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Title: BIOSENSING TOTAL BACTERIAL LOAD IN LIQUID MATRICES TO IMPROVE FOOD SUPPLY CHAIN SAFETY USING CARBOHYDRATE-FUNCTIONALIZED MAGNETIC NANOPARTICLES FOR CELL CAPTURE AND GOLD NANOPARTICLES FOR SIGNALING
Creator: Matta, Leann Lerie
Date: 2018
Collection: Electronic Theses & Dissertations
Description: Economical rapid nano-biosensing methods with expedited electrochemical signaling, were developed using carbohydrate-functionalized magnetic nanoparticles (MNP) and gold-nanoparticles (AuNP) to detect pathogenic bacteria in liquid or homogenized food samples. MNP functionalized with glycan- and amino/glycan ligands were able to rapidly extract bacteria, while concentrated dextrin-coated AuNP labeling improved detection sensitivity. Carbohydrate ligands are more stable than antibodies,...
Show moreEconomical rapid nano-biosensing methods with expedited electrochemical signaling, were developed using carbohydrate-functionalized magnetic nanoparticles (MNP) and gold-nanoparticles (AuNP) to detect pathogenic bacteria in liquid or homogenized food samples. MNP functionalized with glycan- and amino/glycan ligands were able to rapidly extract bacteria, while concentrated dextrin-coated AuNP labeling improved detection sensitivity. Carbohydrate ligands are more stable than antibodies, permitting long shelf life of MNP at room temperature and minimized AuNP aggregation during simple refrigeration. Transmission electron microscopy (TEM) imaged the electrostatic binding between MNP and Salmonella Enteritidis, E. coli O157:H7, Bacillus cereus, Listeria monocytogenes and E. coli C3000, which mimics electrostatic binding by antibodies, although with lower specificity. Capture index (CI) is defined as the parts-per-thousand (ppt) of bacteria extracted per initial bacterial presence. TEM mages showed that attached milk matrix components did not interfere with microbial. capture. Salmonella, E. coli, and Bacillus (3 to 5 log CFU/mL) capture in three milks was 2 ppt to 120 ppt CI. Capture in beef juice and apple cider was 0.002 ppt to 0.011 ppt for E. coli and Listeria, respectively, at 10 log cfu/mL due to accelerated microbial growth immediately following the spike. Viscous homogenized eggs, though, impeded MNP-Salmonella migration to the magnet during separation. This phenomenon was a motivating factor in creating “dip-sticks”: plastic strips coated in MNP (MNP-strip). Rapid nano-biosensing of MNP-cell complexes in under 30 min from either suspended or strip capture was possible using electrochemical technology of spectrometry or a simple handheld potentiostat. Capture concentrates bacteria as MNP-cell from large volumes allowing strong cyclic voltammetric (CV) signaling. Normalized peak current responses (NPCR) for microbial detection from simple matrices (PBS and beef juices) showed sample (S) NPCR lower than negative controls (N) (S/N < 1.0). Whereas in complex matrices (milk, apple cider, and homogenized eggs), S/N were significantly greater than 1.0. NPCR for negative controls were found to be linearly related to matrix components fats, proteins, and sodium (R2 = 0.92). Except for E. coli in beef juices, all S/N were significant (p < 0.05) for contamination levels ranging between 6.2 to 12.3 log CFU/mL.Enhanced signaling of low pathogen presence in food was achieved using electrically active AuNP labeling. Electrochemical detection of MNP-cell-AuNP complexes with spectrophotometry or differential pulse voltammetry (DPV) was significantly more sensitive, detecting 3 log CFU/mL and 5 log CFU/mL E. coli contamination in milk (p < 0.20), respectively. Food component attachment to the complexes altered, but did not interfere, with distinguishing samples from negative controls . MNP carbohydrate ligands exposed to refrigerated milk matrix components (fats, lipids, sugars, protein and sodium) for up to 9-days still extracted bacteria. This makes possible future biocompatible tag-on nano-biosensors inside individual food packaging. Pathogen presence could be monitored over the lifetime of the product, reducing consumption of contaminated foods. Reliable frequent testing along the food supply chain would facilitate reduced human disease, while reducing industry financial losses due to foodborne outbreaks. Flexible carbohydrate-based MNP-cell/(CV) and MNP-cell-AuNP/(DPV or spectrometry) nano-biosensing with electrochemical detection can provide a truly rapid, economical test.
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Title: CHEMICAL BIOLOGY AND GENETIC STUDIES TARGETING THE MYCOBACTERIAL CELL ENVELOPE
Creator: Williams, John Tison
Date: 2021
Collection: Electronic Theses & Dissertations
Description: Mycobacterium tuberculosis is one of the leading causes of death due to a single infectious pathogen. The evolution and spread of drug resistant strains requires new antibiotics to control the TB pandemic. Over the last decade, the lipid flippase MmpL3 has been identified as a potential drug candidate based on its essential nature for cell viability and repeated identification as the lead target of small molecule inhibitors of Mtb growth. Using a combined untargeted and targeted whole cell...
Show moreMycobacterium tuberculosis is one of the leading causes of death due to a single infectious pathogen. The evolution and spread of drug resistant strains requires new antibiotics to control the TB pandemic. Over the last decade, the lipid flippase MmpL3 has been identified as a potential drug candidate based on its essential nature for cell viability and repeated identification as the lead target of small molecule inhibitors of Mtb growth. Using a combined untargeted and targeted whole cell phenotypic screen I identified novel inhibitors of this valued target. A combination of lipid profiling and an innovative competitive binding assay supported MmpL3 as the target of these inhibitors. Cross resistance profiling of MmpL3 inhibitors against twenty-four unique mmpL3 Mtb mutants demonstrated that the level of resistance is associated with the proximity of resistant mutants to essential residues for protein function. Further, these resistance profiles suggested that MmpL3 inhibitors fall into separate clades depending on their chemical scaffolds. The results of this screen led to the development of novel potent analogs for one of the identified MmpL3 inhibitors, HC2099. These analogs were active against clinically relevant drug resistant Mtb strains that cause treatment failure in patients. Active analogs were able to kill Mtb inside of infected macrophages, an infectious niche of Mtb, without inducing cytotoxicity against these important immune cells. One of these analogs, MSU-43085, was orally bioavailable and successfully inhibited Mtb growth in infected mice, supporting further development and highlighting the therapeutic potential of this series. High throughput screens are often used to identify new inhibitors of Mtb growth. However, prioritized hits form these screens often identify similar targets such as MmpL3, lipid synthesis enzymes, redox cyclers, as well as inhibitors of the electron transport chain. Follow up studies of these inhibitors are often time consuming, costly and result in the rediscovery of previously identified targets. While this is not necessarily detrimental to Mtb drug discovery, as these reoccurring targets have therapeutic potential. The continued prioritization of inhibitors for these common metabolic pathways potentially limits the identification of inhibitors for novel targets. Therefore, additional steps that identify inhibitors of these common pathways could reshape how high throughput screen hits are prioritized. By applying the targeted mutant screen used to identify MmpL3 inhibitors to a non-prioritized library of hits from a high throughput screen, we identified more than fifty new potential MmpL3 inhibitors. Using an iterative strategy of applying additional mutants of commonly identified targets, this strategy promises to lead to parallel follow-up studies of inhibitors with known and unknown mechanisms of action. The ability of Mtb to enter into quiescent states in response to host stresses is one of the leading causes for the extended time to cure and evolution of drug resistance. These states can be induced by several environmental stresses including acidic pH, hypoxia, and others. In an effort to study this adaptation in the rapidly growing mycobacterial species M. smegmatis, we identified a lethal sodium citrate phenotype. Transcriptional profiling and genetic screening of mutants tolerant to sodium citrate indicated that this phenotype was due to the combined action of both chelation and osmotic stresses. Cell viability could be reduced from sodium citrate killing by cation and osmoprotectant supplementation. From these experiments we propose a model that can be applied to study carbon source uptake and probe the role of genes identified from the forward genetic screen with unknown function
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Title: COMPUTATIONAL APPROACHES TO COMPLEX BIOLOGICAL PHENOMENA
Creator: Franklin, Joshua Luke
Date: 2021
Collection: Electronic Theses & Dissertations
Description: Biological systems can be difficult to understand due to a vast array of interacting phenom-ena. The result is that some seemingly "easy" questions go unanswered. For example, we have long known that bacteria utilize many distinct flagellar configurations, but in most cases it remains unclear why they do so. We know that cell differentiation is critical to many biological processes, yet we still do not fully understand how such spatiotemporal patterning occurs. Despite mutation being one of...
