soil Linnemannia sclerotiella Mortierella sclerotiella Mouse Dung North America Mexico, India, Wyoming Europe, Asia Spherical, thick walled, yellow in mass Absent Unknown Present Unknown Unknown Ellipsoidal to subglobose, minute striate orna-mentation Abundant, globose, ochraceous Unknown Chien, 1971 Young, 1985 Gams, 1977 161 Table 2.11 (cont’d) Linnemannia sp nov Soil Australia, North America Unknown Linnemannia zychae Mortierella zychae Mortierella brachyrhiza Ant Pellet, Decaying Wood, Bog, Horse Manure Europe, Africa, New Zealand, North America, Puerto Rico Ellipsoid In chains or clusters Mortierella alpina Mortierella oblatispora Mortierella acuminata Mortierella renispora Mortierella monospora Mortierella thaxteri Water fungi & Truffle, Soil, Vermiculture, Alga, Plant Detritus, Fish Kidney & Air Bladder Asia, Europe, North America, Australia Ellipsoid, smooth, hyaline Scarce Hyaline, sub- globose to globose, uncov- ered Hetero- thallic Hyaline, smooth, wall with three distinct layers; suspen- sors hetero- gamous, Hetero- thallic Kuhlman, 1969 Kuhlman, 1972 Watanabe, 2002 Dixon- Stewart, 1932 Gams, 1977 Kuhlman 1975 Domsch et al. 1980 Watanabe, 2002 Takashima et al. 2018 Westerdijk Fungal Biodiversity Institute BRE MRE MB170280 Mortierella antarctica Soil, Root Tip, Fish Air Bladder Antarctica, USA, Europe Present Unknown Unknown MB317880 162 Table 2.11 (cont’d) Mortierella bisporalis Haplosporangium bisporale Facultative Biotrophic Mycophile, Truffle Europe Strongly verrucose and ridged, sporangia one or two-spored Unknown Unknown MB258541 Thaxter, 1914 Gams, 1977 Rudakov, 1978 Domsch et al. 1980 Young, 1985 Watanabe, 2002 Mortierella indohii Agricultural Soil, Animal Dung Asia, Europe, Africa, North America Absent Stylospores Partially invested, Hetero- thallic Chien et al. 1974 MB317900 Mortierella polycephala Mortierella polygonia Mortierella canina Mortierella echinulata Mortierella crystallina Mortierella angusta Mortierella vantieghemi Mortierella vantieghemii Mortierella raphani Mortierella vantieghemi var. raphani Mortierella lemonnieri Soil, Mouse & Rabbit Dung, Bat Cave, Bear Pen Soil, Mushroom Europe, India, North & South America Ovoidal to irregular Stylospores spherical, verrucose to echinulate Present, Homo- thallic or hetero- thallic Domsch et al. 1980 Gams, 1977 Young, 1985 MB145769 163 Table 2.11 (cont’d) Mortierella reticulata Bear Pen Soil, North & South Soil, Mouse America, Dung, Forest Soil Europe Reticulated Submerged, smooth Unknown Young, 1985 MB236117 Entomortierella beljakovae Mortierella beljakovae Root, Soil, & Ant Pellet North America & Europe Short ellipsoidal to subglobose, smooth Abundant, solitary or in chains or irregular clusters, globose, thick-walled, ochraceous Smooth and thick- walled, Hetero- thallic Naked, one large suspenso r Homo- thallic Gams, 1977 MB833729 Watanabe, 2002 Entomortierella chlamydospora Mortierella chlamydospora Azygozygum chlamydosporum Soil, Roots Entomortierella echinosphaera Mortierella echinosphaera Entomortierella lignicola Mortierella lignicola Haplosporangium lignicola Mortierella sepedonioides Soil, Rotting Roots, Vermiculture Decaying Wood, Termite Nests Japan, Europe, North America North America, Europe, Malaysia North & South America, Europe Absent Spiny, often aerial Present Intercalary or terminal, sometimes blunt spines Unknown Watanabe, 2002 Conidia/stylosp ores, spines short & stout Unknown Unknown Kuhlman, 1969 Watanabe et al. 1998 164 Table 2.11 (cont’d) Entomortierella parvispora Mortierella parvispora Mortierella gracilis Soil, Decaying Wood, Needle Litter in Ant Mound Asia, Europe, North America, Antarctica, Brazil Globose, smooth Absent Globose, Hetero- thallic BRE Kuhlman, 1972 Gams, 1977 Domsch et al. 1980 Young, 1985 Takashima et al. 2018 Lobosporangium transversale Echino- sporangium transversalis Soil North America Irregularly shaped Unknown Absent MRE Malloch, 1967 MB488122 Globose, ornamented, usually terminal Unknown Benjamin, 1978 Young, 1985 MB488121 Few, terminal Present, Homo- thallic Unknown MRE Dixon- Stewart, 1932 Young, 1985 Ger- demann & Trappe, 1974 MB833728 MB317772 Gamsiella multidivaricata Mortierella multidivaricata Decaying Wood Asia Gamsiella stylospora Mortierella stylospora Soil, Rabbit Dung, Bear Pen Soil Modicella reniformis Benniella erionia Benniella sp nov 1 Benniella sp nov 2 Soil Soil Soil North America, Europe, New Zealand South America Australia, North America North America Uganda Sporangia two- spored, sporangio- phores branch repeatedly Stylospores single on unbranched aerial hyphae Unknown Unknown 165 Unknown MRE MB833779 Unknown Unknown MRE Table 2.11 (cont’d) Dissophora decumbens Forest Litter North America Dissophora globulifera Mortierella globulifera Mortierella ericetorum Forest Litter, Agricultural Soil Japan, Europe Dissophora ornata Forest Soil South America Globose to angular or irregular in shape Globose to subglobose, echinulate, hyaline Isodiametric, elongate or irregulary lobate Terminal or intercalary, often clustered Globose to irregular, smooth, submerged, thin-walled Globose, thin-walled hyphaI swellings, intercalary or terminal, sometimes in nests Unknown Thaxter, 1914 MB160412 Globose, Hetero- thallic Turner, 1956 Kuhlman, 1972 MB833727 Unknown Veerkamp & Gams, 1983 MB135572 166 Table 2.12 - A comparison of historic Mortierellaceae phylogenies A comparison of the Mortierellaceae phylogenies generated based on the species included in this study, Wagner et al. (2013), Petkovits et al. (2011), and the taxonomic groupings of Linnemann and Gams published in 1977 - 1989. This Study Species Not Included Wagner (2013) Petkovitz (2011) Gams (1977-1989) + Gamsiella & Dissophora Actinomortierella 5 - strangulata & N/A wolfii 1 - selenospora & parvispora 11 /wolfii 12 /selenospora N/A N/A N/A Spinosa Hygrophila Spinosa Hygrophila Spinosa 9 /parvispora N/A Alpina Mortierella macrocystis Mortierella jenkinii Mortierella pulchella Mortierella alliacea Actinomortierella ambigua Actinomortierella capitata Actinomortierella wolfii Lunasporangiospora selenospora Lunasporangiospora chienii Podila clonocystis Podila epigama Podila minutissima Podila epicladia Podila horticola Podila humilis Podila verticillata Necromycomortierella dichotoma Gryganksiella cystojenkinii Gryganksiella fimbricystis Linnemanniella acrotona Linnemanniella exigua Linnemanniella gamsii Linnemanniella nantahalensis Linnemanniella amoeboidea Linnemanniella camargensis Linnemanniella schmuckeri 2 - verticillata- humilis 8 /verticillata- humulis 1 - 9 /parvispora selenospora & parvispora N/A 7 - gamsii 1 /gamsii Hygrophila Spinosa Stylospora Hygrophila Spinosa Simplex 1 /gamsii Schmuckeri 7 - gamsii 167 Table 2.12 (cont’d) Linnemanniella elongata Linnemanniella hyalina Linnemanniella sclerotiella Linnemanniella zychae Linnemanniella sp nov Mortierella alpina Mortierella antarctica Mortierella bisporalis Mortierella indohii Mortierella polycephala Mortierella reticulata Entomortierella parvispora Mortierella claussenii Mortierella bainieri Mortierella sarnyensis Mortierella armillariicola Mortierella zonata Entomortierella beljakovae Entomortierella chlamydospora Entomortierella echinosphaera Entomortierella lignicola Mortierella gemmifera Mortierella khulmanii Lobosporangium transversale Mortierella stangulata Gamsiella multidivaricata Gamsiella stylospora Dissophora globulifera Dissophora decumbens Dissophora ornata Mortierella angusta Hygrophila N/A N/A N/A Schmuckeri 7 - gamsii Hygrophila 1 /gamsii Stylospora 10 /alpina Alpina 6 - alpina & polycephala 2 /polycephala N/A Mortierella (isolated sp) Mortierella 1 - selenospora & parvispora 9 /parvispora Spinosa 3 - lignicola 6 /lignicola 5 - strangulata & 7 /strangulata wolfii 4 - globulifera 5 /mutabilis & angusta 4 /globulifera 3 /angusta 168 Hygrophila (isolated sp) (isolated sp) Stylospora Hygrophila N/A Simplex Gamsiella Stylospora Simplex Dissophora Simplex/Dissophora Simplex Table 2.12 (cont’d) Modicella malleola Modicella reniformis Benniella erionia Benniella sp nov 1 Benniella sp nov 2 Mortierella echinula N/A Hygrophila N/A N/A 169 CHAPTER 3. MORTIERELLA ELONGATA STIMULATES AERIAL GROWTH, SEED PRODUCTION, AND RESPONSES TO AUXIN, ETHYLENE, AND REACTIVE OXYGEN SPECIES IN ARABIDOPSIS THALIANA Authors & Contributions 1. Natalie Vandepol - experiment design & completion, data collection, data analysis, & writing 2. Julian Liber - generation of cured fungal isolates, qPCR, root harvesting 3. Jason Matlock - statistical analysis of plant biomass data 4. Gregory Bonito - research support, experiment design Introduction Microbial promotion of plant growth has great potential to improve agricultural yields and protect plants against pathogens and/or abiotic stresses, while also relieving economic and environmental costs of crop production (Li et al. 2018; Bedini et al. 2018). Agriculturally important metrics pertaining to plant growth promotion include aerial biomass, root biomass, root architecture, seed number, seed size, and flowering time. One group of plant beneficial microbes is early-diverging filamentous fungi, which have been implicated in assisting plants in the colonization of land (Field et al. 2015). There are three main guilds of plant mutualistic fungi relevant to this study: arbuscular mycorrhizal (AM) fungi, ectomycorrhizal (EM) fungi, and non- mycorrhizal (NM) endophytic fungi. For the purpose of this study, NM root endophytes are defined as fungi that are found inside healthy plant roots but do not make any characteristic mycorrhizal structures. Most of these fungi are thought to promote plant growth primarily by providing water and mineral nutrients, and sometimes secondarily by precluding infection by pathogens and/or priming and regulating plant defense responses (Hooker et al. 1994). However, the signaling mechanisms and fungal symbiotic structures are very distinct between these functional guilds, largely because most EM and NM associations represent convergent evolution on a phenotype, rather than a shared evolutionary mechanism of interaction (Tedersoo et al. 2010). 170 Mortierellaceae are soil fungi in the subphylum Mortierellomycotina; they are closely related to Glomeromycotina (AMF) and Mucoromycotina, some of which are EM fungi (James et al. 2006; Spatafora et al. 2016). Plant associations with Mortierella have been recorded since the early 1900s and are broadly considered NM plant associates (Stiles, 1915; Bisby et al. 1935; Domsch et al. 1980). Research on several Mortierella species have been published this past decade, however, the extent of the plant growth promotion (PGP) phenotype(s) and the underlying mechanism(s) of association are still not well understood. Recent inoculation studies of Mortierella on plant roots showed that these fungi elicit a strong plant growth promoting (PGP) phenotype on a broad range of plant hosts (Li et al, 2018; Ozimek et al. 2018; Johnson et al. 2019). Maize plants inoculated with Mortierella elongata had increased plant height and dry aerial biomass and analysis of phytohormone levels indicated high levels of abscisic acid and the auxin IAA (indole-3-acetic acid) in response to M. elongata (Li et al. 2018). In contrast, Arabidopsis inoculated with M. hyalina also showed increased total leaf surface area and aerial dry biomass, with reduced levels of abscisic acid and no stimulation of auxin- responsive genes (Johnson et al. 2019). Mortierella antarctica increases the growth of winter wheat by producing phytohormones IAA and gibberellic acid and the enzyme ACC (1- aminocyclopropane-1-carboxylate) deaminase, which degrades ACC, a precursor to the phytohormone ethylene (Ozimek et al. 2018). In this study, we have focused on the symbiosis between M. elongata and Arabidopsis, as both organisms have reference genomes (and transcriptomes) available, and their lifestyles and growth requirements are conducive to research conditions. We measured PGP of aerial growth at early and late life stages, seed production, and used RNA sequencing to characterize differentially expressed plant genes in response to fungal treatments. One additional question pertaining to Mortierella has to do with whether endohyphal bacteria that colonize these fungi impact their PGP phenotype. Although the incidence of endobacteria within isolates of Mortierella is quite low (<10%), a diversity of bacteria including Mycoavidus 171 cysteinexigens and Mycoplasma-related endobacteria (MRE) are known to colonize mycelium of diverse species across seven of the eight established Mortierellaceae phylogenetic clades (Ohshima et al. 2016; Uehling et al. 2017; Desirò et al. 2018; Takashima et al. 2018). Many species, such as M. elongata, can harbor both M. cysteinexigens and MRE, however, there appears to be a single lineage of endobacteria within any particular isolate (Desirò et al., 2018). Both MRE and a lineage of Burkholderia-related endobacteria (BRE) closely related to Mycoavidus cysteinexigens (i.e. Ca. Glomeribacter) are found in the Glomeromycotina and their impact on the fungal-plant interaction has been characterized (Bonfante & Desirò, 2017). In this study, we used two isolates of M. elongata, NVP64 and NVP80, to better understand mechanisms underlying M. elongata symbioses with plants. These isolates are colonized by Mycoavidus cysteinexigens (NVP64) and MRE (NVP80), designated as NVP64wt and NVP80wt because they are the wild-types of these strains. We generated “cured” isogenic lines of each isolate, NVP64cu and NVP80cu, where the endobacteria were removed though antibiotic treatments, to determine whether either endobacterium has an impact on the plant-fungal symbiosis. Materials & Methods Plant and fungal culturing Growth media Fungal strains were cultured in malt extract broth [MEB: 10 g/L Malt Extract (VWR), 1 g/L Bacto Yeast Extract (Difco, Thomas Scientific; New Jersey, USA)], malt extract agar [MEA: 10 g/L Malt Extract, 1 g/L Bacto Yeast Extract, 10 g/L Bacto Agar (Difco)], and Kaefer Medium [KM: 20 g/L D-Glucose, 2 g/L Peptone, 1 g/L Yeast Extract, 1 g/L Bacto Casamino Acids (Difco), 2 mL/L Fe-EDTA [2.5 g FeSO4*7H2O, 3.36 g Na2EDTA, 500 mL water], 50 mL/L KM Macronutrients [12 g/L NaNO3, 10.4 g/L KCl, 10.4 g/L MgSO4*7H2O, 30.4 g/L KH2PO4], 10 mL/L KM Micronutrients [2.2 g/L ZnSO4*7H2O, 2.2 g/L H3BO3, 0.16 g/L CuSO4*5H2O, 0.5 g/L MnSO4*H2O, 0.16 g/L CoCl2*5H2O, 0.11 g/L (NH4)6Mo7O24*4H2O], pH 6.5 with 10 N KOH, and supplemented 172 with Thiamine (1 mg/L) and Biotin (0.5 mg/L) after autoclaving and cooling to 60°C]. Sterilized seeds were germinated on Murashige & Skoog medium [1xMS: 4.4 g/L Murashige and Skoog medium (Sigma Aldrich; Missouri, USA), pH 5.7 w/ KOH, and 10 g/L agar (Sigma, product# A1296)]. Plant-fungal experiments were conducted on Plant Nutrient Medium [PNM: 0.5 g/L KNO3, 0.49 g/L MgSO4*7H2O, 0.47 g/L Ca(NO3)2*4H2O, 2.5 mL/L Fe-EDTA, 1 mL/L PNM Micronutrients [4.3 g/L Boric Acid, 2.8 g/L MnCl2*4H2O, 124.8 mg/L Cupric Sulfate, 287.5 mg/L ZnSO4*7H2O, 48.4 mg/L Na2MoO4*2H2O, 2.4 mg/L CoCl2*6H2O], 10 g/L agar (Sigma, product# A1296), autoclaved and the pH adjusted with 2.5 mL/L 1M H2KPO4 before pouring 22-24mL per 100mm2 square plate (with grid)]. To generate a fungal substrate suitable for inoculating potting mix, white millet (Natures Window; Michigan, USA), horticultural perlite (PVP Industries, Inc; Ohio, USA), and pearled barley (International Foodsource; New Jersey, USA) were each soaked overnight in DI water. The millet and barley were each boiled in fresh DI water on a hotplate until the grains began to break open, then removed from the hotplate and drained of excess water. When prepared, millet and barley expand to about 150% and 300% of the dry volume, respectively. The boiled millet, boiled barley, and perlite were mixed in a 2:1:1 v:v:v ratio. For each treatment, 600 mL of this “millet mix” was placed into a gusseted Unicorn bag (Unicorn Bags, type 10T; Texas, USA) and autoclaved for 45 minutes, allowed to rest overnight under a sterile hood and autoclaved again for 45 minutes. To generate sterile SureMix-based plant growth substrates, SureMix Perlite (Michigan Growers Products; Michigan, USA) substrate was saturated with deionized water, which was measured and placed into autoclavable bags to ensure the correct volume would be available, 1 bag for each experimental treatment. Potting mix bags were autoclaved 45 minutes on a liquid cycle, stored at room temperature for 3-7 days, autoclaved again for 45 minutes on a liquid cycle, cooled to room temperature, and rinsed through with 3L MilliQ water (18 MΩ·cm). Potting mix rinsing was performed on a dish cart covered with a double layer of window screen mesh and wrapped in a funnel fashioned of garbage bags to direct water into a floor drain, all sterilized with 173 Bleach and rinsed with MilliQ water. Arabidopsis Seed Sterilization & Germination Arabidopsis thaliana Col-0 CS70000 were obtained from the Arabidopsis Biological Resource Center. Seeds were germinated and grown for three generations in a grow room. Bulk seed was collected from the third generation and screened to homogenize seed size with 350 µm and 250 µm sieves (VWR, Pennsylvania, USA), retaining the middle fraction. Arabidopsis seeds were divided from the screened stock into 1.5mL Eppendorf tubes using a 200 seed spoon, with up to 1200 seeds per tube. Seeds were surface sterilized by: 1) washing in 800 µL 70% Ethanol for 20 seconds, 2) discarding the ethanol, 3) washing in 400 µL 20% bleach (Clorox Performance, 8.3% Sodium Hypochlorite, Clorox, California, USA) for 30 seconds, 4) quenching with 1 mL sterile water, 5) discarding the liquid, 6) repeating steps 4 & 5 three times, and 7) resuspending in 500 µL sterile water. Surface sterilized seeds were plated on 1xMS using a p1000 and sterile water, 16 seeds per plate in rows of 3, 4, 5, and 4, with about 1cm between seeds and rows (Fig. 3.1a). We germinated at least 5 times as many seeds as were needed for the experiment to allow greater control of seedling size. 1xMS germination plates were cold stratified for 2 days in the dark at 4°C to synchronize germination, then allowed to germinate and grow for 5 or 10 days, depending on the experiment, in a Percival I-36LLVL growth chamber at 103-118 µmol light with 16 hr day & 8hr night, 22°C, ambient humidity. Light levels were measured using an LI-250A light meter (LI-COR, Nebraska, USA). Potting Mix Experiments Millet Inoculum Each fungal strain was grown in 4-6 250 mL Erlenmeyer flasks with 75 mL of MEB for 2 weeks. Colonized medium was poured out into an autoclaved beaker and the mycelium collected with sterile tweezers, coarsely chopped in a sterile petri dish, and added to sterile millet mix bags. The 174 bags were lightly mixed, sealed in two places with an impulse sealer, and the fungi allowed to colonize the spawn for 2 weeks. Arabidopsis Growth Conditions Five days after germination, Arabidopsis seedlings were transplanted from 1xMS plates to plug trays of autoclaved and rinsed SureMix and moved to a Bio Chambers AC-40 growth chamber with 16hr day, 8hr night, 22°C, ambient humidity. Seedlings were grown in plugs for 11 days (16 days after germination). The soil plugs and seedling roots were treated with Zerotol 2.0 (BioSafe Systems, Connecticut, USA), an algaecide, bactericide, and fungicide containing Hydrogen Peroxide & Peroxyacetic Acid. The Zerotol was applied as a soil drench for 15 minutes, rinsed three times with distilled water, and transplanted into 4in3 pots with SureMix mixed with the appropriate millet mix treatment. Each treatment was contained in a separate waterproof tray with an 18 pot capacity (3 rows of 6 pots). Using seventeen pots per treatment left an empty spot for watering. Four days after transplanting, seedlings were treated with 2L of Peters 20-20-20 fertilizer mixed at 1/8th strength (0.1tsp/L) in MilliQ water. Thereafter, plants were watered with MilliQ water as needed. Above Ground Biomass At 34 days after transplanting and inoculation (50 days after germination), all treatments were observed to have ripening siliques, necessitating harvesting to avoid excessive loss of seed biomass during plant handling. Twelve plants per treatment were harvested by cutting the roots at the potting mix line and trimming and/or folding the aerial parts into tared envelopes (Top Flight no.10 Security Envelope, Strip & Seal). Fresh weight was recorded immediately after harvesting was complete. Plants were dried at room temperature (20-22 ˚C) for 2 weeks and re-weighed for the dry biomass. All envelope and plant biomass measurements were taken on a Mettler Toledo PG2002-S scale. Seed Collection Five plants were randomly selected for seed collection. ARACON tubes (Arasystem, Belgium) 175 were installed over the rosette. When the remaining plants were harvested for biomass, these five plants were moved to a drying room for two weeks. Dry plant material was collected and stored in wax paper bags until processing. Seeds were isolated from plant material by manually massaging the bags to release seeds, filtering through a Rösle Stainless Steel Fine Mesh Tea Strainer (Wire Handle, 3.2-inch, model# 95158) to remove large plant debris, repeatedly passing over copier paper, and picking out remnant plant matter with tweezers. Cleaned seeds were collected in tared 2mL Eppendorf tubes and weighed on a Mettler Toledo AB104-S/FACT scale. To determine average seed mass, approximately 14mg of seeds per sample were weighed on an ultrasensitive balance, adhered to a piece of white paper, scanned, and counted by image analysis in ImageJ (Appendix D.2). Statistical Analysis Since the data were extremely non-normal, we performed Wilcox ranked sum tests. Between NVP64cu v. NVP64wt, NVP80cu v. NVP80wt, and NoMillet v. Uninoculated, we used two-tailed tests. Between each fungal treatment and the Uninoculated, we performed one-tailed tests with the alternative hypothesis being “less” or “greater” as appropriate. Data analysis and visualization was conducted in R using the ggpubr and ggsignif packages (Ahlmann-Eltze, 2019; Kassambara, 2019). Agar-Based Experiments Transplanting & Inoculation We based the design of these experiments on the methodology used by Johnson et al. (2019). Arabidopsis seeds were surface sterilized and germinated as described previously. Ten days after germination, seedlings were categorized into three approximate seedling size “categories”: too small, too big, and average. Three “average” seedlings were transplanted to each mPNM plate such that the cotyledons aligned with the top line of the plate grid and the roots were not covered by the grid pattern (Fig. 3.1b). Each plate was numbered as it was populated with seedlings so that plates could be assigned to treatments serially (e.g., 1-A, 2-B, 3-C, 4-A, 5-B, 6-C, 7-A, etc.), 176 to homogenize variation and bias in seedling size throughout the transplant procedure. Plates were inoculated by transferring two 5mmx5mm squares of Kaefer Medium, sterile or colonized by the appropriate fungal culture, between