Michigan State University Agricultural Experiment Station In Cooperation With Michigan Potato Industry Commission Michigan Potato Research Report Volume 41 2009 Michigan Potato Industry Commission 13109 Schavey Rd., Ste. 7 DeWitt, MI 48820 517.669.8377 Fax 517.669.1121 www.mipotato.com email: info@mipotato.com April 20, 2010 To All Michigan Potato Growers & Shippers: The Michigan Potato Industry Commission, Michigan State University’s Agricultural Experiment Station and Cooperative Extension Service are pleased to provide you with a copy of the results from the 2009 potato research projects. This report includes research projects funded by the Michigan Potato Industry Commission, the USDA Special Grant and special allocations by the Commission. Additionally, the Commission expresses appreciation to suppliers of products for research purposes and special grants to the Commission and researchers. Providing research funding and direction to principal investigators at MSU is a function of the Michigan Potato Industry Commission’s Research Committee. Best wishes for a prosperous 2010 season. Pat DuRussel, Chairman Brian Sackett, Vice Chairman Duane Andersen Dennis Hanson Greg Iott Carl Kruger Mike Schena Randy Styma Tim Young Ex Officios: Don Koivisto, MDA Dr. Dave Douches, MSU Table of Contents Page Introduction and Acknowledgements 2009 Potato Breeding and Genetics Research Report David S. Douches, J. Coombs, K. Zarka, G. Steere, D. Berry, D. Zarka, K. Felcher and D. Kells 2009 Potato Variety Evaluations D.S. Douches, J. Coombs, K. Zarka, G. Steere, M. Zuehlke, D. Berry, C. Long, W. Kirk and J. Hao 2009 On-Farm Potato Variety Trials Chris Long, Dr. Dave Douches, Greg Steere, John Pullis (Presque Isle), Dr. Doo-Hong Min and Chris Kapp (Upper Peninsula) Tolerance of Potato Mini-tubers to PRE and POST Herbicide Applications Calvin F. Glaspie, Wesley J. Everman, Chris Long and Andrew J. Chomas Weed Control in Potato with Reflex Wesley J. Everman and Andrew J. Chomas Weed Control in Potato with Rimsulfuron Formulations Wesley J. Everman and Andrew J. Chomas Herbicide Effect on Growth Cracks in FL2053 Potato Wesley J. Everman, Chris Long and Andrew J. Chomas Tolerance of herbicides in Silverton Potatoes Wesley J. Everman and Andrew J. Chomas Herbicide Timing Effect on Weed Control in Potato Wesley J. Everman and Andrew J. Chomas Seed treatments and seed plus foliar treatments for control of seed- and soil-borne Rhizoctonia, 2008 W. W. Kirk, R. L Schafer and P. Tumbalam Long-Term Research: Simultaneous Management of Disease Suppression and Soil Quality in Potatoes A.S. Grandy 1 5 25 54 72 73 79 83 90 94 102 106 Potato Insect Biology and Management Adam M. Byrne, Walter L. Pett, Zsofia Szendrei and Edward J. Grafius Excretion of 14C-thiamethoxam in Michigan Colorado potato beetles David Mota-Sanchez and Mark E. Whalon Evaluation of fungicide programs for potato late blight control: 2008 W. W. Kirk, R. L Schafer and P. Tumbalam Effect of different genotypes of Phytophthora infestans (Mont. deBary) and temperature on tuber disease development W. Kirk, A. Rojas, P. Tumbalam, E. Gachango, P. Wharton, F. Abu-El Samen, D. Douches, J. Coombs, C. Thill, A. Thompson Evaluation and comparison of biofungicides and fungicides for the control of post harvest potato tuber diseases. E. Gachango, W. W. Kirk, P. S. Wharton, R. Schafer and P. Tumbalam Characterization of Streptomyces Species That Cause Potato Common Scab in Michigan Soil and Determination of Microbial Structure of Disease Suppressive Soil Jianjun (Jay) Hao 2008-2009 Corky Ring-Spot Disease of Potato Research Loren Wernette, George Bird, Willie Kirk, Karl Richie and John Davenport 2009 Michigan Metam Sodium Atmospheric Emission Study George Bird, Ben Kudwa, David Sullivan, Loren Wernette and Mark Otto Effect of 1,4-SIGHT® post-harvest potato dormancy treatment on sugars of stored chip stock in Michigan Chris Long and Greg Steere Vine Desiccation in Potato with Vida Wesley J. Everman and Andrew J. Chomas Vine Desiccation in Potato Wesley J. Everman, Chris Long, and Andrew J. Chomas 110 123 127 136 157 165 172 178 179 188 195 2009 MICHIGAN POTATO RESEARCH REPORT C. M. Long, Coordinator INTRODUCTION AND ACKNOWLEDGMENTS The 2009 Potato Research Report contains reports of the many potato research projects conducted by MSU potato researchers at several locations. The 2009 report is the 41st volume, which has been prepared annually since 1969. This volume includes research projects funded by the Potato Special Federal Grant, the Michigan Potato Industry Commission (MPIC), GREEEN and numerous other sources. The principal source of funding for each project has been noted at the beginning of each report. We wish to acknowledge the excellent cooperation of the Michigan potato industry and the MPIC for their continued support of the MSU potato research program. We also want to acknowledge the significant impact that the funds from the Potato Special Federal Grant have had on the scope and magnitude of potato related research in Michigan. Many other contributions to MSU potato research have been made in the form of fertilizers, pesticides, seed, supplies and monetary grants. We also recognize the tremendous cooperation of individual producers who participate in the numerous on-farm projects. It is this dedicated support and cooperation that makes for a productive research program for the betterment of the Michigan potato industry. We further acknowledge the professionalism of the MPIC Research Committee. The Michigan potato industry should be proud of the dedication of this committee and the keen interest they take in determining the needs and direction of Michigan's potato research. Special thanks go to Bruce Sackett for the management of the MSU Montcalm Research Farm (MRF) and the many details which are a part of its operation. We also want to recognize Barb Smith and Esther Haviland at MPIC for helping with the details of this final draft. WEATHER The overall 6-month average maximum temperature during the 2009 growing season was two degrees lower than the 6-month average maximum temperature for the 2008 season and was one degree lower than the 15-year average (Table 1). There were three recorded temperature readings of 90 °F or above in 2009. This high temperature event was recorded during a period of time from June 23rd to June 25th, prior to tuber bulking. There were no recorded daytime temperatures above 90 °F or night time temperatures above 70 °F in the month of August. There were two days in May that the air temperature was below 32 °F. These occurred on May 11th and 18th. The average maximum temperatures for July and August, 2009 were six and three degrees below the 15-year average, respectively (Table 1). In October 2009, there were 15 days with measureable rainfall and eight daytime highs below 50 °F. Six of these eight days fell on days with no recorded rainfall leaving only 10 days in October that had no rain and temperatures above 50 °F. Rainfall for April through September was 16.82 inches, which was 2.4 inches below the 15-year average. (Table 2). Rainfall recorded during the month of August was the highest recorded for that month since the year 2002. In October 2009, 3.79 inches of rain were recorded. Irrigation at MRF was applied 7 times from June 24th to August 6th, averaging 0.83 inches for each application. The total amount of irrigation water applied during this time period was 5.8 inches. 1 Table 1. The 15-year summary of average maximum and minimum temperatures (°F) during the growing season at the Montcalm Research Farm. April May June July August September 6-Month Average Year Max. Min. Max. Min. Max. Min. Max. Min. Max. Min. Max. Min. Max. Min. 51 1995 50 1996 48 1997 1998 52 51 1999 50 2000 2001 53 51 2002 49 2003 49 2004 2005 51 51 2006 50 2007 2008 49 49 2009 82 80 73 81 76 79 72 81 82 76 81 80 80 80 76 31 31 31 37 37 34 37 36 33 37 36 36 33 37 34 66 64 59 75 71 70 70 63 64 67 65 61 73 67 67 45 44 39 51 48 49 49 42 44 46 41 46 47 40 45 51 50 54 60 59 56 61 56 56 62 62 62 53 61 56 70 70 69 76 73 70 69 77 72 78 77 68 76 73 74 60 55 57 58 62 56 58 62 58 57 58 61 56 58 53 45 51 50 52 48 49 48 52 48 49 51 48 50 50 49 81 75 79 77 77 75 78 79 77 74 82 78 82 77 76 57 57 56 56 55 57 57 58 52 54 60 54 54 56 54 82 76 80 82 84 77 83 85 81 79 82 83 81 80 75 72 69 69 75 73 71 72 73 72 73 75 72 74 73 71 65 59 55 60 56 57 70 58 58 53 58 58 58 54 56 15-Year Average 57 35 67 45 78 56 81 58 79 58 73 49 72 50 The 15-year summary of precipitation (inches per month) recorded during the growing season at the Montcalm Research Farm. Table 2. Year 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 15-Year Average April 3.65 2.46 2.02 2.40 5.49 3.18 3.28 2.88 0.70 1.79 0.69 2.73 2.64 1.59 3.94 2.63 May 1.87 3.99 3.13 2.21 5.07 6.46 6.74 4.16 3.44 8.18 1.39 4.45 1.60 1.69 2.15 3.77 June 2.30 6.28 3.54 1.82 5.82 4.50 2.90 3.28 1.85 3.13 3.57 2.18 1.58 2.95 2.43 3.21 July 5.25 3.39 2.80 0.40 4.29 3.79 2.49 3.62 2.60 1.72 3.65 5.55 2.43 3.07 2.07 3.14 August September 4.59 3.69 2.71 2.22 5.46 5.28 5.71 7.12 2.60 1.99 1.85 2.25 2.34 3.03 4.74 1.38 2.96 1.46 3.05 4.03 5.25 4.43 1.59 2.06 0.32 3.90 3.15 1.18 5.03 1.49 Total 19.04 22.77 15.66 12.10 30.16 28.46 25.55 22.65 13.25 17.13 15.05 20.31 11.77 17.36 16.82 3.71 2.75 19.21 2 GROWING DEGREE DAYS Tables 3 and 4 summarize the cumulative growing degree days (GDD) for 2009. Growing degree days base 50 for May through September, 2009 are in (Table 3) and growing degree days base 40 for May through October, 2009 are in (Table 4). The total GDD base 50 for 2009 was 1963 (Table 3), which is lower than the 10-year average. The total GDD base 40 for 2009 was 3620 (Table 4). Table 3. Growing Degree Days* - Base 50°F. Cumulative Monthly Totals Year 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 10-Year Average May 313 317 319 330 245 195 283 358 205 247 281 June 780 808 903 762 662 826 765 926 700 700 783 July 1301 1441 1646 1302 1200 1449 1444 1494 1298 1133 1371 August September 1851 2079 2214 1922 1639 2035 2016 2084 1816 1622 2256 2379 2613 2256 2060 2458 2271 2495 2152 1963 1928 2290 Table 4. Growing Degree Days* - Base 40°F. Year 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 10-Year Average May 532 639 447 519 Cumulative Monthly Totals June 1310 1503 1240 1264 July 2298 2379 2147 2004 August September October 3923 3180 4443 3277 2973 3834 3620 2800 3707 3966 3596 3420 534 1329 2207 3058 3672 3955 *2000-2009 data from the weather station at MSU Montcalm Research Farm (Michigan Automated Weather Network System Entrican, MI.) 3 PREVIOUS CROPS, SOIL TESTS AND FERTILIZERS The general potato research area utilized in 2009 was rented from Steve Comden, directly to the West of the Montcalm Research Farm. This acreage was planted to a field corn crop in the spring of 2008 and harvested fall 2008 with crop residue disked into the soil. In the spring of 2009, the recommended rate of potash was applied and disked into the remaining corn residue. The ground was deep chiseled, disked and direct planted to potatoes. The area was not fumigated prior to potato planting. Early potato vine senescence was an issue in 2009. It is not clear if the early vine death was the result of the potato early die complex. The soil test analysis for the general crop area was as follows: lbs/A P2O5 K2O Ca Mg 274 (137 ppm) 214 (107 ppm) 720 (360 ppm) 118 (59 ppm) The fertilizers used in the general plot area are as follows. (Variances in fertilizers used for specific research projects are included in the individual project reports.) Application Broadcast at plow down At planting At cultivation At hilling Late side dress (late varieties) Analysis Rate Nutrients (N-P205-K20) 0-0-60 19-17-0 10-34-0 28-0-0 46-0-0 46-0-0 395 lbs/A 20 gpa 12 gpa 22 gpa 135 lbs/A 100 lbs/A 0-0-237 42-37-0 13-45-0 68-0-0 62-0-0 46-0-0 pH 6.1 Magnesium and Sulfur were applied July 17 in the form of Magnesium Sulfate (with an analysis of 9.8% Mg and 12.9% S) for a total application of 20 lb/A. The composite nutrient value resulted in 1 lbs actual Mg and 1.3 lbs of S being applied per acre on the potato production area. HERBICIDES AND PEST CONTROL Hilling was done in late May, followed by a pre-emergence application of Linex at 1.5 qts/A and Dual at 1.33 pints/A. A post-emergence application of Sencor at 1/3 lb/A and Matrix at 1 oz/A was made in mid-July. Platinum was applied at planting at a rate of 8 fl oz/A. Fungicides used were; Bravo, Tanos, Previcur, Revos Top, Champ, Echo, Manzate and Super Tin, over 11 applications. Potato vines were desiccated with Reglone in mid-August at a rate of 1.5 pints/A. 4 David S. Douches, J. Coombs, K. Zarka, G. Steere, D. Berry, D. Zarka, K. Felcher and D. Kells Department of Crop and Soil Sciences Michigan State University East Lansing, MI 48824 2009 POTATO BREEDING AND GENETICS RESEARCH REPORT Cooperators: Ray Hammerschmidt, Willie Kirk, Jay Hao, Zsofia Szendrei and Chris Long At Michigan State University, we are dedicated to developing improved potato INTRODUCTION varieties for the chip-processing and tablestock markets. The program is one of four integrated breeding programs in the North Central region supported through the Potato Special Grant. At MSU, we conduct a multi-disciplinary program for potato breeding and variety development that integrates traditional and biotechnological approaches. In Michigan, it requires that we primarily develop high yielding round white potatoes with excellent chip-processing from the field and/or storage. In addition, there is a need for table varieties (russet, red, yellow, and round white). We conduct variety trials of advanced selections and field experiments at MSU research locations (Montcalm Research Farm, Lake City Experiment Station, Muck Soils Research Farm, and MSU Soils Farm), we ship seed to other states and Canadian provinces for variety trials, and we cooperate with Chris Long on grower trials throughout Michigan. Through conventional crosses in the greenhouse, we develop new genetic combinations in the breeding program, and also screen and identify