Show moreBiological systems can be difficult to understand due to a vast array of interacting phenom-ena. The result is that some seemingly "easy" questions go unanswered. For example, we have long known that bacteria utilize many distinct flagellar configurations, but in most cases it remains unclear why they do so. We know that cell differentiation is critical to many biological processes, yet we still do not fully understand how such spatiotemporal patterning occurs. Despite mutation being one of the driving forces of evolution, we still have a hazy understanding of how organisms respond and adapt to high mutation rates. However, ad- vances in technology, modeling, and experimental techniques have enabled us to investigate the small and nuanced effects that can answer these questions. In this dissertation, I have used modern computational tools and statistical techniques to investigate evolutionary and behavioral processes. Agent-based models of evolution and flagellar inheritance have allowed me to investigate the evolution of mutational robustness and trade-offs associated with flagellar motility, respectively. By writing Bayesian mixed- effect models, I have been able to precisely quantify the metabolic cost of producing flagella and describe spatiotemporal patterns of cell differentiation within fruiting bodies of Myxo- coccus xanthus. Careful quantitative modeling of biological phenomena can help cut through the complexity of these systems. As computational power continues to grow and software continues to become more sophisticated, these computational approaches will both become more powerful and easier to use. Computational approaches will not replace experiments in most cases; instead, computational models can direct experiments, which can themselves direct new modeling efforts, in an iterative loop of progressing knowledge.
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Title: Characterization of map3773c, ferric uptake regulator protein, in iron metabolism of mycobacterium avium subsp. paratuberculosis
Creator: Miyagaki Shoyama, Fernanda
Date: 2020
Collection: Electronic Theses & Dissertations
Description: Mycobacterium avium subsp. paratuberculosis (MAP) is the causative agent of Johne's disease (JD) in ruminants, a chronic inflammation of the intestines characterized by persistent diarrhea that leads to malnutrition and muscular wasting (Rathnaiah et al., 2017). Unfortunately to date, reliable JD diagnostics are lacking. Culture of MAP from feces has been the most reliable method for diagnosis of JD, however MAP requires eight to sixteen weeks to produce colonies in culture, presenting a...
Show moreMycobacterium avium subsp. paratuberculosis (MAP) is the causative agent of Johne's disease (JD) in ruminants, a chronic inflammation of the intestines characterized by persistent diarrhea that leads to malnutrition and muscular wasting (Rathnaiah et al., 2017). Unfortunately to date, reliable JD diagnostics are lacking. Culture of MAP from feces has been the most reliable method for diagnosis of JD, however MAP requires eight to sixteen weeks to produce colonies in culture, presenting a major hurdle to diagnosis (Bannantine et al., 2002). Currently, no current vaccine can protect animals against JD or prevent shedding of MAP (Garcia and Shalloo, 2015). These challenges establish a need for a better understanding of the MAP physiology during infection. Unlike other mycobacteria, MAP has a unique requirement for supplementation of an iron-binding siderophore (mycobactin J) for optimal growth in laboratory media. A whole genome sequence of MAP K10 revealed a truncation of the mbtA gene that was speculated to have led to its mycobactin dependency (Li et al., 2005). Zhu et al (2008) showed that MAP is able to transcribe all mycobactin synthesis genes in an intra-macrophage environment. Furthermore, several genes responsible for iron acquisition in infected tissues, including genes responsible for mycobactin biosynthesis have been shown to be upregulated in naturally infected tissues (Janagama et al., 2010). Its known that iron plays an important role in vital biological processes; however high intracellular concentration of free iron can lead to toxicity to the bacteria. As such, bacteria activate expression of specific group of genes that are controlled by a metal-sensing regulatory transcription factor. In 2009, Janagama and others identified and characterized the iron dependent regulator (IdeR) in MAP. In addition, in a MAP-specific genomic island, MAP carries three putative ferric uptake regulator (Fur) boxes, an iron regulated transcriptional control motif, (Stratmann et al., 2004). To date, nothing is known about the role of Fur in MAP. To elucidate the mechanisms of iron homeostasis in MAP, we investigated LSP15 using a transposon mutant MAP3776c. We demonstrated a phenotype for LSP15 genes in a culture model of cell entry and survival and suggest a function in epithelial cell pathogenesis, however further functional analysis with complementation by a MAP3776c::Tn strain would be necessary to confirm these findings. Additionally, full characterization of a Fur-like protein (MAP3773c) was performed. Using PRODORIC for computational analysis, 23 different pathways that were likely regulated by MAP3773c were identified. These findings were confirmed using a chromatin immunoprecipitation assay followed by high-throughput sequencing (ChIP-seq), that revealed 58 regions where Fur binds under iron replete and deplete conditions. From those, three were directed related to iron regulation MAP3638c (hemophore-like protein), MAP3736c (Fur box) and MAP3776c (ABC transporter). Using the Fur box consensus sequence, we confirmed binding specificity and Mn2+ availability by a chemiluminescent electrophoresis mobility shift assay (EMSA). A transcriptional profile of the parent MAP K10, deletion mutant of MAP3773c and the complemented strains was developed under iron replete and depleted conditions. However, under the current experimental conditions, we are unable to conclude if the lack of transcriptional responses in our study was indicative of a lack of FUR activity.