the three seedlings. Root Length After transplanting and inoculation, seedlings and fungi were left undisturbed for one day to adhere to the media and minimize the likelihood of movement during handling. The plates were then imaged on an Epson scanner at 1200 dpi using Home mode and default settings (Fig 3.1b). Images were processed in ImageJ v.1.52p, using the 13 mm grid on the plates as a scale, the freehand line tool to trace the roots, and the measuring tool to determine starting root length of each seedling. Growth Chamber Light levels were measured using an LI-250A light meter (LI-COR) at 9 different points on each of the four shelves in the growth chamber (Table 3.1). To homogenize variability in environmental conditions across treatments, plates were distributed between light level regions and the lower three shelves as evenly as possible and their location in the chamber recorded. Each of the shelves accommodate 3 rows of 15 plates, with 5 plates assigned to each of the 9 zones on the shelf (Fig. 3.2). Bolting Panel To determine whether bolting time was affected by fungal colonization, PNM plates with 10 day old Arabidopsis seedlings were inoculated and monitored daily for evidence of bolting, which was defined as visible elongation of the emerging inflorescence away from the rosette (Fig. 3.3). As each plant bolted, the date was noted on the plate. Harvesting Aerial Plant Material The aerial portion of each plant was cut away from the roots and placed into a folded “envelope” made from weigh paper and dried in a 65°C drying oven for 48 hours. The envelopes of dried plants were stored in empty tip boxes and double bagged with Ziplock bags to prevent 177 reabsorption of atmospheric water before weighing. Dry plants were weighed on a DeltaRange XP26 ultrasensitive balance (Mettler Toledo; Ohio, USA). Curing Fungi of Endobacteria M. elongata lines NVP64wt and NVP80wt were cured of their endobacteria by repeated culturing in media containing antibiotics, a protocol adapted from Uehling et al. (2017). Fungi were transferred between MEB and MEA supplemented with 1 g/L Bacto Peptone (Difco), 100 µg/mL ciprofloxacin, 50 µg/mL kanamycin, 50 µg/mL streptomycin, and 50 µg/mL chloramphenicol. Each transfer was performed by transplanting a 1-4 mm2 piece of tissue from the outer edge or surface of the mycelium with a Nichrome inoculating loop and submerging the tissue under the agar surface or broth to maximize contact of the growing hyphae with the antibiotics. Transfers were performed every 3 or 4 days, alternating agar and broth substrate, for a total of 7 transfers in antibiotic media. Following antibiotic curing, tissue from the original and newly-cured lines, as well as the wild- type line, were cultured on antibiotic-free 60 mm MEA plates with an autoclaved cellophane sheet placed atop the agar. After 13 days of incubation, fungal tissue was scraped off the cellophane and DNA extracted using a CTAB-based chloroform extraction protocol (Supplementary Methods - CTAB-based DNA extraction protocol; Doyle, 1991). Statistical Analysis We conducted statistical analyses in R v.3.6.0 using the tidyverse v1.3.0, lme4 v1.1-21, lmerTest v3.1-1, car v3.0-6 packages (R Core Team, 2013; Bates et al. 2015; Kuznetsova, Brockhoff, & Christensen, 2017; Fox & Weisberg, 2019; Wickham et al. 2019). Bolting data were visualized as boxplots and visibly non-normal. We used the Kruskal-Wallis test to examine differences in bolting age between treatments (Kruskal & Wallis, 1952). Aerial dry weight data were visualized as boxplots and assessed as approximately normal and homoskedastic. We used analysis of variance (ANOVA) and linear models to examine differences in dry weight within each experimental dataset to determine the effects of environmental factors tested by each experiment. 178 Based on the results of these tests, we constructed a linear mixed model of the combined dry weight data from the two agar experiments, specifying treatment and seedling root length as fixed effects and experiment (Media Panel & Cured Panel) and plate (to account for three plants measured per plate) as nested grouping factors: We used the emmeans v1.4.4 package to perform pairwise comparisons of the model estimates for each treatment (Lenth, 2020). The estimated marginal mean, confidence interval, and significance groups were extracted for graphical summarization. RNA Sequencing & Differential Gene Expression Root Harvesting & Storage The root material for the RNAseq experiment was collected from the plants generated in the Agar experiments (Fig. 3.4). Before collecting the aerial parts of the plants for biomass assays, five plates were selected from each treatment on the basis of similar light levels within the chamber. For each selected plate, two RNAse-zap treated, DEPC water rinsed, autoclaved steel beads were placed in one RNAse-free 1.5mL Eppendorf tube, handled with gloves treated with RNAse-zap. Eppendorf tubes were placed in an autoclavable tube box, open and upright, the box wrapped in foil and autoclaved for 25 minutes on a dry cycle. After autoclaving, wearing RNAse- zap treated gloves, the Eppendorf tubes were carefully removed from the box, closed, and labeled with the numbers of the plates from which the roots were to be collected. During harvest, each plate was removed individually from the chamber, opened, and the roots collected with forceps and a scalpel. The roots were immediately placed in a cold Eppendorf tube and flash frozen in liquid nitrogen. The time between removing the plate from its place in the chamber to freezing the Eppendorf tube and roots did not exceed 30 seconds. The forceps and scalpel were soaked in 10% bleach between samples and excess liquid wicked off by a paper towel before contacting the roots. The Eppendorf tubes of root samples were stored at -80°C prior to extracting RNA. 179 RNA Extraction Tissue was homogenized by three 30 second bursts at 30Hz in a TissueLyzer II (Qiagen; Germany), with 30 second rests in liquid nitrogen between each burst. RNA was extracted using a Qiagen RNEasy Plant Mini Kit, employing 450µL Buffer RLT lysis buffer (with 10µL β-ME per 1mL Buffer RLT), an on-column DNAse digest (RNase-Free DNase Set, Qiagen), and eluting 2x with 50µL RNAse free water. A 5µL aliquot was set aside to perform an initial quantification using a NanoDrop. Samples with less than 75µg/mL were concentrated by ethanol precipitation as described below. RNA was quantified and quality checked using BioAnalyzer (MSU RTSF). All RNA samples had RIN scores >9.0. RNA Ethanol Precipitation Low concentration RNA extractions were amended with 10 µL 3 M Sodium Acetate and then 300 µL ice cold 100% ethanol, vortexed briefly to mix, and precipitated at -20°C overnight. RNA was pelleted by centrifuging for 30 min at full speed at 4°C. The RNA pellet was washed with 200 µL ice cold 70% EtOH and centrifuged for 10 min at full speed at 4°C. The supernatant was discarded and the pellet air-dried for 15 min on the bench before being resuspended in 30-50 µL RNAse-free water. A 5 µL aliquot was taken for quantity and quality analysis and the remainder stored at -80°C. Library Preparation & Sequencing Libraries were prepared using the Illumina TruSeq Stranded mRNA Library Preparation Kit with the IDT for Illumina Unique Dual Index adapters following manufacturer’s recommendations. Completed libraries were QC’d and quantified using a combination of Qubit dsDNA HS and Agilent 4200 TapeStation High Sensitivity DNA 1000 assays. The libraries were pooled in equimolar amounts and the pool quantified using the Kapa Biosystems Illumina Library Quantification qPCR kit. This pool was loaded onto an Illumina NextSeq 500/550 High Output flow cell (v2.5) and sequencing performed in a 1x75 bp single read format using a NextSeq 500/550 High Output 75 cycle reagent kit (v2.5). Base calling was done by Illumina Real Time 180 Analysis (RTA) v2.4.11 and output of RTA was demultiplexed and converted to FastQ format with Illumina Bcl2fastq v2.19.1. qPCR Primer sets for qPCR were designed using 16S rRNA gene sequences of M. elongata NVP64 and NVP80 endobacteria with the IDT PrimerQuest® Tool for 2 primers and intercalating dye (Table 3.2). Primer sets were verified using wild-type DNA samples, for which a standard curve was created with dilutions from 100 to 10-4 and efficiencies were within 90-110%. Absolute copy number calibration was not performed because only presence/absence validation was required. cDNA was synthesized for qPCR quantification using the LunaScript RT SuperMix Kit (New England Biolabs; Massachusetts, USA). qPCR reactions were composed of 7.5 µL Power SYBR Green PCR Master Mix (ThermoFisher Scientific; Massachusetts, USA), 5.5 µL nuclease-free water, 0.25µL each primer, and 1.5 µL of undiluted template. The reaction cycle was 95°C for 10 min, followed by 40 cycles of 95°C for 15 sec and 60°C for 1 min with a fluorescence measurement. A melting curve was performed following amplification: 95°C for 15 sec and 60°C for 15 sec, then a 20 min ramp up to 95°C, followed by 95°C for 15 sec. At least two reactions were performed per sample and primer combination. Sequence Analysis Raw, demultiplexed reads were quality trimmed and filtered using Trimmomatic v.0.38 (Bolger, Lohse, & Usadel, 2014). A combined reference transcriptome was constructed from the Arabidopsis Thaliana Reference Transcript Dataset 2 (AtRTD2_19April2016.fa, accessed 10/21/2019) and Mortierella elongata AG77 (Morel2_GeneCatalog_transcripts_ 20151120.nt.fasta.gz, project 1006314, accessed 10/21/2019) (Zhang et al. 2016; Uehling et al. 2017). This combined reference transcriptome was indexed in Salmon v0.11.3 and used to quasi- map the trimmed reads to transcripts (Patro et al. 2017). DGE Analysis A transcript-to-gene (tx2gene) table was constructed in R v.3.6.0 using only Arabidopsis gene 181 annotations (AtRTD2_19April2016.gtf.txt, accessed on 01/12/2020), since fungal reads were extremely rare in the dataset (R Core Team, 2019; Zhang et al. 2016). Salmon quants.sf files were imported into R using tximport (type=salmon; Soneson et al. 2015). Differential gene expression analysis was carried out with both the EdgeR package and the DESeq2 package in R (Robinson et al. 2010; McCarthy et a., 2012; Love et al. 2014). Gene expression was computed for each treatment across the three biological replicates, with the control treatment specified as the reference level in the experimental design matrix. Differentially expressed genes were identified by contrasting each fungal treatment against the control. In DESeq2, gene lists from each comparison were filtered by adjusted p-value of 0.05 and an absolute value of log2 fold change (LFC) cutoff of 0.585, which corresponds to a fold change in expression of 1.5. We generated volcano plots of these pairwise comparisons using the EnhancedVolcano package in R (Blighe et al. 2019). In EdgeR, the gene list encompassed all four fungal treatments with a single p-value for each gene, so the EdgeR gene list was filtered by overall p-value and whether at least one fungal treatment LFC meeting the LFC cutoff (Robinson, McCarthy, & Smyth, 2010; McCarthy, Chen, & Smyth, 2012). The DESeq2 gene list was filtered to include only genes also present in the EdgeR gene list. Since DESeq2 provided p-values for each comparison, we used the log2-fold change and adjusted p-value of the DESeq2 analyses to compose our final DEG table. Gene ontology was assigned by referencing TAIR and UniProtKB annotation databases and synthesizing the most detailed and supported annotations (Berardini et al. 2015; UniProt Consortium, 2019). Results Potting Mix Experiments Mortierella elongata increased mature Arabidopsis aerial dry biomass All fungal treatments had significantly higher aerial dry biomass than the uninoculated millet control. Aerial dry biomass of full-grown Arabidopsis plants was not significantly different between 182 NVP64cu and NVP64wt or between NVP80cu and NVP80wt, but was significantly higher in the no-millet control than the uninoculated millet control (Fig. 3.5). Mortierella elongata impacted Arabidopsis seed production As with the aerial biomass, total seed mass was significantly higher in the no-millet control plants as compared to the uninoculated millet control. Both NVP80cu and NVP80wt were significantly higher than the uninoculated millet control (Fig. 3.6). In terms of endobacteria, no significant differences in seed mass were found between NVP64wt/cu, nor between NVP80wt/cu isogenic isolate pairs (Fig. 3.7). Unlike total seed mass, the average seed mass of the uninoculated millet control was significantly higher than the no-millet control and NVP64cu. There were no significant differences between uninoculated millet control, NVP80cu, and NVP80wt treatments. Given the potential that sufficient seeds in the fungal treatments could be smaller due to incomplete development, rather than total reduction in seed size, we set out to determine whether this might be visible in histograms of individual seed areas from the image analysis. This would be represented by a bimodal histogram with peaks representing immature and mature seeds. No clear bimodality could be seen in most treatments (Fig. 3.8). The observed slight curve topography more likely represents variation in the mean seed size between samples as opposed to consistent bimodality across all samples. From the total seed mass and the average seed mass, we calculated the total seed number and found no significant differences between NVP64cu and NVP64wt or between NVP80cu and NVP80wt (Fig. 3.9). However, NVP80cu, NVP80wt and the no-millet control each had significantly higher total seed number than the uninoculated millet control. Agar Experiments Mortierella elongata did not impact the timing of Arabidopsis bolting The Kruskal-Wallis Test was conducted to examine the age at which plants bolted according to fungal treatment. No significant differences (Chi square = 4.92, p = 0.296, df = 4) were found 183 among the five treatments. The mean age at which an inflorescence could first be seen to elongate from the rosette was 22 days, 12 days post transplanting and inoculation (DPI). Therefore, we harvested all further agar experiments at 12 DPI to prevent bolting from affecting dry weight data, which differed from the 7 day co-cultivation time used by Johnson et al. (2019). Mortierella elongata increased young Arabidopsis aerial dry biomass We expected that several environmental factors could potentially impact our observation of how Arabidopsis responds to M. elongata. These included the (1) starting size of the plant; (2) local light level, (3) medium on which the fungus was cultured, and (4) process by which the fungi were cured of their endobacteria. We determined that there was no statistically significant correlation between light level and harvested plant dry weight in any of the treatments (Table 3.3). We performed linear modeling of the dry weights as a function of medium, treatment, and interaction between those, and determined there were no significant differences in harvested plant dry weight based on media (F1, 110=0.966, p=0.328; Table 3.4) and no significant interaction between medium and treatment (F4,110=0.331, p=0.857). Analysis of variance found no statistically significant differences in mean harvested plant dry weight, between three independently generated cured lines (L0, L1, and L2) of M. elongata, for both NVP64 (F2,42=0.443 p=0.645) and NVP80 (F2,42=1.966, p=0.153), suggesting that differences between wild-type (wt) and cured (cu) strains are likely due to the presence/absence of endobacteria, rather than accumulated mutations from the antibiotic passaging protocol. Analysis of variance in seedling root length showed that the mean seedling root length was consistent between treatments of each experiment (F4,755=0.953, p=0.433), but differed significantly between experiments (F1,755=267.3, p=2e-16), with no significant interaction effect (F4,755=0.541, p=0.706). Preliminary linear model analysis showed a significant positive correlation between seedling root length and harvested plant dry weight, with no significant differences between the slope of this correlation across experiments or treatments (Table 3.5). We fit a linear mixed model of combined aerial dry weight data from both experiments as a function of treatment and seedling root length. Results of this 184 model can be seen in Table 3.6. The estimated marginal means of aerial dry weight was significantly higher in all four fungal treatments compared to the control, but there were no significant differences between fungal treatments (Fig. 3.10). All Mortierella elongata strains colonize Arabidopsis roots evenly We used the cycle number at which the fluorescent signal of the qPCR probe exceeded the threshold level to calculate the ratio of M. elongata RNA to Arabidopsis RNA in each reaction. This ratio represents the degree of fungal colonization of plant roots. There were no significant differences in this ratio between any of the fungal treatments (p>0.1) and each lineage of endobacteria was detected only in the wild-type strains (Table 3.7; Fig. 3.11). Differential Gene Expression Molecular Results Sequencing returned an average of 34.7 million (30.5-37.7M) reads per sample, with an average of 97.64% (97.22-97.85%) mapping rate to the combined reference transcriptome. Of the mapped reads, an average of 99.82% (98.64-99.99%) mapped to plant transcripts (Table 3.8). Arabidopsis differentially expressed genes in response to Mortierella elongata We conducted initial RNAseq data exploration in DESeq2 to confirm consistent gene expression profiles between biological replicates of each condition (Fig. 3.12). We noted that all four fungal treatments clustered together away from the control and that there was no observed clustering by isogenic strain (NVP64 or NVP80) or by cured/wild-type. Indeed, NVP64cu and NVP80wt seem to be the most similar. DESeq2 identified a total of 465 genes that were differentially expressed and met LFC and adjusted p-value cutoffs in at least one of the four fungal treatments as compared to the control. Of these, there were 301 DEGs in NVP64cu v. Control, 135 in NVP64wt v. Control, 142 in NVP80cu v. Control, and 213 in NVP80wt v. Control (Fig. 3.13). EdgeR identified 679 genes as being differentially expressed at a collective adjusted p-value threshold, and at least one sample 185 meeting the LFC cutoff. There were 376 DEGs in NVP64cu v. Control, 240 in NVP64wt v. Control, 282 in NVP80cu v. Control, and 319 in NVP80wt v. Control. When only considering genes present in both the EdgeR and DESeq2 DEG lists, our analyses identified 385 DEGs (Table 3.9; Fig. 3.14). Since DESeq2 provided p-values for each comparison, we used the log2-fold change and adjusted p-value of the DESeq2 analyses to filter the expression patterns in the final DEG list. Thirty-four plant genes were differentially expressed when inoculated with any/all of the four fungal treatments as compared to the uninoculated control, 55 were significantly altered in expression in three fungal treatments, 114 were significantly altered in two fungal treatments, and 182 DEGs were significantly altered in only one fungal treatment (Table 3.9). Of the included LFC values, all treatments were consistent in the trend of being either up- or down-regulated as compared to the control, with one exception (Table 3.9). Defense response genes Thirty-four DEGs were broadly involved in plant defense against other organisms. Nine were specifically related to defense against bacteria, eight of which were upregulated. These included FLS2 and CML12, which are essential to the perception of an innate immune response to bacterial flagellin and CML12 also participates in regulating the activity of an auxin efflux protein (Bender & Snedden, 2013). Three cysteine-rich receptor-like protein kinases (CRK10, CRK18, and CRK31) were up-regulated. The functions of CRKs are not well understood, though several members of this protein family, including CRK10, have been shown to respond to pathogens and/or oxidative stress (Rayapuram et al. 2012). The down-regulated gene was euonymus lectin S3 (EULS3), which is involved in ABA-mediated stomatal closure in response to bacterial pathogens (Van Hove et al. 2015). Twelve DEGs were involved in defense responses to fungus, 7 down-regulated and 5 up- regulated. Foure of these, dl4875c, AT4G22214, AT4G22217, and CAPE3, were significant in all four treatments. The first, dl4875c, is a down-regulated ubiquitin-protein transferase involved in regulating defense response (Mukhtar et al. 2011). The second and third are predicted to be 186 members of the defensin-like protein family, which are involved in killing non-self cells. The fourth is an up-regulated CAP (Cysteine-rich secretory proteins, Antigen 5, and Pathogenesis-related 1 protein) superfamily protein of unknown function. Of the other defense genes, CEP1 is a down- regulated protease that supports the final stages of programmed cell death during fungal infection (Höwing et al. 2014). TI1 is another down-regulated member of the defensin-like protein family involved in defense responses to fungi (Chassot et al. 2007). The other four up-regulated DEGs were HR3, F18O19.27. HR3 is expressed in response to fungal infection, though it does not confer resistance to fungal pathogens (Xiao et al. 2007). Nine DEGs were identified as defense responses via hormone signaling or metabolism. These included AZI1, AZI3, and EARLI1, which are collectively involved in salicylic acid signaling and priming of both systemic acquired resistance (SAR) and induced systemic resistance (ISR) (Cecchini et al. 2015). Unexpectedly, AZI1 was up-regulated while the other two were down- regulated. Transcriptional regulator of defense response TDR1 was up-regulated and is involved in ethylene signaling in response to chitin (Riechmann & Meyerowitz, 1998; Libault et al. 2007). GDSL lipase GLIP2, also up-regulated, responds to pathogen attack, salicylic acid, jasmonic acid and ethylene by down-regulating auxin signaling (Lee et al. 2009). Hormone Signaling Genes In total, there were 36 DEGs primarily related to hormone signaling and 18 “cross-categorized” as hormone signaling in defense (9 DEGs), development (3 DEGs), metabolism (3 DEGs), or abiotic stress responses (3 DEGs). In addition to GLIP2 described earlier, twelve DEGs were related to auxin biosynthesis and/or signaling, 8 down-regulated and 4 up-regulated in plants grown with M. elongata. Four enzymes related to auxin biosynthesis (NIT1, NIT2, GH3.17, GH3.7, and UGT74E2) were down-regulated. NIT1 and NIT2 are nitrilases that mediate IAA production from indole-3-acetonitrile (IAN) (Grsic- Rausch et al. 2000; Pollmann et al. 2006). GH3.17 conjugates amino acids to IAA (Staswick et al. 2005). GH3.7 conjugates cysteine to chorismate, which is a precursor to salicylic acid and 187 aromatic amino acids, depending on downstream modifications (Mano & Nemoto, 2012; Holland et al. 2019). The cysteine-chorismate conjugate is a precursor to aromatic amino acids, including tryptophan, which is a biosynthetic precursor to IAA (Pieck et al. 2015; Holland et al. 2019). UGT74E2 glycosylates the auxin indole-3-butyric acid (IBA), which has activity independent of IAA and can be interconverted to IAA (Tognetti et al. 2010). Two auxin efflux carrier proteins (PILS3 and PILS5) were down-regulated; these proteins regulate intracellular IAA concentration and are themselves regulated by brassinosteroid signaling and abiotic environmental stimuli, such as light and temperature (Sun et al. 2019). The ethylene- and auxin-responsive genes ARGOS and SAUR76 were up-regulated. In addition to ARGOS, SAUR76 and TDR1, seven DEGs were related to ethylene signaling. The ethylene biosynthesis enzyme ACS7 was down-regulated (Riechmann & Meyerowitz, 1998; Huang et al. 2013; Prasch & Sonnewald, 2013). Ethylene responsive transcription factor RAP2-9 and three ethylene response factors (ERT2, ERF59, and ERF73), the first three of which were up-regulated and the last was down-regulated. ERT2 is a negative regulator of ethylene-activated signailing pathways (Sakai et al. 1998). ERF73 and ERF112 are ethylene-responsive transcription factors. ERF59 is a point of cross-talk between the ethylene and jasmonic acid (JA) signaling pathways (Pré et al. 2008). Three DEGs were found to be related to jasmonic acid synthesis and signaling: JOX2, RGLG3, and WRKY51. The first two were down-regulated and the last was up-regulated. JOX2 hydroxylates JA, repressing the JA signaling pathway (Smirnova et al. 2017). RGLG3 is an upstream modulator of JA signaling, potentially by mediating SA suppression of JA signaling (Zhang et al. 2015). WRKY51 is one of the proteins that mediate SA repression of JA signaling (Gao et al. 2011). Three DEGs were found to be involved in abscisic acid pathways (NCED3, MYB74, and KIN1), all down-regulated (Kurkela & Franck, 1990; Sato et al. 2018). NCED3 is a key enzyme in ABA biosynthesis. We also identified GIM2 as an up-regulated DEG in our dataset. GIM2 188 negatively regulates ABA sensitivity and gibberellin biosynthesis (Li et al. 2019). Two wall-associated signaling kinases, WAK1 and WAK2, and two genes that regulate WAK1 activity, GRP3 and GRP3S, were up-regulated in fungal treatments (Park et al. 2001; Brutus et al. 2010). GRP3 is expressed in response to ABA, SA, and ethylene (de Olivera et al. 1990). WAK1 functions in defense responses via salicylic acid signaling (Brutus et al. 2010). Three DEGs were related to brassinosteroid signaling, a putative squalene epoxidase (SQE4) was down-regulated and baurol synthase BARS1 and brassinosteroid-induced positive cell growth regulator ARL were up-regulated (Hu et al. 2006; Lodeiro et al. 2007; Rasbery et al. 2007). Abiotic Stress Response Genes Fifty-five DEGs were identified as having functions related to abiotic stress responses. Fifteen DEGs were related to hypoxia and/or oxidative stress, 6 of which were down-regulated and 9 up- regulated. Seven DEGs were related to drought and/or cold/salt stress, all of which were down- regulated. Eleven DEGs were identified as responsive to iron, potassium, and phosphate deficiency, all but one down-regulated. Finally, four DEGs are broad responses to ABA and many other abiotic stresses, one is a hypothetical protein (T9L3_30), and eight are classified as RmlC- like cupins superfamily proteins, seven of which were up-regulated. Development We identified 30 DEGs related to plant development. Five down-regulated DEGs (MRN1, MRO, THAS1, THAH, and THAD) compose two operon-like gene sets involved in root development (Field & Osbourn, 2008; Field et al. 2011; Go et al. 2012; Johnson, 2012). Six DEGs were related to general growth regulation, three up-regulated and three down-regulated. Twelve DEGs were annotated as either regulating flowering or only expressed during the flowering life stage, ten of which were down-regulated, including a transcription factor involved in gibberellin signaling. Metabolism One hundred and nine DEGs were related to metabolism, some with tenuous or conflicting 189 annotations related to hormone signaling or defense pathways. Ten DEGs were related to toxin catabolism, 9 of which were various glutathione S-transferases, 7 of which were down-regulated. There were also 14 DEGs related to protein modification. Eleven DEGs were transporters of various nutrients and metabolites, including amino acids, nitrate, toxins, and cations, almost all of which were down-regulated. Ten DEGs were related to amino acid metabolism and/or nitrogen metabolism, six down-regulated and four up-regulated. Unknown There were 77 DEGs with no broad process or pathway classification, 35 down-regulated and 42 up-regulated. Eight were transmembrane proteins or described as having extracellular activity. Notably, 15 DEGs were significant in at least 3 of the 4 fungal treatments and therefore of consistent importance. Discussion In this study, we sought to molecularly characterize symbiosis between plants and M. elongata. We specifically assayed aerial plant growth, seed production, and differential gene expression in Arabidopsis plants responding to several different M. elongata strains. We also tested whether two different fungal strains, each associated with (or cured of) a different bacterial endosymbiont, had significantly different phenotypes for each tested metric of plant growth. Finally, we used RNA-seq to identify plant genes that are differentially expressed during Arabidopsis-M. elongata symbiosis in order to begin describing the mechanism of interaction. Mortierella elongata promotes Arabidopsis growth independent of endobacteria We found that Arabidopsis inoculated with any of our four fungal treatments had increased aerial growth compared to the uninoculated controls, whether harvested before or after flowering. These results are corroborated by recent studies of M. elongata inoculated maize, where M. elongata increased the height and dry aerial biomass of maize in V3-V5 early vegetative stages, which corresponds to when maize has begun relying on photosynthesis and the environment for 190 resources, rather than seed resources (Li et al. 2018; Abendroth et al. 2011). We were surprised to see that neither BRE nor MRE had a significant impact on plant growth in either experimental system, although NVP80wt showed a weak trend towards smaller plants than NVP80cu in the potting mix experiment (Fig. 3.5). Our seed production data also indicate that fungal treatments had a strong effect on Arabidopsis seed size and total seed number. NVP80cu and NVP80wt both had significantly higher total seed number than the uninoculated millet controls, whereas neither NVP64cu nor NVP64wt were significantly different from uninoculated control. Although 5 replicates were used, additional replication might have strengthened the statistically weak trend of NVP64wt toward higher seed number. Average seed size was unexpectedly higher in the uninoculated millet control plants compared to most of the fungal treatments (Fig. 3.7). This may represent a fitness strategy in which plants grown under stressful conditions create fewer, larger seeds to increase offspring fitness, whereas healthy plants can produce a higher number of smaller seeds because they will each need fewer starting resources to survive and reproduce (Sadras, 2007; Breen & Richards, 2008). The potting mix experiments demonstrated that uninoculated grains in control treatments not only invite colonization by environmental contaminants, but the grains have a strong, consistent negative impact on plant growth. Preliminary studies of Mortierella interacting with millet plants using millet-based spawn suggest that some of this effect may be due to allelopathic compounds in the grains, as millet plants were observed to be much less affected by a millet-based spawn than Arabidopsis (data not shown). Comparisons between uninoculated spawn and inoculated spawn treatments, neglecting to include a no-spawn control, could potentially bias results toward stress mitigation and not neutral environment plant growth promotion. Another challenge of the potting mix-based experiments was deciding at what point to conclude the experiment, since the highly stressed uninoculated spawn control plants matured much sooner than the other treatments. The difficulty of handling maturing Arabidopsis without significant loss of seeds and 191 siliques necessitated harvesting all plants for aerial biomass before the plants completed seed production and senesced. This meant that the plant life stage could not be controlled in the biomass and seed production data. The potting mix experiment was necessary and technically sufficient to collect data about seed production but may have benefited from an increased sample size for seed collection rather than harvesting those plants for aerial biomass. The agar system was more suited to assay early life- stage aerial growth and root gene expression. Now that M. elongata has been shown to impact plant growth, more extensive experiments can be justified to further explore plant-fungal interactions. The agar system is well suited for high-throughput assays of plant and fungal knock- out mutants to further isolate important genes and pathways involved in this symbiosis. An improved potting mix system, with a grain-free inoculation protocol, would be ideal to non- destructively track plant growth over time and to construct a more detailed description of how M. elongata affects plant growth and development. Mortierella elongata may regulate Arabidopsis defense and abiotic stress responses A number of plant hormones mediate the initiation and maintenance of plant-microbe symbioses, including auxins (most commonly IAA), jasmonates/jasmonic acid (JA), salicylic acid (SA), abscisic acid (ABA), ethylene (ET), and brassinosteroids (BRs). These hormones can be produced by both the plant and microbial symbionts and are often required to appropriately suppress and redirect the plant defense response in order for the microbe to establish symbiosis. The regulation and importance of each hormone depends on the type of interaction, pathogenic vs. beneficial, bacterial vs. fungal, and both species of plant and microbe that are interacting. For example, ethylene suppresses AMF colonization, but promotes EM colonization (Chanclud & Morel, 2016; Foo et al. 2016; Splivallo et al. 2009). Similarly, the beneficial non-mycorrhizal fungi M. hyalina and S. indica stimulate plant production of jasmonic acid and salicylic acid, respectively, when initiating symbiosis with Arabidopsis (Meents et al. 2019; Vahabi et al. 2015). While this study did not include direct measurement of phytohormone levels, we did identify 192 several DEGs related to the biosynthesis and signaling of ethylene, auxin, and abscisic acid. Auxin and Root Development Many fungi synthesize and secrete auxin, which have been shown to impact plant growth. M. verticillata and M. antarctica both synthesize IAA and were shown to improve winter wheat seedling growth (Ozimek et al. 2018). The genome of M. elongata (strain AG77) has the key genes of IAA synthesis and maize roots inoculated with M. elongata had a 37% increase in IAA concentration (Li et al. 2018). Our study found that M. elongata suppressed Arabidopsis auxin biosynthesis genes (NIT2 and GH3.7), but up-regulated several auxin-responsive genes. Since 1) Arabidopsis auxin biosynthesis is being down-regulated, 2) auxin synthesis is generally self- inhibitory in plants, and 3) auxin response genes are up-regulated, we hypothesize that the Arabidopsis roots are responding to M. elongata-derived auxins (Salehin et al. 2015). In contrast, Arabidopsis auxin-related genes did not respond to initial or established M. hyalina colonization, even though Arabidopsis roots had a 3-fold increase in IAA concentration during initial colonization as compared to control roots (Johnson et al. 2019; Meents et al. 2019). Moreover, some of this IAA was again fungal in origin, as the M. hyalina mycelium alone had a significantly higher IAA concentration than the tested pathogenic fungi (Meents et al. 2019). Their assay did show a very brief response to auxin that quickly dissipated to background gene expression levels. They hypothesized that Arabidopsis roots did respond to fungal auxin very briefly, but the auxin response was likely interrupted by other plant hormones/elicitors. Indeed, JA acts antagonistically to auxin responses and M. hyalina was found to produce high levels of JA in pure culture and initially stimulates significant accumulation of JA in Arabidopsis roots (Meents et al. 2019). However, JA levels were not elevated several days after initial colonization, indicating that these hormone responses are not maintained throughout the Arabidopsis-M. hyalina symbiosis (Johnson et al. 2019). Since we found increased auxin responsive gene expression during well- established symbiosis, our data suggest M. elongata employs a different phytohormone regulatory strategy than is indicated in M. hyalina. 193 Enhanced aerial plant growth by auxin-producing microbes is attributed to improved root structure, particularly lateral root growth, but assessing the impact of Mortierellaceae fungi on plant root development is not so straightforward (Li et al. 2018). Johnson et al. (2019) found that M. hyalina had a slight, but significant negative impact on Arabidopsis root dry biomass compared to uninoculated plants and identified three root development (SHR, CPC, and AHP6) genes that responded to M. hyalina as opposed to the plant pathogen Alternaria brassicae. These genes were not among the DEGs identified in our study. However, we did find that the entire operon-like gene set related to thalianol biosynthesis and metabolism was downregulated by M. elongata (Field & Osbourn, 2008). Thalianol-related metabolites are predicted to function in promoting root development, but the mechanism is still under investigation (Field & Osbourn, 2008). Future research is needed to determine how each of these fungi impact Arabidopsis root development and how that relates to increased aerial plant growth. Ethylene (ET) Ethylene is a plant hormone involved in maturation, senescence, and response to biotic and abiotic stress. Decreasing the level of ethylene in plant tissues generally promotes plant growth. The role of ET in plant response to pathogens is well characterized and includes increased ET biosynthesis and signaling through a single conserved pathway, which includes proteins in the TDR1 family (Broekaert et al. 2006). However, the origin and role of ET in the initiation of beneficial plant-fungal symbioses is specific to the fungi involved. For instance, elevated ET appears to promote colonization by ectomycorrhizal fungi, but inhibits colonization by AMF (Chanclud & Morel, 2016; Foo et al. 2016; Splivallo et al. 2009). Moreover, the ET signaling pathway is known to have multiple points of crossover with other hormone signaling pathways, including JA and cytokinin, some of which occur through the ERF family of transcription factors, including TDR1 (Broekaert et al. 2006). In our study, we found that Arabidopsis colonized by M. elongata had down-regulated ACC synthase ACS7, which synthesizes the metabolite 1-amino- cyclopropane-1-carboxylate (ACC), which is a precursor to ethylene. However, some genes 194 related to ethylene signaling were up-regulated in response to M. elongata. Since ET biosynthesis is downregulated in Arabidopsis roots in response to M. elongata, it is possible that related response genes are being up-regulated via other hormone pathways, although there were only three DEGs specifically associated with JA signaling in our dataset and they were each significant in only one fungal treatment. Abscisic Acid (ABA), Abiotic Stress, & Reactive Oxygen Species (ROS) In general, genes related to ABA and abiotic stress are down-regulated by M. elongata. These include the ABA synthesis enzyme NCED3 and responses to drought, cold, salt, iron deficiency, potassium deficiency, phosphorous deficiency, and heavy metal tolerance. Many plant growth promoting fungi are thought to transport water and nutrients to plants, particularly phosphorus. Mortierellaceae species are known to solubilize phosphate and improve its uptake in plants (Zhang et al. 2011). Considering the availability of potassium, phosphorus, and iron in the PNM growth medium, it is striking that so many genes related to deficiencies of these nutrients were down-regulated compared to the control plants. There were two main exceptions to this reduction in abiotic stress: oxidative stress responses and a group of RmlC-like cupins superfamily proteins whose function is unknown. ROS are a common plant defense response to both beneficial and pathogenic microbes (Nath et al. 2017). Both M. hyalina and M. elongata stimulate ROS-responsive genes, though the two ROS-responsive genes specifically tested by Johnson et al. (2019) were not among the DEGs in our dataset. Six of the up-regulated oxidative stress genes are peroxidases. One is a raffinose synthase. Raffinose is thought to act as an osmoprotectant and ROS scavenger (Nishizawa et al. 2008). Finally, we observed down-regulation of uridine diphosphate glycosyltransferase UGT74E2, which responds to ROS and drought to convert the auxin IBA to IBA-Glc (Tognetti et al. 2010). ROS also stimulates conversion of IAA to IBA. Increased expression of UGT74E2 further sequesters IBA and prevents oxidation back to IAA (Tognetti et al. 2012). While no UGT74E2 suppression or deletion mutant phenotypes have been reported, overexpression of 195 UGT74E2 leads to increased sensitivity to ABA (Tognetti et al. 2010). In summary, we observe down-regulation of auxin synthesis, ABA synthesis and signaling, and an important gene connecting the ROS, ABA, and auxin pathways. From this, we infer that M. elongata stimulates ROS responsives genes, but these responses are isolated from other hormone pathways and limited to peroxidases and antioxidants. Calcium Signaling and Plant Defense In addition to hormones, many plant-microbe interactions involve calcium signaling in plant roots (Yuan et al. 2017). M. hyalina symbiosis with Arabidopsis is activated by calcium signaling (Johnson et al. 2019). This calcium-signaling was required both for the plants to receive pathogen protection by M. hyalina, and for M. hyalina to colonize Arabidopsis roots, but the signaling- deficient plants still showed the wild-type aerial growth promotion. This suggests a calcium- signaling dependent defense response to limit the rate of root colonization by M. hyalina. Johnson et al. (2019) identified four Ca-signaling genes (At3g47480, At3g03410, At5g23950, and At3g60950) that specifically responded to M. hyalina, as opposed to the plant pathogen Alternaria brassicae. These genes were not among the DEGs identified in our study. However, we did note up-regulation of the calcium-signaling gene CML12 identified in our RNA-seq experiment, which is induced by both stress and hormone signals, including auxin, touch, darkness, oxidative stress, and herbivory (McCormack & Braam, 2003; Cho et al. 2016). DEG analyses show that M. elongata stimulated several general, fungal, and bacterial defense-related genes in Arabidopsis roots. However, we also noted suppression of genes involved in programmed cell death and production of defensin-like proteins meant to kill cells of invading organisms. As such, these defense responses could indicate both regulation of M. elongata colonization and a priming of the plant innate immune response, explaining the elevated expression of definitively bacterial defense genes like FLS2. As noted in maize-M. elongata symbioses, M. elongata may curate auxin levels to colonize maize roots to suppress systemic defense through the salicylic acid pathway (Li et al. 2018). Further, this active microbial regulation 196 of the plant immune response can promote plant growth in a field environment by limiting further resource allocation to defense when attacked by pathogens (Kazan & Manners, 2009; Li et al. 2018). The role of phytohormones in fungi While it is well established that fungi can manipulate, and often produce, phytohormones to orchestrate plant responses as described here and in Chapter 1, the effects of phytohormones on fungi are not understood. Studies of plant hormone impacts on fungal growth and development are currently limited to a few plant pathogens and AM fungi. Generally, exogenous ethylene promotes fungal spore germination and mycelial growth (Lockhart et al, 1968; El-Kazzaz et al, 1983; Kepczynska, 1989, 1993). Exogenous ethylene is required for spore germination in species of Alternaria, Botrytis, Pennicilium, and Rhizopus and often promotes mycelial growth (Kepczynska, 1989). It is worth noting that these species infect fruit and likely evolved this requirement to ensure spore germination in the presence of ripening fruit, limiting the relevance of those findings to mechanisms employed by root-associated fungi (El-Kazzaz et al, 1983). Gryndler et al (1998) found that exogenous auxin (IAA) repressed hyphal growth of two AM fungi, Glomus fistulosum and G. mosseae, at biologically relelvant concentrations, but abscisic acid (ABA) and cytokinins had no perceivable effect until applied in concentrations very high, non- physiological concentrations. The current model of phytohormone regulaiton of AM fungi suggests that 1) SA inhibits pre-symbiotic growth; 2) ethylene, JA, and cytokinins inhibit symbiotic fungal growth inside plant roots; and 3) auxin, JA, and ABA promote the formation and function of arbuscules within plant root cells (Pozo et al, 2015). It is unclear how these relationships and regulatory systems apply to the growth, development, or plant associations of M. elongata. Future Directions In this study, we measured plant growth and productivity at early and late life stages after a stable symbiosis had been established. It is important to note that the mechanism by which M. elongata maintains symbiosis with Arabidopsis may be very different from that required to initiate 197 and establish symbiosis, as in the case of JA levels in the Arabidopsis-M. hyalina symbiosis or transient stress responses in Arabidopsis during S. indica infection (Johnson et al. 2019; Meents et al. 2019; Vahabi et al. 2015). Future research may illuminate mechanisms of extremely early stages of interactions between M. elongata and plants. Our results indicate that M. elongata may affect Arabidopsis root architecture and development. When designing plant-fungal symbiosis experiments, it may be important to conduct phytohormone tests in a medium/system that shields roots and “below-ground” interactions from light to prevent any fungal production of 2-keto- 4-methylthiobutyric acid (KMBA) to ethylene that might not take place in a natural system (Splivallo et al. 2009; Chagué, 2010). It would be highly informative to conduct shared-media assays that test whether direct contact is required for this symbiosis. A spent-medium assay could also be used to test whether constitutively produced metabolites from one organism trigger a response in the other to initiate interaction. We were unable to analyze the fungal transcriptome due to extremely low read abundance. It might be possible to use a microbiome enrichment kit or other technique to isolate or increase the proportion of fungal RNA. This could allow co-expression network analysis and significantly improve our understanding of the fungal response to the plant, rather than just the plant response to the fungus. The hormone signaling pathways discussed here are each composed of scores to hundreds of genes. Our differential gene expression analysis yielded only ~45 genes related to hormone signals, with at most 10-12 DEGs in any one hormone signaling pathway, as in the cases of auxin and ethylene. While it is concerning to have so small a portion of these signal pathways represented, we are encouraged in our focus on auxin and ethylene as potentially important mediators due to the presence of key biosynthesis and response genes in our dataset. We present these data as the basis for future experiments and not as conclusive evidence of a proposed mechanism. 