exotic germplasm that will enhance the varietal breeding efforts. With each cycle of crossing and selection we are seeing directed improvement towards improved varieties (e.g. combining chip-processing, scab resistance, and late blight resistance). In addition, our program has been utilizing genetic engineering as a tool to introduce new genes to improve varieties and advanced germplasm for traits such as solids, insect resistance, disease resistance and nutritional enhancement. We feel that these in-house capacities (both conventional and biotechnological) put us in a unique position to respond to and focus on the most promising directions for variety development and effectively integrate the breeding of improved chip-processing and tablestock potatoes. The addition of the SolCAP translational genomics project, funded through the USDA, will enhance our abilities to identify important traits and then breed them into elite germplasm. potato industry. Traits of importance include yield potential, disease resistance (scab, late blight, early die, and PVY), insect (Colorado potato beetle) resistance, chipping (out-of-the- field, storage, and extended cold storage) and cooking quality, bruise resistance, storability, along with shape, internal quality, and appearance. We are also developing potato tuber moth resistant lines as a component of our international research project. If these goals can be met, we will be able to reduce the grower’s reliance on chemical inputs such as The breeding goals at MSU are based upon current and future needs of the Michigan 5 insecticides, fungicides and sprout inhibitors, and improve overall agronomic performance with new potato varieties. Over the years, key infrastructure changes have been established for the breeding program to make sound assessments of the breeding selections moving through the program. These include the establishment and expansion of the scab nursery, the development of the Muck Soils Research Farm for late blight testing (now moving to Clarksville), the incorporation of no-choice caged studies for Colorado potato beetle assessment, the Michigan Potato Industry Commission (MPIC)-funded construction of the B.F. (Burt) Cargill Demonstration Storage adjacent to the Montcalm Research Farm, new land at the Lake City Experiment Station along with a well for irrigation and expanded land at the Montcalm Research Farm and Lake City Experiment Station, the new plot harvester and the development of the grading line at the MSU campus facility. Each year, during the winter months, 500-1000 crosses are made using about 150 of PROCEDURE I. Varietal Development the most promising cultivars and advanced breeding lines. The parents are chosen on the basis of yield potential, tuber shape and appearance, chip quality, specific gravity, disease and insect resistance, adaptation, maturity, lack of internal and external defects, etc. The seeds collected from these crosses are then used as the breeding base for the program. We also obtain seedling tubers or crosses from other breeding programs in the US to include other germplasm with desirable traits. The seedlings are grown annually for visual evaluation (size, shape, set, internal defects) at the Montcalm and Lake City Research Farms as part of the first year selection process of this germplasm each fall. Each selection is then evaluated post harvest for specific gravity and chip processing. These selections each represent a potential variety. This system of generating new seedlings is the initial step in an 8-12 year process to develop new varieties. This step is followed by evaluation and selection at the 8-hill, 20-hill and 30-hill stages. The best selections out of the four-year process are then advanced for testing in replicated trials (Preliminary, Adaptation, Advanced, Grower-cooperator trials, North Central Regional Trials, USPB/Snack Food Association Trials, and other out-of-state trials) over time and locations. The agronomic evaluation of the advanced breeding lines in the replicated trials is in the annual Potato Variety Evaluation Report. There is a need to find a russet table potato that will be profitable and produce quality russets for the eastern market. Currently, the three most desirable potatoes for production and type in Michigan are GoldRush, Russet Norkotah and Silverton Russet. The latter two potatoes suffer as symptomless carriers of PVY. Norkotah also has a weak vine and susceptibility to potato early die. We need a PVY resistant or PVY expressing Silverton Russet potato. We are continuing to make more russet crosses and selections in the breeding program to support this new russet market. Evaluation of Advanced Selections for Extended Storage we are positioned to evaluate advanced selections from the breeding program for chip- processing over the whole extended storage season (October-June). Tuber samples of our With the Demonstration Storage facility adjacent to the Montcalm Research Farm, 6 To supplement the genetic base of the varietal breeding program, we have a elite chip-processing selections are placed in the demonstration storage facility in October and are sampled monthly to determine their ability to chip-process from colder (42-48°F) and/or 50°F storage. In addition, Chris Long evaluates the more advanced selections in the 10 cwt. box bins and manages the 500 cwt. storage bins which may have MSU-developed lines. II. Germplasm Enhancement "diploid" (2x = 24 chromosomes) breeding program in an effort to simplify the genetic system in potato (which normally has 4x = 48 chromosomes) and exploit more efficient selection of desirable traits. This added approach to breeding represents a large source of valuable germplasm, which can broaden the genetic base of the cultivated potato. The diploid breeding program germplasm base at MSU is a synthesis of seven species: S. tuberosum (adaptation, tuber appearance), S. raphanifolium (cold chipping), S. phureja (cold-chipping, specific gravity, PVY resistance, self-compatability), S. tarijense and S. berthaultii (tuber appearance, insect resistance, late blight resistance, verticillium wilt resistance), S. microdontum (late blight resistance) and S. chacoense (specific gravity, low sugars, dormancy and leptine-based insect resistance). In general, diploid breeding utilizes haploids (half the chromosomes) from potato varieties, and diploid wild and cultivated tuber-bearing relatives of the potato. Even though these potatoes have only half the chromosomes of the varieties in the U.S., we can cross these potatoes to transfer the desirable genes by conventional crossing methods via 2n pollen. III. Integration of Genetic Engineering with Potato Breeding Through transgenic approaches we have the opportunity to introduce new genes into our cultivated germplasm that otherwise would not be exploited. It has been used in potato as a tool to improve commercially acceptable cultivars for specific traits. Our laboratory has now 16 years experience in Agrobacterium-mediated transformation to introduce genes into important potato cultivars and advanced breeding lines. We are presently using genes in vector constructs that confer resistance to Colorado potato beetle and potato tuber moth (Bt- cry3A and Bt-cry1Ia1), late blight resistance via the RB gene (from the wild potato species S. bulbocastanum), drought resistance (CBF1), PVY, and late blight resistance from S. microdontum. Furthermore, we are investing our efforts in developing new vector constructs that use alternative selectable markers and give us the freedom to operate from an intellectual property rights perspective. In addition, we are exploring transformation techniques that eliminate the need for a selectable marker (antibiotic resistance) from the production of transgenic plants. RESULTS AND DISCUSSION I. Varietal Development Breeding germplasm and advanced seedlings that are improved for cold chipping, and resistance to scab, late blight, and Colorado potato beetle. For the 2009 field season, progeny from over 550 crosses were planted and evaluated. Of those, the majority were crosses to select for round whites (chip-processing and tablestock), with the remainder to select for yellow flesh, The MSU potato breeding and genetics program is actively producing new 7 Over 70% of the single hill selections have a chip-processing parent in their long/russet types, red-skin, and novelty market classes During the 2009 harvest, over 1,500 selections were made from the 50,000 seedlings produced. All potential chip-processing selections will be tested in January and April 2010 directly out of 45°F (7.2°C) and 50°F (10°C) storages. Atlantic, Pike (50°F chipper) and Snowden (45°F chipper) are chip- processed as check cultivars. Selections have been identified at each stage of the selection cycle that have desirable agronomic characteristics and chip-processing potential. At the 8- hill and 20-hill evaluation state, about 175 and 40 selections were made, respectively. Selection in the early generation stages has been enhanced by the incorporation of the Colorado potato beetle, scab and late blight evaluations of the early generation material. Chip-Processing pedigree. Based upon the pedigrees of the parents we have identified for breeding cold- chipping potato varieties, there is a diverse genetic base. We have at least eight cultivated sources of cold-chipping. Examination of pedigrees shows up to three different cold-chipping germplasm sources have been combined in these selections. Our promising chip-processing lines are MSJ147-1, MSH228-6 (moderate scab resistance), MSJ126-9Y (scab resistant), MSL007-B (scab resistance), MSK409-1 (scab resistant), MSN191-2Y, MSL292-A, MSR061-1 (scab and PVY resistant) and MSQ070-1 (scab and late blight resistant). Other new promising lines include MSP270-1 (scab resistant), MSP459-5 (scab and moderate late blight resistant), MSP516-A (scab and late blight resistant), MSN170-A (scab resistant) MSR036-5 (scab and late blight resistant), MSR102-3 (scab and late blight resistant), MSR127-2 (scab resistant) and MSQ279-1 (scab resistant). Tablestock good cooking quality, high marketable yield and resistance to scab, late blight and PVY. Our current tablestock development goals now are to continue to improve the frequency of scab resistant lines, incorporate resistance to late blight along with marketable maturity and excellent tuber quality, and select more russet and yellow-fleshed lines. We have also been spinning off some pigmented skin and tuber flesh lines that may fit some specialty markets. From our breeding efforts we have identified mostly round white lines, but we also have a number of yellow-fleshed and red-skinned lines, as well as some purple skin selections that carry many of the characteristics mentioned above. We are also selecting for a dual-purpose russet, round white, red-skin, and improved Yukon Gold-type yellow-fleshed potatoes. Some of the tablestock lines were tested in on-farm trials in 2009, while others were tested under replicated conditions at the Montcalm Research Farm. Promising tablestock lines include MSM182-1 and MSL268-D and MSQ176-5. We have a number of tablestock selections with late blight resistance (MSQ176-5, MSM182-1, and MSL268-D). MSL211-3 has late blight and moderate scab resistance with a bright skin. We are using these russets as parents in the breeding program to combine the late blight and scab resistance. Some newer lines with promise include the high yielding round white line MSQ279-1 (scab resistant), MSQ440-2 (scab resistant) and MSN230-6RY (scab and late blight resistant). MSM288-2Y is a bright yellow flesh selection similar in type to Yukon Gold. MSS544-1R is a new scab resistant red skinned table potato. Some new pigmented lines are MSS576-05SPL (red Efforts have been made to identify lines with good appearance, low internal defects, 8 splash) and Michigan Red and Purple Splash. MSQ558-2RR and MSR226-1RR are red fleshed chippers and MSQ432-2PP is a purple-fleshed chipper. Early harvest breeding material screen In 2009, we initiated an early harvest observation trial of our breeding lines to learn about the potential to replace Atlantic as an early harvest variety. We harvested the plots at 92 days and observed the yield, tuber size and tuber shape/ appearance. In addition, we measured specific gravity and made chips out of the field. From this trial of 176 lines, we were able to identify some promising early breeding lines for the out-of-the-field chipping and tablestock use. Table 1 (next page) summarizes these results. Some of these lines are also characterized to have some scab resistance and late blight resistance along with the desirable chipping traits. We will continue to test many of these lines and other selections in 2010. We also identified some desirable early tablestock lines among this material tested. The shaded cells in the table indicate the higher yielding plots and lines with higher specific gravity. 9 Table 1 Early Observation Trial: Most promising chip-processing lines EARLY OBSERVATIONAL TRIAL 2009 Montcalm Research Farm May 15 to August 14, 2009 (92 days) Weight (lbs) Chip Trial Pedigree Male S440 Scab Female - - B1254-1 - PENTA SP GR OTF 1.0! 1.082 1.077 1.0 1.0 1.080 1.0 1.083 1.077 1.0 1.0 1.078 1.0 1.072 1.092 1.0 1.0! 1.092 1.0 1.092 1.5 1.072 1.082 1.0 1.0! 1.075 1.0 1.070 1.079 1.0 1.0 1.078 1.5 1.084 1.0 1.084 1.093 1.0 1.0 1.082 1.5 1.077 1.082 1.0 1.0 1.083 1.0 1.081 1.0 1.076 1.074 1.0 1.0 1.075 1.0 1.083 1.092 1.0 Total 6.5 Beacon Chipper 15.9 FL1879 7.8 Kalkaska 12.2 Snowden 7.6 MSH228-6 10.2 MSJ126-9Y 15.2 MSM037-3 10.5 MSM060-3 6.2 MSN148-A 8.7 MSN190-2 12.5 MSP515-2 9.3 MSQ070-1 12.4 MSQ086-3 13.2 MSQ279-1 15.2 MSR058-1 7.5 MSR061-1 9.0 MSR127-2 6.2 MSR159-02 9.1 MSS026-2Y 15.3 MSS165-2Y 15.2 MSS176-1 12.3 MSS934-4 9.4 MST033-2 10.3 MST094-1 8.9 MST096-2Y 14.8 MST412-3 9.6 MST429-3Y 12.8 MST443-1 11.4 MST443-2Y Single rep observational 10 ft plots. CHIP SCORE: Snack Food Association Scale (Out of the field); Ratings: 1-5; 1: Excellent, 5: Poor. SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. 