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Title: Characterization of the development of the tonsillar microbiome in pigs
Creator: Peña Cortes, Luis Carlos
Date: 2017
Collection: Electronic Theses & Dissertations
Description: "Pig tonsils are identified as a potential reservoir for many bacterial and viral pathogens that can survive asymptomatically in this location and may have a high potential of being zoonotic. It has been suggested that the microbiome plays a significant/ substantial role in host colonization by pathogenic microorganisms and also exerts regulatory roles in the resistance to infection. Despite the important role that the tonsillar microbiome could play in the colonization and persistence of...
Show more"Pig tonsils are identified as a potential reservoir for many bacterial and viral pathogens that can survive asymptomatically in this location and may have a high potential of being zoonotic. It has been suggested that the microbiome plays a significant/ substantial role in host colonization by pathogenic microorganisms and also exerts regulatory roles in the resistance to infection. Despite the important role that the tonsillar microbiome could play in the colonization and persistence of pathogens in the host, there are no in-depth studies characterizing the development of tonsillar microbiome in pigs or how this microbiome is structured over time. Surprisingly a similar study is also absent in humans. There was a clear need to investigate the development of the tonsillar microbiome in pigs to lay the basis for future studies focused on more complex subjects such as the relationship between the normal tonsillar microbiome and pathogens in the tonsils. Understanding the development of the pig tonsillar microbiome over time and the role of the tonsillar microbiome in the acquisition and persistence of a pathogenic microorganism will lay the basis for the design of novel intervention strategies to control the presence of the pathogen and reduce the risk of transmission to other animals or humans. Moreover, these studies are expected to provide an animal model to test hypotheses generated by microbiome data that cannot be tested in humans. The goal of this study was to characterize tonsillar microbiome development in pigs, and how this microbiome is structured and how the structure changes through different times in the life of pigs. The chapters in this thesis will present pertinent data related with the composition of the pig tonsillar microbiome and how it alters through the life of pigs, possible maternal sources for some of the identified members of this microbiome, as well as the microbiome structure and progressive change through their life. Furthermore, the results will show that challenges associated with management procedures typically present in swine farms generate prominent changes in the microbiome composition and abundance of diverse bacterial families. Finally, the study will show the microscopic structure of the tonsillar epithelium and crypts and the presence of diverse bacterial communities on the surface of pig tonsils throughout different time points of their life. The final chapter will also describe the morphological changes of the tonsillar surface in pigs that are seen and are associated with changes in the microbial communities observed through different time points in their life. Taken together, the results presented here demonstrate that there is a temporal succession in the development of the pig tonsillar microbiome through the life of pigs."--Pages ii-iii.
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Title: Characterizing single-cell behavior of flagellated pathogenic bacteria in mucus and visco-elastic environments
Creator: Nguyen, Nhu Thi Quynh
Date: 2020
Collection: Electronic Theses & Dissertations
Description: Flagellar motility is required for some enteric pathogens to colonize the intestine. Understanding how these pathogens overcome the mucus layer protecting the epithelial tissue is necessary for disease prevention. In this thesis project I examined bacterial motility in mucus to understand factors that facilitate mucus penetration and contrasted this with the motility in different visco-elastic materials.In this thesis, I used single cell tracking to characterize the flagellar motility of...
Show moreFlagellar motility is required for some enteric pathogens to colonize the intestine. Understanding how these pathogens overcome the mucus layer protecting the epithelial tissue is necessary for disease prevention. In this thesis project I examined bacterial motility in mucus to understand factors that facilitate mucus penetration and contrasted this with the motility in different visco-elastic materials.In this thesis, I used single cell tracking to characterize the flagellar motility of Vibrio cholerae and Salmonella enterica in different visco-elastic environments. First, I tested if V. cholerae and S. enterica were still motile in unprocessed pig intestinal mucus. Second, I studied factors that supported their motility in mucus. The first factor I investigated was the effect of pH on V. cholerae motility. I also studied the role of curvature in V. cholerae motility within mucus and some other visco-elastic environments, including liquid and agar. Last, I began investigation of the role of flagellar number in S. enterica motility. In these studies, I focused on analyzing the effective diffusion of bacteria and factors promoting the diffusion in each environment. My findings demonstrate that V. cholerae and S. enterica are able to swim in mucus, and that the torque, and the curvature of V. cholerae, and the flagellar number of S. enterica, play a significant role in bacteria motility in mucus and liquid. Moreover, my findings help elucidate the significance of motility in pathogenesis.
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Title: Combination of physical and chemical interventions for reduction of loosely and tightly associated bacteria on broiler carcass skin
Creator: Singh, Pranjal
Date: 2016
Collection: Electronic Theses & Dissertations
Description: The study was conducted to develop processing interventions to reduce pathogen load on broiler carcasses and to understand patterns of bacterial association to broiler skin with the following purposes: 1) assess the effect of hot water spray (HWS, 71oC, 1 min) on broiler carcasses for reduction of loosely, intermediately, and tightly associated bacteria, 2) quantify loosely and tightly associated bacteria on broiler skin using different sampling protocols, 3) assess the effect of trisodium...
Show moreThe study was conducted to develop processing interventions to reduce pathogen load on broiler carcasses and to understand patterns of bacterial association to broiler skin with the following purposes: 1) assess the effect of hot water spray (HWS, 71oC, 1 min) on broiler carcasses for reduction of loosely, intermediately, and tightly associated bacteria, 2) quantify loosely and tightly associated bacteria on broiler skin using different sampling protocols, 3) assess the effect of trisodium phosphate dip, hot water dip, and their combinations with/without brushing on reduction of loosely- and tightly-associated bacteria on broiler carcasses and related structural changes in the skin, and 4) assess the characteristics of Salmonella association and penetration to broiler skin with and without stomaching. In study 1, broiler skin was quantitatively assessed for loosely, intermediately, and tightly associated bacteria by rinsing, stomaching, and grinding the same skin. Hot water spraying (71oC, 1 min) of broiler carcasses followed by water immersion chilling reduced mesophilic aerobic bacteria (MAB) populations by 2.07, 1.84, and 2.04 log CFU/g and Salmonella prevalence by 65, 65, and 73% at loose, intermediate and tight association levels, respectively. Hot water spraying and chilling reduced loosely associated Campylobacter prevalence by 45% but no reduction was observed at intermediate and tight association levels. Broiler carcasses suffered from an undesirable partially cooked appearance after the hot water spray treatment. In study 2, the left and right side skin (10 X 7 cm) of broiler carcasses were sampled by 10 swabings and 10 stomachings, and finally ground. Sixty five and 83 % of MAB populations on broiler skin could not be recovered after 10 consecutive stomachings and swabbings, respectively, but were recovered after grinding. The first stomaching or swabbing recovered most of the loosely associated bacteria but not tightly associated bacteria, which were recovered by grinding. In general, stomaching was more effective than swabbing for bacteria recovery from broiler skin. In study 3, microbial reductions and structural changes in broiler skin were evaluated after trisodium phosphate dip (TWD/TSP), hot water dip (TWD/HWD), and their combination (TSP/HWD) with (TSP/HWD/B)/without brushing. Microbial analysis, scanning electron microscopy and histological staining showed that TSP/HWD caused greater reduction in MAB, E. coli, total coliforms, and Salmonella with deeper penetration into the stratum compactum layer of the skin dermis than single application of TSP or hot water dip. TSP/HWD/B yielded lowest skin population of MAB whereas penetration into the dermis was similar to TSP/HWD but with sloughing off of part of stratum compactum in some areas. Both TSP/HWD and TSP/HWD/B changed skin color, with an increase in yellowness being the most prominent. In study 4, loose and tight associated GFP tagged Salmonella were quantified and imaged after refrigerated incubation of inoculated broiler skins for up to 48 h. GFP tagged Salmonella were not able to associate tightly with broiler skin during exposure for up to 48 h at 4oC as application of two stomachings (1 min each) removed almost 88% of the Salmonella cells from the inoculated skin. Confocal imaging of broiler skins, either dipped (2 min) or stomached (2 min) in inoculated buffer, revealed that Salmonellae were present on the surface and inside crevices at average depths of 10 and 68 μm, respectively, after dipping, with some cells pushed to average depths of 62 and 132 μm, respectively, after stomaching. Trapped water seemed to hold Salmonellae deep inside the crevices.