198 Conclusions In conclusion, our data show that M. elongata promotes aerial plant growth and also affects seed production. This plant phenotype was found to be independent of whether Mortierella symbionts were colonized by MRE or BRE endohyphal bacterial symbionts. We hypothesize that the mechanism of plant-fungal symbiosis involves fungal production of auxin and stimulation of the ethylene and ROS response pathways. Future research is needed to test these hypotheses and further characterize the fungal side of this symbiosis. 199 Figures & Tables Figure 3.1 – Arabidopsis seedlings used in plant-fungal interaction assays Panel a) 10-day old seedlings on 1xMS germination plates and b) 11-day old seedlings and blocks of media (colonized by fungi in fungal treatments or sterile in uninoclated control treatments) as arranged on PNM plates for the agar-based plant-fungal interaction experiments. 200 Table 3.1 - A map of the light levels in the growth chamber Arabidopsis seeds germination and Arabidopsis-M. elongata interaction studies were conducted on agar plates. These were incubated in a Percival growth chamber. Each shelf in the chamber was divided into nine regions and the light level in each region was measured using an LI-250A light meter (LI-COR) with the chamber door closed to ensure realistic conditions. Light levels on the middle and bottom shelves were measured after arranging agar plates on the above shelf/shelves. Shelf Row Front Top Middle Back Front Middle Middle Back Front Bottom Middle Back Zone Left Middle Right Left Middle Right Left Middle Right Left Middle Right Left Middle Right Left Middle Right Left Middle Right Left Middle Right Left Middle Right Light Level (umol) 103 112 104 104 113 104 107 116 109 112 116 111 111 116 110 113 118 112 109 114 110 108 113 108 109 114 109 201 Figure 3.2 – Agar plates with Arabidopsis plants in the growth chamber Arabidopsis seeds germination and Arabidopsis-M. elongata interaction studies were conducted on agar plates. These were incubated in a Percival growth chamber. Plates were stacked on a gentle angle to encourage smooth directional root growth along the agar surface. 202 Figure 3.3 – Bolting phenotype The arrow indicates the elongation of the Arabidopsis inflorescence away from the rosette of leaves which was considered to indicate “bolting.” 203 Figure 3.4 – Arabidopsis plants at the time of harvest for aerial biomass assay Ten days after germination, Arabidopsis seedlings were transplanted from 1xMS germination plates to these PNM plates and inoculated with small blocks of Kaefer Medium, either colonized by fungi (left) or sterile (right). The Arabidopsis (and fungi, when applicable) grew on PMN plates for 12 days, at which point these pictures were captured and the plants harvested for aerial biomass assays. 204 Table 3.2 - qPCR primer sets The qPCR primer sets used to quantify fungal colonization of plant roots and check for BRE/MRE in cured and wild-type fungal strains and fungus-colonized plant roots. Target Organism Target Gene Name Arabidopsis thaliana Glyceraldehyde-3- phosphate dehydrogenase C2 (GAPC2) Mortierella elongata RNA polymerase II large subunit (RPB1) qGAPDH-F1 qGAPDH-R1 qRPB1-F2 qRPB1-R2 Mycoavidus cysteinexigens (L. elongata BRE) 16S Mollicutes-related endobacteria (L. elongata MRE) 16S MycAvi_16S_F1 MycAvi_16S_R1 NVP80MREq_16S_F1 NVP80MREq_16S_R1 Sequence CATGACCACTGTC CACTCTATC CACCAGTGCTGCT AGGAATAA TCACCAAGTTCATC ACCATCTC AAGCCCGTCATGG GTATTG TCAACCTGGGAAC TGCATAC CGGTGTTCCTCCA CATATCTAC CCTGAAAGAAGCT GGTGATACT TGACTGCCTTCGC CTTTATT 205 Figure 3.5 - Aerial dry biomass of Arabidopsis plants grown in sterile potting mix Treatments refer to the composition of the potting mix. The untreated control (NoMillet) contrasted treatments where the sterile potting soil was mixed 97:3 v:v with sterile millet mix (Uninoculated), or millet mix inoculated with one of four Mortierella elongata strains (NVP64cu, NVP64wt, NVP80cu, or NVP80wt). Arabidopsis was grown to maturity and the aerial biomass harvested and dried. Colors correspond to treatment, horizontal brackets and numbers indicate pairwise Wilcox ranked sum tests and the resulting p-value. N=12 for all treatments. Between NVP64cu v. NVP64wt, NVP80cu v. NVP80wt, and NoMillet v. Uninoculated, we used two-tailed tests. Between each fungal treatment and the Uninoculated, we performed one-tailed tests with the alternative hypothesis “greater”. 206 Figure 3.6 – Total mass of Arabidopsis seed Treatments refer to the composition of the potting mix in which Arabidopsis plants were grown. The untreated control (NoMillet) contrasted treatments where the sterile potting soil was mixed 97:3 v:v with sterile millet mix (Uninoculated), or millet mix inoculated with one of four Mortierella elongata strains (NVP64cu, NVP64wt, NVP80cu, or NVP80wt). Arabidopsis was grown to maturity and the seeds collected by Aracon tubes. N=5 for all treatments. Colors correspond to treatment, horizontal brackets and numbers indicate pairwise Wilcox ranked sum tests and the resulting p-value. 207 Figure 3.7 – Average Arabidopsis seed mass Treatments refer to the composition of the potting mix. The untreated control (NoMillet) contrasted treatments where the sterile potting soil was mixed 97:3 v:v with sterile millet mix (Uninoculated), or millet mix inoculated with one of four Mortierella elongata strains (NVP64cu, NVP64wt, NVP80cu, or NVP80wt). Arabidopsis was grown to maturity and the seeds collected by Aracon tubes. Average seed mass was determined by weighing and then counting a subset of seeds taken from the total seed mass. N=5 for all treatments. Colors correspond to treatment, horizontal brackets and numbers indicate pairwise Wilcox ranked sum tests and the resulting p- value. 208 Figure 3.8 - Density histogram of Arabidopsis seed image area “Strain” refers to the composition of the potting mix in which Arabidopsis plants were grown. The untreated control (NoMillet) contrasted treatments where the sterile potting soil was mixed 97:3 v:v with sterile millet mix (Uninoculated), or millet mix inoculated with one of four Mortierella elongata strains (NVP64cu, NVP64wt, NVP80cu, or NVP80wt). Arabidopsis was grown to maturity and the seeds collected by Aracon tubes. A subset of seeds from 5 samples per treatment were adhered to white paper and imaged using an Epson scanner. The x-axis indicates the pixel count of each individual seed scanned for each treatment, with samples pooled within treatments. The vertical dashed lines indicate the mean pixel area for seeds in each treatment. 209 Figure 3.9 – Total seed number produced by Arabidopsis Treatments refer to the composition of the potting mix. The untreated control (NoMillet) contrasted treatments where the sterile potting soil was mixed 97:3 v:v with sterile millet mix (Uninoculated), or millet mix inoculated with one of four Mortierella elongata strains (NVP64cu, NVP64wt, NVP80cu, or NVP80wt). Arabidopsis was grown to maturity and the seeds collected by Aracon tubes. Average seed mass was calculated by dividing total seed mass by average seed mass for each sample. N=5 for all treatments. Colors correspond to treatment, horizontal brackets and numbers indicate pairwise Wilcox ranked sum tests and the resulting p-value. 210 Table 3.3 - Linear modeling of Arabidopsis aerial dry weight as a function of light level The aerial dry biomass of Arabidopsis plants harvested from agar-based Arabidopsis- Mortierella elongata interaction experiments and modeled as a function of light level. Medium indicates the composition of the medium on which M. elongata was cultured: KM = Kaefer Medium; MEA = Malt Extract Agar. Treatment indicates the strain of M. elongata with which Arabidopsis was inoculated or the uninoculated control. Medium Treatment KM MEA NVP64cu NVP64wt NVP80cu NVP80wt Control NVP64cu NVP64wt NVP80cu NVP80wt Control Trend Slope 0.00 0.01 0.03 0.01 -0.02 -0.01 0.03 0.01 0.01 -0.03 SE DF 0.02 100 0.02 100 0.02 100 0.02 100 0.02 100 0.02 100 0.02 100 0.02 100 0.02 100 0.02 100 0.95 Conf. Limit -0.030 - 0.037 -0.027 - 0.049 -0.009 - 0.062 -0.030 - 0.049 -0.055 - 0.010 -0.055 - 0.027 -0.017 - 0.075 -0.034 - 0.057 -0.036 - 0.054 -0.067 - 0.013 211 NVP64cu NVP64wt NVP80cu NVP80wt Control KM MEA KM MEA KM MEA KM MEA KM EMM 2.22 2.19 1.96 1.92 2.06 2.01 2.10 2.11 1.84 SE 0.075 0.081 0.075 0.081 0.075 0.081 0.075 0.081 0.075 0.027 0.11 110 0.248 0.80 Contrasts between Media DF 0.95 Conf. Limit ΔEMM SE DF t.ratio p 110 110 110 110 110 110 110 110 110 2.05 - 2.39 2.01 - 2.38 1.79 - 2.13 1.74 - 2.11 1.89 - 2.23 1.83 - 2.20 1.93 - 2.27 1.93 - 2.30 1.67 - 2.01 -0.018 0.11 110 -0.161 0.87 0.035 0.11 110 0.320 0.75 0.044 0.11 110 0.398 0.69 0.154 0.11 110 1.393 0.17 Table 3.4 – Linear modeling of Arabidopsis aerial dry weight as a function of treatment and medium The aerial dry biomass of Arabidopsis plants from agar-based Arabidopsis-Mortierella elongata interaction experiments, modeled as a function of treatment (control v. different strains of Mortierella elongata), the medium on which the fungi had been cultured, and any interaction between those terms. We also conducted pairwise comparisons within treatments of the estimate marginal means (EMMs) for each inoculating medium. Treatment Medium Estimated Marginal Mean (EMM) MEA 1.69 0.081 1.50 - 1.87 110 212 Table 3.5 - Linear modeling of Arabidopsis aerial dry weight as a function of starting seedling root length The aerial dry biomass of Arabidopsis plants from agar-based Arabidopsis-Mortierella elongata interaction experiments, modeled as a function of seedling starting root length. There were no significant differences in the slope of the relationship of starting root length to final aerial dry weight across experimental rounds or treatments. Experiment Treatment Slope SE DF 0.95 Conf. Limit NVP64cu NVP64wt NVP80cu NVP80wt Control NVP64cu NVP64wt NVP80cu NVP80wt Control 0.1254 0.1578 0.1185 0.1614 0.1348 0.0885 0.0796 0.0721 0.1471 0.0615 Media Panel Cured Panel 0.047 0.0424 0.0425 0.0403 0.0427 0.0182 0.0347 0.019 0.0363 0.0291 1034 1034 1034 1034 1034 1034 1034 1034 1034 1034 -0.013 - 0.263 -0.033 - 0.282 -0.006 - 0.243 -0.043 - 0.28 -0.009 - 0.26 -0.035 - 0.142 -0.022 - 0.181 -0.016 - 0.128 -0.040 - 0.254 -0.024 - 0.147 Signif. Group a a a a a a a a a a 213 Table 3.6 - Linear mixed modeling of Arabidopsis aerial dry weight To account for having measurements for three plants per agar plate and two independent repetitions of the agar-based interaction experiment, experimental round and plate were treated as random/grouping effects. The starting root length and experimental treatment were fixed effects, where the uninoculated control treatment was estimated as the intercept. Fixed Effects (Intercept) treatment=NVP64cu treatment=NVP64wt treatment=NVP80cu treatment=NVP80wt Root Length Estimate Std.Error df 0.581 0.601 0.565 0.650 0.681 0.122 0.098 0.068 0.076 0.068 0.076 0.008 8.502 230.9 232.6 230.8 231.9 514.1 t- value 5.92 8.79 7.41 9.52 8.93 16.06 p 2.7E-04 3E-16 2E-12 <2E-16 <2E-16 <2E-16 Plate Experiment Residual Random effects Name Variance Std.Dev. # of Groups (Intercept) (Intercept) 0.117 0.074 0.005 0.342 0.273 0.072 - 255 2 - Contrast Control - NVP64cu Control - NVP64wt Control - NVP80cu Control - NVP80wt NVP64cu - NVP64wt NVP64cu - NVP80cu NVP64cu - NVP80wt NVP64wt - NVP80cu NVP64wt - NVP80wt NVP80cu - NVP80wt SE EMM Pairwise Comparisons df estimate -0.6005 250 249 -0.5654 249 -0.6498 248 -0.6807 0.0351 250 249 -0.0494 250 -0.0803 -0.0844 250 249 -0.1153 -0.0309 249 0.069 0.0763 0.0689 0.0762 0.0689 0.0573 0.069 0.0689 0.0763 0.0689 t.ratio p -8.7 -7.41 -9.43 -8.93 0.509 -0.86 -1.16 -1.23 -1.51 -0.45 <.0001 <.0001 <.0001 <.0001 0.9864 0.9108 0.7717 0.7363 0.5555 0.9916 214 Figure 3.10 – Mortierella elongata colonization of Arabidopsis increased aerial dry weight in agar-based interaction experiments The estimated marginal mean of Arabidopsis aerial dry weight modeled as a function of starting root length and treatment, which included the uninoculated control and four strains of M. elongata. The degrees of freedom for each comparison were approximated using the kenward- roger method and the p-values adjusted for multiple comparisons using the Tukey method for comparing a family of 5 estimates. Letters indicate significantly different groups with an alpha value of 0.05. Exact values can be found in Table 3.6. 215 Table 3.7 – qPCR of plant, fungal, and endobacterial genes from RNA Values indicate the qPCR cycle number at which amplification reached the threshold of detection for each locus tested in each cDNA library from the Arabidopsis root RNA samples used in the RNAseq experiment. Dash = not tested. Arabidopsis GADPH and M. elongata RPB1 are single copy genes. The bacterial 16S gene is multicopy, which was necessary for detection, since these endobacteria are very low abundance in the fungal hyphae. M. elongata Arabidopsis Strain Sample Number (GADPH) 17.44 17.28 16.13 16.19 16.25 16.34 16.34 16.06 16.21 16.56 16.69 15.96 (RPB1) 30.77 33.29 29.51 29.05 30.07 29.47 24.83 25.88 27.65 31.68 30.69 26.67 MRE (16S) BRE (16S) - - - - - - - - - 18.31 15.13 11.8 - - - 34.71 36.07 34.76 - - - - - - NVP64cu NVP64wt 118 108 48 94 64 24 36 NVP80cu 106 NVP80wt 46 22 82 102 216 Figure 3.11 – Mortierella elongata strains equivalently colonized Arabidopsis roots RNA was extracted from Arabidopsis roots colonized by M. elongata, pooled from all three plants on each agar plate, from three plates per treatment. The inferred ratio of fungal:plant cDNA is based on the qPCR results and standard curves for each qPCR primer set. Since Arabidopsis GADPH and M. elongata RPB1 are single copy genes, the ratio of fungal and plant template provides a normalized estimate of fungal colonization of plant roots. 217 Table 3.8 – Molecular results of RNA sequencing run The number of sequenced reads passing initial filtration by the sequencer, the percentage of those reads that mapped to the combined reference transcriptome, and the proportion of mapped reads that mapped to plant or fungal transcripts. Treatment Sample Number Sequenced Mapping Reads Rate Mapped to Arabidopsis Mapped to M. elongata 37,420,119 97.66% 36,495,398 97.67% 37,754,726 97.78% 37,276,912 97.58% 32,066,022 97.72% 30,536,173 97.70% 32,494,719 97.22% 33,188,011 97.53% 33,919,080 97.31% 34,589,059 97.73% 36,239,973 97.70% 34,826,178 97.65% 33,645,723 97.85% 35,809,882 97.77% 34,944,673 97.77% 99.960% 99.989% 99.965% 99.955% 99.967% 99.946% 98.647% 99.710% 99.395% 99.981% 99.964% 99.808% 99.996% 99.996% 99.996% 0.040% 0.011% 0.035% 0.045% 0.033% 0.054% 1.353% 0.290% 0.605% 0.019% 0.036% 0.192% 0.004% 0.004% 0.004% NVP64cu NVP64wt NVP80cu NVP80wt Control 48 108 118 24 64 94 36 46 106 22 82 102 50 60 80 218 Figure 3.12 – Principal component analysis of differential Arabidopsis gene expression Arabidopsis root RNAseq data analyzed using DESeq2, sequenced from three biological replicates taken from each of the uninoculated control and fungal treatments inoculated with Mortierella elongata. 219 Figure 3.13 - Volcano plots of differential gene expression Pairwise comparisons of normalized gene expression between fungal treatments and the uninoculated control, calculated from the DESeq2 analyses. Each point represents a gene, plotted by adjusted p-value and Log2 Fold Change (LFC) in expression between the fungal treatment and the control. Vertical dashed lines indicate the |LFC|=1 threshold and horizontal lines indicate the adjusted p-value threshold of 0.05 used to identify genes with significant changes in expression. Genes are colored by which of the LFC and p-value cutoffs were exceeded: gray = failed both; green = exceeded only the LFC cutoff, but not the p-value cutoff; blue = exceeded p- value cutoff, but not LFC; red = exceeded both cutoffs. 220 Table 3.9 - Arabidopsis genes differentially expressed in response to Mortierella elongata Log 2 fold change (LFC) values were calculated by DESeq2 and filtered at |LFC|=log2(1.5)=0.58 and adjusted p-value = 0.05. Table is organized first by functional annotation, then by direction of regulation, and finally by the number of fungal treatments in which the gene was differentially expressed. Functional Annotation Broad Middle Detail Log2 Fold-Change NVP 64cu NVP 64wt NVP 80cu NVP 80wt Name Gene Abiotic Stress Al tolerance Abiotic Stress Broad Abiotic Stress Broad Abiotic Stress Abiotic stress Cold/Heat/Salt/ Drought Cold/Salt/ Drought Abiotic Stress Drought Abiotic Stress Drought Abiotic Stress Abiotic Stress Drought, cold, & salt Drought, cold, & salt Abiotic Stress Abiotic Stress Abiotic Stress Hypoxia Hypoxia/ Oxidative Stress Hypoxia/ Oxidative Stress Hypoxia/ Oxidative Stress Hypoxia/ Oxidative Stress Hypoxia/ Oxidative Stress Abiotic Stress Abiotic Stress Abiotic Stress aluminum activated malate transporter family protein RESPONSIVE TO HIGH LIGHT 41 Sucrose synthetase Annexin 7 ORGANIC CATION/CARNITINE TRANSPORTER5 Methylenetetrahydrofolate reductase family protein sucrose synthase 3 NAD(P)-linked oxidoreductase superfamily protein NAD(P)-linked oxidoreductase superfamily protein PHYTOGLOBIN 1 -1.88 -0.99 -1.15 -1.54 -2.43 -1.49 -0.62 F-box/RNI superfamily protein -5.34 -4.79 alpha/beta-Hydrolases superfamily protein -1.72 -1.83 - AT1G08440 0.60 0.70 RHL41 SUS1 AT5G59820 AT5G20830 -0.61 ANNAT7 AT5G10230 OCT5 AT1G79410 -1.06 POX2 AT5G38710 SUS3 AT4G02280 -2.14 AKR4C9 AT2G37770 - AT5G62420 0.81 0.82 HB17 AT2G16060 -5.06 T18K17.22 AT1G73120 -1.42 CXE6 AT1G68620 Peroxidase superfamily protein 2.26 1.92 1.84 1.98 PER28 AT3G03670 Stachyose synthase, Raffinose synthase 4 DNA polymerase epsilon catalytic subunit A 1.72 0.93 1.31 1.54 STS AT4G01970 1.14 1.25 1.09 - AT1G19530 221 Table 3.9 (cont’d) Abiotic Stress Abiotic Stress Hypoxia/ Oxidative Stress Hypoxia/ Oxidative Stress Abiotic Stress Hypoxia/Salt Abiotic Stress Hypoxia/Salt Abiotic Stress Iron deficiency Abiotic Stress Iron deficiency Abiotic Stress Iron deficiency Abiotic Stress Iron deficiency Abiotic Stress Abiotic Stress Abiotic Stress Abiotic Stress K deficiency Iron deficiency Iron deficiency Iron deficiency Abiotic Stress Abiotic Stress Abiotic Stress Abiotic Stress Abiotic Stress Metal/Ion Transport Metal/Ion Transport Metal/Ion Transport Metal/Ion Transport Metal/Ion Transport Peroxidase superfamily protein Peroxidase superfamily protein HSP20-like chaperones superfamily protein 17.6A HSP20-like chaperones superfamily protein 17.8 basic helix-loop-helix (bHLH) DNA- binding superfamily protein ferric reduction oxidase 2 basic helix-loop-helix (bHLH) DNA- binding superfamily protein basic helix-loop-helix (bHLH) DNA- binding superfamily protein iron-regulated transporter 1 nicotianamine synthase nicotianamine synthase CBL-interacting protein kinase 9 DETOXIFICATION 43, FERRIC REDUCTASE DEFECTIVE 3, MANGANESE ACCUMULATOR 1 alkenal reductase copper transporter 2 cation/H+ exchanger 17 STELAR K+ outward rectifier Abiotic Stress Oxidative Stress Peroxidase 56 Abiotic Stress Oxidative Stress Zinc-binding dehydrogenase family protein Abiotic Stress Oxidative Stress Peroxidase 37 222 1.51 1.98 -4.02 -3.84 -1.64 -1.25 -4.20 -4.27 -3.22 -3.09 -2.78 -5.46 -1.73 -1.52 -5.24 1.65 PER10 AT1G49570 PER5 AT1G14550 -3.13 HSP17.7 AT5G12030 -1.55 HSP17.8 AT1G07400 -1.68 BHLH101 AT5G04150 FRO2 AT1G01580 ORG2 AT3G56970 -2.26 ORG3 AT3G56980 -1.61 -1.47 IRT1 NAS2 NAS1 CIPK9 AT4G19690 AT5G56080 AT5G04950 AT1G01140 -0.94 -0.77 -0.65 -0.75 DTX43 AT3G08040 -1.60 -2.80 -1.61 1.48 -0.64 -0.61 0.82 -1.17 P1 AT5G16970 COPT2 AT3G46900 CHX17 AT4G23700 SKOR AT3G02850 PRX56 AT5G15180 - AT5G17000 0.85 0.96 PRX37 AT4G08770 0.68 0.72 - - -1.99 -1.64 0.97 0.87 -1.67 -1.17 RNS1 G3Pp1 -1.44 -1.09 -1.21 -1.24 AT2G18150 AT4G36430 AT2G02990 AT3G47420 AT2G03260 AT2G41380 - - Abiotic Stress Salt Abiotic Stress P deficiency Abiotic Stress Response to Cd Table 3.9 (cont’d) Abiotic Stress Oxidative stress peroxidase superfamily protein Abiotic stress Oxidative stress Peroxidase 49 ribonuclease 1 Abiotic Stress P deficiency - Abiotic Stress P deficiency EXS (ERD1/XPR1/SYG1) family protein S-adenosyl-L-methionine-dependent methyltransferases superfamily protein TONOPLAST INTRINSIC PROTEIN 2;3 hypothetical protein RmlC-like cupins superfamily protein RmlC-like cupins superfamily protein RmlC-like cupins superfamily protein RmlC-like cupins superfamily protein RmlC-like cupins superfamily protein RmlC-like cupins superfamily protein RmlC-like cupins superfamily protein RmlC-like cupins superfamily protein CBL-interacting serine/threonine protein kinase Abiotic Stress Unspecified Abiotic Stress Unspecified Abiotic Stress Unspecified Abiotic Stress Unspecified Abiotic Stress Unspecified Abiotic Stress Unspecified Abiotic Stress Unspecified Abiotic Stress Unspecified Abiotic Stress Unspecified Abiotic Stress/ Hormone Abiotic Stress/ Hormone Abiotic Stress/ Hormone/ Signaling Broad/ABA/ Calcium signal Cold/Drought/ ABA Broad/ABA Dehydrin family protein annexin 4 -0.66 -0.82 -0.67 TIP2;3 AT5G47450 -1.03 2.34 3.03 3.23 2.35 2.46 1.93 2.23 -3.21 - - - -0.59 T9L3_30 AT5G14730 AT5G38910 AT5G39150 AT5G38940 2.66 2.47 2.00 MXF12.14 AT5G39110 AT5G39160 AT5G39120 AT5G39180 AT3G05950 - - - - 2.00 1.54 1.74 2.26 2.11 2.84 2.92 3.45 -0.60 -0.69 CIPK14 AT5G01820 - AT4G38410 -0.78 -0.94 -0.70 -0.90 ANNAT4 AT2G38750 Abiotic Stress/ Metabolism Defense Defense Defense Hypoxia/ Protein Modification Bacteria Bacteria Bacteria AGC2 KINASE 1, Oxidative Signal Inducible 1 -0.91 AGC2-1 AT3G25250 -0.64 euonymus lectin S3 Calcium-binding EF hand family protein 1.38 1.57 1.78 1.63 sigma factor binding protein 1 1.03 0.97 1.11 0.87 223 EULS3 CML12 SIB1 AT2G39050 AT2G41100 AT3G56710 indole glucosinolate