2 4 1 3 1 MSC127-3 OP OP 1 1 MSE230-6 ND2676-10 1 MSG007-1 ND2676-10 1 MSH095-4 MSJ143-4 1 MSI234-6Y MSG227-2 Missaukee 1 1 MSK061-4 Missaukee Missaukee Onaway 1 Pike Boulder 1 1 W1201 MSJ319-1 1 W1201 NY121 1 MSJ167-1 MSG227-2 1 MSL766-1 MSJ126-9Y MSJ126-9Y 2 1 MSM188-1 MSL159-AY 1 ND7377Cb-1 1 MSL211-3 1 1 MSG227-2 MSH228-6 1 MSG227-2 MSJ126-9Y 1 MSN105-1 MSM051-3 Missaukee 1 2 MSM070-1 OP 2 MSM070-1 OP ND5822C-7 MSL211-3 ND6095-1 Atlantic NY126 NY112 SJ-Y7 10 Disease and Insect Resistance Breeding Scab: Disease screening for scab has been an on-going process since 1988. Results from the 2009 MSU scab nursery indicate that 69 of 156 lines evaluated had a scab rating of 1.5 or less (better than or equivalent to Pike). The limitation of breeding for scab resistance is the reliance on the scab nursery. In addition to the replicated trial, we have been conducting early generation selection for scab resistance among our breeding material. In 2009, 128 of 327 early generation selections showed strong scab resistance (rating of 1.0 or better). These data were incorporated into the early generation selection evaluation process at Lake City. We are seeing that this expanded effort is leading to more scab resistant lines advancing through the breeding program. We hope that the nutrient film technology (NFT) hydroponic tuberization system will help us more reliably screen for scab resistance. The NFT study is supported through Project GREEEN. In 2009 we conducted an inoculated scab trial at the scab nursery at MSU. We planted seed pieces into peat pots filled with scab infested vermiculite. Alternately, the vermiculite was spread in the furrow prior to planting rather than in the peat pot. The four varieties tested were Pike, Atlantic, Snowden and FL1879. The first planting was in mid- May and the second planting was two weeks later. At harvest the tubers were laid on the ground and plot and tuber scab ratings were taken. Table 2 below summarizes the results from the scab ratings that were collected. We learned in this first year that the peat pot inoculation treatments led to greater levels of scab infection on the tubers and did differentiate resistant from susceptible varieties. We will continue to conduct scab inoculation experiments in 2010 to improve our ability to screen for scab resistance in the breeding program. Table 2. Streptomyces Inoculated Scab Trial Main Effects Means for Scab Rating (0-5: 0 = No scab; 5 = Severe pitted scab). Combined Rating c bc b a a 1.93 2.20 2.43 2.87 2.97 0.41 2.44 2.81 2.82 1.72 0.38 b ab a c Source Scab Treatment Main Effects: 1 Non-tx control 2 In-furrow-1X 3 In-furrow-2X 4 Cup-1X 5 Cup-2X LSD0.05 Variety Main Effects: Atlantic Private Chipper Check Snowden Pike LSD0.05 First Rating 1.81 2.13 2.13 2.60 2.47 NA 2.20 2.53 2.53 1.65 0.54 a a a b Second Rating d cd bc ab a 2.07 2.29 2.79 3.13 3.67 0.58 a a a b 2.68 3.11 3.10 1.83 0.53 11 Late Blight: No late blight research was completed because of June flooding of the research plots. All field trials from the breeding program were lost. Colorado potato beetle: With support from GREEEN, we conducted our Colorado potato beetle screen at the Montcalm Research Farm. In 2009, 16 of 40 breeding lines were at least moderately resistant to Colorado potato beetle at the Montcalm Research Farm Beetle Nursery. The beetle pressure was extremely high leading to complete defoliation in all susceptible check lines. Percent defoliation was visually estimated during the beetle infestation in June and July. This resistant material was selected for further advancement in the breeding program and also for use in the next round of crossing to develop beetle resistant cultivars. Some of these lines are beginning to enter the preliminary trials in the breeding program and are being used as parents for further breeding. It is a great challenge to achieve host plant resistance to insects in a commercially acceptable line. We have some promising advanced selections with partial resistance to Colorado potato beetle. In addition, we have Bt-cry3A transgenic lines that could be commercialized if the processors renewed their acceptance and regulatory environment was modified to reduce costs. Russet Table Varieties for Michigan The dynamics of the potato industry in Michigan have been changing in the recent years. A reason for this change is Michigan’s position to major markets in the central and eastern US. With rising fuel costs, Michigan growers can capture table market share with a freight advantage over western potatoes. Key to capturing this market is having russet varieties that suit Michigan’s climate and soils and also serves the consumers taste and quality needs. Current russet varieties may not provide the quality and production levels to compete profitably in these markets. The three most desirable potatoes for production and type in Michigan are Russet Norkotah, GoldRush and Silverton Russet. Two of these potatoes suffer as symptomless carriers of PVY. Russet Norkotah also has a weak vine and susceptibility to potato early die. We need a PVY resistant or PVY expressing Silverton Russet potato. GoldRush has proven not to perform well in Michigan’s southern tier of counties. New russet varieties with adaptability to Michigan could lead to greater market penetration and further diversify the markets for the Michigan potato industry. The breeding strategy is to make selected crosses that have a high probability of selecting Norkotah types. We grew out large progenies to further increase the probability of finding desirable selections. We will use Silverton, Russet Norkotah, MSE192-8RUS, A95109-1RUS, etc. as parents. Single hill selections were made in 2009. These will be further evaluated and a new set of crosses will be evaluated in 2010 at Lake City. 12 Sugar Profile Analysis of Early Generation Selections for Extended Storage: Chip- processing Results From the MPIC Demonstration Commercial Storage (October 2008 - June 2009) The MSU Potato Breeding Program has been conducting chip-processing evaluations each year on potato lines from the MSU breeding program and from other states. For 10 years we have been conducting a long-term storage study to evaluate advanced breeding lines with chip-processing potential in the Dr. B. F. (Burt) Cargill Potato Demonstration Storage facility directly adjacent to the MSU Montcalm Research Farm to identify extended storage chippers. We evaluated advanced selections from the MSU breeding program for chip-processing over the whole extended storage season (October-June). Tuber samples of our elite chip-processing selections were placed in the demonstration storage facility in October and were sampled 9 times to determine their ability to chip-process from storage. In October 2008, tuber samples from 14 MSU lines from the Montcalm Research Farm and Lake City Experiment Station trials were placed in the bins. The first samples were chip-processed in October and then 8 more times until June 2009. Samples were evaluated for chip-processing color and defects. Table 3 summarizes the chip-processing color and scab rating of 14 lines and four check varieties (Atlantic, FL1879, Pike and Snowden) over the 7-month storage season. From November to April all lines chip- processed acceptably. The lines that chip processed exceptionally well were Beacon Chipper, MSH228-6, MSJ126-9Y, MSJ147-1, MSL292-A, MSM037-3, MSM246-B and MSQ279-1. These lines are highlighted in the table. We are continuing to advance these lines except MSM246-B and MSM037-3 because of scab susceptibility and low specific gravity issues, respectively. Early generation sugar profiling was also conducted on a series of MSU advanced breeding lines. These glucose and sucrose sugar profiles are presented in Figures 1-4. The results confirm the good storage potential of MSJ126-9Y, MSH228-6 and MSL292- A. MSJ147-1 has stored longer in previous years, but in the past storage seasons the MSJ147-1 tubers physiologically aged sooner than previous years. Of the newer advanced breeding lines tested MSQ070-1 and MSR061-1 showed promising sugar profiles. Both lines exhibit scab resistance. The other two lines, MSN148-A and MSQ089-1 were discontinued because of their susceptibility to scab. We also undertook a study to measure acrylamide levels in potato chips of nine potato lines along with Snowden. The chip samples were sent to the University of Wisconsin for analysis. The acrylamide data (ppb) was correlated with the glucose, sucrose and defect data collected by Techmark. Figures 5a, b and c summarize the results. We learned that acyrlamide levels ranged from 650 ppb to over 1700 ppb when the chip color was acceptable. There was no correlation between glucose level, sucrose level and defect levels in the tubers with acrylamide levels in the chip samples. For example the potato chip acrylamide level ranged from 650 ppb -1700 ppb for tuber glucose readings of 0.002% or less. We are conducting follow up studies in 2009-10. 13 Table 3. 2008-2009 Demonstration Storage Chip Results of Elite MSU Breeding Lines SFA Chip Score Rating Scale 1-5 2/2009 3/2009 4/2009 5/2009 ScabMR LBR ScabR LINE Atlantic Beacon Chipper FL1879 Kalkaska (MSJ036-A) ScabR MSH228-6 ScabR MSJ147-1 MSJ461-1 MSK061-4 MSL292-A MSM037-3 MSM246-B MSN170-A MSN191-2Y MSP459-5 MSQ279-1 MSR036-5 Pike Snowden ScabR ScabMR ScabR-LBR ScabR ScabR-LBR ScabR 2009 Scab 10/2008 11/2008 12/2008 1/2009 2.7 1.3 2.0 1.3 1.3 1.7 2.1 1.4 2.3 1.3 2.8 1.0 2.8 1.8 1.4 1.3 1.5 2.3 1.5 1.0! 1.0 1.5 1.0 1.0 1.0 1.0 1.0! 1.0 1.0 1.0 1.0! 1.0 1.0 1.5 1.0 1.0 1.5 1.0 1.0 1.0 1.0 1.0! 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0! 1.0 2.0 1.0 1.5 1.5 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.5 1.0 1.0 1.5 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.5 2.0 1.0 1.0 1.5 1.0 1.5 1.5 1.0 1.0! 1.5 1.0 1.0! 1.0 1.0! 1.0! 1.0 1.0! 1.0 1.5 1.0 1.0 1.0 1.0 1.0 1.5 1.0 1.0 1.5 1.0! 1.0! 1.0 1.0 1.0! 1.0! 1.0! 1.0 2.0 1.0 1.0 1.5 1.0 1.0 3.0 1.0 1.0 1.5 1.0 1.0 1.0 1.0 3.0 1.0 1.0 1.0 2.0 1.5 2.0 3.0 1.5 1.5 3.5 1.0 1.0 2.5 1.0 1.0 1.0 1.0 3.0 1.0 1.5 2.0 2.5 2.5 3.0 6/2009 3.5 1.5 2.0 4.0 1.0 1.5 2.0 2.5 1.5 1.0 1.0 3.5 2.0 2.0 1.5 3.0 2.5 3.0 14 ) % (   e s o c u G l ) 0 1 x % (   e s o r c u S Early Generation Sugar Profiling 2008‐2009 for Glucose 0.140 0.120 0.100 0.080 0.060 0.040 0.020 0.000 10/20/2008 11/20/2008 12/20/2008 1/20/2009 2/20/2009 3/20/2009 4/20/2009 5/20/2009 Date Early Generation Sugar Profiling 2008‐2009 for Sucrose 6.2 5.2 4.2 3.2 2.2 1.2 0.2 10/20/2008 11/20/2008 12/20/2008 1/20/2009 2/20/2009 3/20/2009 4/20/2009 5/20/2009 Date MSN148‐A MSQ070‐1 MSQ089‐1 MSR061‐1 Snowden MSN148‐A MSQ070‐1 MSQ089‐1 MSR061‐1 Snowden 15 Elite Breeding Line Sugar Profiling 2008‐2009 for Glucose 0.18 0.16 0.14 0.12 0.1 0.08 0.06 0.04 0.02 0 10/20/2008 11/20/2008 12/20/2008 1/20/2009 2/20/2009 3/20/2009 4/20/2009 5/20/2009 Date Elite Breeding Line Sugar Profiling 2008‐2009 for Sucrose 5.2 4.2 3.2 2.2 1.2 ) % (   e s o c u G l ) 0 1 x % (   e s o r c u S MSH228‐6 MSJ126‐9Y MSJ147‐1 MSL292‐A Snowden MSH228‐6 MSJ126‐9Y MSJ147‐1 MSL292‐A Snowden 0.2 10/20/2008 11/20/2008 12/20/2008 1/20/2009 2/20/2009 3/20/2009 4/20/2009 5/20/2009 Date   16 Acrylamide Chip Samples, Glucose and Acrylamide Correlation y = 2E‐06x + 0.0021 R² = 0.0054   ) % (   e s o c u G l 0.030 0.025 0.020 0.015 0.010 0.005 0.000 600 800 1000 1200 1400 1600 1800 Acrylamide (ug/kg) Acrylamide Chip Samples, Sucrose and Acrylamide Correlation y = 0.0003x + 0.5299 R² = 0.0229 600 800 1000 1200 1400 1600 1800 Acrylamide (ug/kg) Acrylamide Chip Samples, Total Defects and Acrylamide Correlation y = ‐0.0027x + 15.842 R² = 0.0018 600 800 1000 1200 1400 1600 1800 Acrylamide (ug/kg)   ) 0 1 x % (   e s o r c u S 2.500 2.000 1.500 1.000 0.500 0.000   ) % (   s t c e f e D   l a t o T 60.0 50.0 40.0 30.0 20.0 10.0 0.0 17 We released MSJ036-A as Kalkaska (scab resistant and verticllium wilt tolerant Variety Release round white) in 2008 and MSJ461-1 as Missaukee (late blight, golden nematode and verticillium wilt resistant round white) in 2009. We are continuing to promote the seed production and testing of Beacon Chipper, a 2005 release. In addition, we are also continuing to promote Michigan Purple, Jacqueline Lee for the tablestock specialty markets. Boulder is being commercially grown in Quebec. Lastly, commercial seed of MSH228-6, MSJ147-1, and MSJ126-9Y are being produced and we will continue to seek commercial testing of these lines. MSQ070-1 is also being fast-tracked for the chip-processing market. It has both scab and late blight resistance. We also have a focused ribavirin-based virus eradication system to generate virus-free tissue culture lines for the industry. We are initiating mini-tuber increase of three scab-resistant chippers: MSL007-B, MSR061-1 and MSP270-1. We are also increasing MSL292-A, a long-term storage chipper. About 30 lines are in ribaviran treatment at this time to remove PVS and PVY. This year, about 60 new MSU breeding lines are being put into tissue culture. MSU Variety Releases: ________________________________________________________________________ Kalkaska (MSJ036-A) Parentage: B1254-1 X S440 Developers: Michigan State University and the Michigan Agricultural Experiment Station. Plant Variety Protection: submitted Strengths: MSJ036-A is a high yielding, round white potato with an attractive round appearance with shallow eyes.MSJ036-A has a strong vine and a full season maturity. This variety has resistance to Streptomyces scabies (common scab) stronger than Pike. MSJ036-A also has chip-processing storage characteristics and better tolerance to blackspot bruise than Snowden. Weaknesses: Sugar levels have to be watched at harvest during cold temperatures. Incentives for production: High yield and good tuber type combined with scab resistance. ________________________________________________________________________ 18 Missaukee (MSJ461-1) Parentage: Tollocan X NY88 Developers: Michigan State University and the Michigan Agricultural Experiment