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Title: Crop microbiomes and the search for effective biocontrol of Fusarium graminearum on wheat
Creator: MacCready, Kristi Gdanetz
Date: 2018
Collection: Electronic Theses & Dissertations
Description: "Manipulation of naturally occurring microbial communities to reduce plant diseases or increase crop yields requires a thorough understanding of interactions within the phytobiome, in particular, how microbial communities change as plants age, across plant species and organs, and under different land management regimes. Plants were sampled from a wheat-maize-soybean crop rotation site that implements four different land management strategies (conventional, no-till, reduced inputs, and organic...
Show more"Manipulation of naturally occurring microbial communities to reduce plant diseases or increase crop yields requires a thorough understanding of interactions within the phytobiome, in particular, how microbial communities change as plants age, across plant species and organs, and under different land management regimes. Plants were sampled from a wheat-maize-soybean crop rotation site that implements four different land management strategies (conventional, no-till, reduced inputs, and organic). The fungal and bacterial communities of leaves, stems, and roots of wheat, maize, and soybean throughout the growing season were analyzed using fungal internal transcribed spacer and bacterial 16S rRNA gene amplicon sequencing. Analysis of sequence-based fungal communities has some limitations due to the unreliable phylogenetic resolution of DNA sequence alignments. To improve this deficiency, a tool that improved phylogenetic resolution was developed. This tool increases the number of operational taxonomic units which are identified at genus and species levels. Endophytes were isolated from the wheat plants used for microbial community analysis and tested for antagonistic activity toward the wheat pathogen Fusarium graminearum during wheat seedling and head infection. Endophytes on crops can be developed to manage disease, and endophyte-based biocontrols could solve current limitations in F. graminearum disease control. Additionally, functional analysis of F. graminearum secondary metabolite genes provides insight into the function of their gene products for this fungal pathogen. Microbial community structure is affected by various genetic factors of the host plant, environmental factors, and interactions with other organisms. Understanding community responses to these factors is necessary for targeted manipulation of communities to reduce plant disease."--Pages ii-iii.
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Title: DYNAMIC DESERTS : THE SYNERGISTIC EFFECTS OF FUNGI, SUNLIGHT, AND NON-RAINFALL MOISTURE ON PLANT LITTER DECOMPOSITION IN DRYLANDS
Creator: Logan V, James Robert
Date: 2021
Collection: Electronic Theses & Dissertations
Description: Drylands cover well over one third of the Earth’s land and are an important part of the global carbon cycle. Despite this, most models underestimate carbon turnover in arid and semi-arid systems, limiting our ability to predict how they will respond to changing climates. This is partly because many models are driven by rainfall, assuming little to no decay between precipitation events. Unlike in many wetter systems though, plant litter decomposition in drylands is largely controlled by non...
Show moreDrylands cover well over one third of the Earth’s land and are an important part of the global carbon cycle. Despite this, most models underestimate carbon turnover in arid and semi-arid systems, limiting our ability to predict how they will respond to changing climates. This is partly because many models are driven by rainfall, assuming little to no decay between precipitation events. Unlike in many wetter systems though, plant litter decomposition in drylands is largely controlled by non-rainfall processes including photodegradation and biotic decomposition supported by non-rainfall moisture (fog, dew, and water vapor; “NRM”). Despite their importance however, few studies have examined how these drivers interact with one another and with fungal communities to influence carbon turnover. In this dissertation, I demonstrate how photodegradation, NRM, and fungal decomposers interact to accelerate carbon turnover in drylands. To do this, I leveraged a natural gradient of NRM frequency in the Namib Desert that receives intense solar radiation. In one study, I used a reciprocal transplant design to show that moisture regime exerts a strong influence on litter-associated fungal communities and show that the relationship between NRM and litter decay rates depends on the composition of the decomposer community. In another study, I manipulated solar radiation for three years and found that photodegradation of the plant cuticle allows litter to absorb more water during NRM events, accelerating biotic decomposition. By examining litter-associated fungal communities under these same radiation treatments, I also show that fungi are largely insensitive to radiation stress and that photodegradation mainly affects decomposition rates in this system through photochemical changes in litter that increase subsequent biotic decomposition. Finally, to quantify the relationship between NRM and carbon turnover on multi-year timescales, I measured mass loss for 30 months along a moisture gradient spanning an order of magnitude of NRM frequency. By coupling these data with continuous meteorological measurements over the same period, I show that accounting for NRM and temperature sensitivity substantially improves the performance of a simple exponential litter decay model. These findings build on previous work demonstrating the importance of solar radiation and NRM as crucial drivers of litter decomposition and point a way forward for future studies to examine how these two processes may interact under future climate scenarios. Drylands are undergoing significant changes from anthropogenic climate change and understanding the drivers of litter decomposition allows us to better predict how these ecosystems are responding to global change.
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Title: ECOLOGICAL AND EVOLUTIONARY CONSEQUENCES OF EXOMETABOLTIES FOR MICROBIAL INTERACTIONS
Creator: Chodkowski, John Luke
Date: 2021
Collection: Electronic Theses & Dissertations
Description: Interspecies interactions have fundamental roles in shaping microbial communities. Microbial community members can produce and release a diverse set of extracellular small molecules, collectively referred to as exometabolites. Interspecies interactions that result from exometabolites can alter the response and behaviors of microbial community members. This dissertation work demonstrates the establishment of a synthetic community system that facilitates the study of exometabolite-mediated...
Show moreInterspecies interactions have fundamental roles in shaping microbial communities. Microbial community members can produce and release a diverse set of extracellular small molecules, collectively referred to as exometabolites. Interspecies interactions that result from exometabolites can alter the response and behaviors of microbial community members. This dissertation work demonstrates the establishment of a synthetic community system that facilitates the study of exometabolite-mediated interspecies interactions. This system was then used to understand the consequences of exometabolite-mediated interactions in a 3-member synthetic microbial community over stationary phase using a multi-omics approach. Lastly, an experimental evolution showed the consequences of long-term exometabolite interspecies interactions on the evolution of antibiotic resistance. This work advances knowledge on the dynamic response and behaviors of microbial community members’ during non-growth states. This work also demonstrates how bacterial-bacterial interactions in a simple environment can lead to the emergence of antibiotic resistance.