biosynthesis cysteine-rich RLK (RECEPTOR-like protein kinase) 31 Leucine-rich receptor-like protein kinase family protein CAP (Cysteine-rich secretory proteins, Antigen 5, and Pathogenesis-related 1 protein) superfamily protein Cysteine-rich receptor-like protein kinase cysteine-rich receptor-like protein kinase SBP (S-ribonuclease binding protein) family protein Defensin-like protein 99 Defensin-like protein 100 trypsin inhibitor protein 1 papain-like cysteine protease Defensin-like protein 96 chitinase A CAP (Cysteine-rich secretory proteins, Antigen 5, and Pathogenesis-related 1 protein) superfamily protein Chitinase family protein homolog of RPW8 3 Lectin like protein induced by chitin Defensin-like protein 98 0.90 1.54 1.50 2.13 -0.77 -0.62 -2.34 -2.09 -1.07 3.02 1.08 0.61 1.01 0.80 MYB51 AT1G18570 1.75 1.65 CRK31 AT4G11470 0.94 1.18 FLS2 AT5G46330 1.71 F2J10.7 AT1G50050 0.94 CRK10 AT4G23180 CRK18 AT4G23260 1.42 -4.15 -3.10 -3.20 -3.49 dl4875c AT4G17680 -1.74 -1.39 -1.48 -0.77 -1.68 -1.02 -2.26 -2.49 -0.64 - - TI1 CEP1 - CHIB1 AT4G22214 AT4G22217 AT2G43510 AT5G50260 AT4G22230 AT5G24090 2.77 2.17 3.08 2.63 CAPE3 AT4G33720 1.98 2.36 F18O19.27 AT2G43620 AT3G50470 1.10 1.04 1.60 AT3G16530 AT4G22212 HR3 - - -1.02 -2.44 EARLI1 AT4G12480 AZI3 AT4G12490 Table 3.9 (cont’d) Defense Bacteria Defense Bacteria Defense Bacteria Defense Bacteria Defense Bacteria Defense Bacteria Defense Fungus Defense Defense Defense Defense Defense Defense Fungus Fungus Fungus Fungus Fungus Fungus Defense Fungus Fungus Fungus Fungus Fungus Defense Defense Defense Defense Defense/ Hormone Defense/ Hormone General/SA priming the SAR and ISR responses -0.86 General/SA priming the SAR and ISR responses -2.06 224 Table 3.9 (cont’d) Defense General Defense General Defense General General/SA Defense/ Hormone Defense General Defense/ Auxin, JA, SA, Hormone Ethylene Defense/ Fungus/ Hormone Ethylene Defense/ SA dependent/ Hormone Oxidative Stress Defense/ General/ Metabolism Secondary Defense/ General/ Metabolism Secondary Defense/ SAR/ Metabolism Secondary Development Flowering Development Flowering Development Flowering Development Flowering Development Flowering Development Flowering Development Flowering Development Flowering Development Flowering nodulin MtN21-like transporter family negatively regulates resistance against biotrophic pathogens UDP-glycosyltransferase 73B4 Disease resistance-responsive (dirigent-like protein) family protein priming the SAR and ISR responses -0.90 -1.00 1.94 Mannose-binding lectin family protein 0.68 GDSL lipase 2 0.83 Ethylene-responsive transcription factor 1.94 UDP-Glycosyltransferase 73B3 UDP-Glycosyltransferase 73B2 ATP binding cassette G6 -0.78 -0.79 -0.71 Phytoalexin deficient 3 0.82 -1.12 UMAMIT36 AT1G70260 UGT73B4 AT2G15490 - AT4G11210 AZI1 AT4G12470 0.78 - AT1G33790 0.70 0.86 GLIP2 AT1G53940 2.04 TDR1 AT3G23230 UGT73B3 AT4G34131 UGT73B2 AT4G34135 ABCG6 AT5G13580 PAD3 AT3G26830 Agamous-like 19 DNAJ heat shock N-terminal domain- containing protein UDP-Glycosyltransferase superfamily protein SGNH hydrolase-type esterase superfamily protein hypothetical protein UDP-glycosyltransferase 79B8 myb domain protein 45 expansin-like B1 glycosyl hydrolase 9B17 -0.78 -0.71 -0.83 AGL19 AT4G22950 -0.88 -1.06 -1.71 -1.90 -1.17 -0.63 -1.34 -0.95 - AT2G21510 -0.88 UGT87A2 AT2G30140 -1.58 - AT2G40250 -1.97 F21F14.100 AT3G61930 -0.64 UGT79B8 AT2G22930 AT3G48920 MYB45 EXLB1 AT4G17030 GH9B17 AT4G39000 225 Late embryogenesis abundant (LEA) protein-like protein Vascular-related unknown protein 2 EXPANSIN B2 FANTASTIC FOUR 3 promotes cell growth in response to light xanthine dehydrogenase 2 Regulates cortical microtubule organization Light sensitive hypocotyls 4 marneral oxidase Thalian-diol desaturase cytochrome P450, family 705, subfamily A, polypeptide 5 thalianol hydroxylase cytochrome P450, family 708, subfamily A, polypeptide 2 Thalianol synthase 1 marneral synthase CYTOCHROME P450, FAMILY 78, SUBFAMILY A, POLYPEPTIDE 6 DNA/RNA Degradation 2-oxoglutarate (2OG) and Fe(II)- dependent oxygenase superfamily protein Petal Loss Table 3.9 (cont’d) Development Flowering Development Growth Development Growth Development Growth Development Growth Development Growth Development Growth Development Transcription Development Root Development Root Development Root Development Root Development Root Development Seed Development Senescence Development Senescence Development Transcription Factor Development Development Flowering Development/ Hormone Broad/ SA/JA/ABA CURVATURE THYLAKOID 1C CLAVATA 1 EXTENSIN 1/4, OBP3-RESPONSIVE GENE 5 0.59 0.64 0.81 226 0.78 -0.95 -1.74 -0.67 0.75 -0.83 -1.33 - VUP2 EXPB2 FAF3 AT1G54890 AT1G50930 AT1G65680 AT5G19260 0.96 0.70 1.16 0.77 LSH10 AT2G42610 0.82 1.00 0.91 0.75 XDH2 AT4G34900 0.72 0.78 SP1L2 AT1G69230 0.69 0.75 0.97 0.68 -0.76 -0.92 -0.87 -1.05 LSH4 MRO AT3G23290 AT5G42590 -1.65 -1.38 -1.42 -1.64 THAD1 AT5G47990 -1.16 -1.93 -3.06 -1.19 THAH AT5G48000 -1.71 THAS MRN1 AT5G48010 AT5G42600 0.81 0.93 0.59 0.76 0.63 CYP78A6 AT2G46660 0.60 -1.41 BFN1 AT1G11190 1.01 - AT3G49630 PTL AT5G03680 CURT1C AT1G52220 AT1G75820 CLV1 EXT4 AT1G76930 Table 3.9 (cont’d) Development/ Hormone Flowering/ Gibberellin Hormone Hormone Hormone Hormone Hormone Hormone Hormone Hormone Hormone Hormone ABA & Gibberellin ABA/SA/Eth Abscisic Acid Abscisic Acid Abscisic Acid Auxin Auxin/ Brassinosteroid Auxin Auxin Auxin Hormone Auxin Hormone Hormone Hormone Hormone Auxin/ Brassinosteroid Auxin Auxin Auxin Hormone Auxin, Ethylene Hormone Auxin, Ethylene -0.73 0.99 1.00 1.38 Transcription factor PRE4 2-oxoglutarate (2OG) and Fe(II)- dependent oxygenase superfamily protein GLYCINE RICH PROTEIN 3 9-cis-epoxycarotenoid dioxygenase 3 MYB domain protein 74 Stress-induced protein KIN1 nitrilase 2 Auxin efflux carrier family protein Nitrilase 1 Uridine diphosphate glycosyltransferase 74E2 Acyl acid amido synthetase IAA-amido synthase that conjugates Asp and other amino acids to auxin in vitro -1.70 -1.26 -1.05 -0.95 -0.77 -1.47 Auxin efflux carrier family protein -0.89 ZINC INDUCED FACILITATOR-LIKE 1 -0.70 Auxin response factor 20 big grain like 1 SAUR-like auxin-responsive protein family Auxin-Regulated Gene Involved in Organ Size 0.66 1.34 0.65 -2.10 0.76 PRE4 AT3G47710 1.07 GIM2 AT2G36690 1.11 GRP3 NCED3 -0.61 MYB74 KIN1 NIT2 -0.80 -0.87 AT2G05520 AT3G14440 AT4G05100 AT5G15960 AT3G44300 -0.80 PILS5 AT2G17500 -0.78 NIT1 AT3G44310 UGT74E2 AT1G05680 GH3.7 AT1G23160 -0.61 GH3.17 AT1G28130 PILS3 AT1G76520 ZIFL1 ARF20 BGL1 AT5G13750 AT1G35240 AT1G69160 SAUR76 AT5G20820 ARGOS AT3G59900 -2.13 SQE4 AT5G24140 AIF1 AT3G05800 1.09 1.01 ARL AT2G44080 Hormone Brassinosteroid squalene monooxygenase 2 -1.80 -1.76 Hormone Brassinosteroid ATBS1(ACTIVATION-TAGGED BRI1 SUPPRESSOR 1)-INTERACTING FACTOR 1 Hormone Brassinosteroid ARGOS-like protein -0.60 1.03 227 Table 3.9 (cont’d) Hormone Hormone Hormone Brassinosteroid baruol synthase 1 Cytokinin Cytokinin Hormone Hormone Hormone Ethylene (Eth) Jasmonic Acid Jasmonic Acid RING DOMAIN LIGASE 3 Hormone Ethylene (Eth) Hormone Ethylene (Eth) Hormone Hormone Eth/JA Ethylene (Eth) Hormone Ethylene (Eth) Hormone Ethylene (Eth) Hormone Jasmonic Acid Hormone Hormone Signaling Signaling Hormone Signaling Hormone/ Development Hormone/ Metabolism Metabolism Gibberellin/ ABA/ Flowering Cytokinin/ Secondary Amino Acid Metabolism Amino Acid Metabolism Amino Acid SULFOTRANSFERASE 4B UDP-glucosyl transferase 73C1 1-amino-cyclopropane-1-carboxylate (ACC) synthase 7 Ethylene-responsive transcription factor ERF112 ethylene response factor ETHYLENE RESPONSE 2 a member of the ERF (ethylene response factor) subfamily B-2 of ERF/AP2 transcription factor family Integrase-type DNA-binding superfamily protein ethylene-activated signaling pathway Jasmonic acid oxidase 2 Involved in jasmonic acid inducible defense response wall-associated kinase 2 cell wall-associated kinase glycine-rich protein 3 short isoform Regulates the function of the receptor protein kinase WAK1 Gibberellin-regulated protein 14 Cytokinin-induced F-Box protein Glutamine dumper 2 Transmembrane amino acid transporter family protein ACC Oxidase 1 -0.63 -0.59 0.73 228 3.80 2.74 3.44 -0.71 3.29 BARS1 ST4B AT4G15370 AT1G13420 UGT73C1 AT2G36750 -1.01 -0.99 -0.85 -1.08 ACS7 AT4G26200 -0.79 ERF112 AT2G33710 0.74 0.76 0.69 0.80 0.84 0.79 0.84 ERF59 ERT2 AT1G06160 AT3G23150 0.73 1.94 1.49 -0.91 0.60 ERF73 AT1G72360 2.04 TDR1 AT3G23230 1.44 -0.60 RAP2.9 JOX2 RGLG3 AT4G06746 AT5G05600 AT5G63970 1.16 WRKY51 AT5G64810 1.41 1.11 1.53 1.16 2.86 3.14 1.79 WAK2 WAK1 AT1G21270 AT1G21250 GRP3S AT2G05380 0.67 0.75 0.69 GASA14 AT5G14920 -0.77 CFB AT3G44326 -0.61 GDU2 AT4G25760 -0.84 AVT3 AT5G65990 0.71 0.81 ACO1 AT2G19590 Table 3.9 (cont’d) Metabolism Metabolism Metabolism Amino Acid Amino Acid Cell Wall Metabolism Cell Wall Metabolism Cell Wall Metabolism Cell Wall Metabolism Cell Wall Metabolism Cell Wall Metabolism Cell Wall Metabolism Metabolism DNA Repair Lipid Metabolism Lipid Metabolism Lipid Metabolism Lipid Metabolism Methylation Metabolism Nitrogen Metabolism Nitrogen Metabolism Nitrogen Metabolism Nitrogen Metabolism Nitrogen GLUTAMINE DUMPER 5 D-Amino acid racemase 1 Cellulose synthase-like protein E1 rhamnogalacturonan II specific xylosyltransferase xyloglucan endotransglucosylase/hydrolase 16 invertase/pectin methylesterase inhibitor superfamily xyloglucan endotransglucosylase/hydrolase 7 Glycosyl hydrolase 9B13 XYLOGLUCAN ENDOTRANSGLUCOSYLASE/HYDR OLASE 9 NUDIX HYDROLASE HOMOLOG 18 Lipid transfer-like protein VAS UDP-3-O-acyl N-acetylglycosamine deacetylase family protein GDSL-like Lipase/Acylhydrolase superfamily protein; Lipase class 3-related protein S-adenosyl-L-methionine-dependent methyltransferases superfamily protein Nitrile specifier protein 3 Glutamine synthetase cytosolic isozyme 1-1 nitrate transport Glutamine synthetase cytosolic isozyme 1-4 HIGH AFFINITY NITRATE TRANSPORTER 2.6 Metabolism Oxidative Stress Cyclin-dependent kinase inhibitor 229 0.94 0.59 -0.60 -0.70 -0.61 -0.63 0.61 -0.89 -0.72 -25.00 0.97 -0.94 -1.31 -0.62 -0.60 -0.71 0.90 -0.71 0.88 0.60 0.64 0.82 -0.67 GDU5 DAAR1 CSLE1 AT5G24920 AT4G02850 AT1G55850 RGXT3 AT1G56550 XTH16 AT3G23730 PME60 AT5G51500 XTH7 AT4G37800 GH9B13 AT4G02290 XTH9 AT4G03210 NUDT18 AT1G14860 AT5G13900 VAS LPXC3 AT1G25054 1.10 1.01 GDSL1 AT1G29670 2.80 - - AT5G24220 AT3G56080 -0.61 NSP3 AT3G16390 -0.64 GLN1-1 AT5G37600 NPF1.2 AT1G52190 GLN1-4 AT5G16570 NRT2.6 AT3G45060 -0.69 - AT3G20340 Table 3.9 (cont’d) Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Phosphate/ Protein modification Phosphate/ Protein modification Protein modification Protein modification Protein modification Protein modification Protein modification Protein modification Protein modification Protein modification Protein modification Protein modification Protein modification Protein modification PURPLE ACID PHOSPHATASE 17 -0.94 purple acid phosphate 8 U-box domain-containing protein kinase family protein Yippee family putative zinc-binding protein Eukaryotic aspartyl protease family protein RING/U-box superfamily protein Zinc ion binding RING/U-box superfamily protein Sulfite exporter TauE/SafE family protein Eukaryotic aspartyl protease family protein ADP-ribosylation factor D1A Leucine-rich repeat protein kinase family protein EP1-like glycoprotein 4 curculin-like (mannose-binding) lectin family protein SMAX1-LIKE 8 -0.77 -2.34 -0.94 -2.27 1.02 1.15 3.00 0.67 alpha-(1,6)-fucosyltransferase 0.69 -0.87 -0.67 0.67 -0.90 -1.48 1.04 1.57 1.87 1.79 -0.89 PAP17 AT3G17790 PAP8 AT2G01890 -2.36 PUB34 AT2G19410 - - - AT3G55890 AT5G19110 AT4G00305 ATL35 AT4G09110 - - AT4G21250 AT3G51340 ARFD1A AT1G02440 AT1G51810 GAL2 AT1G78860 SMXL8 AT2G40130 - - - AT5G28960 AT1G66800 AT1G60750 Metabolism Redox Metabolism Redox NAD(P)-binding Rossmann-fold superfamily protein NAD(P)-linked oxidoreductase superfamily protein -1.04 -1.25 -1.33 -1.25 -0.79 230 Table 3.9 (cont’d) Metabolism Redox Metabolism Redox Metabolism Redox Metabolism Redox Metabolism Redox Metabolism Metabolism Redox Redox Metabolism Redox Metabolism Metabolism Metabolism Redox Secondary Secondary Metabolism Secondary Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Secondary Secondary Secondary Secondary Secondary Starvation Metabolism Toxin & Lipid NAD(P)-binding Rossmann-fold superfamily protein NAD(P)-binding Rossmann-fold superfamily protein ALTERNATIVE OXIDASE 1A Cyclopropane-fatty-acyl-phospholipid synthase 2-oxoglutarate (2OG) and Fe(II)- dependent oxygenase superfamily protein Glutaredoxin 3 Thioredoxin superfamily protein member of the CC-type glutaredoxin (ROXY) family Monothiol Glutaredoxin 5 beta glucosidase 11 Aldolase superfamily protein S-adenosylmethionine decarboxylase proenzyme nitrilase 4 Tyrosine transaminase family protein peroxidase superfamily protein Terpenoid Synthase 12 Terpene synthase 8 senescence-associated family protein 12-OXOPHYTODIENOATE REDUCTASE 2 Metabolism Toxin Catabolism glutathione S-transferase TAU 25 Metabolism Toxin Catabolism glutathione transferase belonging to the tau class of GSTs Metabolism Metabolism Toxin Catabolism glutathione S-transferase TAU 16 Toxin Catabolism glutathione transferase lambda 1 -0.71 -0.63 1.22 0.87 1.14 -1.25 -0.60 -0.72 - - AT1G64590 AT2G29320 AOX1A AT3G22370 - AT3G23510 1.11 1.15 F2A19.2 AT3G61400 0.77 0.85 1.19 GRXS3 AT4G15700 GRXC14 AT3G62960 1.01 0.90 GRXS4 AT4G15680 0.98 0.85 -0.99 GRXS5 AT4G15690 -0.70 BGLU11 AT1G02850 AT1G44318 HEMB2 - AT5G15948 5.76 5.82 2.61 NIT4 - - TPS12 TPS08 -0.76 DUF581 AT5G22300 AT4G28420 AT5G39580 AT4G13280 AT4G20210 AT1G22160 OPR2 AT1G76690 -0.76 -0.82 GSTU25 AT1G17180 -0.63 -0.76 GSTU14 AT1G27140 -0.72 GSTU16 AT1G59700 -2.91 AT5G02780 GSTL1 0.60 -2.88 -0.65 -1.49 5.91 3.21 0.60 -0.80 -1.20 -0.87 -3.25 231 Table 3.9 (cont’d) Metabolism Toxin Catabolism Phenolic glucoside malonyltransferase 1 Metabolism Metabolism Toxin Catabolism glutathione S-transferase TAU 24 Toxin Catabolism glutathione S-transferase TAU 22 Metabolism Toxin Catabolism GLUTATHIONE S-TRANSFERASE TAU 8 -1.37 -1.06 -1.25 -0.85 Metabolism Metabolism Metabolism Metabolism Toxin Catabolism glutathione S-transferase TAU 12 Toxin Catabolism glutathione S-transferase F3 Transport Transport 2.33 2.41 3.12 2.40 -0.84 -1.34 Metabolism Transport Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Transport Transport Transport Transport Transport Transport Metabolism Transport Metabolism Transport Metabolism Metabolism Metabolism Metabolism Metabolism -1.27 -0.83 organic cation/carnitine transporter1 DETOXIFICATION 22 Nodulin-like / Major Facilitator Superfamily protein -1.77 ABC transporter family protein NITRATE TRANSPORTER 2.4 -0.75 glycolipid transfer & ceramide transport -1.19 pleiotropic drug resistance 6 -0.68 Amino acid transport Amino acid transport multidrug and toxic compound extrusion & iron homeostasis under osmotic stress ATP-BINDING CASSETTE B9, P- GLYCOPROTEIN 9 UDP-3-O-acyl N-acetylglycosamine deacetylase family protein GDSL-motif esterase/acyltransferase/lipase Mannose-binding lectin superfamily protein NADP-malic enzyme 1 UDP-Glycosyltransferase superfamily protein -3.38 -0.93 -0.75 -1.41 -4.30 1.20 -1.15 PMAT1 AT5G39050 -1.56 -0.83 GSTU24 AT1G17170 GSTU22 AT1G78340 GSTU8 AT3G09270 GSTU12 AT1G69920 AT2G02930 GSTF3 OCT1 AT1G73220 AT1G33090 DTX22 -1.06 -1.18 - AT2G34350 -1.06 -1.37 ABCB15 AT3G28345 AT5G60770 -1.04 NRT2.4 GLTP2 AT1G21360 ABCG34 AT2G36380 AT4G21120 AT5G02170 AAT1 -1.11 - 0.92 0.98 DTX48 AT1G58340 0.71 ABCB9 AT4G18050 -3.66 LPXC5 AT1G25210 -0.77 - AT1G28660 -4.10 JAL12 AT1G52120 -1.41 NADP-ME1 AT2G19900 -0.70 - AT3G46700 232 Table 3.9 (cont’d) Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Metabolism Jacalin-related lectin 41 HXXXD-type acyl-transferase family protein Acyl-CoA N-acyltransferases (NAT) superfamily protein Uncharacterized protein family (UPF0497) Tyrosine transaminase family protein Rhamnogalacturonate lyase family protein S-adenosylmethionine-dependent methyltransferase activity Ankyrin repeat family protein Ankyrin repeat family protein Phosphoglycerate mutase family protein hydroxyproline-rich glycoprotein family protein NmrA-like negative transcriptional regulator family protein Plant invertase/pectin methylesterase inhibitor superfamily protein Thioredoxin superfamily protein S-adenosylmethionine-dependent methyltransferase activity nodulin MtN21-like transporter family protein a member of the glycerophosphodiester phosphodiesterase like (GDPD-like) family alpha carbonic anhydrase 2 Plant invertase/pectin methylesterase inhibitor superfamily 233 -0.84 -0.75 JAL41 AT5G35940 -1.15 -1.37 -1.03 -1.13 BAHD1 AT5G47980 -1.52 - AT5G67430 CASPL1C1 AT4G03540 - - - AT4G23590 AT4G37950 AT5G38780 -1.17 -0.86 -1.68 1.12 1.24 1.30 1.12 F12G12.13 AT2G24600 1.97 1.27 1.74 1.70 F12G12.13 AT5G52710 0.92 0.72 0.71 1.46 1.30 1.06 0.62 0.59 - - - - AT1G09932 AT1G11070 AT1G19540 AT1G23205 0.62 0.79 1.20 0.60 1.07 0.94 1.20 GRXS7 AT4G15670 1.34 - AT1G15125 UMAMIT22 AT1G43650 SVL2 AT1G66970 0.60 ACA2 AT2G28210 PME25 AT3G10720 Table 3.9 (cont’d) Metabolism Metabolism Metabolism Metabolism/ Hormone Metabolism/ Hormone Toxin & Lipid/ SA response Toxin Catabolism/ SA response P450 P450 P450 P450 P450 P450 P450 P450 P450 P450 P450 P450 Serine carboxypeptidase-like 16 Anthranilate phosphoribosyltransferase-like protein Berberine bridge enzyme-like 26 12-OXOPHYTODIENOATE REDUCTASE 1 GLUTATHIONE S-TRANSFERASE 25, GLUTATHIONE S-TRANSFERASE TAU 7 Terpenoid cyclases/Protein prenyltransferases superfamily protein cytochrome P450, family 705, subfamily A, polypeptide 12 cytochrome P450, family 89, subfamily A, polypeptide 5 sterol 22-desaturase cytochrome P450, family 710, subfamily A, polypeptide 4 CYTOCHROME P450, FAMILY 89, SUBFAMILY A, POLYPEPTIDE 2 cytochrome P450, family 72, subfamily A, polypeptide 8 CYTOCHROME P450, FAMILY 72, SUBFAMILY A, POLYPEPTIDE 13 CYTOCHROME P450, FAMILY 72, SUBFAMILY A, POLYPEPTIDE 15 Cytochrome P450 superfamily protein cytochrome P450, family 706, subfamily A, polypeptide 1 cytochrome P450, family 706, subfamily A, polypeptide 2 cytochrome P450, family 71, subfamily B, polypeptide 22 0.70 -0.87 -0.75 1.24 -1.83 0.92 0.82 SCPL16 AT3G12220 MCTO13 AT5G03435 ATBBE26 AT5G44400 OPR1 AT1G76680 GSTU7 AT2G29420 TPS16 AT3G29110 -1.33 -1.28 -1.15 -1.53 CYP705A12 AT5G42580 -1.10 -3.43 -0.60 -1.49 -0.99 -0.60 -1.47 -0.66 CYP89A5 AT1G64950 -3.34 CYP710A4 AT2G28860 CYP89A2 AT1G64900 CYP72A8 AT3G14620 CYP72A13 AT3G14660 CYP72A15 AT3G14690 CYP81D11 AT3G28740 1.30 1.03 1.41 1.23 CYP706A1 AT4G22690 1.38 1.72 1.87 1.35 CYP706A2 AT4G22710 3.02 2.92 CYP71B22 AT3G26200 234 Table 3.9 (cont’d) P450 P450 P450 P450 Transcription Senescence Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Transcription Factor Transcription Factor CYTOCHROME P450, FAMILY 735, SUBFAMILY A, POLYPEPTIDE 2 putative obtusifoliol 14-alpha demethylase CYTOCHROME P450, FAMILY 709, SUBFAMILY B, POLYPEPTIDE 2 cytochrome P450, family 705, subfamily A, polypeptide 3 NAC DOMAIN CONTAINING PROTEIN 59, ORE1 Sister 1 HOMEOBOX-LEUCINE ZIPPER PROTEIN 17 Protein RADIALIS-like 2 MATERNAL EFFECT EMBRYO ARREST 3 TCP INTERACTOR CONTAINING EAR MOTIF PROTEIN 2 myb domain protein 112 zinc-finger protein 10 zinc finger (AN1-like) family protein WRKY DNA-binding protein 75 NAC DOMAIN CONTAINING PROTEIN 100 WRKY DNA-binding protein 31 basic helix-loop-helix DNA-binding superfamily protein RING/FYVE/PHD zinc finger superfamily protein WRKY DNA-binding protein 30 Zinc-finger domain of monoamine- oxidase A repressor R1 protein basic leucine-zipper 8 WRKY DNA-binding protein 59 235 0.65 0.60 0.70 2.13 -0.81 -0.79 0.89 CYP735A2 AT1G67110 CYP51A1 AT2G17330 CYP709B2 AT2G46950 CYP705A3 AT4G15360 NAC59 AT3G29035 -0.77 HB17 AT2G01430 0.81 0.75 RL2 AT2G21650 -0.63 -0.60 -0.61 TIE2 AT2G20080 -1.01 -0.76 -1.43 -1.21 -0.82 -1.26 -0.72 -1.08 MYB112 AT1G48000 AT2G37740 -0.67 -1.38 AT3G28210 -1.33 WRKY75 AT5G13080 ZFP10 SAP12 -0.69 NAC100 AT5G61430 WRKY31 AT4G22070 BHLH118 AT4G25400 20.55 20.88 19.39 21.00 - AT5G36670 2.87 2.68 WRKY30 AT5G24110 2.21 - AT1G67270 bZIP AT1G68880 WRKY59 AT2G21900 3.32 2.75 0.67 2.41 Table 3.9 (cont’d) Transcription Transcription Transcription Transcription Transcription/ Defense/ Hormone/ Signaling Signaling Calcium Signaling Extracellular Signaling Signaling Protein modification Protein modification Signaling Unspecified Unknown Extracellular Unknown Extracellular Unknown Unknown Unknown Unknown Unknown Extracellular Extracellular Extracellular Extracellular Extracellular Plant invertase/pectin methylesterase inhibitor superfamily a member of the DREB subfamily A-4 of ERF/AP2 transcription factor family ARABIDOPSIS MYB-RELATED PROTEIN 1 WRKY DNA-binding protein 51 1.39 0.80 0.76 MYB domain protein 30 -0.61 AFG1-like ATPase family protein represses plant growth, root development response to N starvation & broad hormone signaling Leucine-rich repeat transmembrane protein kinase Leucine-rich repeat transmembrane protein kinase P-loop containing nucleoside triphosphate hydrolases superfamily protein transmembrane protein Bifunctional inhibitor/lipid-transfer protein/ seed storage 2S albumin superfamily protein transmembrane protein transmembrane protein TRAF-like family protein transmembrane protein transmembrane protein 236 -1.22 1.16 PME20 AT2G47550 TINY2 AT5G11590 MYR1 AT5G18240 WRKY51 AT5G64810 MYB30 AT3G28910 -0.62 - AT4G30490 CEP5 AT5G66815 1.65 0.75 1.06 1.30 T3M22.2 AT1G29740 0.67 - AT1G29730 1.23 0.80 0.73 1.06 MAE1.1 AT5G60760 -1.23 -0.72 -0.74 AT14A AT3G28290 -1.71 3.26 1.99 1.97 -2.39 -1.53 2.47 2.85 2.00 1.86 1.56 1.11 1.28 - - - - - - AT4G12500 AT1G66465 AT3G60470 AT3G20360 AT5G44572 AT5G48175 Table 3.9 (cont’d) Unknown Extracellular Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown ncRNA 2.38 -0.70 -0.61 -1.01 -0.76 -1.03 -1.45 -1.24 exocyst subunit exo70 family protein A3 SHORT OPEN READING FRAME 5 Vesicle transport protein VQ motif-containing protein Outer arm dynein light chain 1 protein hypothetical protein Haloacid dehalogenase-like hydrolase superfamily protein Cysteine-rich repeat secretory protein 4 -0.80 conserved upstream opening reading frame relative to major ORF AT1G70780.1 Pollen Ole e 1 allergen and extensin family protein Galactose oxidase/kelch repeat superfamily protein Remorin family protein hypothetical protein NFU1 iron-sulfur cluster protein TRAF-like family protein spastin, putative Haloacid dehalogenase-like hydrolase (HAD) superfamily protein cysteine-rich transmembrane module stress tolerance protein hypothetical protein DUF538 family protein, putative MICRORNA414, SHORT OPEN READING FRAME 16 Carbohydrate-binding X8 domain superfamily protein -0.72 -1.16 -1.23 -1.97 -1.12 -0.78 -0.99 -0.65 -2.04 -0.77 237 -1.08 -0.76 -1.25 -0.86 -0.85 EXO70A3 AT5G52350 - SORF5 AT3G57157 AT5G23840 -0.91 AT1G17147 -0.71 -1.34 T11I11.17 AT1G78230 -0.92 AT4G33666 VQ1 - -0.59 -0.62 - AT5G02230 -0.76 -0.72 -0.91 CRRSP4 AT1G63600 -0.63 CPuORF28 AT1G70782 -0.89 PRP1 AT2G47530 F17A17.6 AT3G07720 -0.91 T2J13.220 AT3G48940 AT4G37700 -1.11 -1.18 AT5G07330 F9D12.8 AT5G26260 AT5G46060 -0.87 - - - -0.69 - AT5G59490 ATHCYSTM 1 - -1.31 -0.61 DUF538 AT1G05340 AT1G52342 AT1G55265 -0.62 MIR414 AT1G67195 - AT1G78520 Table 3.9 (cont’d) Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown maternal effect embryo arrest protein pseudogene D14-like 2, AB hydrolase-1 domain- containing protein pseudogene U-box kinase family protein hypothetical protein hypothetical protein (DUF581) alpha/beta-Hydrolases superfamily protein Nucleotide-diphospho-sugar transferase family protein F-box/RNI-like/FBD-like domains- containing protein cotton fiber-like protein stress up-regulated Nod 19 protein GPI-anchored adhesin-like protein, putative LURP-one-like protein hypothetical protein Ankyrin repeat family protein CLAVATA 3/ESR (CLE)-like protein PLAC8 family protein pseudogene Glycine-rich protein family hypothetical protein Unknown gene pseudogene short open reading frame 2 Leucine-rich repeat protein family protein 238 -0.88 -1.62 -1.43 -0.71 -1.21 -0.85 - - AT2G01008 AT2G07811 -0.62 DLK2 AT3G24420 -1.25 -1.39 -0.67 -3.30 -0.70 - - - - - - - - - AT3G56275 AT3G61410 AT4G04745 AT4G39795 AT5G42930 AT5G44820 AT5G50270 AT5G54300 AT5G61820 0.83 0.70 0.82 0.76 DUF547 AT1G16750 2.48 2.03 2.41 2.35 2.35 1.81 1.70 2.16 1.85 1.87 1.82 1.76 1.52 1.28 1.59 1.14 1.69 1.25 1.43 1.94 1.84 1.58 2.94 3.45 3.53 0.77 0.74 0.59 0.72 0.88 0.87 0.72 0.75 1.10 0.79 DUF567 - - CLE46 PCR6 - - - - - SORF2 0.71 0.89 - AT1G33840 AT4G39675 AT5G54710 AT5G59305 AT1G49030 AT1G58130 AT2G05530 AT4G16008 AT5G01740 AT1G05135 AT1G11185 AT1G49750 Table 3.9 (cont’d) Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown Unknown alpha/beta-Hydrolases superfamily protein pseudogene Rhodanese/Cell cycle control phosphatase superfamily protein GDSL-like Lipase/Acylhydrolase superfamily protein Embryo sac development arrest 32 hypothetical protein CBS domain protein Ankyrin repeat family protein hypothetical protein decreased in response to Mn, increased by cytokinin Leucine-rich repeat (LRR) family protein P-loop containing nucleoside triphosphate hydrolases superfamily protein pseudogene Glycine-rich protein family Glycine-rich protein family E6-like protein Cysteine/Histidine-rich C1 domain family protein hypothetical protein TRAF-like family protein Retrotransposon like protein HXXXD-type acyl-transferase family protein transmembrane protein hypothetical protein 239 1.17 3.09 1.00 2.33 - - AT1G52700 AT2G24750 0.71 0.76 STR9 AT2G42220 1.27 1.15 K24A2.4 AT3G27950 0.68 0.60 0.86 0.82 0.69 0.66 1.75 1.20 0.84 3.63 0.67 1.69 0.97 0.75 0.77 1.17 0.88 0.91 1.90 0.60 0.63 0.81 1.69 EDA32 - - - - - - AT3G62210 AT4G16000 AT5G52790 AT5G54720 AT1G13480 AT1G19960 AT1G33612 IAN4 AT1G33900 - GRP9 - E6L1 - - - - - - - AT1G54660 AT2G05440 AT2G05510 AT2G33850 AT2G43220 AT3G46880 AT4G00780 AT4G16870 AT5G07860 AT5G44574 AT5G44585 Figure 3.14 - Abundance of differentially expressed Arabidopsis genes Arabidopsis genes differentially expressed (DEGs) in roots colonized with Mortierella elongata as compared to the uninoculated control, identified usng DESeq2 with fold-change threshold of 1.5 and p-value threshold of 0.05. a) A Venn diagram of all DEGs in the final, filtered dataset. b) A bar graph of all DEGs, split between up- and down-regulated. c-d) Venn diagrams of c) up- and d) down-regulated DEGs identified for each fungal treatment. 