Station, Michigan Potato Industry Commission Plant Variety Protection: Plant Variety Protection is being considered for this variety. Strengths: MSJ461-1 is a round white chip- processing variety with an attractive round shape and bright skin. The primary strength of this variety is its strong foliar resistance to late blight (Phytophthora infestans) combined with chip-processing quality. MSJ461-1 can also be marketed as tablestock because of its good culinary quality. The tubers will chip process out-of-the-field and from 10°C (50°F) storage. MSJ461-1 performed well in Michigan on-farm trials and regional testing. Under irrigated conditions, the yield is similar to Snowden. MSJ461-1 is being considered for release, although no name has yet been chosen for this line. Weaknesses: The specific gravity of MSJ461-1 is lower than Snowden in Michigan. Incentives for production: High yield with uniform tuber size combined with strong foliar resistance to late blight, GN resistance and tolerance to verticillium wilt. Can be used for both chip-processing and table use. ________________________________________________________________________ MSJ147-1 Parentage: NorValley X S440 Developers: Michigan State University and the Michigan Agricultural Experiment Station Plant Variety Protection: Will be considered. Strengths: MSJ147-1 is a round white chip- processing potato that has a bright skin, white flesh and round shape. In addition, it has been determined to store at temperatures below 50°F and maintain low reducing sugar levels into May or June. Weaknesses: Small vine, slow to emerge. Incentives for production: MSJ147-1 produces many A-size tubers that are low in defects, however we are seeing some HH in the large tubers this storage season. Potatoes maintain low reducing sugar content for chip-processing out of the field and from storage. ________________________________________________________________________ 19 MSJ126-9Y Parentage: Penta x OP Developers: Michigan State University and the Michigan Agricultural Experiment Station Plant Variety Protection: To Be Applied For. Strengths: MSJ126-9Y is a chip-processing potato with an attractive round appearance with shallow eyes. MSJ126-9Y has a medium vine and an early to mid-season maturity. This variety has resistance to Streptomyces scabies (common scab) stronger than Pike. MSJ126-9Y also has excellent chip-processing long-term storage characteristics and better tolerance to blackspot bruise than Snowden. Incentives for production: Excellent chip-processing quality with long-term storage characteristics, common scab resistance superior to Pike, and good tuber type. ________________________________________________________________________ MSQ176-5 Parentage: MSI152-A x Missaukee (MSJ461-1) Developers: Michigan State University and the Michigan Agricultural Experiment Station Plant Variety Protection: To Be Applied For. Strengths: MSQ176-5 is a high-yielding freshmarket potato with bright skin and a uniform smooth, round appearance with an attractive tuber type. This variety has a strong vine and a mid-season maturity. MSQ176-5 has strong foliar resistance to the US8 genotype of late blight. MSQ176-5 also has resistance to Streptomyces scabies (common scab) similar to Pike. Incentives for production: Excellent freshmarket tuber quality and type with foliar late blight resistance and common scab resistance. ________________________________________________________________________ 20 II. Germplasm Enhancement In 2009 we developed genetic mapping populations (both at diploid and tetraploid levels) for late blight resistance, beetle resistance, scab resistance and also for tuber quality traits. We will start to characterize these populations in 2010. The diploid genetic material represent material from South American potato species and other countries around the world that are potential sources of resistance to Colorado potato beetle, late blight, potato early die, and ability to cold-chip process. We have used lines with Verticillium wilt resistance, PVY resistance, and cold chip-processing. We are monitoring the introgression of this germplasm through marker assisted selection. Through GREEEN funding, we were able to continue a breeding effort to introgress leptine-based insect resistance using new material selected from USDA/ARS material developed in Wisconsin. We will continue conducting extensive field screening for resistance to Colorado potato beetle at the Montcalm Research Farm and in cages at the Michigan State University Horticulture Farm. We made crosses with late blight resistant diploid lines derived from Solanum microdontum to our tetraploid lines. We have conducted lab-based detached leaf bioassays and have identified resistant lines. These lines are being used crosses to further transmit resistance. III. Integration of Genetic Engineering with Potato Breeding Commercialization of Potato Tuberworm Resistant Potatoes in South Africa The potato tuberworm (Phthorimaea operculella Zeller) is a primary pest problem facing potato farmers in developing countries. Currently, the primary means to control the potato tuberworm and avoid major crop losses is the use of chemical pesticides. Michigan State University (MSU), funded by the U.S. Agency for International Development (USAID), initiated biotechnology research on the development of potato tuberworm resistant varieties in 1992. A Bacillus thuringiensis (Bt)-cry1Ia1 gene, was successfully introduced into several potato varieties and shown to be highly resistant to potato tuberworm in the Spunta-G2 line (both tuber and foliage). This Bt potato will be one of the first public sector developed products to reach farmers in developing countries and will serve as a model for the public sector deployment of insect resistant transgenic crops. The commercialization project includes six components: Product Development, Regulatory File Development, Obtaining Freedom to Operate and Establishing Licensing Relationships, Marketing and Technology Delivery, Documentation of Socio-Economic Benefits, and Public Communication. This technology would also have benefits in controlling PTM in the US and reducing the need for insectcide-based protection. In 2007, we focused on collecting the regulatory data that has to be submitted to the review agency. In 2008, we submitted the regulatory file to the South African authorities. In late 2009 the South African government denied the approval on non-scientific reasons. We are appealing, but the political realities probably will not change the final outcome. Regardless of the outcome, our team at MSU is well positioned to commercialize future GM potato varieties. 21 Potato Translation Initiation Factor 4E (eIF4E) over-expression to obtain resistance to PVY in susceptible potato varieties USDA/ARS funded project: USDA PI: Jonathan Whitworth, USDA-ARS, Aberdeen, Idaho. Jonathan.Whitworth@ars.usda.gov 208-397-4181 x112 Cooperator: David Douches, Dept. Crop and Soil Sciences, Michigan State University Summary of the Problem Douchesd@msu.edu 517-355-0271 x 1194 Numerous potato viruses are prevalent worldwide and can cause substantial economic losses. In the US four potato viruses PVY, PVX, PLRV and PVS are most frequently identified, but PVY and its various associated strains is the most common and economically most harmful (Valkonen 2007). These potato viruses are transmitted to the next seed generation through tubers. The use of disease-free tissue culture stocks in combination with state seed certification programs has historically been a source of clean seed to the commercial farmers, but in recent years, the level of PVY in potato certified seed lots has reached problem levels (Whitworth et al. 2005). The extensive spread of various strains of PVY have become very common in seed production due to the amount of PVY symptom-less expression varieties being grown combined with the high numbers of non-persistent PVY vectoring aphids present in potato growing regions. It is difficult to produce seed clean of PVY when the inoculum is so widely distributed throughout seed production regions. The variety, Russet Norkotah and its line selections, make it the second most common variety in the US (NASS 2007). This variety along with Shepody and Silverton Russet are described as being symptom-less carriers of PVY. One solution to this problem is to replace these varieties with new and improved ones. Ideally these varieties would have extreme resistance to all PVY strains, but some advanced breeding lines such as A95109-1 that show great promise still have the weakness of PVY susceptibility. Resistance to PVY common and necrotic (NTN, N:O) strains is critical as the necrotic strains are present in the industry and can cause tuber defects. Michigan State University and other breeding programs are currently using the Ry gene to introduce extreme resistance to PVY into advanced breeding germplasm through conventional breeding combined with marker-assisted selection techniques (Gebhardt et al. 2006). It will take a significant number of years to identify, release and commercialize a new variety that will compete with the market impact of Russet Norkotah. The conventional breeding strategy must be employed; however current technology exists to introduce PVY resistance directly into Russet Norkotah and other PVY susceptible varieties using pathogen-derived resistance (e.g. viral coat protein). NatureMark had released in the late 1990s transgenic lines of Russet Burbank that were resistant to PVY (Kaniewski and Thomas, 2003). It is well known that these and other transgenic potato lines were removed from the market in 2001 when the quick serve restaurant industry was attacked by the anti-biotech activists through media tactics to create concern among the public regarding the food and environmental safety of these potatoes (Simon 2003). 22 Transgenic technology has continued to advance since the 1990s and Simplot scientists have recently developed a new method to introduce native genes into potato without any additional genes or DNA sequences (Rommens et al., 2004). With this technology they can create transgenic potato lines that contain only potato genes rather than genes obtained from other organisms. The public perception of this technology is much more accepting of this transformation technique that employs only the crop’s genes rather than genes from other organisms such are viruses, bacteria, etc. (K. Swords pers. comm.). Research Objectives and Research Plan The new transgenic approach can be applied to the PVY problem in the potato industry. Our overall objective is to conduct studies that will lead to transgenic Russet Norkotah, Silverton Russet, and A95109-1 lines that have PVY resistance conferred by a native resistance gene from potato. Through gene mapping studies Valkonen’s group was able to map the extreme resistance to PVY to Chr. 11 (Hamalainen et al. 1997). A genetic marker has been identified that co-segregates with the extreme resistance to PVY (Ryadg) (Kasai et al. 2000). Valkonen’s group has also made an effort to clone this PVY resistance gene (a LRR-NBS R-gene), but the over- expressed gene they cloned did not confer resistance and they theorized that another non- cloned R-gene in the hotspot on Chr. 11 may be the actual R-gene that confers resistance. In pepper a PVY resistance gene maps to Chr. 3 and provides natural resistance to PVY that is different than the R-gene resistance on Chr. 11. Ruffel et al. (2005) was able to demonstrate that the pot-1 gene in tomato (Solanum lycoperisicum) is an orthologue to the pvr2 gene in pepper. In transient expression assays, they were able to show that the eIF4E gene (referred to as pot-1) accounted for the resistance to PVY in tomato. Using a comparative genomics approach, we have been able to clone the translation initiation factor 4E (eIF4E) gene from potato that may be the orthologue to the recessive PVY resistance conferred by the pvr2 locus in pepper (Capsicum annum). Our eIF4E gene, cloned from potato using the tomato pot-1 primers has an identical sequence length and a 96% sequence homology match to the tomato orthologue that confers PVY resistance in tomato. We hypothesize that the eIF4E gene we cloned is the orthologue of the pot-1 and pvr2 PVY resistance genes in tomato and pepper, respectively. Progress Report (since October 2009) One of the objectives of this research is to test the tomato pot-1 (eIF4E) gene as a source of PVY resistance in potato. RT-PCR and cDNA amplification using gene specific primers allowed amplification of a tomato gene from L. hirsutum accession PI247087. The sequence of the cloned gene was identical to the Genbank sequence identified as pot-1(AY723736). This sequence was subsequently cloned into the Agrobacterium binary vector pSPUD4 which contains a Cauliflower mosaic virus 35S promoter (CaMV 35S) which should express the pot-1 gene constitutively in plants. A previously cloned potato gene with over 96% sequence identity to the tomato pot-1 gene but lacking the signature amino acid changes in key regions known to be associated with 23 PVY resistance in pepper and tomato was sub-cloned into a pSPUD4 binary vector as well and will be used in transformations as a control. Transformation experiments were done using the PVY susceptible line MSE149-5Y. Over twenty independently generated transgenic plants have been isolated and are in culture. Insertion of either the tomato sequence or the potato control sequence was confirmed in each of the transgenic plants by PCR. Because of conservation of sequence between the different eIF4E sequences, primers for this PCR were designed to span the junction between the 35S promoter and the tomato or potato eIF4E sequences thus; these primers will not amplify in non-transgenic plants. A preliminary PVY test was attempted in the greenhouse using this first generation of the transgenic lines. Inconsistent responses in the control plants were observed. These plants are now being grown in preparation for revised PVY resistance tests. Transformation experiments were also conducted with Silverton Russet and Classic Russet. The regeneration ability of these lines is much lower that MSE149-5Y and modifications in the regeneration protocol will be made. In a second experiment to allele mine the potato eIF4E gene for sequence homology to pot-1 and pvr2, DNA sequences from 27 total accessions of four species of potato (S. chacoense, S. microdontum, S. phureja, S. tuberosum subsp. andigena) exhibiting different levels of PVY resistance were examined for natural variation in amino acid sequences. Due to introns separating the key signature regions, RT-PCR was used to create and clone cDNA fragments so that DNA sequencing through all four key regions could be accomplished in a single pass. At least three to five independent cDNA clones from 2 different eIF4E genes (i.e. eIF4E1 and eIF4E2) were sequenced for each variety. None of the sequences contained changes identical to the tomato resistance gene. In fact, most of the sequences in the signature regions contained amino acid residues identical to those of a PVY susceptible tomato variety or were conservative changes not expected to affect resistance function. In a follow-up experiment to help identify the mechanisms of resistance for these 27 accessions, a PCR experiment was performed to determine if resistance was associated with a known extreme resistance gene linked to markers M45 (Rysto) and SCAR-RYSC3 (Ryadg). Preliminary PCR results were negative for these markers. However control samples were inconsistent and additional experiments will be needed to confirm the results. 