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Title: ENVIRONMENTAL DRIVERS AND EVOLUTIONARY CONSEQUENCES OF HORIZONTAL GENE TRANSFER IN SOIL BACTERIA
Creator: Kittredge, Heather
Date: 2021
Collection: Electronic Theses & Dissertations
Description: Horizontal gene transfer (HGT) is a driving force in bacterial evolution and could drive rapid adaptation in bacterial communities. Natural transformation is one mechanism of HGT that allows bacteria to pick up extracellular DNA (eDNA) from the environment and integrate it into their genome. But the rate of HGT in natural environments, and the role this process plays in facilitating rapid adaptation remains unknown. As climate change threatens the stability of environments worldwide,...
Show moreHorizontal gene transfer (HGT) is a driving force in bacterial evolution and could drive rapid adaptation in bacterial communities. Natural transformation is one mechanism of HGT that allows bacteria to pick up extracellular DNA (eDNA) from the environment and integrate it into their genome. But the rate of HGT in natural environments, and the role this process plays in facilitating rapid adaptation remains unknown. As climate change threatens the stability of environments worldwide, understanding how quickly bacteria can adapt to novel environments is essential. My dissertation research characterizes the environmental drivers and evolutionary consequences of natural transformation in a highly transformable model soil bacterium Pseudomonas stutzeri.Despite decades of research on understanding HGT at the molecular level, less is known about the ecological drivers of HGT. To understand the soil conditions relevant for transformation, I first measured eDNA in the field over a short-term drying rewetting disturbance (Ch. 2). I found that eDNA increased in response to the rewetting disturbance but quickly disappeared from soil, suggesting a small portion of this eDNA could be transformed by bacterial cells recovering from the disturbance. To test the efficiency of transformation under the conditions in which eDNA disappeared, I created a novel microcosm system for quantifying transformation in soil (Ch. 3). Here, I inoculated soil with live antibiotic-susceptible, and dead antibiotic-resistant P. stutzeri. I then tracked the evolution of antibiotic resistance over a range of soil conditions and eDNA concentrations. Transformation drove the evolution of antibiotic resistance across a wide range of soil moistures and increased in response to larger inputs of dead cells (eDNA source), with antibiotic resistance repeatedly appearing in antibiotic free soil. Despite the prevalence of transformation across bacterial species, the evolutionary origins and consequences of transformation are still largely unknown. Transformation presumably provides a fitness benefit in stressful or continuously changing environments, but few studies have quantified changes in transformation in response to adaptive evolution. Here, I evolved P. stutzeri at different salinities and tested how the growth rate and transformation efficiency changed in response to salt adaptation (Ch. 4). Overall, the growth rate increased in response to adaptation, but the transformation efficiency declined, with only ~50% of the evolved populations transforming eDNA at the end of experiment – as opposed to 100% of ancestral populations transforming eDNA. Overall, my dissertation research elucidates the factors driving transformation in soil, setting the stage for future experiments to scale up estimates of transformation to the whole community level. I find that transformation occurs under most soil conditions and allows genetic variants to arise at low frequencies in the absence of selection. I also report novel experimental evidence that transformation efficiency can change dramatically, and in a highly variable manner, over just ~330 generations. Taken together, this body of research highlights a role for transformation in many natural systems of ecological significance, and points to dead cells as an important but often overlooked source of genetic diversity.
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Title: EPIDEMIOLOGY OF ANTIBIOTIC RESISTANT SHIGA TOXIN-PRODUCING ESCHERICHIA COLI (STEC) AND NON-TYPHOIDAL SALMONELLA (NTS) IN MICHIGAN
Creator: Mukherjee, Sanjana
Date: 2018
Collection: Electronic Theses & Dissertations
Description: The enteric pathogens, Shiga toxin-producing E. coli (STEC) and non-typhoidal Salmonella (NTS), are leading causes of foodborne infections in the US, resulting in 265,000 and 1.2 million illnesses every year, respectively. The emergence of antibiotic resistance in these pathogens has been documented and is of great concern due to negative patient health outcomes and the possibility of transfer of resistance genes to other clinically relevant pathogens. However, there is a scarcity in...
Show moreThe enteric pathogens, Shiga toxin-producing E. coli (STEC) and non-typhoidal Salmonella (NTS), are leading causes of foodborne infections in the US, resulting in 265,000 and 1.2 million illnesses every year, respectively. The emergence of antibiotic resistance in these pathogens has been documented and is of great concern due to negative patient health outcomes and the possibility of transfer of resistance genes to other clinically relevant pathogens. However, there is a scarcity in information about frequencies of antibiotic resistant and factors associated with resistant STEC and NTS infections in Michigan. It is necessary to have a complete understanding about the of emerging antibiotic resistance and factors driving the rise of resistance in STEC and NTS to help develop effective control strategies. In this dissertation, 980 STEC isolates collected from patients in Michigan between 2001 and 2014 were examined for resistance to clinically relevant antibiotics. The examination of STEC strains for resistance, revealed high frequencies of resistance to ampicillin and trimethoprim-sulfamethoxazole, with significant increases in antibiotic resistance rates observed over this 14-year period. Multivariate logistic regression analysis identified non-O157 serotypes to be independently associated with antibiotic resistance. The recent increase in incidence of non-O157 serotypes observed in the US, coupled with the high frequencies of antibiotic resistance observed in this study, suggest the emergence of antibiotic resistant non-O157s as important human pathogens. Additionally, antibiotic resistant STEC isolates from patients in recent years (2010-2014) were more likely to cause hospitalizations than pansusceptible STEC isolates, suggesting that resistant STEC infections may result in adverse patient outcomes. Using whole genome sequencing, we also identified chromosomal mutations and 33 horizontally acquired genes present in the genomes of non-O157 STEC, likely conferring resistance. Importantly, by creating a co-occurrence network of these genes, we identified the co-occurrence of certain resistance genes, which are possibly present on the same mobile genetic element, thus resulting in multi-drug resistance. In addition to examining resistance in STEC, a total of 198 clinical NTS isolates collected between 2011 and 2014 were also examined for antibiotic resistance in this dissertation. Resistance to tetracycline, trimethoprim-sulfamethoxazole and ampicillin were commonly observed. Concerningly, high frequencies of multidrug resistant NTS were also observed with significant increases in their prevalence observed between 2011 and 2014. These high multidrug resistant rates have important implications on patient care as the efficacy of multiple antibiotics is reduced. Antibiotic resistant NTS isolates were also found to result in significantly longer mean hospital stays compared to pansusceptible NTS. Serovar specific differences in frequencies of antibiotic resistance were observed; S. Enteritidis were observed to have lower resistance frequencies than other serovars. Lastly, to better understand the role that cattle reservoirs play in harbouring antibiotic resistant STEC strains, we examined 121 STEC isolates collected in 2012 from six cattle farms in Michigan for antibiotic resistance. While high resistance frequencies to tetracycline and trimethoprim-sulfamethoxazole were observed in certain herds, no resistance to ampicillin was observed, unlike what was observed in STEC isolates collected from patients. While different populations of resistant STEC may be circulating in the clinical and agricultural environments, continuous monitoring of resistance in the cattle reservoir is warranted to determine if animal reservoirs can serve as potential sources of resistant infections in humans.