240 CHAPTER 4. SYNTHESIS Objectives The goals of this dissertation research were three-fold: 1) to resolve the phylogeny of the Mortierellaceae using novel phylogenetic markers and phylogenomics. 2) To confirm and characterize plant growth promotion by Mortierella elongata in Arabidopsis thaliana and determine what affect fungal endosymbiotic bacteria may have on that phenotype. 3) To then elucidate the genetic basis of Mortierella-plant association using transcriptome sequencing. Two side projects aimed to a) to develop an Agrobacterium tumefaciens-mediated transformation system in M. elongata (Appendix B) and b) establish a mating system for M. elongata as a basis for identifying genetic regulators of sexual reproduction and how endobacteria might impact fungal mating (Appendix C). Mortierellaceae Phylogeny & Taxonomy In Chapter 2, I identified novel, phylogenetically informative, single-copy loci for which I developed family-specific primers. I used those primers to amplify target loci from over 300 Mortierellaceae isolates. In collaboration with Dr. Stajich, I also used low-coverage genome sequencing of over 60 representative Mortierellaceae isolates to recover over 400 genetic loci. I combined the amplicon and LCG datasets to generate a highly supported Mortierellaceae phylogeny. By combining these approaches, I was successful in resolving the phylogeny of Mortierellaceae into 13 monophyletic genera, 7 of which are newly proposed. Of the non-ribosomal markers used in this study, the most universally informative locus was RPB1, which is already an established phylogenetic marker, and should probably supersede the ITS region for isolate identifications as reference sequences are accumulated. However, the RPB1 locus was not entirely sufficient for resolving the full phylogeny and the other non-ribosomal loci proved necessary in discriminating between very closely related species, such as Locus 2451 241 in Podila. We selected from the full set of loci identified by our pipeline on the basis of similar primer melting temperature to RPB1, since we were multiplexing the primer sets. It is possible that some of the untested loci could be of similar value to RPB1. These loci, and more importantly the primers, were selected and designed from only three representative genomes. As additional de novo genomes become available, the locus selection process could be repeated and would probably yield a narrower selection of potentially suitable novel loci from which more broadly suitable primers could be designed. This study simultaneously included novel species lineages and included limited established species diversity. This study was the first inclusion of Modicella in a detailed molecular study of the Mortierellaceae. Moreover, our expanded geographical sampling efforts identified a novel genus containing at least three novel species and one novel species in the Linnamannia. Even so, this study only included a total of 44 of the 125 described species in the Mortierellaceae. The type specimens for represented species were often not included, which limited our ability to resolve the occasional overlapping species groupings, such as Podila humilis and P. verticillata. In addition, some species were only represented by a few or one isolate, such as Necromortierella dichotoma. This limits our confidence in the placement of those species in the phylogeny. Despite the limitations of the ITS region for phylogenetics and species identification, we did use ITS sequences to estimate where most of the excluded species might fall in the proposed taxonomy. I expect that the next revision of the Mortierellaceae phylogeny and taxonomy will employ either genome sequencing of additional species diversity or a second effort similarly combining phylogenomic analysis of a subset of isolates used to anchor an amplicon dataset including broader species diversity. Given the continuing advances in genome sequencing, the former approach seems more likely. However, an amplicon-based study can make use of sequences deposited to reference databases, such as RPB1, if it becomes widely applied to identifying Mortierellaceae isolates, which could then capture much higher intraspecific diversity due to a higher sampling capacity than a genome sequencing effort. 242 Continued geographic sampling efforts are still needed to fully characterize Mortierellaceae species diversity and distribution. Based on available culture collections, Africa, Asia, and South America are particularly undersampled. While the Mortierellaceae phylogeny and taxonomy improved by our study, these are likely to change as we accumulate ecological and sequence data from these fungi. Eventually, this data will allow for delineation of ecological functions within each group, inference about the ecological function of new species or isolates classified within those groups, and study of how such traits and ecological adaptations evolved. As geographic sampling continues, one of the most valuable future contributions to our understanding of Mortierellaceae would be a curated database of reference sequences for selected phylogenetic markers with updated taxonomy. This would aid in accurately identifying new isolates and placing novel species within genera. Secondly, this consolidated record of the geographic and environmental origin of isolates worldwide would allow us to establish the range and ecologies of these species. Mortierella elongata - Arabidopsis thaliana symbiosis In Chapter 3, I demonstrated that Mortierella elongata promotes the aerial growth and seed production of Arabidopsis thaliana. I found that neither BRE or MRE have a significant impact on the parameters of plant performance that I measured. I used RNA sequencing to identify genes that were differentially regulated in fungal treatments as compared to the uninoculated control. I identified differentially regulated genes involved in plant defense, hormone signaling, root development, abiotic stress, and metabolism. Many studies have explored the impact of a variety of Mortierellaceae species in different environmental and experimental conditions. Given the variation in the Arabidopsis-M. elongata association under different conditions (Appendix A), care should be taken to understand the environmental context of each study and how that might impact the association. For instance, the potting mix study methodology created a stress condition that confounded the intended 243 hypothesis testing. While the grain spawn substrate at issue is not necessary for fast-growing strains like M. elongata, many Mortierellaceae strains cannot survive blending for direct inoculation, as is often used for soil or potting mix-based experiments. We will need to optimize these protocols further for standardizing across studies and to ensure that the intended hypotheses are actually being tested and conclusions are translatable. The role of Mortierellaceae bacterial endosymbionts in the plant-fungal symbiosis was previously unexplored. However, just because BRE and MRE did not have an impact on the plant- fungal symbiosis in our experimental system and timepoints does not preclude their having an impact on M. elongata in other systems. It is well established that both endobacteria strongly alter the fungal growth and metabolism (Uehling et al, 2017). The M. elongata genome also seems to have unusually few secondary metabolite synthesis genes, some of which are present in the BRE genome (Uehling et al, 2017). It is possible that endobacteria supply the fungus with defense and signaling compounds that are relevant in other environments and interactions. In this study, we measured plant growth and productivity at early and late life stages after a stable symbiosis had been established. The mechanism of maintaining symbiosis may be very different from that required to initiate and establish symbiosis, as demonstrated by the shift in JA levels throughout the Arabidopsis-M. hyalina symbiosis or transient stress responses in Arabidopsis during S. indica infection (Johnson et al. 2019; Meents et al. 2019; Vahabi et al. 2015). Future research may illuminate mechanisms of extremely early stages of interactions between M. elongata and plants, using protocols similar to those described in Meents et al. (2019). Our preliminary agar experiments were extremely discouraging, in that Arabidopsis colonized by any Mortierellaceae was visibly more stressed and senescent than uninoculated plants. These experiments were conducted on Murashige and Skoog medium with sucrose, rather than PNM, (details in Appendix A) and with a different Arabidopsis Col-0 lineage. At the time, we also inoculated at the base of the plate and let the roots and hyphae grow together, giving plants and fungi much more time to communicate prior to making contact and also increasing the age of the 244 plant at the time of contact. A number of factors could be responsible for the reversal of the positive plant-fungal association we observed in the experiments described in Chapter 3. It would be informative to determine whether the medium, timing and mechanism of inoculation, or genetic drift in the plant genotype had such a strong impact on the plant-fungal association. I suspect that the medium may have played the biggest role, as PNM has no carbon source for the fungus, whereas MS+sucrose has abundant carbon. I observed significantly more abundant mycelial growth on MS plates, making the fungi less dependent on the plant for carbon and potentially increasing the concentrations of metabolic by-products that might have been toxic to the plants. Both our preliminary and final results strongly indicate that M. elongata affects Arabidopsis root architecture and development. Scanning and image analysis during early stages of symbiosis might be suitable for tracking root branching and growth before roots begin to overlap and grow along the edges of the plate where they are no longer visible. Since ethylene seems to be involved in this process, it may be important to test whether light is converting fungal production of metabolic by-products to ethylene, or use phytagel to ensure that fungi are not degrading agarose to ethylene, which would not take place in a natural system (Splivallo et al. 2009; Chagué, 2010). We were unable to analyze the fungal transcriptome due to extremely low read abundance. It might be possible to use a microbiome enrichment kit or other technique to isolate or increase the proportion of fungal RNA. This could allow co-expression network analysis and significantly improve our understanding of the fungal response to the plant, rather than just the plant response to the fungus. Once candidate fungal symbiotic genes are identified, completing and implementing the M. elongata transformation system discussed in Appendix B will provide a means for manipulating those genes and testing hypotheses. The transcriptomic study indicated that both auxin and ethylene were regulated in the plants colonized by M. elongata. Biosynthesis of these phytohormones was downregulated, while response pathways were upregulated. I hypothesize that this could be due to fungal production of auxin and ethylene. An obvious next step is to directly quantify the concentrations of auxin and 245 ethylene in fungal hyphae in pure culture, in uncolonized plant roots, and in colonized roots. It would also be valuable to inoculate auxin- and ethylene-insensitive mutants with M. elongata to test whether the plant-fungal symbiosis is affected. It would be highly informative to conduct shared-media assays that test whether direct contact is required for this symbiosis, or simply an exchange of signals and metabolites. A spent-medium assay could also be used to test whether constitutively produced metabolites from one organism trigger a response in the other to initiate interaction. Conclusions Mortierellaceae-plant associations have been described for over 100 years, but the mechanism and potential applications of these associations were not a concerted research focus until the last 5 years. Now the Mortierellaceae are emerging as an unusually tractable research system. The Mortierella species for which plant benefits have been described are distributed across several phylogenetic clades. It is valuable to understand the mechanism of interaction in each of these representative species to determine whether the Mortierellaceae have a conserved mechanism of plant association or how each functional group interacts with plants and how those mechanisms compare to those of the Glomeromycotina and Endogonales. While Arabidopsis is still the quintessential model plant, it is far from representative of most agriculturally and industrially relevant plant species. Fortunately, interaction studies with Mortierellaceae have been conducted in multiple plant species. Conducting these experiments in a panel of model species, such as Brachypodium, tomato, and Poplar may allow for identifying a very narrow set of common features in their associations with Mortierellaceae. I think that Mortierellaceae species have the potential to become agriculturally important for biocontrol of pathogens, helping to orchestrate the plant rhizobiome community, and solubilizing nutrients for plants. While these fungi are naturally occuring, Li et al. (2018) and Liao et al. (2019) showed increased plant benefit from increasing their abundance by supplemental inoculation. 246 Unless Mortierellaceae can be optimized for seed coating, which may be too early a life stage for such a heavy application, or blending and slurry-based application, it may be more successful to identify mechanisms and conditions by which plants recruit Mortierellaceae and optimize the plant side of the symbiosis. However, on the fungal side of the equation, very little is known about intraspecific variation in the plant associations reported in each study. It would be helpful to characterize symbiotic associations in a panel of isolates from diverse geographic and environmental origins before extrapolating findings across a species. Such precautions will likely identify particularly strong and weak associations. Side-by-side comparisons of each end of a spectrum could shed light on the mechanism of association quite quickly. In addition, species and strains adapted to specific environmental conditions might be superior at protecting plants from biotic or abiotic stresses specific to those environments, such as heat, cold, salt, drought, water-logging, or heavy metals. The concept is based on the idea that symbionts can confer habitat-specific adaptations to their hosts. Most of the Mortierellaceae-plant interaction studies have been conducted in neutral conditions, so additional research into seemingly neutral or even weakly negative associations might identify strains better suited to specific stresses. The current microbiome paradigm predicts that rhizosphere species work cooperatively to benefit themselves, and consequently their host plant. While there will always be limitations to the direct applicability of bi- or tripartite interaction studies, understanding the impact of each member in isolation before we can begin to recognize synergies and competitions in more complex systems. Moreover, it is possible that the endobacteria regulate how their host fungi interact with other members of the rhizosphere. 247 APPENDICES 248 APPENDIX A: PLANT-FUNGAL EXPERIMENTS Preliminary agar experiments For all of these experiments, I used sterilized, stratified, Arabidopsis seeds germinated as described in Chapter 3. Preliminary Mortierellaceae species panel Four day old seedlings were transplanted from germination plates to half-strength Murashige & Skoog medium (0.5xMS+suc). This medium was prepared by mixing 2.2 g/L Murashige and Skoog medium (Sigma Aldrich), 10 g/L sucrose, and 10 g/L agar (Sigma, product# A1296), 1 L water and the pH adjusted to 5.7 with 1 N KOH before autoclaving, cooling, and pouring into 100mm2 square plates (with grid). We used 6 seedlings per plate, 3 plates per treatment. After transplanting, seedlings were allowed to grow on the 0.5xMS+suc plates for 7 days, then were inoculated 1cm from the bottom of the plate by cutting out two 1 cm x 0.5 cm rectangles out of the agar and filling with the inoculating agar block. Fungal strains were maintained on MEA or PDA and inoculated onto 0.5xMS+suc several days to a week in advance of use to inoculate plant interaction plates. The strains used were M. selenospora 1228cu and 1228wt, Benniella erionia (=Mortierella sp. nov.) GBAus27Bwt and GBAus27Bcu, M. elongata NVP64cu, NVP64wt NVP80cu, and NVP80wt. We noted that after 3 days of interaction, plants were visibly smaller with purple stems and some yellowed, senescing leaves when inoculated with fungi. Also, as Arabidopsis root tips and Mortierellaceae hyphae approached each other, root growth generally slowed and even stopped, with root tips often curling up away from the media, and lateral branching increased compared to the uninoculated plants (Fig A.1). Fungal Exudate Experiment I transplanted 4 day old seedlings from germination plates to 05.X+suc plates, 6 plants per plate, 3 plates per treatment. Three days later, I inoculated the 7 day old seedlings. I had two 249 controls, a “true negative” control without any fungi, as described above, and an “empty moat” control without any fungi and a 0.5 cm “moat” in the agar about 2 cm from the bottom of the plate. The three fungal strains were NVP80wt, NVP64wt, and NVP64cu. Each fungal strain was previously cultured for three days on a separate 0.5xMS+suc plate. Fungal exudate blocks were cut along the periphery of the hyphal growth, approximately 0.5 cm x 2 cm. Fungal exudate blocks were inserted into moats cut into the agar as described for the “empty moat” control. Finally, fungal mycelium was inoculated onto plates with empty moats. In theory, the empty moats would prevent the diffusion of fungal exudates in advance of the hyphae and the fungal exudate blocks would only diffuse the fungal exudates without the roots ever contacting fungi. First, I observed no fungal growth from the fungal exudate blocks, confirming that no hyphae were accidentally transferred. I did not observe any impact on root growth in the fungal exudate treatments (Fig A.2). I did not observe impact on root growth in the inoculated plates until the roots and/or the hyphae had bridged the moat and made contact, which occurred within 3-4 days of inoculation. The plants were still smaller and visibly distressed as compared to the controls. Pilot study on PNM This pilot study was the first implementation of the PNM-based experimental methods described in Chapter 3. The methods were as described, with two exceptions: 1) the uninoculated control, NVP80wt, and NVP80cu were cultured on KM, but NVP64wt and NVP64cu were cultured on MEA; 2) plants were harvested at 14 DPI, instead of 12 DPI. Data were analyzed by linear modeling of aerial dry weight as a function of treatment and starting seedling root length, with plants grouped by plate to account for subsampling and plates treated as a random effect. I found that plants inoculated with NVP80cu and NVP80wt treatments had higher aerial dry biomass than the uninoculated control, whereas plants grown with NVP64cu and NVP64wt were not significantly different from the control (Fig A.3). I also observed that some of the plants had begun to bolt. This experiment demonstrated that at least NVP80 strains promoted plant growth and that NVP64 strains may be affected by BRE. This data prompted the bolting time and media 250 panel experiments described in Chapter 3. Preliminary Mortierella species panel in potting mix Materials and methods were exactly as