24 D.S. Douches, J. Coombs, K. Zarka, G. Steere, M. Zuehlke, D. Berry, C. Long, W. Kirk, and J. Hao Departments of Crop and Soil Sciences and Plant Pathology Michigan State University East Lansing, MI 48824 2009 POTATO VARIETY EVALUATIONS Funding: Fed. Grant/MPIC Each year, the MSU potato breeding and genetics team conducts a series of INTRODUCTION variety trials to assess advanced potato selections from the Michigan State University and other potato breeding programs at the Montcalm Research Farm (Entrican). In 2009, we tested 220 varieties and breeding lines in the replicated variety trials. The variety evaluation also includes disease testing in the scab nursery (MSU Soils Farm, E. Lansing) and foliar and tuber late blight evaluation (Muck Soils Research Farm, Bath). The objectives of the evaluations are to identify superior varieties for fresh or processing markets. The varieties were compared in groups according to market class, tuber type, skin color, and to the advancement in selection. Each season, total and marketable yields, specific gravity, tuber appearance, incidence of external and internal defects, chip color (from the field, 45°F (7.2°C) and 50°F (10°C) storage), as well as susceptibilities to common scab, late blight (foliar and tuber), and blackspot bruising are determined. PROCEDURE Entrican, MI. They were planted as randomized complete block designs with two to four replications. The plots were 23 feet (7 m) long and spacing between plants was 10 inches (25.4 cm). Inter-row spacing was 34 inches (86.4 cm). Supplemental irrigation was applied as needed. The field experiments were conducted on a sandy loam soil that was in corn the previous year and in potatoes 4 years previously. The most advanced selections in the breeding program were harvested at two dates to evaluate early and late harvest potential (Early Harvest Trial). These same clones also harvested at a later standard harvest date, included in the various other variety trials. The Date of Harvest Early and Late Trials were replaced by the Early Trial entries being included in other trials for the second (Late) harvest. The most advanced selections were tested in the Advanced trial, representing selections at a stage after the Adaptation Trial. The other field trials were the North Central, Russet, Adaptation (chip-processors and tablestock), and Preliminary (chip-processors and tablestock). Note: We also conducted an early harvest observation trial (92 days), to screen newer lines from the Nine field experiments were conducted at the Montcalm Research Farm in 25 breeding program for early performance potential as out of the field chip-processing and tablestock varieties. The early observational trial is discussed in the breeding report. In each of these trials, the yield was graded into four size classes, incidence of Early Trial: external and internal defects in >3.25 in. (8.25 cm) diameter (or 10 oz. (283.5 g) for Russet types) potatoes were recorded. Samples were taken for specific gravity, chipping, disease tests and bruising tests. Chip quality was assessed on 25-tuber composite sample from four replications, taking two slices from each tuber. Chips were fried at 365°F (185°C). The chip color was measured visually with the SFA 1-5 color chart. Tuber samples were also stored at 45°F (7.2°C) and 50°F (10°C) for chip-processing out of storage in January and March. Advanced selections are also placed in the MPIC B.F. Burt Cargill Commercial Demonstration Storage in Entrican, MI for monthly sampling. The scab nursery at the MSU Soils Farm and the late blight trial at the Muck Soils Research Farm are used for scab and foliar late blight assessment of lines in the agronomic trials. Maturity ratings (1 early - 5 late) were taken for all variety trial plots in late August to differentiate early and late maturing lines. The simulated blackspot bruise results for average spots per tuber have also been included in the summary sheets this year. RESULTS A. Chip-processors and Tablestock (Table 1: Early Harvest) are summarized in Table 1. Atlantic, Onaway and FL1867 were used as check varieties. The plot yields were average to slightly below average in the early harvest (102 days), and specific gravity values were typical to an average year. Hollow heart was the most prevalent internal defect in the early harvest this year, although only to a limited degree. MSQ176-5 and MSM037-3 showed the highest incidence of hollow heart in the late harvest (30% and 28%, respectively). Interestingly, the hollow heart standard Atlantic, had less incidence of hollow heart (3%) compared to average years. In the early harvest trial, the best yielding lines were Onaway, Michigan Purple Red Sport, MSQ086-3, MSL211-3, MSM037-3, and MSQ176-5. Michigan Purple Red Sport is a red-skinned selection with splashes of purple from a sport of Michigan Purple. MSQ086-3 is a round- white breeding line which chip-processes out of the field, is showing early bulking potential, and has strong foliar late blight resistance. MSL211-3 is an attractive, smooth- skinned, round to oval tablestock line with foliar late blight resistance. MSQ176-5 is a round-white freshmarket potato with good yield, round, uniform tuber shape, strong foliar late blight resistance, and moderate scab resistance. There were 18 entries that were evaluated at the early harvest trial. The results 26 B. A summary of the 25 entries evaluated in the Advanced trial results is given in Table 2. Overall, the yields for the Advanced trial (135 days) were average or slightly below average. The check varieties for this trial were Snowden, Pike, FL1879, and FL2137. The highest yielding lines were tightly clustered (and not significantly different) between MSP515-2 (316 cwt/a), Kalkaska, FL1879, MSQ089-1, and Beacon Chipper (265 cwt/a). The next highest yielding group was MSQ070-1, followed by MSR036-5, MSK061-4, and MSH228-6. Hollow heart and vascular discoloration were the predominant internal defects, with Kalkaska, MSR159-02, and FL2137 having the highest levels of hollow heart (30, 30, and 23%, respectively). Specific gravity was average with five lines having specific gravities higher than Snowden (1.086): MSQ070-1 (1.097), MSN191-2Y, MSJ147-1, FL2137, and MSK409-1 (1.087). All entries in the trial had excellent chip- processing quality out of the field, with an SFA score of 1.0. Most of the MSU breeding lines have moderate to strong scab resistance. Kalkaska and Beacon Chipper continue to be consistently high yielding lines with good specific gravity, chip quality, and scab resistance. Two promising chip-processing lines are MSQ070-1 (chip quality, high specific gravity, scab and late blight resistance) and MSR061-1 (chip quality, good specific gravity, scab and PVY resistance, and moderate late blight resistance). Variety and Advanced Breeding Line Characteristics moderate scab tolerance along with excellent chip-processing quality. Yield performance in the USPB/SFA trials was also high. type and has performed well in on-farm trials. Kalkaska (MSJ036-A) – an MSU chip-processing selection with high yield potential. It also has a high specific gravity and scab resistance. The tuber type of MSJ036-A is round and attractive. and long-term storage potential. This line also has scab resistance and an attractive type. MSJ147-1 – a full season storage chipper that also has some early sizing. It has excellent chip-processing quality and a high solids content. It has performed well in on- farm trials and has demonstrated an excellent long-term storage chipping profile. MSH228-6 – a chip-processing line with moderate scab resistance. It has a good MSJ126-9Y – an earlier season chip-processing line with excellent chip quality Beacon Chipper – a chip processing line that has high yield potential and Advanced Trial (Table 2) Missaukee (MSJ461-1) – an MSU chip-processing selection with strong foliar resistance to late blight and maturity similar to Snowden. It has excellent chip-processing quality, round shape and above average yield, but an intermediate specific gravity in most years. The chips show few defects. It has good tablestock quality too. 27 MSK061-4 – an attractive round-white chip-processing line with good scab resistance. This line produces clean chips with good specific gravity and average yield, with low blackspot bruising, but has a short dormancy. earlier maturing line has average yield and slightly lower specific gravity. MSK409-1 – a round-white chip-processing line with good scab resistance. This MSL007-B – an MSU chip-processing selection with strong scab resistance, uniform round type, and a unique netted skin. This newer line produces excellent chips with a good specific gravity and average yield. resistance, moderate scab resistance, and an early maturity. MSL211-3 – an attractive round-white tablestock line with strong foliar late blight MSL268-D – is also a round-to-slightly oval white tablestock line with moderate scab resistance, strong foliar late resistance, and PVY resistance. This line has an average yield with mid-early maturity. strong foliar late blight resistance. This line also has an moderately early maturity with a ‘Superior’ type tuber appearance. MSM171-A – a round-white tablestock line with moderate scab resistance and MSM246-B – a round-white chip-processing line with good specific gravity and MSN170-A – a new round-white chip-processing line with good scab resistance, MSN105-1 – an attractive round-white tablestock line with moderate foliar late excellent chip quality that has demonstrated potential for good long-term chip quality. blight resistance, moderate scab resistance, and an early maturity. average specific gravity, and good type. This line produces clean chips with good specific gravity and an early maturity, and has storage potential. This newer line produces excellent chips with a high specific gravity and low incidence of internal defects. MSN191-2Y – an MSU chip-processing selection with a very uniform round type. MSP459-5 – another new MSU chip-processing selection with scab resistance, Two varieties were released in 2009: Kalkaska and Missaukee. The breeding line average specific gravity, and a good, round type. This line has excellent chip quality with a low incidence of internal defects and storage potential. MSJ036-A was released as ‘Kalkaska.’ We have submitted the PVP application to the USDA and the variety release description to the American Journal of Potato Research. Kalkaska is a high yielding, round white potato with an attractive round appearance with shallow eyes. Kalkaska has a strong vine and a full season maturity. This variety has resistance to Streptomyces scabies Thaxter (common scab of potato) similar to Pike. 28 MSJ461-1 was released as ‘Missaukee.’ Missaukee is a round white chip Kalkaska also has industry approved chip-processing storage characteristics (light color and low incidence of defects) and it also has better tolerance to blackspot bruise than Snowden. Specific gravity in Michigan averages 1.083, ranging from 1.075 to 1.096. Kalkaska also has a higher marketable yield than Pike and does not express heat necrosis in the tubers. The name Kalkaska was chosen to acknowledge a town located in the Michigan seed growing region. processing potato variety resulting from a cross between Tollocan and NY88 and has foliar resistance to potato late blight (Phytophthora infestans de Bary). This variety has an attractive round shape and mildly netted, bright skin. Seven years of field testing in Michigan indicate that the yield of total marketable tubers in Missaukee is similar to that of Snowden. However, Missaukee has a lower incidence of internal defects than Snowden. Specific gravity ranged from 1.069 to 1.086 in Michigan trials and out-of-the- field chip scores were similar to those of Snowden. Missaukee showed some resistance to Verticillium wilt in 2-years of trials. DNA marker and greenhouse tests indicate that Missaukee is also resistant to the golden cyst nematode (Globodera rostochiensis Woll) pathotype Ro1. North Central Regional Trial Entries (Tables 3 and 4) In December 2004, 2005, 2007, and 2008, the MPIC sponsored a booth at the Great Lakes Fruit, Vegetable, and Farm Market Expo to market Liberator, Michigan Purple and Jacqueline to the farm market/roadside stand market segment. The breeding program sponsored the booth in 2009 to continue to promote varieties and promising advanced selections that may be of interest to this market segment. There continues to be a strong interest in specialty potato varieties and a growing demand for new, unique potato varieties. We also showcased some of the newer up-and-coming selections from the breeding program to get a sense of the interest from growers who stopped by the booth. C. regional locations) to provide adaptability data for the release of new varieties from Michigan, Minnesota, North Dakota, Wisconsin, and Canada. Twenty-one entries were tested in Michigan in 2009. The clones were from three market classes: Red (9 entries), Russet (4 entries), or Round White (8 entries). The results are presented in Tables 3 and 4. The MSU lines Missaukee (MSJ461-1), MSN170-A, MSM171-A, and MSL268-D were the Michigan representatives included in the 2009 North Central Trial. The two lines MSM171-A and MSL268-D were trialed in the Russet Trial due to trial size limitations. Missaukee has a good, round type and chip-processing quality combined with strong foliar late blight resistance and continues to perform well in Michigan and other out of state testing locations. MSM171-A a round-white tablestock line with moderate scab resistance, strong foliar late blight resistance, and an early maturity. MSN170-A has exceptional chip-processing quality and typical agronomic performance. MSL268-D has dual-purpose characteristics; good chip-processing quality and an The North Central Trial is conducted in a wide range of environments (11 29 Russet Trial (Table 4) Adaptation Trial (Tables 5 and 6) The Adaptation Trial is conducted as two separate trials based on market class: attractive freshmarket type, combined with late blight resistance, and some early bulking potential. D. We continue to increase our russet breeding efforts to reflect the growing interest in russet types in Michigan. In 2009, 18 lines evaluated after 128 days. The results are summarized in Table 4. Russet Norkotah was the reference variety used in the trial. Overall, the internal quality in the russet trial was above average; however, hollow heart and vascular discoloration continue to be the most prevalent internal defects. The highest hollow heart level was observed in AC99375-1Rus (50%), Classic Russet (A95109- 1Rus) (40%), and MN02467RUS (15%). Classic Russet also had a significant amount of vascular discoloration (30%). Specific gravity measurements were average with Russet Norkotah at 1.074. The yield of the overall trial was average to below average for 2009. Off type and cull tubers were found in nearly all lines tested, but ranged only from a high of 7% down to 1%. The highest yielding entry was AC99375-1Rus with 367 cwt/a US#1 yield, followed by A02062-TE and A01025-4. E. chip-processing and tablestock trials. The majority of the lines evaluated in the Adaptation Trial were tested in the Preliminary Trial the previous year. Four reference cultivars (Atlantic, Snowden, Pike, and FL1879), and 15 advanced breeding lines are reported in the chip-processing trial. The trial was harvested after 135 days and the results are summarized in Table 5. All entries had good out-of-the-field chip scores (1.0 SFA scale). Specific gravity values were average for the Montcalm Research Farm (Atlantic was 1.090 and Snowden was 1.085). The highest specific gravity was MSR102-3 at 1.095. The overall plot yields for this trial were lower than average in 2009. Boulder was the highest yielding line in 2008 and 2009 (133 cwt/a greater than Atlantic). Multiple new breeding lines combine scab resistance and chip-processing: MSR102-3, MSR058-1, MSR127-2, MSR161-2, and MSR169-8Y. MSR102-3 also combines late blight resistance, scab resistance, and chip-processing with a high specific gravity. MSR058-1 and MSR157-1Y are also late blight resistant and have moderate scab resistance. MSQ461-2PP is a purple-skinned purple flesh line with good specific gravity and scab resistance that can be used to make chips for the specialty market. In the tablestock trial, 22 advanced breeding lines were evaluated with Onaway and Yukon Gold check varieties. The trial was harvested after 128 days and the results are summarized in Table 6. In general, the yield was average in this trial and internal defects were low. The greatest amount of hollow heart was seen in Yukon Gold (15%), followed by Reba (13%) and MSQ176-5 (10%). There were a significant number of oversize potatoes in MSQ176-5 and MSQ279-1. The highest yielding line was MSI005- 20Y (yellow flesh) at 330 cwt/a, followed by MSQ279-1, MSS176-1, and MSQ086-3. 30 The Preliminary trial is the first replicated trial for evaluating new advanced Eight of the 20 lines have late blight resistance and eight lines have moderate to strong scab resistance. Seven of the 20 lines also had early maturity, similar to Yukon Gold. Promising lines with attractive type for the tablestock market and strong foliar late blight resistance include MSM182-1, MSS176-1, MSQ086-3, MSQ176-5, and MSS737-1Y. MSM182-1 also has PVY resistance. MSQ086-3 is a round-white breeding line which chip-processes out of the field, is showing early bulking potential, and has strong foliar late blight resistance. It is exciting to see lines with combined traits for type, scab, late blight, and PVY resistance, and earlier maturity classes in more advanced selections in the breeding program. F. Preliminary Trial (Tables 7 and 8) selections from the MSU potato breeding program. The division of the trials was based upon pedigree assessment for chip-processing and tablestock utilization. The chip- processing Preliminary Trial had 34 advanced selections and two check varieties (Atlantic and Snowden). The chip-processing trial was harvested after 133 days and is summarized in Table 7. Most lines chip-processed well from the field (SFA chip score 1.0 – 1.5). Specific gravity values were average for the trial (Atlantic: 1.086). The yields were slightly below average with Atlantic at 291 cwt/a and Snowden at 250 cwt/a. Twelve of the lines (35%) were classified to be resistant or moderately resistant to scab (< 1.5 scab disease rating). Seven lines have demonstrated foliar late blight resistance. MSQ029-1 has good agronomic performance with yield potential, solid specific gravity, late blight and PVY resistance. (Onaway was the check variety). This tablestock trial was harvested and evaluated after 128 days. Ten of the 32 lines were late blight resistant, two have moderate late blight resistance, and seven were scab resistant or moderately resistant (< 1.5 scab disease rating). MST500-1, Stirling, MSR601-22, MSS070-B, MST384-1PP, MSS206-2 were the highest yielding lines. In general, there was a low incidence of internal defects, except for some hollow heart: Stirling (95%), MST377-2P (30%), MSS487-2 (25%). Four of the top yielding lines have late blight resistance and marketable maturities (MST500-1, MSS070-B, MSS206-2, and MSS483-1). In addition to traditional round white, red-skinned, and yellow flesh freshmarket categories, there are some unique specialty lines. A few of the lines in this trial were considered for their unique color attributes for the specialty potato market: MST377-2P (purple skin, white flesh), MST123-1RY (red skin, yellow flesh), MST235-2SPL (splash), MST384-1PP, MSS514- 1PP (purple skin, purple flesh). G. Potato Scab Evaluation (Table 9) conducted to assess resistance to common scab. We are using a scale of a 0-5 ranking Table 8 summarizes the 32 tablestock lines evaluated in the Preliminary Trial Each year, a replicated field trial at the MSU Soils Farm (E. Lansing, MI) is 31 The check varieties Russet Norkotah, Yukon Gold, Onaway, Pike, Atlantic and based upon a combined score for scab coverage and lesion severity. Usually examining one year's data does not indicate which varieties are resistant but it should begin to identify ones that can be classified as susceptible to scab. Our goal is to evaluate important advanced selections and varieties in the study at least three years to obtain a valid estimate of the level of resistance in each line. Table 9 categorizes many of the varieties and advanced selections tested in 2009 at the MSU Soils Farm Scab Nursery over a three-year period. The varieties and breeding lines are placed into six categories based upon scab infection level and lesion severity. A rating of 0 indicates zero scab infection. A score of 1.0 indicates a trace amount of infection. A moderate resistance (1.2 – 1.8) correlates with <10% infection. Scores of 4.0 or greater are found on lines with >50% infection and severe pitted lesions. Snowden can be used as references (bolded in Table 9). The table is sorted in ascending order by 2009 rating. In general, most russet lines were scab resistant. This year’s results continue indicate that we have been able to breed numerous lines for the chip- processing and tablestock markets with resistance to scab. A total of 69 lines, of the 157 tested, had a scab rating of 1.5 (better than or equivalent to Pike) or lower in 2009. Most notable scab resistant MSU lines are MSH228-6, Kalkaska (MSJ036-A), MSJ126-9Y, MSK061-4, MSL007-B, MSN230-1RY, MSQ070-1, MSQ289-5, MSQ440-2, MSR036- 5, MSR061-1, MSR102-3; as well as some earlier generation lines MSS176-1, MSS544- 1R, S737-1Y, and MST306-01. The greater number of MSU lines in the resistant and moderately resistant categories indicates we are making progress in breeding more scab resistant lines for the chip-processing and tablestock markets. There are also an increasing number of scab resistant lines that also have late blight resistance and PVY resistance. We also continue to conduct early generation scab screening on selections in the breeding program beginning after one year. Of the 327 early generation selections that were evaluated, 128 were resistant (scab rating of ≤ 1.0). Scab results from the disease nursery are also found in the Trial Summaries (Tables 2-8). H. Late Blight Trial previous years, 256 entries were planted in replication for evaluation in replicated plots. These include lines tested in the agronomic variety trial and entries in the National Late Blight Variety Trial. Block planting full rows of advanced selections provide a better assessment of the late blight resistance of these lines. We also planted 171 early generation breeding lines that have a late blight resistant pedigree. The field was planted on June 4. Two weeks following planting, almost six inches of rain fell at the farm over 12 days. The flooding from these and subsequent rains damaged the plots beyond recovery. Unfortunately, all plots were destroyed and no data were taken. We were able to do a late planting for a trial to test 90 Solanum microdontum accessions. The late blight trials will be conducted at a new location next year at the MSU Clarksville Horticultural Experiment Station. We will try again for a successful late blight disease field test in 2010. In 2009, a late blight trial was planted at the Muck Soils Research Farm. As in 32 Evaluations of advanced seedlings and new varieties for their susceptibility to I. Blackspot Bruise Susceptibility (Table 10) blackspot bruising are also important in the variety evaluation program. Based upon the results collected over the past years, the non-bruised check sample has been removed from our bruise assessment. A composite bruise sample of each line in the trials consisted of 25 tubers (a composite of 4 replications) from each line, collected at the time of grading. The 25 tuber sample was held in 50°F (10°C) storage overnight and then was placed in a hexagon plywood drum and tumbled 10 times to provide a simulated bruise. The samples were peeled in an abrasive peeler in October and individual tubers were assessed for the number of blackspot bruises on each potato. These data are shown in Table 10. The bruise data are represented in two ways: percentage of bruise free potatoes and average number of bruises per tuber. A high percentage of bruise-free potatoes is the desired goal; however, the numbers of blackspot bruises per potato is also important. Cultivars which show blackspot incidence greater than Atlantic are approaching the bruise-susceptible rating. In addition, the data is grouped by trial, since the bruise levels can vary between trials. Conducting the simulated bruise on 50°F (10°C) tubers has helped to standardize the bruise testing. We are observing less variation between trials since we standardized the handling of the bruise sample. In 2009, the bruise levels were comparable to previous years. The most bruise resistant MSU breeding lines this year from the Advanced trial were MSQ289-5, MSP459-5, MSQ131-A, MSQ130-4, MSL292-A, Pike, MSQ089-1, MSR061-1, MSJ126-9Y, and MSK061-4. The most susceptible lines from the Advanced trial were Kalkaska, FL2137, MSN191-2Y, MSL007-B, MSK409-1, and FL1879. Of the earlier generation breeding lines (Preliminary Trial), the most bruise resistant were MSS927-1, MST096-2Y, MST169-07, MSS199-A, MSS514-1PP, and MST065-2. The most bruise resistant russet entries were A02062-1TE, AOTX95265-4Rus, CO99053-4Rus, and CO99100-1Rus; the most susceptible were PA03NM5-1, Canela Russet, and AC99375- 1Rus. The most bruise resistant entries in the US Potato Board/Snack Food Association Trial were NY138, CO96141-4W, and Kalkaska. Snowden, AF2291-10, CO97043-14W, and Atlantic were the most bruise susceptible in this trial. 33 Table 1 EARLY HARVEST TRIAL MONTCALM RESEARCH FARM May 5 to August 14, 2009 (102 days) CWT/A PERCENT OF TOTAL1 TOTAL MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS PERCENT (%) SCAB4 US#1 315 282 278 252 225 217 213 212 203 200 198 192 180 179 170 159 158 101 207 61 US#1 Bs As OV PO 1 90 2 92 86 1 1 83 1 93 92 0 0 83 1 94 84 1 0 79 0 79 93 0 2 93 2 86 0 83 70 1 1 80 78 2 LINE Onaway MI Purple Red Sport MSQ086-3LBR MSL211-3LBR MSM037-3 MSQ176-5LBR Atlantic MSQ131-ALBR MSN170-A FL1867 MSL292-A MSQ279-1 MSS582-1SPL MSL228-1SPL MSP368-1 MSN105-1 MSQ130-4LBR MSR036-5LBR MEAN LSD0.05 LBR Line(s) demonstrated foliar resistance to Late Blight ( Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. 