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Title: Ecology of calliphorid larval masses and postmortem colonization estimate variability
Creator: Weatherbee, Courtney R.
Date: 2016
Collection: Electronic Theses & Dissertations
Description: "The objectives of this work were to first, classify the insect and microbe interactions associated with carrion decomposition; and second, evaluate the variability in post-colonization interval (PCI) estimates among temperature sources and Calliphoridae species. Replicate (N = 6) swine carcasses were placed in a field and sampled regularly throughout decomposition. The ambient temperature at varying distances from the carcasses was recorded, and samples of larvae and their associated...
Show more"The objectives of this work were to first, classify the insect and microbe interactions associated with carrion decomposition; and second, evaluate the variability in post-colonization interval (PCI) estimates among temperature sources and Calliphoridae species. Replicate (N = 6) swine carcasses were placed in a field and sampled regularly throughout decomposition. The ambient temperature at varying distances from the carcasses was recorded, and samples of larvae and their associated microbiomes were collected. Microbial communities were characterized using 16s amplicon sequencing. I hypothesized that insect and microbial community composition would shift over time and that different microbial communities would become more similar to each other over time. Additionally, I predicted that different Calliphoridae species would produce different accumulated degree hour (ADH) ranges and the closest temperature data set to the carcass would result in a more accurate PCI estimate. Larval masses consisted of three Calliphoridae species (Cochliomyia macellaria, Lucilia coeruleiviridis, and Phormia regina) whose relative abundances shifted over time. Microbial communities of the carcass surface, maggot mass, and internal larvae also changed over time as well as among the different locations. The closest temperature source produced the greatest ADH range but the estimated PCI was most similar to ADH ranges generated from local and regional weather station data. These findings are relevant for both carrion ecology and the forensic sciences by contributing to the understanding of the effect of carrion within ecosystems as well as advancing a new direction of forensic microbiology and the quantification of variability in forensic entomology"--Page ii.
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Title: Effects of dietary fiber sources on the gastro-intestinal microbiota, fermentation metabolites, and listeria monocytogenes in vivo and in vitro
Creator: Walker, Ryan (Ryan Adam)
Date: 2019
Collection: Electronic Theses & Dissertations
Description: Dietary fiber consumption influences the gastro-intestinal microbiota, gastro-intestinal function, and health. This research investigated the effects of dietary fiber sources on bacterial composition, short-chain fatty acid (SCFA) production, gastro-intestinal barrier function, and Listeria monocytogenes challenge in mice and human colon cells. L. monocytogenes causes life-threatening illness in humans and animals. Some dietary fibers protect animals against illness in models of infection,...
Show moreDietary fiber consumption influences the gastro-intestinal microbiota, gastro-intestinal function, and health. This research investigated the effects of dietary fiber sources on bacterial composition, short-chain fatty acid (SCFA) production, gastro-intestinal barrier function, and Listeria monocytogenes challenge in mice and human colon cells. L. monocytogenes causes life-threatening illness in humans and animals. Some dietary fibers protect animals against illness in models of infection, while others enhance infection. Therefore, it is unclear if consuming certain dietary fiber sources confers protection against foodborne illnesses. The objectives of this research were: 1) describe how dietary fiber sources affect bacterial composition in vivo and in vitro; 2) quantify SCFAs produced by bacterial fermentation; 3) determine if fiber sources differentially affect L. monocytogenes infection in vivo; and 4) determine if bacterial metabolites promote or inhibit L. monocytogenes infection by affecting in vitro epithelial barrier function.In this project, dietary fiber sources differentially affected gastro-intestinal bacterial composition in vivo and in vitro, L. monocytogenes infection in mice, and enhanced barrier integrity in vitro. The overall results of this project demonstrate that dietary fiber sources differentially influence certain gastro-intestinal bacterial populations, measures of diversity, and that resulting compositional changes are important in the pathogenicity of L. monocytogenes. Additionally, fermentation end products enhance gastro-intestinal barrier function in this in vitro model, which may be an important factor in the prevention of enteric infection in humans. In summary, both the gastro-intestinal microbiota and its metabolites are important factors for maintaining gastro-intestinal health.
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Title: Environmental regulation of cyclic di-GMP turnover in vibrio cholerae
Creator: Koestler, Benjamin J.
Date: 2014
Collection: Electronic Theses & Dissertations
Description: 3', 5'-cyclic diguanylic acid (c-di-GMP) is an intracellular bacterial second messenger that mediates the transition between a sessile, biofilm forming lifestyle to a motile, virulent lifestyle. Diguanylate cyclase (DGC) enzymes synthesize c-di-GMP, whereas c-di-GMP specific phosphodiesterase (PDE) enzymes hydrolyze the second messenger. Although numerous bacterial behaviors are regulated by c-di-GMP, the regulatory inputs of this system remain mostly undefined. Here, I examine how the marine...
Show more3', 5'-cyclic diguanylic acid (c-di-GMP) is an intracellular bacterial second messenger that mediates the transition between a sessile, biofilm forming lifestyle to a motile, virulent lifestyle. Diguanylate cyclase (DGC) enzymes synthesize c-di-GMP, whereas c-di-GMP specific phosphodiesterase (PDE) enzymes hydrolyze the second messenger. Although numerous bacterial behaviors are regulated by c-di-GMP, the regulatory inputs of this system remain mostly undefined. Here, I examine how the marine bacterium and human pathogen Vibrio cholerae utilizes c-di-GMP signaling to interpret and respond to environmental cues. The central hypothesis that underpins my research is that V. cholerae senses environmental signals with DGCs and PDEs to modulate c-di-GMP concentrations in different environments. As c-di-GMP is a widely conserved second messenger utilized by many different bacteria, the mechanisms by which V. cholerae utilizes c-di-GMP in different environments can be applied to other bacterial systems to further comprehend how they behave in and adapt to various surroundings. To examine the influence of environmental factors on c-di-GMP synthesis and hydrolysis, I have developed a novel method named The Ex vivo Lysate c-di-GMP Assay (TELCA) that systematically measures total DGC and PDE cellular activity. I have shown that V. cholerae grown in different environments exhibits distinct intracellular levels of c-di-GMP, and using TELCA have determined that these differences correspond to changes in both c-di-GMP synthesis and hydrolysis. These findings highlight that modulation of both total DGC and PDE activity alters the intracellular concentration c-di-GMP.While searching for specific environmental cues that regulate c-di-GMP, I have found that bile acids, a prevalent constituent of the human proximal small intestine, increase intracellular c-di-GMP in V. cholerae. This bile-mediated increase in c-di-GMP is quenched by bicarbonate, the intestinal pH buffer secreted by intestinal epithelial cells. These findings lead me to propose that V. cholerae senses distinct microenvironments within the small intestine, using bile and bicarbonate as chemical cues, and responds by modulating intracellular c-di-GMP.In addition to its function as a bacterial second messenger, c-di-GMP has potent immunostimulatory properties in eukaryotes; these properties make c-di-GMP a prime candidate for use as a vaccine adjuvant. Here, I present a novel method of delivering c-di-GMP into eukaryotic cells using adenovirus. I have demonstrated that c-di-GMP can be synthesized in vivo by delivering DGC DNA into the cell, and that this c-di-GMP increases the secretion of numerous cytokines and chemokines. This novel adenovirus c-di-GMP delivery system offers a more efficient and cost-effective method to administer c-di-GMP as an adjuvant to stimulate innate immunity.