described in Chapter 3 for the potting mix experiment. Due to space constraints, the full panel of fungal strains was split into two batches. The “Batch 1” strains were M. elongata NVP64cu, Mortierella sp. nov. (Benniella erionia) GBAus27b, M. alpina GBAus31, M. humilis PMI1414cu, M. minutissima AD051cu, M. selenospora KOD1228cu, and the no millet control. The “Batch 2” strains were M. paraensis KOD1235, Dissophora ornata KOD1234, M. echinosphaera KOD1233, M. cystojenkinii KOD1230, M. strangulata KOD1227, M. gamsii AM1032, M. hyalina AM1038, and the uninoculated millet control. I expected that combining these datasets with the dataset presented in Chapter 3 would allow for normalizing between batches, since the Chapter 3 dataset had both controls and NVP64cu. However, this was an invalid interpretation of block design and the lack of overlapping controls or other treatments in every single batch prevented controlling for batch effects. Within Batch 1, I found that Arabidopsis aerial dry weight was significantly smaller in all 5 fungal treamtents as compared to the no millet control (Fig. A.4a). Within Batch 2, I found that Arabidopsis aerial dry weight was significantly larger in all fungal treatments except Dissophora ornata KOD1234 as compared to the uninoculated millet control (Fig. A.4b). A critical analysis of the potting mix experiment methodology This study began with potting mix-based experiments to maintain a relatively realistic experimental system representative of the real-world environments in which M. elongata and plants naturally interact. However, I encountered several significant issues and challenges with the potting mix system. First, I discovered that not only does the uninoculated spawn invite colonization by environmental contaminants, but the spawn itself has a strong, consistent negative impact on plants. Preliminary studies of Mortierella interacting with millet plants using 251 millet-based spawn suggest that some of this effect is probably due to allelopathic compounds in the grains, as millet plants are much less affected by a millet-based spawn than Arabidopsis (data not shown). For our continued experiments in Arabidopsis, I increased the proportion of perlite in the spawn from the 2:1:1 perlite:barley:millet used here to 18:1:1 perlite:barley:millet. Other studies have relied on comparisons between Uninoculated spawn and Inoculated spawn treatments, neglecting to include a NoSpawn control and potentially biasing their results toward stress mitigation and not neutral environment plant growth promotion. Second, the potting mix also needed to be autoclaved thoroughly to ensure sterility and isolation of the experiments from contaminants. Unfortunately, autoclaved potting media accumulates unknown by-products that are toxic to plants (Kremer et al. 2018). The potting mix had to be rinsed through with large volumes of water prior to use. However, at this experimental scale, each treatment required several liters of water to thoroughly rinse the potting mix, the containment and draining of which was also a technical and logistical challenge. Another challenge of the potting mix-based experiments was deciding at what point to conclude the experiment, since the highly stressed uninoculated spawn control plants matured much sooner than the other treatments. This meant that life stage might be an incompletely controlled factor in the biomass and seed production data. However, the difficulty of handling mature Arabidopsis without significant loss of seeds and siliques necessitated harvesting plants before full maturity and maximal seed production. Having struggled with the negative impacts of spawn and difficulty of preparing sterile potting mix and seedlings in the potting mix experiments, I decided to switch to agar plates, as these afford superior control of the plant environment, straightforward controls, increased replication, and improved access to plant roots for qPCR, RNA-seq, and visual inspection of architecture and fungal growth. The agar experiments described in Chapter 3 were harvested at a much earlier lifestage, but still showed a very similar trend in plant aerial biomass between uninoculated and fungal treatments. The dry weight of the fully-grown plants from the potting mix experiments 252 include the rosette and inflorescences, both of which might have been independently affected by the fungal treatments. The bolting trial (Ch 3) demonstrated that the age at which plants first began to bolt was unaffected, but additional work should be done to assess the inflorescence development, architecture, flowering, and seed production at a level of detail that was not captured by these experiments, since I looked at plants either well before or after plants had completed these processes. The potting mix experiment was necessary and technically sufficient to collect data about seed production, though I should have increased the sample size from which I collected seed, instead of harvesting those plants to assay dry biomass. The agar system was more suited to assay aerial growth and root gene expression. Now that M. elongata has been shown to impact plant growth, more extensive experiments can be justified to refine our understanding of this plant-fungal interaction. An improved potting mix system, with a grain-free inoculation protocol, would be ideal to non-destructively track plant growth over time and construct a more detailed description of how M. elongata affects plant growth and development. The agar system is well suited for high- throughput assays of plant and fungal knock-out mutants to further isolate important genes and pathways involved in this symbiosis. 253 Figures Figure A.1 – 23 day old Arabidopsis plants on 0.5xMS+suc, 12 DPI Panel a) uninoculated control, b) Mortierella selenospora 1228wt, or c) M. elongata NVP64wt. Black marks tracked daily root tip growth. 254 Figure A.2 – Plates from the Fungal Exudate pilot study These plants are 21 days old, at 10 DPI. Treatments are a) “Empyt moat” control, b) “negative control”, c) , and d) “empty moat” NVP64cu. 255 Figure A.3 - Estimated marginal mean of Arabidopsis aerial dry weight (agar pilot study) The degrees of freedom for each comparison were approximated using the kenward-roger method and the p-values adjusted for multiple comparisons using the Tukey method for comparing a family of 5 estimates. Letters indicate significantly different groups with an alpha value of 0.05. 256 Figure A.4 – Aerial dry biomass of Arabidopsis grown in sterile potting mix (species panel) In each treatment, the potting mix was amended with: nothing (NoMillet), sterile millet mix (Uninoculated), or millet mix inoculated one of twelve fungal strains (M. elongata NVP64cu, Mortierella sp. nov. (Benniella erionia) GBAus27b, M. alpina GBAus31, M. humilis PMI1414cu, M. minutissima AD051cu, M. selenospora KOD1228cu, M. paraensis KOD1235, Dissophora ornata KOD1234, M. echinosphaera KOD1233, M. cystojenkinii KOD1230, M. strangulata KOD1227, M. gamsii AM1032, M. hyalina AM1038). Colors correspond to the revised taxonomy proposed in Chapter 2, horizontal bars and numbers indicate pairwise t- tests with alternative hypotheses defined as a) NoMillit being “greater than”, or b) Uninoc is “less than”, each fungal treatment and the resulting p-value. 257 APPENDIX B: MORTIERELLA ELONGATA TRANSFORMATION SYSTEM Introduction Transformation systems are used to manipulate genetic material, whether to add, modify, or delete genes or alter the expression of a gene by interfering with the mRNA post-translation. There are four basic approaches to transforming filamentous fungi: protoplasting, Agrobacterium- mediated transformation, electroporation, and nuclear bombardment. Not all approaches are suitable to all fungi or applications. In particular, there are several challenges to developing a transformation system in zygomyceteous fungi, including M. elongata. First, the fungal hyphae are coenocytic (lacking regular septae), which precludes traditional protoplasting techniques that involve digesting the cell wall away from fungal cells, since the resulting protoplasts would be too large and fragile to survive the protoplast collection and downstream processes. In addition, each protoplast would have many copies of the nucleus. It is extremely difficult, if not impossible, to transform every nucleus with the desired mutation. Another approach is to collect and transform spores, directly or as they germinate. Of the three spore forms produced by M. elongata, sporangiospores are the most suitable for transformation, as they have the smallest number of nuclei, thinner cell walls, and they are typically more abundantly produced. However, many strains of M. elongata do not sporulate very aggressively and the spores are very small (about 6 μm x 12 μm) and unpigmented. This makes it difficult to confirm collection of spores. The only extant transformation system in Mortierellaceae is in M. alpina. There was one report of successful protoplasting and PEG-mediated transformation with a construct confering HygB resistance under the control of the His4 promoter and relying on random chromosomal integration in the ribosomal region (Mackenzie et al, 2000). The more common approach is to transform germinating sporangiospores, by nuclear bombardment or Agrobacterium tumefaciens-mediated transformation (Takeno et al. 2004b; Ando et al. 2009a; Ando et al. 2009b). Selection for transformants is usually accomplished by working in a uracil auxotrophic strain 258 or fungicide selection (Takeno et al. 2004a; Ando et al, 2009a; Ando et al. 2009b). The most effective and affordable fungicide for most Mortierellaceae is carboxin, which targets succinate dehydrogenase B (Laleve et al. 2014; Nyilasi et al. 2015). Resistance of sdhB to carboxin can be accomplished by a single nucleotide substitution in one of three possible locations, which all result in amino acid substitutions (Laleve et al. 2014). The most effective of these three mutations is H272L in Botrytis cinerea, which corresponds to H243L in M. alpina and H244L in M. elongata (Laleve et al. 2014). Unfortunately, since resistance is so easily conferred, it also arises spontaneously and accounts for about 10% of colonies that appear to be transformants when carboxin resistance is the only selective marker (Ando et al. 2009a). The concentration of carboxin required for selection varies considerably between fungal strains and even between strains of the same species (Nyilasi et al. 2014). Most constructs for transformation of M. alpina used the Histone 4.1 promoter, but a screen of a number of M. alpina gene promoters yielded a number of other options, the chief among them being the promoter for ATP binding protein SSA2, particularly a truncated version with only the last 400bp (Okuda et al. 2014). Transformation of M. alpina has focused on increasing the production of eicosapentaenoic acid (EPA) by adding additional copies of the native biosynthesis gene w3-desaturase (Ando et al. 2009b). However, our interest in a transformation system in M. elongata is much broader, including GFP for microscopy and gene manipulation to test hypotheses regarding the genetic basis of the Mortierella-plant symbiosis. GFP expression is the simplest starting point, since a construct for eGFP compatible with fungal codon usage is already available and does not require cloning native genes. Also, use of Agrobacterium-mediated transformation is a more approachable system than nuclear bombardment, since it does not require a gene gun. Compatibility between the fungus, the Agrobacterium strain, and the plasmid is vital to the success of a transformation system, necessitating careful design of each component. 259 Methods Media Recipes The sporulation medium Czapek-Dox Agar (CZA) was prepared by dissolving 2.0 g/L NaNO3, 1.00 g/L K2HPO4, 0.50 g/L KCl, 0.50 g/L MgSO4*7H2O, 0.01 g/L FeSO4*7H2O, and 30.0 g/L Sucrose in 1 L Water and adjusting the pH to 6.0 with ~3 dozen drops 3.7% HCl, adding 20.0 g/L BactoAgar, and autoclaving. S.O.C. Medium (SOC) was prepared with 20 g/L tryptone, 5 g/L yeast extract, 10 mM NaCl, 2.5 mM KCl, 10 mM MgCl2, 10 mM MgSO4, and 20 mM glucose. Protoplasting NVP64cu was cultured in 400mL PDB for 3 days at room temperature, shaking at 120rpm. The mycelium was collected on a sterile Whatman filter by vacuum filtration, washed with sterile water, and transferred to a sterile 50mL Falcon tube. The mycelium was suspended in 40mL 0.6M KCl, supplemented with 1g Glucanex (Sigma), and incubated at room temperature, shaking at 75rpm for 4 hours. Sporangiospore Collection Fungal strains were transferred to CZA plates and cultured at room temperature for 2 weeks, at which point sporangiophores were visible in mycelium near the agar surface. Plates were washed with 3mL sterile 0.5% Tween-20 and the agar surface scraped with sterile microspatulas to release spores and mycelium. The spore suspension was filtered through a double layer of sterile Nitex membrane (100um pore size). Fungicide resistance panels To test the resistance of M. elongata to potential selective fungicides, 50mL PDB was supplemented with 25, 50, 100, 200, and 300ug/mL nourseothricin or 6, 240, 900, 1710, and 3000 ug/mL hygromycin. Flasks were inoculated with small plugs of M. elongata NVP64WT previously cultured on solid medium. Flasks were observed daily for growth. To assess strain resistance to a wide range of carboxin levels, I collected sporangiospores from M. alpina GBAus31, NVP17b, and NVP153 and M. elongata NVP5, NVP64cu, NVP80cu, 260 and AG77- as described above and plated them on PDA and PDA supplemented with 1mg/mL hygromycin and 67, 333, 1000, and 1500 ug/mL carboxin. The PDA plate served as a positive control for spores in the spore suspension. Plates were monitored daily for signs of spore germination and growth. Amplifying Mortierella elongata genes & promoters To amplify the ef1a promoter, we performed PCR of 1kb of genomic DNA 3’ of ef1a from M. elongata using primers designed from the M. elongata AG77 genome, primers EF1Ap_F and EF1Ap_R, and HF Phusion PCR reagents (Table B.1). The HygB gene was amplified using plasmid template DNA from the Trail lab, primers Hyg5 and Hyg3, and HF Phusion PCR reagents. The PCR products were cleaned with the WizSV Gel + PCR Cleanup System (Promega). Plasmid & Construct Design 20p_CBX_TrpCt has 20bp of the pEF1a sequence, sdhB H244L, and TrpCt. The 20bp is to allow for overlap extension PCR to attach the pEF1a promoter. The H244L site was located by aligning the protein sequences of sdhB from B. cinerea BQ-3 (KR866382.1), M. alpina 1S-4 (AB373636.1), and M. elongata AG77, which was identified using a BLAST search of the M. alpina sequence in the MycoCosm genome portal (Fig. B.1). pSSA2_CBX_TrpCt_15ApeI has the truncated SSA2 promoter developed by Okuda et al. (2014) and the same CBX gene and TrpC terminator used in 20p_CBX_TrpCt, along with 15bp overlap with the pRFHUE-eGFP plasmid as digested with AfeI for integration with InFusion. Constructs were designed in SnapGene. Primers and synthetic constructs were ordered from IDT. Cloning & Overlap Extension PCR To attach pEF1a to 20p_CBX_TrpCt, we performed overlap extension PCR. Since this protocol relies on overlap between the two components, we first used an extended PCR primer to add 13 bp of the CBX 5’ sequence to the 3’ end of pEF1a in an HF Phusion PCR reaction (primers EF1Ap_F and CBX_pEF1a_R) and cleaned the PCR product with the WizSV cleanup kit. 261 Overlap extension PCR is a two step reaction, the first step uses each of the two overlapping fragments as a PCR primer for synthesizing the other fragment and generating full-length templates for the second step which has traditional PCR primers for each end of the full construct. We used HF Phusion reactions with recommended reaction conditions, annealing temperatures of 66, 63, 60, 55, and 50 in a gradient PCR for the first step and 56 for the second step. There were 10 PCR cycles for the first step and 30 cycles for the second step. In the first step, it is important to use equivalent concentrations (75-100 ng) of each component to be joined. Propagation of pDS23_eGFP We received a streak plate of E. coli pDS23_eGFP from the Trail lab. We picked a colony to inoculate 5mL of LB liquid medium supplemented with 100 ug/mL ampicillin and incubated at 37°C overnight under agitation. A glycerol stock of E. coli pDS23_eGFP was prepared by mixing equal volumes of the overnight culture with autocleved 50% glycerol. The pDS23_eGFP plasmid was extracted using Zyppy Plasmid Miniprep Kit (Zymo) and stored at -20°C. We chemically transformed E. cloni cells generously provided by the Hamberger lab with the extracted pDS23_eGFP plasmid. The 20 µl E. cloni cell aliquot was thawed on ice for 5 minutes, then 1.5 µl of 10 ng/µL plasmid DNA was added. The reaction was incubated on ice for 20-30 minutes, heat shocked at 42°C for 30 seconds, and returned to the ice. Next, 250 µl SOC was added and the suspension shaken at 37°C for 1 hour, then plated on LB agar medium supplemented with 100 ug/mL ampicillin and incubated overnight at 37°C. Preparation of Electrocompetent Agrobacterium Agrobacterium AGL1 was streaked onto solid LB medium supplemented with 20ug/mL rifampicin, and 75ug/mL carbenicillin (hereafter LB-Rif/Carb) and incubated at 28 °C for 1–2 days until colonies are visible. I picked a colony to inoculate 5 mL of liquid LB-Rif/Carb and incubated overnight at 28 °C, shaking at 200 rpm. I used the overnight culture to inoculate 100 mL of liquid LB-Rif/Carb and incubated for 15–18 h at 28 °C and shaking at 170 rpm until the OD600 reached 0.5–0.8. I aliquoted the culture into 50mL Falcon tubes, cooled it to 4 °C (about 30 min), 262 centrifuged for 10 min at 3,000*g at 4°C, and discarded the supernatant. The pellets were resuspended in 5 mL of ice-cold sterile water and adjusted the volumes to 50 mL with ice-cold water, then repeated the centrifuge and washing step twice more. The pellets were resuspended in 100 mL of 10 % (v/v) ice-cold glycerol solution, centrifuged for 10 min at 3,000 × g at 4°C, and the supernatant discarded. The pellets were resuspended in 50 mL of 10 % (v/v) ice-cold glycerol solution, combined into one Falcon tube, and centrifuge for 10 min at 3,000 × g at 4°C. The supernatant was discarded and the pellet resuspended in 1 mL of 10 % (v/v) glycerol and portioned into 50 μL aliquots in 1.5mL tubes, flash frozen in liquid nitrogen, and stored at −80°C. Results & Discussion While some labs have reported successfully protoplasting Mortierellaceae hyphae, my attempts were unsuccessful. Therefore, I decided to use sporangiospores, since protoplasting coenocytic hyphae seemed an unnecessary challenge in light of the abundant spore-based protocols for M. alpina. To this end, we performed several fungicide panels. Several Mortierellaceae species have been tested for susceptibility to nourseothricin, hygromycin, and carboxin, but M. elongata was not included in that study (Nyilasi et al. 2015). Our first choice of plasmid, pDS23_eGFP, conferred resistance to nourseothricin. We tested M. elongata NVP64wt susceptibility to 0-300ug/mL nourseothricin, but observed no difference in fungal growth between any flasks, indicating no susceptibility to nourseothricin in NVP64wt. We then focused on hygromycin, as it is a frequently used marker in ATMT of fungi. While I did observe impaired growth at 1700ug/mL, all flasks eventually grew after 5-7 days. Finally, I tested a panel of M. elongata and M. alpina strains for spore germination and growth on solid medium with 1mg/mL hygromycin in combination with a range of carboxin concentrations. All strains grew abundantly on the negative control plates. For one week, none of the strains grew on any of the fungicide treated media. Eventually, M. elongata NVP5 grew a single colony on a 66 µg/mL carboxin plate and M. alpina NVP17b grew a single colony on a 300 µg/mL carboxin plate. I found that not only 263 was the lowest concentration of carboxin (66 µg/mL) effective with 1mg/mL hygromycin, but higher carboxin concentrations crystallized too aggressively in the medium, liquid or solid, to be of practical use in a transformation system. This combination is anticipated to function in the transformation system by screening most all spores with the carboxin and the hygromycin delaying the growth of spontaneous mutants. Therefore, selecting positive transformants within 1-3 days should not suffer from the 10% false positive rate observed in the M. alpina system and requires lower concentrations of both fungicides than would otherwise be required for selection for most Mortierellaceae species and strains. This allows much more flexibility in selection of the background fungal strain by criteria other than highest fungicide susceptibility. The pDS23_eGFP plasmid is used for ATMT in Fusarium graminearum to express eGFP and confers resistance to nourseothricin (nat). Since M. elongata was resistant to nourseothricin, I planned to use restriction enzymes EcoRI and NruI to cut out the nat gene and replace it with a construct carrying HygB and CBX to confer hygromycin and carboxin resistance, respectively, the latter under the control of the native M. elongata EF1a promoter (Fig. B.2). I also received the HygB resistance gene from Trail lab, which I amplified from a second plasmid commonly used in their protocols. I did successfully amplify and sequence the native M. elongata EF1a promoter (termed pEF1a), which was assumed to exist in the 1kb genomic DNA sequence 5’ of the EF1a gene. The construct was cloned into pJet and we used PCR to add 13bp of CBX construct to increase overlap between the components (pEF1a_20CBX). Since the sdhB genomic sequence includes introns that significantly and unnecessarily increase the insert length, I designed and ordered a synthetic construct from IDT with the last 3’ 20bp of pEF1a, the M. elongata sdhB coding sequence with the H244L point mutation, and TrpCt (20pEF1a_CBX_TrpCt). I repeatedly tried to perform overlap extension PCR to attach pEF1a_20CBX to this construct. Gel electrophoresis of the PCR products only ever showed the 1kb pEF1a or 1.7kb CBX fragments, never the 2.6kb joined fragment. 