1SIZE: B: < 2 in.; A: 2-3.25 in.; OV: > 3.25 in.; PO: Pickouts. 2CHIP SCORE: Snack Food Association Scale (Out of the field); Ratings: 1-5; 1: Excellent, 5: Poor. 3QUALITY: HH: Hollow Heart; BC: Brown Center; VD: Vascular Discoloration; IBS: Internal Brown Spot. Percent of 40 Oversize and/or A-size tubers cut. 4SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. SP GR 1.073 1.072 1.079 1.074 1.071 1.067 1.095 1.070 1.084 1.097 1.089 1.073 1.072 1.083 1.084 1.081 1.078 1.077 1.079 0.004 349 307 322 305 241 237 256 226 243 252 251 205 193 207 204 227 197 130 242 65 5 12 0 11 7 9 0 3 1 1 0 12 22 4 3 0 0 2 TUBER QUALITY3 CHIP SCORE2 HH VD IBS BC 0 0 3 0 0 0 3 0 3 0 0 0 0 0 0 0 0 0 3.0 1.5 1.0 1.5 1.0 1.5 1.0 1.0 1.0 1.0 1.0 1.0 - 1.5 1.0 1.0 1.0 1.0 0 20 0 0 28 30 3 0 0 0 0 0 3 3 0 0 3 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 3 3 3 8 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 9 6 13 16 6 8 16 6 16 20 21 6 5 12 17 30 19 21 86 79 86 72 86 83 83 90 83 78 79 81 71 83 81 70 80 75 1.6 2.8 2.5 2.4 1.3 1.8 2.7 2.0 - - 2.3 1.4 1.6 2.5 - 2.0 1.8 1.3 * Two-Year Average 34 Table 2 ADVANCED TRIAL MONTCALM RESEARCH FARM May 5 to September 17, 2009 (135 days) CWT/A PERCENT OF TOTAL1 PERCENT (%) CHIP TUBER QUALITY3 TOTAL 16 11 7 14 6 27 11 19 13 19 10 5 6 21 21 31 23 40 29 23 33 25 43 32 42 75 81 84 83 88 72 76 80 82 79 72 83 81 77 75 67 76 58 70 73 67 71 56 66 58 8 7 9 2 6 0 12 1 4 0 14 11 12 1 4 0 0 1 0 3 0 0 0 1 0 1 1 0 1 0 0 1 0 1 1 4 1 1 2 0 1 0 1 1 0 0 3 0 2 0 381 316 300 321 282 318 246 267 245 260 239 216 220 236 222 249 214 274 218 198 222 205 242 202 206 252 53 US#1 316 280 278 274 265 229 216 215 212 207 206 204 204 183 176 169 163 162 152 151 150 146 137 135 118 198 52 US#1 Bs As OV PO SP GR SCORE2 HH VD IBS BC SCAB4 MAT5 BRUISE6 83 89 93 85 94 72 88 81 87 79 86 94 93 77 79 68 76 59 70 77 67 71 56 67 58 LINE MSP515-2 Kalkaska (J036-A) FL1879 MSQ089-1 Beacon Chipper MSQ070-1LBR MSR036-5LBR MSK061-4 MSH228-6 MSQ035-3LBMR MSR159-02LBR MSQ131-ALBR FL2137 MSJ126-9Y MSR061-1LBRS Snowden Pike MSJ147-1 MSP459-5LBRS MSQ130-4LBR MSL292-A MSK409-1 MSN191-2Y MSQ289-5 MSL007-B MEAN LSD0.05 LBR Line(s) demonstrated foliar resistance to Late Blight ( Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. 1SIZE: B: < 2 in.; A: 2-3.25 in.; OV: > 3.25 in.; PO: Pickouts. 2CHIP SCORE: Snack Food Association Scale (Out of the field); Ratings: 1-5; 1: Excellent, 5: Poor. 3QUALITY: HH: Hollow Heart; BC: Brown Center; VD: Vascular Discoloration; IBS: Internal Brown Spot. Percent of 40 Oversize and/or A-size tubers cut. 4SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. 5MATURITY RATING: August 24, 2009; Ratings 1-5; 1: Early (vines completely dead); 5: Late (vigorous vine, some flowering). 6BRUISE: Simulated blackspot bruise test average number of spots per tuber. 1.079 1.085 1.080 1.075 1.077 1.097 1.080 1.085 1.081 1.080 1.083 1.067 1.088 1.082 1.080 1.086 1.086 1.091 1.078 1.073 1.084 1.087 1.095 1.086 1.083 1.083 0.004 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.5 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 2.1 1.7 1.3 1.8 1.6 2.3 2.9 1.8 2.0 1.3 2.5 1.9 1.5 1.6 1.9 2.0 2.0 2.1 1.0 1.0 1.1 1.3 1.0 1.0 1.6 5 0 5 5 20 0 8 25 0 0 3 0 3 3 5 23 3 0 3 0 5 10 0 0 3 1.8 1.3 2.0 1.9 1.3 1.3 1.3 1.4 1.3 2.0 1.5 2.0 - 1.3 1.1 2.3 1.5 1.7 1.8 1.8 2.3 1.6 2.8 1.3 1.0 1.1 3 30 10 8 0 3 0 0 3 0 30 0 23 0 5 3 0 0 3 5 0 0 3 3 0 3 0 0 3 0 0 3 0 0 0 0 0 0 0 0 0 0 0 0 8 0 0 0 0 0 0 5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS 3-YR AVG US#1 CWT/A - 356* 366 - 335 387* - 283 263 - - - - 248 237* 264* 209* 196 204* 0.8 1.6 1.0 0.4 0.8 0.9 0.6 0.5 0.7 1.0 0.5 0.2 1.1 0.5 0.4 0.8 0.4 0.9 0.2 0.3 0.4 1.0 1.0 0.1 1.0 * Two-Year Average - - 208 214 - - 0.4 35 Table 3 CWT/A TOTAL NORTH CENTRAL REGIONAL TRIAL MONTCALM RESEARCH FARM May 13 to September 8, 2009 (118 days) MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS PERCENT (%) 3-YR AVG 1.1 0.4 85 84 82 77 88 85 82 79 86 84 79 77 72 85 64 76 71 67 61 2 7 1 0 4 3 4 0 3 5 5 3 4 1 6 4 0 0 6 3 1 1 0 1 1 0 2 1 2 1 2 3 3 10 1 4 2 9 PERCENT OF TOTAL1 CHIP TUBER QUALITY3 10 7 17 22 6 11 14 19 10 9 15 17 20 11 20 19 24 31 25 361 345 377 398 319 332 335 362 303 297 311 314 316 277 309 227 220 209 209 306 71 US#1 315 315 312 308 296 292 287 285 270 264 260 253 242 240 217 182 157 140 138 251 69 US#1 US#1 Bs As OV PO SP GR SCORE2 HH VD IBS BC SCAB4 MAT5 BRUISE6 CWT/A 87 91 83 77 93 88 85 79 89 89 84 81 77 87 70 80 71 67 66 LINE MN96013-1RY W5767-1R Snowden ATND98459-1RY Atlantic ND8305-1 Missaukee (MSJ461-1)LBR ND028842-1RY Red Norland MSN170-A W5015-12 MN02616RY WV4992-1RUS W2978-3 CV01238-3RUS CV99073-1R ND8304-2 MN19298RY WV5843-6R MEAN LSD0.05 LBR Line(s) demonstrated foliar resistance to Late Blight ( Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. All the lines in the Round White Trial in 2008 were North Central Regional Trial entries. 1SIZE: B: < 2 in.; A: 2-3.25 in.; OV: > 3.25 in.; PO: Pickouts. 2CHIP SCORE: Snack Food Association Scale (Out of the field); Ratings: 1-5; 1: Excellent, 5: Poor. 3QUALITY: HH: Hollow Heart; BC: Brown Center; VD: Vascular Discoloration; IBS: Internal Brown Spot. Percent of 40 Oversize and/or A-size tubers cut. 4SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. 5MATURITY RATING: August 24, 2009; Ratings 1-5; 1: Early (vines completely dead); 5: Late (vigorous vine, some flowering). 6BRUISE: Simulated blackspot bruise test average number of spots per tuber. 1.068 1.067 1.083 1.070 1.087 1.085 1.074 1.065 1.061 1.078 1.078 1.067 1.075 1.071 1.067 1.063 1.075 1.061 1.054 1.071 0.003 1.5 2.0 1.0 2.5 1.0 1.0 1.0 2.0 2.5 1.0! 1.5 1.5 1.5 1.0 1.5 3.5 1.0 1.0 3.0 1.8 2.0 2.0 1.6 2.3 1.1 2.6 1.3 1.0 1.6 3.4 1.0 1.5 1.4 1.3 1.5 1.0 1.3 1.0 294* - - 326 - 298 - - - - 0.4 0.8 0.8 0.1 1.7 1.1 0.2 0.3 0.1 0.4 0.7 0.8 0.8 0.1 0.1 0.2 0.2 0.1 0.5 * Two-Year Average 139* - - - - - - - - - - 2.3 - 2.7 - - - - - - - - - - - - - - 0 3 0 0 8 0 0 0 0 8 0 0 0 0 0 0 0 0 0 0 0 11 0 0 0 3 10 0 0 5 0 0 0 0 15 5 0 0 0 5 0 0 3 0 0 0 0 11 5 0 0 0 0 0 0 0 3 3 8 0 0 5 0 0 8 0 0 0 0 0 0 8 0 5 0 3 36 Table 4 RUSSET TRIAL 2009 MONTCALM RESEARCH FARM May 5 to September 10, 2009 (128 days) CWT/A PERCENT OF TOTAL1 PERCENT (%) TUBER QUALITY2 TOTAL MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS 3-YR AVG US#1 CWT/A 368* - - - - 337 312* 307 - 0.6 0.0 0.3 3.6 0.5 0.4 0.4 0.4 0.3 0.3 0.2 0.8 0.2 0.2 1.0 0.1 0.2 0.2 * Two-Year Average 289* 227* 207 241 - 201* 155 314* - 11 20 12 10 11 23 10 11 1 7 15 0 3 5 2 4 0 1 7 5 5 4 4 4 7 2 4 4 6 2 4 5 1 4 3 2 66 69 68 73 63 63 71 80 73 76 66 72 69 67 75 58 65 52 473 357 390 355 396 335 336 293 343 299 295 321 319 303 263 262 230 270 324 72 US#1 78 90 80 83 74 86 81 92 75 82 81 72 72 72 77 62 65 53 US#1 367 319 314 294 292 287 273 269 256 246 240 231 229 217 202 162 149 143 249 70 Bs As OV PO SP GR HH VD IBS BC SCAB3 MAT4 BRUISE5 10 7 8 14 13 7 11 6 5 7 11 8 5 7 8 7 6 6 LINE AC99375-1Rus A02062-1TE A01025-4 PA03NM5-1 MN02467RUS Classic Russet (A95109-1Rus) CO99053-3Rus **MSM171-ALBR Goldrush Russet Silverton Russet W7098-2Rus **MSL268-DLBR CO99053-4Rus CORN #8 Canela Russet AOTX95265-4Rus CO99100-1Rus Russet Norkotah MEAN LSD0.05 **Not Russet lines LBR Line(s) demonstrated foliar resistance to Late Blight ( Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. NCR North Central Regional Entry 1SIZE: B: < 4 oz.; A: 4-10 oz.; OV: > 10 oz.; PO: Pickouts. 2QUALITY: HH: Hollow Heart; BC: Brown Center; VD: Vascular Discoloration; IBS: Internal Brown Spot. Percent of 40 Oversize and/or A-size tubers cut. 3SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. 4MATURITY RATING: August 24, 2009; Ratings 1-5; 1: Early (vines completely dead); 5: Late (vigorous vine, some flowering). 5BRUISE: Simulated blackspot bruise test average number of spots per tuber. 1.080 1.070 1.074 1.085 1.080 1.074 1.076 1.066 1.075 1.068 1.067 1.080 1.078 1.071 1.083 1.072 1.075 1.074 1.075 0.003 3.1 1.8 2.1 3.4 3.4 1.6 2.5 1.3 1.1 1.4 2.1 1.8 1.0 1.4 1.5 1.3 1.0 1.1 1.3 1.5 1.0 1.0 0.4 1.3 1.5 2.3 1.0 1.3 1.3 2.5 1.5 1.0 0.7 1.3 1.3 2.0 50 0 3 8 15 28 8 5 0 3 0 3 0 13 0 0 0 5 5 18 13 30 0 30 10 0 0 3 10 18 5 10 5 0 8 3 3 0 0 0 0 0 0 3 0 3 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1.1 0.6 37 Table 5 ADAPTATION TRIAL, CHIP-PROCESSING LINES MONTCALM RESEARCH FARM May 5 to September 17, 2009 (135 days) CWT/A PERCENT OF TOTAL1 PERCENT (%) CHIP TUBER QUALITY3 MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS TOTAL 0.8 - 1.6 0.6 1.7 - 1.1 2.1 0.6 0.2 1.1 0.3 0.7 0.4 0.9 1.1 0.4 1.1 0.4 3 14 11 14 21 13 13 18 32 22 19 14 37 15 18 25 24 42 43 64 83 72 84 77 84 69 74 66 77 78 84 63 80 82 71 76 57 57 32 2 14 2 2 3 8 6 0 0 1 1 0 3 1 0 0 0 0 1 2 3 0 0 0 9 1 2 1 2 1 0 2 0 4 0 1 0 320 355 295 295 256 225 250 239 279 234 221 203 275 202 192 220 195 207 136 242 57 US#1 309 299 254 253 201 196 194 192 184 179 176 172 172 168 158 157 148 119 78 190 55 US#1 Bs As OV PO SP GR SCORE2 HH VD IBS BC SCAB4 MAT5 BRUISE6 97 84 86 86 79 87 78 80 66 77 80 85 63 83 82 71 76 57 57 LINE Boulder AO1143-3C MSR102-3LBR MSP270-1 MSR058-1LBR MSQ461-2PP MSR127-2 MSN148-A MSR128-4Y AO0188-3C Atlantic FL1879 Snowden MSQ440-2 Table Pike MSR161-2 MSR157-1YLBR MSN190-2 MSR169-8Y MEAN LSD0.05 LBR Line(s) demonstrated foliar resistance to Late Blight (Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. 1SIZE: B: < 2 in.; A: 2-3.25 in.; OV: > 3.25 in.; PO: Pickouts. 2CHIP SCORE: Snack Food Association Scale (Out of the field); Ratings: 1-5; 1: Excellent, 5: Poor. 3QUALITY: HH: Hollow Heart; BC: Brown Center; VD: Vascular Discoloration; IBS: Internal Brown Spot. Percent of 40 Oversize and/or A-size tubers cut. 4SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. 5MATURITY RATING: August 24, 2009; Ratings 1-5; 1: Early (vines completely dead); 5: Late (vigorous vine, some flowering). 6BRUISE: Simulated blackspot bruise test average number of spots per tuber. 1.075 1.080 1.095 1.078 1.083 1.078 1.087 1.087 1.090 1.083 1.090 1.079 1.085 1.064 1.085 1.087 1.080 1.094 1.084 1.083 0.005 2.1 2.5 3.0 2.5 2.3 1.5 2.5 1.5 2.5 2.3 1.8 1.1 1.9 1.3 1.8 2.0 2.0 1.0 2.0 0.5 8 8 18 0 0 0 0 3 0 0 5 3 0 0 5 0 0 0 0 3 0 0 0 3 0 0 10 0 10 3 18 10 48 10 3 8 0 3 2.3 1.3 0.8 1.5 1.3 0.8 1.0 2.0 2.0 1.3 2.7 2.0 2.3 1.0 1.5 1.0 1.5 1.6 1.0 1.1 1.0 - 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 - 1.0 1.0 1.0 1.0 1.0 0 0 0 0 0 0 0 0 0 0 3 0 0 0 0 0 0 0 0 3 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 38 Table 6 ADAPTATION TRIAL, TABLESTOCK LINES MONTCALM RESEARCH FARM May 5 to September 10, 2009 (128 days) CWT/A PERCENT OF TOTAL1 PERCENT (%) TUBER QUALITY2 MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS 2 3 3 0 3 1 2 3 1 1 3 1 1 4 0 1 0 0 1 6 1 0 4 5 84 92 87 77 89 92 77 84 88 92 87 86 68 79 83 75 68 80 63 85 63 80 65 90 14 6 10 23 7 7 21 13 11 7 11 13 31 18 17 25 32 20 36 10 36 20 31 5 81 78 80 75 80 79 73 74 87 83 84 82 67 77 80 71 68 78 63 76 63 80 65 90 3 14 7 1 9 13 4 10 1 8 3 4 1 2 3 4 0 2 0 8 0 0 0 0 393 334 335 380 305 296 304 278 265 251 265 265 286 240 226 242 230 196 246 180 240 173 202 124 261 68 US#1 TOTAL US#1 Bs As OV PO SP GR HH VD IBS BC SCAB3 MAT4 BRUISE5 330 306 292 291 273 271 235 235 233 230 230 228 194 189 186 181 157 156 156 152 150 137 131 112 211 66 LINE MSI005-20Y MSQ279-1 MSS176-1LBR MSQ086-3LBR MI Purple Red Sport MSQ176-5LBR MSN230-1RYLBR MSS737-1YLBR MSM037-3 MI Purple Onaway Reba MSM182-1LBR PVYR MSL228-1SPL MSQ134-5LBR MSL211-3LBR MSQ425-4PYSPL MSS576-05SPL MSS108-1 Yukon Gold MSN105-1 MSR217-1R MSN215-2P MSQ432-2PP MEAN LSD0.05 LBR Line(s) demonstrated foliar resistance to Late Blight (Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. NCR North Central Regional Entry 1SIZE: B: < 2 in.; A: 2-3.25 in.; OV: > 3.25 in.; PO: Pickouts. 2QUALITY: HH: Hollow Heart; BC: Brown Center; VD: Vascular Discoloration; IBS: Internal Brown Spot. Percent of 40 Oversize and/or A-size tubers cut. 3SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. 4MATURITY RATING: August 24, 2009; Ratings 1-5; 1: Early (vines completely dead); 5: Late (vigorous vine, some flowering). 5BRUISE: Simulated blackspot bruise test average number of spots per tuber. 1.074 1.080 1.074 1.080 1.074 1.067 1.080 1.071 1.070 1.071 1.071 1.074 1.075 1.081 1.073 1.073 1.076 1.072 1.075 1.077 1.079 1.065 1.073 1.068 1.074 0.003 2.8 1.4 1.3 2.5 2.8 1.8 0.3 1.3 1.3 2.3 1.6 2.0 2.9 2.5 1.9 2.4 2.3 2.0 - 2.3 2.0 1.8 0.8 1.8 1.1 1.6 2.9 2.0 1.8 1.0 1.8 2.0 2.1 1.8 1.3 1.4 1.9 1.6 1.1 1.8 1.0 1.5 1.4 1.6 1.0 1.3 1.0 1.0 1.8 0.3 0.2 0.6 0.4 0.5 0.6 0.4 0.3 0.1 0.0 0.2 0.3 0.9 0.8 0.4 0.6 0.0 0.5 0.2 0.2 0.0 0.2 0.3 0.2 - 0 0 0 3 3 10 0 0 8 5 0 13 3 0 0 0 0 0 0 15 0 0 0 0 0 0 0 10 5 0 10 5 3 5 0 0 0 3 0 3 0 0 3 8 0 3 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 10 3 0 0 0 0 0 0 0 0 0 0 0 0 0 3 0 0 0 0 0 0 0 0 0 0 0 0 0 0 39 Table 7 MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS PRELIMINARY TRIAL, CHIP-PROCESSING LINES MONTCALM RESEARCH FARM May 5 to September 14, 2009 (133 days) CWT/A PERCENT OF TOTAL1 PERCENT (%) CHIP TUBER QUALITY3 LINE US#1 TOTAL US#1 Bs As OV PO SP GR SCORE2 HH VD IBS BC SCAB4 MAT5 BRUISE6 MST222-5 MST220-08LBR MST193-4Y MST412-3 MSQ029-1LBR PVYR CO00197-3W MST611-1Y MSM246-B MSS934-4 MST443-1 Atlantic MST169-07 MST424-3 Snowden MSN111-4PP MST458-04LBR MST429-3YLBR MST008-01LBR MST443-2Y MST184-3 MSS165-2Y MST202-5 MSS258-1 MSS026-2Y MST611-2 MSS428-2 MST096-2Y 386 365 339 332 315 312 306 302 301 295 291 278 266 250 244 240 237 231 230 228 219 201 187 184 179 172 162 405 419 408 367 376 407 352 340 347 334 328 330 298 327 324 254 304 306 317 264 294 274 216 232 246 228 197 95 87 83 90 84 77 87 89 87 88 89 84 89 76 75 94 78 76 73 86 75 73 87 79 73 76 82 2 11 15 7 8 22 8 9 6 11 11 16 8 23 24 2 9 23 27 7 17 16 12 18 12 24 18 67 76 82 64 67 75 67 78 65 79 88 81 85 76 75 58 61 60 73 70 74 73 83 78 67 76 82 29 11 1 26 17 2 21 10 21 9 1 3 4 0 1 37 17 15 0 16 1 0 4 1 6 0 0 3 2 2 2 8 1 5 2 7 1 0 0 3 0 1 4 13 2 0 7 8 10 1 2 15 0 0 1.062 1.078 1.077 1.074 1.084 1.079 1.075 1.081 1.079 1.083 1.086 1.073 1.076 1.081 1.069 1.075 1.073 1.060 1.087 1.080 1.082 1.080 1.068 1.092 1.073 1.080 1.073 1.5 1.5 1.5 1.0 1.5 1.0 1.5 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.5 1.0 1.5 1.0 1.0 1.0 1.5 1.0 1.0 1.5 1.0 1.0 1.5 5 25 0 20 20 5 0 20 0 0 0 0 0 0 0 0 25 10 0 15 15 5 5 0 0 5 0 20 5 0 5 0 10 0 0 0 0 0 0 0 0 0 0 5 0 5 0 0 15 0 0 0 0 0 0 5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 2.2 2.1 2.0 2.0 2.0 3.1 - 2.8 2.8 - 2.7 1.5 1.3 2.3 1.0 1.5 1.8 2.8 1.5 1.6 1.5 1.8 2.0 2.5 1.8 2.3 1.5 2.8 4.0 3.3 2.8 4.3 1.3 3.0 2.0 2.3 2.0 2.0 1.0 2.5 2.8 1.3 1.0 3.3 1.0 1.3 3.0 2.8 1.3 1.0 2.5 1.8 1.0 1.5 0.6 1.1 1.0 0.2 0.5 0.6 0.2 0.6 1.0 0.7 1.3 0.1 1.3 1.4 0.9 0.9 0.4 0.2 0.9 0.8 0.7 0.2 0.9 1.2 0.4 1.0 0.0 40 Table 7 MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS PRELIMINARY TRIAL, CHIP-PROCESSING LINES MONTCALM RESEARCH FARM May 5 to September 14, 2009 (133 days) CWT/A PERCENT OF TOTAL1 PERCENT (%) CHIP TUBER QUALITY3 LINE US#1 TOTAL US#1 Bs MST007-2 MSS297-3 MST190-15YLBR MST229-1 MSS927-1 MST094-1 MST458-06 CO00188-4W MST306-01LBR MEAN LSD0.05 157 157 155 155 149 148 144 121 90 231 78 212 247 233 184 176 176 211 223 199 288 85 74 63 67 84 84 84 68 54 45 23 36 32 11 16 15 32 46 54 As 74 63 67 83 77 61 68 54 45 OV PO SP GR SCORE2 HH VD IBS BC SCAB4 MAT5 BRUISE6 0 0 0 1 7 23 0 0 0 3 1 1 4 0 0 0 0 1 1.080 1.077 1.080 1.080 1.070 1.071 1.070 1.081 1.074 1.077 0.007 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 30 0 0 10 0 0 0 0 0 0 5 0 5 5 10 0 0 0 5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0.5 0.6 0.3 0.8 0.0 2.2 - 0.2 0.7 1.8 1.0 2.3 1.3 1.5 1.5 2.5 2.0 1.0 1.1 1.5 1.3 2.3 4.3 1.3 1.5 1.0 1.0 1.5 0.6 LBR Line(s) demonstrated foliar resistance to Late Blight (Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. 