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Title: Establishment of novel Wolbachia symbiosis and characterization of sex determination genes in dengue mosquito vectors
Creator: Liang, Xiao
Date: 2020
Collection: Electronic Theses & Dissertations
Description: As one of the deadliest animals on earth, mosquitos transmit numerous diseases to humans, including dengue, Zika and malaria, which account for over one million human deaths every year. Due to insufficiency of traditional vector control strategies, significant efforts have recently been made to develop novel genetic approaches to either directly suppress mosquito populations or reduce mosquito’s ability to transmit pathogens to humans. One of them is based on the maternally transmitted...
Show moreAs one of the deadliest animals on earth, mosquitos transmit numerous diseases to humans, including dengue, Zika and malaria, which account for over one million human deaths every year. Due to insufficiency of traditional vector control strategies, significant efforts have recently been made to develop novel genetic approaches to either directly suppress mosquito populations or reduce mosquito’s ability to transmit pathogens to humans. One of them is based on the maternally transmitted intracellular symbiotic bacterium Wolbachia. Estimated to infect more than 60% of arthropods in nature, Wolbachia can spread through host populations by means of a reproduction-interfering referred to as cytoplasmic incompatibility (CI). By altering the host’s physiological environment, including immune priming or metabolic perturbation, Wolbachia can also confer antiviral resistance in mosquito vectors. Successful field trials have been conducted to release Wolbachia-infected mosquito males to induce incompatible matings for population suppression or spread Wolbachia into mosquito populations to reduce or block dengue transmission by population replacement. Both population suppression and replacement require for establishment of an artificial Wolbachia symbiosis in mosquito to make it incompatible with target populations. In order to develop a Wolbachia-based strategy for dengue/Zika control in Singapore and Mexico, I have established the transinfected line WB2. By comparing with another transinfected line WB1 which developed 15 years ago, I have demonstrated that wAlbB maintains a stable symbiosis with Ae. aegypti. Further assays show that Wolbachia induces strong resistance to dengue, Zika and Chikungunya viruses in WB2. WB2 line has now been released for field trials in both Mexico and Singapore. In order to improve Wolbachia-based mosquito control, transinfected mosquitoes must be optimized to display maximum pathogen blocking, the desired CI pattern, and the lowest possible fitness cost. Achieving such optimization, however, requires a better understanding of the interactions between the host and various Wolbabachia strains. Thus, we transferred the Wolbachia wMel strain into Ae. albopictus, resulting in a transinfected line, HM (wAlbAwAlbBwMel), no CI was induced when the triply infected males were crossed with the wild-type GUA females or with another triply infected HC females carrying wPip, wAlbA, and wAlbB, but removal of wAlbA from the HM line resulted in the expression of CI after crosses with lines infected by either one, two, or three strains of Wolbachia. These results show that introducing a novel strain of Wolbachia into a Wolbachia-infected host may result in complicated interactions between Wolbachia and the host and between the various Wolbachia strains, with competition likely to occur between strains in the same supergroup. In order to manage the potential risk of failure in population suppression in Singapore, I developed another Ae. aegypti carrying wMal. The transinfected line showed 100% maternal transmission. To facilitate developing a perfect sex separation approach for Wolbachia-based population suppression, I established the CRISPR/Cas9 approach to characterize the function of sex determination pathway genes in Ae. aegypti. By individually knocking out doublesex (dxl) and transformer-2 (tra-2), two essential genes in mosquito sex determination pathway, we show that dxl is not essential gene for female development while knockout of tra-2 results in male-biased sex ratio and absence of female mosquito with homozygous tra-2. These results indicate that the tra-2 is a potential sex determination target that can be explored to develop the female-specific lethality for mosquito sex separation.
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Title: Evaluation of a household contact disinfection device for inactivation of bacteriophage MS2 and murine norovirus
Creator: Leak, Emaly
Date: 2013
Collection: Electronic Theses & Dissertations
Description: Obtaining safe drinking water is problematic in many developing nations around the world. The HaloPure disinfection canister designed by HaloSource was created to provide household water treatment for middle-class families in India. The Waterbird device was tested for its effectiveness in reducing viruses. The main objective of this study was to determine the effectiveness of the Waterbird device in removing or inactivating bacteriophage MS2 and murine norovirus as surrogates for human...
Show moreObtaining safe drinking water is problematic in many developing nations around the world. The HaloPure disinfection canister designed by HaloSource was created to provide household water treatment for middle-class families in India. The Waterbird device was tested for its effectiveness in reducing viruses. The main objective of this study was to determine the effectiveness of the Waterbird device in removing or inactivating bacteriophage MS2 and murine norovirus as surrogates for human pathogens. Secondary objectives were to determine the potential impacts, if any, that added organic contaminants (in the form of raw sewage) and pH adjustment have on the effectiveness of the device. The Waterbird device was tested by adding MS2 and murine norovirus stock to five liters of well water (with or without sewage); the pH of the water was adjusted to 7.5 or 9 before treatment. The murine norovirus samples were all reduced to the detection limit, achieving a minimum of 2.0 to 4.0 log10 reductions after treatment, but the performance of the device could not be accurately examined using these results. For the MS2, the Waterbird device inactivated or removed an average of 5.4 log10. The MS2 log reduction was affected by pH (p=0.006) and sampling times (p<0.001). Overall, the Waterbird device met the U.S. EPA's guidelines for water purifiers (which requires at least 4 log10 removal of viruses).
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Title: Fate and detection of Bacillus anthracis spores in pasteurized milk, juice and eggs
Creator: Shah, Sandip H.
Date: 2009
Collection: Electronic Theses & Dissertations

Title: Genetic and chemical biology studies of Mycobacterium tuberculosis pH-driven adaptation
Creator: Dechow, Shelby J.
Date: 2021
Collection: Electronic Theses & Dissertations
Description: Mycobacterium tuberculosis (Mtb) endures robust immune responses by sensing and adapting to its host environment. One of the first cues the bacterium encounters during infection is acidic pH, a characteristic of its host niche – the macrophage. Targeting the ability of Mtb to sense and adapt to acidic pH has the potential to reduce survival of Mtb in macrophages. A high throughput screen of a >220,000 compound small molecule library was conducted to discover chemical probes that inhibit Mtb...