264 Finally, I intended to digest the pDS23_eGFP plasmid and attempt InFusion with the plasmid, pEF1a, and 20pEF1a_CBX_TrpCt. However, the glycerol stock of E. coli pDS23_eGFP could not be revived and I did not get colonies from transforming E. cloni with pDS23_eGFP extracted from the original E. coli pDS23_eGFP overnight culture. In light of these challenges, I attempted to procure the plasmid and Agrobacterium C58C1 used in M. alpina (Ando et al. 2009a; Ando et al. 2009b). Personal communication with the corresponding authors of those manuscripts was not fruitful. Nor were the Agrobacterium strain nor the plasmid available from a repository. Therefore, I identified A. tumefaciens AGL1 as an appropriate strain for our purposes, since it has been used to transform filamentous fungi and was available through our collaboration with Dr. Benning (Wang et al. 2020). Specifically, A. tumefaciens AGL1 was used to transform Aspergillus carbonarius with the plasmid pRFHUE- eGFP, which confers expression of GFP and resistance to Hygromycin (Fig. B.3; Crespo- Sempere et al. 2011). Therefore, the only changes required for use in transforming M. elongata were to add the carboxin resistance gene. Of the restriction enzymes with only one cut site (unique cutters) in pRFHUE-eGFP, AfeI cuts at a very convenient location in the plasmid and is available through our collaboration with Dr. Hamberger. To add carboxin resistance to pRFHUE-eGFP, I designed the cassette pSSA2_CBX_TrpCt_15ApeI. The CBX gene is the SdhB gene sequence reported from M. alpina, without introns, with the H244L mutation as appropriate for M. elongata. It is regulated by the SSA2 promoter identified by Okuda et al. (2014) and terminated by the classic Aspergillus nidulans TrpC terminator sequence also used in the M. alpina transformation systems. Finally, it includes the 5’ end 15bp overlap with the plasmid vector as it would be cut by AfeI, which is required for InFusion cloning and controls the direction of integration into the plasmid (Fig. B.4). 265 Future Directions 1. Perform the InFusion protocol in collaboration with Dr. Hamberger using primers InFusion- FOR and InFusion-REV. 2. Isolate the plasmid and screen for successful integration using PCR primers pRFHUE- CBXscrF and pRFHUE-CBXscrR (Table B.1). If the CBX cassette was integrated, the PCR product should be ~2600 bp. The PCR product can be sequenced to ensure correct orientation and screen for mistakes in the sequence using two PCR primer pairs pRFHUE- CBXseqF1/pRFHUE-CBXseqR1 (1151bp product) and pRFHUE-CBXseqF2/ pRFHUE- CBXseqR2 (1277bp product), since the full insert is 2100bp and too long to Sanger sequence fully in one reaction. a. Future use of this vector for M. elongata transformation will likely require substitution of the eGFP gene with another gene of interest. Assuming use of the same promoter and terminator sequences, the gene can be replaced using restriction sites TspMI, XmaI, or SmaI and KpnI or FspI, the latter two of which are available through our collaboration with Dr. Hamberger. 3. Attempt and optimize the method described by Sakuradani et al. (2015) to generate & collect a large number of M. elongata sporangiospores. b. Once a supply of spores has been collected, a small subset should be used to stain with DAPI to determine the number of nuclei in M. elongata sporangiospores. If the spores are uninucleate, then most traditional targeted gene mutations and deletions are available to future research efforts. Multinucleate spores are a considerably more complex challenge. 4. Transform A. tumefasciens AGL1 with pRFHUE-eGFP-CBX. I used the Hamberger lab protocol described above to generate electrocompetent Agrobacterium AGL1 compatible with downstream protocols, but these cells have not been tested. 5. Use the freshly transformed AGL1 to transform the M. elongata sporangiospores. 266 Transformation Protocol Media Recipes Czapek-Dox Agar (CZA): 2.0g NaNO3, 1.00g K2HPO4, 0.50g KCl, 0.50g MgSO4*7H2O, 0.01g FeSO4*7H2O, 30.0g Sucrose, 1L Water, pH 6.0 with ~3 dozen drops 3.7% HCl, 20.0g BactoAgar, and autoclave. Minimal Medium Broth (MMB): 10mM K2HPO4, 10mM KH2PO4, 2.5mM NaCl, 2mM MgSO4*7H2O, 0.7mM CaCl2, 9uM FeSO4*7H2O, 4mM (NH4)2SO4, 10mM Glucose, 1L Water, pH 7.0, and autoclave. Potato Dextrose Agar (PDA): 12g Potato Dextrose Broth, 5g Yeast Extract, 1L Water, 15g BactoAgar, and autoclave. Transformant Selection Agar (TSA): 12g Potato Dextrose Broth, 5g Yeast Extract, 1L Water, 15g BactoAgar, autoclave, cool, and supplement with 200g/mL Cefotaxime, 1mg/mL Hygromycin, 66ug/mL Carboxin, and 0.3g Nile Blue A. Induction Medium Broth (IMB): 10mM K2HPO4, 10mM KH2PO4, 2.5mM NaCl, 2mM MgSO4- 7H2O, 0.7mM CaCl2, 9uM FeSO4-7H2O, 4mM (NH4)2SO4, 10mM Glucose, 0.5%w/v Glycerol, 39.2mg Acetosyringone, 40mM MES, 1L Water, pH 5.3, and autoclave. Co-cultivation Agar (CCA): 10mM K2HPO4, 10mM KH2PO4, 2.5mM NaCl, 2mM MgSO4- 7H2O, 0.7mM CaCl2, 9uM FeSO4-7H2O, 4mM (NH4)2SO4, 5mM Glucose, 0.5%w/v Glycerol, 39.2mg Acetosyringone, 40mM MES, 1L Water, pH 5.3, 15g BactoAgar, and autoclave. Transformation of Agrobacterium Cells (adapted from Hamberger lab protocol) Mix 50 ng of expression vector with 50 μL of electrocompetent Agrobacterium AGL1 cells thawed on ice. Transfer the mixture to a pre-cooled 2 mm electroporation cuvette and electroporate using a Gene Pulser (Capacity 25 μF; 2.5 kV; 400 Ω). Let the transformed bacteria recover in 450 μL of Luria-Bertani (LB) broth medium for 2-4 h at 28°C, shaking at 170 rpm. Spread 50-100 μL on agar plates of LB supplemented with 50 μg/mL Kanamycin, 20 μg/mL 267 Rifampicin, and 75 μg/mL Carbenicillin (hereafter LB-K/R/C). Seal the petri dish with parafilm and incubate at 28°C. Colonies should appear after 48 h. NOTE: The plate can be stored at 4 °C. Freshly transformed Agrobacterium is best for transient expression; however, Agrobacterium can be kept on plates for a few weeks, without losing the ability to transform Nicotiana benthamiana. Generating & Harvesting Mortierella elongata spores Inoculate M. elongata on fresh PDA and cultivate for at least 5 days to generate fresh mycelium for subsequent inoculations. Pour 150 mL of CZA into a tissue culture flask. Inoculate in six places with the fresh culture. Cultivate at room temperature for at least 14 days and another 14 days at 4°C to induce sporulation. The culture flask can be kept as a spore stock at 4°C for up to 3 years. Pour 30 mL sterilized 0.05% Tween 80 into the tissue culture flask and scrape mycelium off the agar surface using a cleaning brush. Filter this suspension through a 125 mL capacity Buchner funnel fitted with Miracloth and then a 60 mm glass disc (rough porosity grade) into a 50mL Falcon tube. Rinse the agar surface of the tissue culture flask with 30 mL sterilized 0.05% Tween 80 twice more and filter through the same Buchner funnel each time into fresh 50 mL Falcon tubes. Combine into two Falcon tubes and centrifuge at 8,000*g for 10 min and discard the supernatants. Wash each spore pellets with 25 mL sterilized water with gentle shaking, combine into one Falcon tube, centrifuge at 8,000*g for 10min and discard the supernatant. Add sterilized water to adjust the spore concentration to approximately 108 spores/mL, determined with a Burker-Turk counting chamber. ATMT of Mortierella elongata sporangiospores Using a plate of transformed Agrobacterium, do colony PCR on 2-3 colonies to confirm the vector is present. Use a single colony to inoculate a 5mL starter culture of MMB-Kan/Rif/Carb and grow for 48hr at 28°C shaking at 170 rpm. Centrifuge Agrobacterium cells at 5,800*g, resuspend in IMB, re-centrifuge, and discard supernatant. Resuspend the pellet in fresh IMB to an OD600 = 268 0.15 and grow at 28°C, shaking at 200rpm, until OD600 = 0.5-1.5 (8-12 hours). Mix equal volumes of Agrobacterium cells and the M. elongata sporangiospore suspension (concentration 108 spores per mL) and plate 100 µl of the mixture on nitrocellulose membranes (0.45um pore) on CCA (at least 9+ plates). After 24, 48, 72, and 96 hrs at 23°C, transfer the membranes to TSA. Transfer hyphae from growing colonies (should be blue from taking up the Nile blue in the TSA medium) to fresh PDA-Hyg/Cbx (may take 3-5 days) and observe for continued growth. 269 Figures & Tables Figure B.1 - Alignment of the sdhB amino acid sequences of M. elongata AG77, M. alpina 1S-4, and B. cinerea BQ-3 The yellow highlight indicates the conserved histidine residue at which site directed mutagenesis to a leucine confers resistance to carboxin. 270 Figure B.2 - A map of plasmid pDS23_eGFP_CBX-HygB 271 Figure B.3 - A map of plasmid pRFHUE-eGFP 272 Figure B.4 - A map of plasmid pRFHUE-eGFP_CBX 273 Table B.1 - Primers for constructing and screening pRFHUE_eGFP_CBX Sequence (5' to 3') GCTTGGCTGGAGCTAGTGGAG CGGTCGGCATCTACTCTATTCCTT CCGAGTGGAGATGTGGAGTGG ATCCTCTACGCCGGACGCATCGTGG GTCGGAAAGGCGCTCGGTCTTGCC CTCGCCACTTCGGGCTCATGAGC AGACGGCAGGTCCGAGGTATTGATCCG Primer Name Hyg5 Hyg3 TrpCt_R pRFHUE-CBXscrF pRFHUE-CBXscrR pRFHUE-CBXseqF1 pRFHUE-CBXseqR1 pRFHUE-CBXseqF2 GTGAGGGTATCTGCGGTTCCTGCGCC pRFHUE-CBXseqR2 InFusion-FOR InFusion-REV EF1Ap_F EF1Ap_R HygF HygR pDS23_A pDS23_B CBX_pEF1a_R AACAGTCCCCCGGCCACGGG TTCGGGCTCATGAGCGCTGCTATGCGAACGGTTCATTTTGC CACGCCGAAACAAGCCCGAGTGGAGATGTGGAGTGG CTAGGTTCTTGTTTCTACGATTTTGG GCTAGAAAGTGGTGATAAATGTACAG GACAGTTCTGGTTAGCCGTCAC GTCGACGACAACTACCATCGATC GGGCGAACTCCGTCGCGACCGAGTGGAGATGTGGAGTGG GACCATGATTACGAATTCGCTTGGCTGGAGCTAGTGGAG GTGTTTGTCCGGTGCTAGAAAGTGGTGATAAATGTACAG 274 APPENDIX C: MORTIERELLA ELONGATA MATING SYSTEM Introduction Mating systems in fungi regulate the process of sexual reproduction, which can impact the abundance, resilience, and evolution of those fungi (Burnett, 1956). Sexual reproduction is either heterothallic, where strains are required to out-cross with a compatible partner to mate, or homothallic, where a single strain possesses both mating types and is able to complete the sexual process without another individual. Mortierellaceae sexual spores are called zygospores, the morphology of which are highly variable between species. There are both heterothallic and homothallic species in this lineage, but no notable phylogenetic pattern between species having each mating strategy (Kuhlman, 1972). Heterothallic mating can be an advantageous evolutionary strategy in that it prevents self-crossing and increases genetic diversity, but the requirement for meeting a compatible partner in favorable environmental conditions could be a considerable disadvantage. Homothallic mating also results in nuclear recombination and alleviates the requirement for meeting a compatible partner (Olive, 1963). High asexual spore production can largely mitigate the disadvantages of both mating systems, leading some fungi to lose sexual reproduction altogether (Olive, 1963). Although mating and sex-regulating genes are known for the sub-phylum Mucoromycotina, these genes have not been identified yet in Mortierellaceae (Lee & Heitman, 2014). In the Mucorales, mating is regulated by trisporic acid, which is collaboratively by the (+) and (-) strains. Both strains produce synthesized B-carotene, which (+) and (-) strains metabolize to trisporic acid precursor molecules 4-dihydrotrisporic acid and trisporol, respectively (Gooday & Carlile, 1997). Each (+)/(-) mating strain has the enzyme necessary to synthesize trisporic acid from the precursor produced by the other (-)/(+) partner (Gooday & Carlile, 1997; Lee & Heitman, 2014). It is suspected that, similar to the Mucorales, the Mortierellaceae use trisporids to regulate mating (Schimek et al. 2003). 275 It is also unknown what environmental conditions regulate mating, only that some media support/induce mating better than others, especially low-nutrient media having complex compounds; optimal mating media seems to vary between species (Gams et a., 1972; Kuhlman, 1972). In addition, endobacteria are known to regulate mating in other systems, such as Rhizopus microsporus (Mucoromycotina), in which strains cured of their endobacteria can no longer form asexual or sexual spores (Mondo et al. 2017). Prior to this research, it was unknown whether either MRE or BRE affect Mortierellaeceae mating and whether either is transmitted in mating. Mating in M. elongata is heterothallic and substrate conditions have been optimized to some degree (Gams et al. 1972; Kuhlman, 1972). Since the Bonito lab has a library of M. elongata isolates, with and without MRE and BRE, I set out to establish mating assays to address research questions regarding the genetic basis, chemical signals, and impact of endobacteria on M. elongata mating. Methods Media Recipes Hay agar has been shown to stimulate the highest zygospore production in Mortierella elongata compared to a number of other media recipes (Gams et al. 1972; Kuhlman, 1972). We chose two different hay agar media types for our mating assays. We used grass hay produced for animal consumption, obtained from an equine medical center, which contained a few forbs, especially clover. Hay agar 1 (HAY1) was made by autoclaving 50g of hay in 1L of water on a 25min sterilization cycle and filtered with a Cat1 Whatman filter. The volume was adjusted to 1L with MilliQ water, the pH was adjusted to ~6 with K2HPO4, and 10g Difco BactoAgar added before autoclaving again for 25min sterilization. Plates were poured with about 20mL per plate. Hay agar 2 (HAY2) was made by autoclaving 12.5 g of hay in 900 mL of water in a 2L Erlenmeyer flask for 45 min on liquid cycle. It was filtered through a coffee filter in a metal strainer, 276 the volume of filtrate measured, supplemented with BactoAgar to achieve a final strength of 1%, and the medium autoclaved for 24 min on liquid cycle. Plates were poured very thin, about 15mL per plate. Mating & Microscopy I placed 1cm2 blocks of each strain on the HAY agar, 1cm apart and near the center of the plate (Fig. 1). I wrapped plates with extra parafilm or saran wrap to prevent desiccation and incubated the plates for 4-6 weeks. I observed the plates weekly, monitoring plate macromorphology and examining the zone of interaction between strains through the bottom of the agar plate at 40x and 100x magnification on a light microscope. Signs of mating were marked on the plate with sharpie for continued observation. Mating structures were visualized more closely by excising them from the agar and mounting on a glass slide and examination at 100x- 400x magnification. Results & Discussion Mating Our first round of mating plates used HAY1 and strains PMI86, NVP64wt, NVP64cu, NVP5. We observed zygospores after 6 weeks between NVP64cu*PMI86 and NVP64cu*NVP5 (Fig. 2; Table C.1). Significantly more zygospores were produced in the NVP64cu*PMI86 pairing. We designated NVP64cu to be type ‘A’ and its partners type ‘B’, since there are already ‘+’ and ‘-’ type strains designated, and selected PMI86 and NVP64cu to be tester strains. We will try to obtain these reference isolates in order to determine the +/- designation for our types A/B. In the second mating panel, I used HAY2 and paired 15 strains of interest with our tester strains, PMI86 and NVP64cu, and re-paired both NVP64wt and NVP64cu with PMI86, the former to re-check for mating in the wild-type strain and the second as a positive control. In the second panel, I observed zygospores in matings between NVP64cu and GBAus25, NVP4, AD073c, and JL63. Interestingly, I never observed zygospores or mating macromorphology in any pairing that 277 involved either NVP80wt (which has MRE) or NVP80cu. Kulhman (1972) described M. elongata as having both homothallic and heterothallic isolates and indicated that one of his homothallic isolates increased zygospore production when co- cultured with a heterothallic strain. However, none of his isolates were compatible with those shared by Gams, who had found them very fertile (Gams et al. 1972; Kuhlman, 1972). It is likely that M. elongata is a species complex, so perhaps there are both heterothallic and homothallic species in the complex and this could eventually be used as a diagnostic feature. Alternatively, the asexual spore and mycelial charactersistics of M. elongata are indistinguishable from those of a homothallic species, which may have since been distinguished by DNA sequencing. Finally, it is possible that homothallic species share the mating signals secreted by heterothallic species (Schimek et al. 2009; Lee & Heitman., 2014). Morphology In all successful matings, I observed both zygospores and suspensor cells, generally along the zone of interaction and not to one strain’s “side” of the plate (Fig. 1a-b). Zygospore formation was usually not observed closer to the center of the plate and to proceed outward as the edges of each colony continued to meet. Instead, zygospores usually appeared first about an inch away from the inoculating agar blocks. In some cases, as plates aged, I repeatedly observed the same suspensor cells in various stages of cellular content transfer between suspensor cells where it seemed like transfer and zygospore development had frozen. In most successful matings, I observed development of hyphal clusters, that looked like hyphal knot-like aggregations, under the agar surface along the zone of interaction (Fig. 1a-b; Fig. 2a-b). These did not occur in all successful matings, nor do they strictly correlate with the location of zygospores being produced. However, I did observe them only in successful matings and zygospores do seem to cluster in small “nests” (Fig. 2a-b). Most mating plates were not successful, in that I never observed zygospores. However, the scale of mating plates vs. the scale of zygospores makes it impossible to definitively say that no 278 zygospores existed on the plates we classified as negative. In most all putatively unsuccessful pairings, at least one of the strains produced abundant aerial hyphae on their side of the plate (Fig. 1c). This phenomenon was not observed in successful matings. However, it is possible that there were indeed zygospores present in the “unsuccessful” pairings that could not be observed due to the thick mycelial mat obscuring the passage of light through the agar. Effect of Endobacteria All matings with wild-type strains, those having endobacteria, morphologically resembled unsuccessful pairings (Fig. 1c). Moreover, no zygospores were ever observed in pairings with wild-type strains, though we cannot conclusively say that no zygospores were produced. HAY+cellophane Our collaborator Dr. Jessie Uehling at Oregon State University expressed interest in performing RNAseq of mating pairs to identify genes that might regulate mating in M. elongata. Cellophane is used to provide a smooth, firm surface to which mycelium cannot adhere, though they can still obtain nutrients from the agar underneath. This greatly increases the ease of collecting fungal mycelium without contaminating agar, the compounds of which often interfere with DNA and RNA extraction and analysis. However, cellophane does generally decrease fungal growth and there were concerns that mating would not be able to take place. To that end, I mated NVP64cu*PMI86 on HAY1 with a layer of sterile cellophane between the mycelium and the agar. Fortunately, I did observe mating on HAY1+cellophane, though the abundance of zygospores was reduced compared to regular HAY1 agar. Future Directions With successful mating, we can continue to screen M. elongata isolates for A/B mating type and eventually use the reference isolates to determine the +/- mating type. Using cellophane and close observation, the transcriptome of mating fungi may be obtained. Metabolomics of the media from mating versus single isolates may reveal candidate signals being exchanged during mating. Between these two approaches and careful genome comparison of the two mating types may be 279 sufficient to identify the genetic and chemical basis for mating compatibility, at which point strains could be classified as +/- with a PCR screen. It would also be extremely interesting to compare the transcriptomes and metabolomes of PMI86*NVP64cu and PMI86*NVP64wt to identify the mechanism by which BRE are putatively interfering with mating. 280 Figures & Tables Figure C.1 - Macromorphology of Mortierella elongata mating on HAY1 Panels a-b) show compatible mating of Mortierella elongata strains and panel c) shows an incompatible mating. 281 Figure C.2 - Micromorphology of M. elongata zygospores Zygospores were produced by mating NVP64cu*PMI86 on HAY1, viewed at a) 40x, b) 100x, c) 400x, and d) 1000x magnification under a light microscope. White arrows indicate zygospores in lower magnification images. 282 Table C.1 – Mortierella elongata mating strains The strains tested for mating, the mating type when zygospores were observed, and the type of endobacteria present, where applicable. Strain NVP5 NVP5 PMI86 NVP64cu NVP64wt NVP80cu NVP80wt GBAus25 NVP4 AD073c GBAus38 KOD979 AG77- AD022wt AD022cu AD073cu AD073wt JL11 JL51 JL63 Mating Type Endobacteria B B B A B B B B BRE MRE BRE MRE 283 APPENDIX D: SUPPLEMENTARY METHODS Fast DNA Extraction Extraction Solution (ES): 5mL 1M Tris stock (pH 9), 0.93g KCl, 0.19g Na2-EDTA, 50mL dH2O, titrated to pH 9.5-10.0 with 1M NaOH, sterilized with 0.2 μm filter, and aliquoted into 2mL Eppendorf tubes. 1. 3% BSA: 1.5g BSA in 50mL dH2O. 2. Pipette 20 µl ES into 8-strip tubes. 3. Place 10-20 mg of tissue sample into 8-strip tube, submerging in the ES and crushing/grinding if possible. Do not overload ES, err on the side of too little tissue to avoid high concentrations of PCR inhibitors. 4. Incubate at room temperature for 10+ minutes, then for 10 minutes at 95C in a thermal cycler. 5. Add 40 µl 3% BSA so that the final ES:BSA ratio is 1:2 (1:3 and 1:4 can also work well). 6. Samples are now ready for PCR. Use 1-2 µl for PCR and store DNA extractions in a freezer. Seed counting by automated image analysis in ImageJ Preliminary manual image analysis to determine parameters: 1. Open sample image in ImageJ 2. Select Working Area, i.e. the area to analyze for that sample 3. Edit>clear outside 4. Image>Adjust>Threshold (unselect dark background, we used 1.25%) 5. Analyze> Analyze Particles 6. Summary, Outlines, Min = 10??, Max = 1000 7. Show Results 284 Recording Macros for Batch Analysis 8. Start with an open image file, go to Plugins>Macros>Record 9. Take the image analysis steps determined in preliminary manual analysis 10. Hit “Create” and save in the ImageJ Macros folder Using Macros for Batch Analysis 11. Process>Batch>Macro 12. Input & Output must be in SEPARATE FOLDERS to avoid overwriting input images 13. Open+ Point to macro in ImageJ Macro Folder 14. Process In the case of the seed sheets analyzed in this study, there were four Working Areas in each raw image, one for each sample. This necessitated selecting each area in the raw image and exporting it as a separate input image to enable batch processing. CTAB-based DNA extraction protocol Fungal mycelium was placed into 450 µL of 2x CTAB buffer (100 mM Tris-HCl 8.0 pH, 1.4 M NaCl, 20 mM EDTA, 2% CTAB, 4% PVP MW=10,000) and homogenized with a tube pestle. Next, 450 µl of 24:1 chloroform:isoamyl alcohol was added. The tubes were shaken briefly by hand, then centrifuged at 18,213 g for 8 min. The supernatant was removed and placed into a new tube. Chilled 2-propanol was added to the supernatant at 0.6 times its volume. The tubes were inverted about 20 times, then placed at -80°C for 8 minutes. The tubes were immediately placed in a pre- cooled 4°C centrifuge and centrifuged at 18,213 g for 15 minutes to pellet genomic DNA. The supernatant was discarded and the pellet washed with 800 µl of chilled 80% ethanol, then centrifuged at room temperature for 90s. This rinse was repeated exactly. 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