Show moreMycobacterium tuberculosis (Mtb) endures robust immune responses by sensing and adapting to its host environment. One of the first cues the bacterium encounters during infection is acidic pH, a characteristic of its host niche – the macrophage. Targeting the ability of Mtb to sense and adapt to acidic pH has the potential to reduce survival of Mtb in macrophages. A high throughput screen of a >220,000 compound small molecule library was conducted to discover chemical probes that inhibit Mtb growth at acidic pH. From this screen, AC2P20 was identified as a chemical probes that kills Mtb at pH 5.7 but is inactive at pH 7.0. Through a combination of transcriptional profiling, mass spectrometry, and free thiol abundance and redox assays, I show that AC2P20 likely functions by depleting intracellular thiol pools and dysregulating redox homeostasis. Findings from this study have helped define new pathways involved in Mtb’s response to acidic pH using a chemical genetic approach.Upon sensing acid stress, Mtb can adapt accordingly by entering a nonreplicating persistent state, resulting in increased tolerance to host immune pressures and antibiotics. During growth in vitro, when given glycerol as a sole carbon source, Mtb responds to acidic pH by arresting its growth and entering a metabolically active state of nonreplicating persistence, a physiology known as acid growth arrest. To answer how Mtb regulates and responds to acidic pH, I performed genetic selections to identify Mtb mutants defective in acid growth arrest. These selections identified enhanced acidic growth (eag) mutants which all mapped to the proline-proline-glutamate ppe51 gene and resulted in distinct amino acid substitutions: S211R, E215K, and A228D. I demonstrated that expression of the PPE51 variants in Mtb promotes significantly enhanced growth at acidic pH showing that the mutant alleles are sufficient to cause the dominant gain-of-function, eag phenotype. Furthermore, I performed single carbon source experiments and radiolabeling experiments showing that PPE51 variants preferentially uptake glycerol at an enhanced rate, suggesting a role in glycerol acquisition. Notably, the eag phenotype is deleterious for growth in macrophages, where the mutants have selectively faster replication but reduced virulence in activated macrophages as compared to resting macrophages. This supports that acid growth arrest is a genetically controlled, adaptive process that could act as a potential targetable physiology in future TB therapeutics. My work with the carbonic anhydrase inhibitor, ethoxzolamide, sought to combine genetic and chemical biology to better understand pH-adaptation in Mtb. Ethoxzolamide is a potent inhibitor of Mtb carbonic anhydrase activity and the PhoPR regulon, suggesting a previously unknown link between carbon dioxide and pH-sensing. We hypothesized that the production of protons from carbonic anhydrase activity could be modulating PhoPR signaling. Mtb has three carbonic anhydrases (CanA, CanB, and CanC), and by using CRISPRi and gene knockout, I show that CanB is required for pathogenesis in macrophages, but I did not observe a function in controlling PhoPR signaling. However, transcriptional profiling at different pH and CO2 concentrations show that PhoPR is induced by high CO2 and also revealed a core subset of CO2 responsive genes independent of PhoPR or acidic pH regulation. Overall, these studies defined new functions for thiol- and redox-homeostasis, glycerol uptake, and CO2-concentration in regulating Mtb adaptation to acidic environments and provide new targets for the development of acidic pH-dependent therapeutics.
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Title: Genetic diversity of clinical and bovine non-o157 shiga toxin-producing escherichia coli (stec
Creator: Blankenship, Heather Marie
Date: 2019
Collection: Electronic Theses & Dissertations
Description: Shiga toxin-producing Escherichia coli (STEC) is a leading cause of foodborne infection resulting in 265,000 illnesses and more than 3,600 hospitalizations annually. Since its identification in 1982 associated with an outbreak of haemorrhagic colitis, serotype O157:H7 has been the primary focus of research and surveillance. However, the increasing incidence of other serogroups, or non-O157 STEC, that are associated with clinical illness has since surpassed the incidence of O157 and has raised...
Show moreShiga toxin-producing Escherichia coli (STEC) is a leading cause of foodborne infection resulting in 265,000 illnesses and more than 3,600 hospitalizations annually. Since its identification in 1982 associated with an outbreak of haemorrhagic colitis, serotype O157:H7 has been the primary focus of research and surveillance. However, the increasing incidence of other serogroups, or non-O157 STEC, that are associated with clinical illness has since surpassed the incidence of O157 and has raised questions about the genetic diversity of this pathogen population. Six serogroups, O26, O45, O103, O111, O121, and O145, have been denoted as "big six" non-O157 STEC serogroups since they are frequently associated with clinical outcomes.In this dissertation, 895 non-O157 STEC isolates recovered from patients in Michigan between 2001-2018 were analyzed using whole genome sequencing (WGS) to identify virulence gene profiles and apply new typing methods to better discriminate closely related strains. The recovery of a wide range of serogroups from cases presenting with symptoms ranging from mild diarrhea to hemorrhagic colitis, indicates that genetic diversity and variation may have an impact on disease outcomes. The number and richness of serogroups identified over the past 18 years has been steadily increasing and serogroup alone lacks the discriminatory capabilities to classify related isolates. Indeed, strains representing the same sequence types (ST) were often found to be unrelated by serogroup. Notably, some serogroups, STs, virulence gene profiles and alleles were associated with clinical outcomes and patient demographics. Contrast to national surveillance, cases between 11 and 29 years of age had the highest frequency of STEC infections in Michigan.Additionally, a subset of 44 non-O157 STEC recovered from Michigan patients between 2000 and 2006 were examined more comprehensively while making comparisons to 114 clinical STEC isolates from Connecticut to examine the impact of geographic location on risk factors for non-O157 STEC infections. Lastly, a subset of STEC isolates associated with outbreaks in Michigan were examined to identify the impact of WGS on identification of strain relatedness for surveillance compared to pulsed-field gel electrophoresis.While most of the work outlined in this dissertation focused on characterizing clinical non-O157 STEC isolates, a comparative analysis of cattle isolates was also performed since cattle are an important reservoir of STEC. Indeed, numerous outbreaks and illnesses have been traced back to contaminated cattle-based food products or fecal contamination of water and crops. The ability of STEC to persist in the cattle reservoir and farm environment may give rise to more pathogenic strains due to the accumulation of horizontally acquired genes. 66 STEC isolates recovered from a beef herd over four samplings were examined to identify the genetic diversity within the cattle population and longitudinal persistence. The ability of a strain to form a strong biofilm was associated with the ability to persist and be recovered at multiple sampling phases from the same animal. Further, to better understand the genetic diversity of STEC recovered from the cattle reservoir, an additional 12 STEC isolates from three bovine herds (n = 78) and 241 clinical O157 STEC isolates (n = 1,135) were included to identify shared profiles. The similarity in serogroups and virulence gene profiles warrant a continued surveillance of the cattle environment to better understand crossover events and the ability of strains to evolve into new virulent STEC lineages. The work described in this dissertation helped to elucidate the genetic characteristics important for clinical outcomes and identified targets for future surveillance to better understand lineages that may be important for disease.
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