1SIZE: B: < 2 in.; A: 2-3.25 in.; OV: > 3.25 in.; PO: Pickouts. 2CHIP SCORE: Snack Food Association Scale (Out of the field); Ratings: 1-5; 1: Excellent, 5: Poor. 3QUALITY: HH: Hollow Heart; BC: Brown Center; VD: Vascular Discoloration; IBS: Internal Brown Spot. Percent of 20 Oversize and/or A-size tubers cut. 4SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. 5MATURITY RATING: August 24, 2009; Ratings 1-5; 1: Early (vines completely dead); 5: Late (vigorous vine, some flowering). 6BRUISE: Simulated blackspot bruise test average number of spots per tuber. 41 Table 8 LINE MST500-1LBR StirlingLBR MSR601-22 MSS070-BLBMR MST384-1PP MSS206-2LBR MST065-1 MSS483-1LBR Onaway MST377-2P MST285-2LBR ATTX961014-1RY MSS199-ALBR MSS487-2LBR MST065-2 CO99256-2R Reba MSR601-19 MST235-2SPL MSR601-21 MST145-1LBR MSS514-1PP CO00270-7W MST123-1RY CO99076-6R MST359-3LBR MST075-1R Midnight PRELIMINARY TRIAL, TABLESTOCK LINES MONTCALM RESEARCH FARM May 5 to September 9, 2009 (128 days) MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS CWT/A PERCENT OF TOTAL1 PERCENT (%) TUBER QUALITY3 US#1 TOTAL US#1 Bs As OV PO SP GR HH VD IBS BC SCAB4 MAT5 BRUISE6 424 413 384 373 339 336 317 299 298 292 280 274 267 262 250 248 244 242 234 231 222 205 204 198 197 194 194 178 469 454 420 416 367 358 361 387 344 352 325 373 310 286 289 334 275 345 256 296 294 261 246 272 234 224 264 310 90 91 91 90 92 94 88 77 87 83 86 73 86 92 87 74 89 70 91 78 75 78 83 73 84 87 73 57 9 6 9 8 5 2 11 22 8 14 6 26 12 8 9 25 11 30 9 19 23 17 16 16 12 11 27 41 76 59 89 79 74 50 78 75 81 76 67 68 78 65 74 74 84 70 88 75 73 75 81 67 75 83 73 54 15 32 2 10 19 44 10 2 6 7 19 6 8 27 13 0 5 0 4 3 2 3 2 6 9 4 0 4 1 3 0 2 3 4 1 1 5 3 8 0 2 0 4 1 0 0 0 3 1 4 0 11 4 3 0 2 1.073 1.065 1.064 1.076 1.071 1.066 1.076 1.071 1.071 1.062 1.073 1.073 1.073 1.072 1.059 1.065 1.071 1.076 1.073 1.071 1.069 1.061 1.076 1.063 1.067 1.074 1.067 1.053 5 95 0 0 0 20 0 15 0 30 15 0 0 25 0 0 5 0 0 0 0 0 0 0 10 0 0 0 0 0 0 0 0 0 5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 0 0 0 0 0 0 0 0 0 0 0 5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 0 0 0 0 0 0 0 0 0 0 0 2.7 2.8 2.5 2.0 1.5 2.1 2.1 2.3 1.6 1.5 1.5 3.5 2.3 2.0 1.8 1.8 2.0 2.0 2.5 3.3 2.0 1.5 2.8 1.4 2.5 1.8 1.8 2.3 3.5 3.5 2.0 2.3 3.3 2.3 3.5 1.0 1.0 1.3 3.0 1.0 2.3 3.5 1.0 1.8 2.0 2.5 1.0 1.0 2.0 1.3 1.3 2.8 1.0 2.8 1.0 1.0 0.5 1.6 0.2 0.3 0.4 0.3 0.7 0.4 1.1 0.6 0.3 0.3 0.1 1.3 0.1 0.9 0.1 0.5 0.6 0.3 0.4 0.1 0.4 0.4 0.6 0.2 0.2 0.4 42 Table 8 PRELIMINARY TRIAL, TABLESTOCK LINES MONTCALM RESEARCH FARM May 5 to September 9, 2009 (128 days) CWT/A PERCENT OF TOTAL1 PERCENT (%) TUBER QUALITY3 MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS LINE MSR297-ALBRS MSS544-1R MST033-2LBR CO98012-5R MEAN LSD0.05 US#1 TOTAL US#1 Bs 90 56 68 56 10 44 30 44 162 157 136 132 256 105 180 281 200 234 313 108 As 86 56 65 56 OV PO SP GR HH VD IBS BC SCAB4 MAT5 BRUISE6 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 0 3 0 0 0 2 0 1.066 1.069 1.075 1.068 1.069 0.005 0.2 0.4 0.4 1.0 1.7 0.8 1.5 1.8 1.1 1.5 1.0 1.0 1.3 0.7 LBR Line(s) demonstrated foliar resistance to Late Blight (Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. 1SIZE: B: < 2 in.; A: 2-3.25 in.; OV: > 3.25 in.; PO: Pickouts. 2CHIP SCORE: Snack Food Association Scale (Out of the field); Ratings: 1-5; 1: Excellent, 5: Poor. 3QUALITY: HH: Hollow Heart; BC: Brown Center; VD: Vascular Discoloration; IBS: Internal Brown Spot. Percent of 20 Oversize and/or A-size tubers cut. 4SCAB DISEASE RATING: MSU Scab Nursery; 0: No Infection; 1: Low Infection <5%; 3: Intermediate; 5: Highly Susceptible. 5MATURITY RATING: August 24, 2009; Ratings 1-5; 1: Early (vines completely dead); 5: Late (vigorous vine, some flowering). 6BRUISE: Simulated blackspot bruise test average number of spots per tuber. 43 Table 9 LINE Sorted by ascending 2009 Rating; MSN230-1RY MN02467RUS Canela Russet MSR176-4P MSR102-3LBR MSQ461-2PP MSN215-2P MSS544-1R MSQ405-1PP MSR161-2 MSQ440-2 MSR127-2 CORN#8 MSR169-8Y MSR226-ARR MSS297-3 MSR226-1RR MSN111-4PP A01025-4 Goldrush Russet MSL007-B MST306-01 PA03NM5-1 MSR061-1LBMR,PVYR Classic Russet (A95109-1Rus) Kalkaska (MSJ036-A) MSQ289-5 MSR036-5LBR MSJ126-9Y MSH228-6 Beacon Chipper MSQ558-2RR Silverton Russet AC99375-1RUS CO99100-1RUS MSR058-1 MSS737-1YLBR MSM037-3 A01143-3C MST229-1 MST424-3 MST491-2RUS W7098-2Rus MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS 2007-2009 SCAB DISEASE TRIAL SUMMARY SCAB NURSERY, EAST LANSING, MI 3-YR* AVG. 2009 2009 2009 2008 2008 2008 2007 2007 2007 RATING WORST N RATING WORST N RATING WORST N - - 0.8 1.0* 0.8 1.2 0.9* 0.9* - - - - - - 1.0 1.1 1.1 1.8 1.0* 1.0* 1.3* 1.5* 1.9* - - - - - 1.1 1.0 1.0 1.1 1.3 1.2 1.3 1.3 1.6 1.0* 1.1* 1.3* 1.3* 1.5* 1.5* 0.3 0.4 0.7 0.7 0.8 0.8 0.8 0.8 0.8 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.1 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1.3 1 1 1 1 1 1 1 1 1 1 2 1 1 1 1 1 2 3 1 1 1 2 1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 3 2 4 5 3 3 4 4 4 4 4 4 4 4 4 4 4 4 4 4 1 4 3 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 - - 1.4 1.3 1.1 1.5 1.0 1.0 - 1.0 1.3 1.3 2.1 1.0 1.0 1.5 2.0 2.9 - - - - - 1.3 1.0 1.1 1.0 1.5 1.1 1.0 1.0 1.6 0.8 1.0 1.3 1.3 1.7 1.8 - - - - - - - 2 2 2 2 1 1 - 1 2 2 3 1 1 2 2 4 - - - - - 2 2 2 2 2 2 1 1 2 1 1 3 2 2 2 - - - - - - - 4 4 4 4 4 4 - 4 4 4 4 2 2 1 3 4 - - - - - 4 4 4 4 3 4 3 1 4 4 1 4 4 3 4 - - - - - - - 0.3 - 0.5 1.3 - - - 1.0 1.0 1.0 2.3 - - - - - - - - - - 1.0 0.7 0.8 1.0 1.0 1.3 1.5 1.8 2.0 - - - - - - - - - - - - - 1 - 1 2 - - - 1 1 1 3 - - - - - - - - - - 1 1 1 1 1 2 2 2 3 - - - - - - - - - - - - - 4 - 2 4 - - - 3 4 3 4 - - - - - - - - - - 4 3 4 4 3 4 4 4 4 - - - - - - - - - - - 44 Table 9 LINE Sorted by ascending 2009 Rating; MSQ070-1LBR MSS176-1LBR AOTX95265-4Rus A00188-3C MSK061-4 MSQ279-1 MSS165-2YLBR MST123-1RY MSR157-1Y Pike MSS514-1PP CO99053-4RUS CO99053-3RUS MSR159-02LBR MSS927-1 A02062-1TE MSP270-1 MST033-2 MST094-1 MST096-2Y MST169-07 MST285-2 MST377-2P MST384-1PP MST443-2Y MST458-04 MSK409-1 MSN190-2 MSS582-1SPL Onaway MST184-3 MSJ147-1 MSR297-A MSP459-5LBMR MSQ432-2PP MSQ130-4LBR MSR217-1R MSQ176-5LBR MSR218-AR CO98012-5R MSR241-4RY CO99256-2R MSP515-2 MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS 2007-2009 SCAB DISEASE TRIAL SUMMARY SCAB NURSERY, EAST LANSING, MI 3-YR* AVG. 2009 2009 2009 2008 2008 2008 2007 2007 2007 RATING WORST N RATING WORST N RATING WORST N 1.0 1.2* 1.8* - 1.1 1.5 1.3* - 1.4 1.4 1.1* 1.4* 1.5* 1.5* 1.8* - - - - - - - - - - - 1.5 1.6 2.0 1.7* - 1.3 1.7* 1.4 1.5 1.6 1.6* 1.9 1.4* 1.9* 2.0* - - 1.3 1.3 1.3 1.3 1.4 1.4 1.4 1.4 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 1.6 1.6 1.6 1.6 1.6 1.7 1.7 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.8 2 2 2 2 2 2 2 3 2 2 3 2 3 2 2 2 2 2 3 3 3 2 2 2 3 2 2 3 3 2 2 2 2 3 3 3 3 3 3 4 3 3 2 3 3 3 3 4 4 4 4 4 8 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 2 4 4 4 8 4 3 3 4 4 4 4 4 4 4 4 4 4 1.0 1.0 2.3 - 1.0 1.5 1.3 - 1.5 1.4 0.8 1.4 1.5 1.5 2.0 - - - - - - - - - - - 2.0 2.0 2.4 1.8 - 1.4 1.8 1.5 1.5 1.5 - 2.0 1.0 2.1 2.3 - - 1 1 3 - 1 2 2 - 2 2 1 2 3 2 2 - - - - - - - - - - - 4 2 3 2 - 2 2 2 2 2 - 2 1 3 3 - - 4 1 4 - 4 4 4 - 4 15 4 4 4 3 4 - - - - - - - - - - - 3 4 4 7 - 4 3 4 2 4 - 3 1 4 4 - - 0.8 - - - 1.0 1.8 - - 1.3 1.4 - - - - - - - - - - - - - - - - 0.8 1.3 2.0 - - 1.0 - 1.0 1.3 1.5 1.5 2.0 - - - - - 1 - - - 1 3 - - 2 2 - - - - - - - - - - - - - - - - 1 2 3 - - 1 - 1 2 2 2 2 - - - - - 4 - - - 4 4 - - 4 8 - - - - - - - - - - - - - - - - 4 4 5 - - 4 - 4 3 4 2 4 - - - - - 45 Table 9 LINE Sorted by ascending 2009 Rating; MST007-2 MST065-2 MST075-1R MST202-5 MST359-3 MST429-3Y MST611-2 MSQ089-1 MSQ134-5LBR MSR128-4Y MSQ029-1LBR MSQ035-3LBR Reba MSN313-A MSN105-1LBMR FL1879 Russet Norkotah MSN148-A MSQ131-ALBR MSS258-1 MSS487-2 CO00188-4W MSR601-19 MSS070-B MSS576-05SPL MST145-1 MST193-4Y MST412-3 MSM060-3 MSS206-2LBR MST065-1 MST220-08 MST222-5 MSM171-ALBR Boulder MSL292-A Snowden Yukon Gold MSQ425-4Y SPL MSS428-2 MSS097-3LBR MSS438-1 MST190-15Y MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS 2007-2009 SCAB DISEASE TRIAL SUMMARY SCAB NURSERY, EAST LANSING, MI 3-YR* AVG. 2009 2009 2009 2008 2008 2008 2007 2007 2007 RATING WORST N RATING WORST N RATING WORST N - - - - - - - 1.6 1.8 1.7 1.8 1.7 1.9 1.9* 2.0 2.2 2.0* 1.7* 2.0* 2.0* 2.0* - - - - - - - 1.8 1.9* - - - 1.7 1.9 2.4 2.5 2.7 2.4 2.0* 2.3* - - 1.8 1.8 1.8 1.8 1.8 1.8 1.8 1.9 1.9 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.0 2.1 2.1 2.1 2.1 2.2 2.3 2.3 2.3 2.3 2.3 2.3 2.3 2.3 2.3 2.3 3 3 3 3 2 2 2 3 2 3 2 2 3 3 2 3 3 3 3 3 3 2 3 3 3 4 3 2 3 3 3 3 3 3 3 3 3 3 4 3 3 3 3 4 3 4 4 4 4 4 4 4 4 4 4 8 4 4 7 4 4 4 4 4 4 3 4 4 4 4 3 4 4 4 4 3 4 4 4 12 4 4 4 4 4 4 - - - - - - - 1.9 1.9 2.0 2.0 1.5 2.0 - 1.9 2.5 - 1.4 2.0 2.0 2.0 - - - - - - - 1.5 1.8 - - - 1.7 1.6 2.8 2.6 3.0 1.9 1.7 2.3 - - - - - - - - - 2 3 3 2 2 3 - 3 3 - 2 2 2 2 - - - - - - - 2 2 - - - 3 2 3 3 3 2 2 3 - - - - - - - - - 7 4 4 4 3 8 - 4 11 - 4 4 1 1 - - - - - - - 4 4 - - - 8 4 4 16 1 4 3 3 - - - - - - - - - 1.0 1.5 1.0 1.3 1.5 1.8 1.8 2.0 2.0 2.0 - - - - - - - - - - - 1.8 - - - - 1.3 1.8 2.3 2.6 2.8 3.0 - - - - - - - - - - - 1 2 1 2 2 2 2 3 2 3 - - - - - - - - - - - 2 - - - - 2 2 3 3 3 3 - - - - - - - - - - - 3 4 3 3 2 4 4 4 4 4 - - - - - - - - - - - 4 - - - - 4 4 4 18 4 1 - - - - 46 Table 9 2007-2009 SCAB DISEASE TRIAL SUMMARY SCAB NURSERY, EAST LANSING, MI MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS 2009 2009 2009 2008 2008 2008 2007 2007 2007 3-YR* AVG. RATING WORST N RATING WORST N RATING WORST N 2.1 1.8* - - 1.7 2.0 2.7 2.1* 2.3* 2.4* - - - - - 2.5 2.3 2.3 2.5 2.8* LINE Sorted by ascending 2009 Rating; Michigan Purple MSS199-A Midnight MSL211-3 MSL268-DLBR,PVYR MSQ086-3LBR Jacqueline LeeLBR MSL228-1SPL MSS026-2Y MSR219-2R CO99076-6R MSR601-22 MST235-2SPL MST458-06 MST500-1 Atlantic MSN191-2Y MSI005-20Y MSM246-B MSS934-4 CO00270-7W MI Purple Red Sport MST008-01 Stirling MSM182-1LBR,PVYR CO00197-3W MSR601-21 ATTX961014-1RY LSD0.05 = SCAB DISEASE RATING: MSU Scab Nursery plot rating of 0-5; 0: No Infection; 1: Low Infection <5%, no pitted leisions; 3: Intermediate >20%, some pitted leisions (Susceptible, as commonly seen on Atlantic); 5: Highly Susceptible, >75% coverage and severe pitted leisions. LBR Line(s) demonstrated foliar resistance to Late Blight ( Phytopthora infestans ) in inoculated field trials at the MSU Muck Soils Research Farm. N = Number of replications. 2.3 - - - 1.5 2.0 2.3 - - - - - - - - 2.4 1.5 2.0 2.3 - - - - - 2.0 - - - 0.9 1.8 1.3 - - 1.1 1.5 3.3 1.6 2.2 2.3 - - - - - 2.4 2.5 2.2 2.5 2.8 - - - - 2.1 - - - 0.9 2.3 2.3 2.3 2.4 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.7 2.7 2.8 2.8 2.8 2.8 2.8 2.8 2.8 2.8 2.9 3.1 3.3 3.5 1.1 4 4 - - 4 4 4 4 3 4 - - - - - 12 4 9 3 2 - - - - 4 - - - 4 - - - 4 4 4 - - - - - - - - 16 4 4 4 - - - - - 4 - - - 3 2 - - 2 2 4 2 3 3 - - - - - 3 3 3 3 3 - - - - 3 - - - 8 3 3 4 4 4 4 3 4 2 4 2 4 4 3 8 4 4 4 4 4 3 4 4 4 4 3 4 3 - - - 2 2 3 - - - - - - - - 3 2 2 3 - - - - - 3 - - - 3 3 4 3 4 4 3 4 3 3 3 3 3 4 3 3 3 3 4 3 3 4 3 4 4 4 4 4 - - - - 2.3 - - - 47 Table 10 ENTRY ADVANCED TRIAL MSQ289-5 MSP459-5 MSQ131-A MSQ130-4 MSL292-A Pike MSQ089-1 MSR061-1 MSJ126-9Y MSK061-4 MSR159-02 MSR036-5 MSH228-6 MSP515-2 Beacon Chipper Snowden MSJ147-1 MSQ070-1 FL1879 MSK409-1 MSL007-B MSN191-2Y MSQ035-3 FL2137 Kalkaska (J036-A) RUSSET TRIAL A02062-1TE AOTX95265-4Rus CO99053-4Rus CO99100-1Rus Russet Norkotah CORN #8 W7098-2Rus Silverton Russet A01025-4 Goldrush Russet 2009 BLACKSPOT BRUISE SUSCEPTIBILITY TEST SIMULATED BRUISE SAMPLES* MICHIGAN STATE UNIVERSITY POTATO BREEDING and GENETICS NUMBER OF SPOTS PER TUBER 3 4 5+ 1 1 1 1 1 1 1 1 1 1 2 3 2 4 5 3 3 2 2 5 1 2 2 1 1 1 1 2 3 4 2 3 6 1 6 2 1 3 6 4 4 2 6 7 1 0 22 21 24 19 18 17 18 18 15 16 16 15 12 15 11 10 12 16 13 12 10 8 12 11 7 24 23 21 20 20 19 19 19 17 17 1 3 4 5 6 7 5 5 8 6 5 7 9 2 10 9 8 3 4 4 8 11 8 5 5 1 2 4 5 5 6 6 5 8 8 PERCENT (%) BRUISE FREE AVERAGE SPOTS/TUBER 88 84 96 76 72 68 72 72 60 64 64 60 48 60 44 40 48 64 52 48 40 32 48 44 28 96 92 84 80 80 76 76 76 68 68 0.1 0.2 0.2 0.3 0.4 0.4 0.4 0.4 0.5 0.5 0.5 0.6 0.7 0.8 0.8 0.8 0.9 0.9 1.0 1.0 1.0 1.0 1.0 1.1 1.6 0.0 0.1 0.2 0.2 0.2 0.2 0.2 0.3 0.3 0.3 48 2009 BLACKSPOT BRUISE SUSCEPTIBILITY TEST SIMULATED BRUISE SAMPLES* NUMBER OF SPOTS PER TUBER ENTRY CO99053-3Rus Classic Russet (A95109-1Rus) MSM171-ANCR MN02467RUSNCR AC99375-1Rus MSL268-DNCR Canela Russet PA03NM5-1 0 17 18 17 14 16 10 12 1 1 7 5 6 9 5 11 7 3 NORTH CENTRAL REGIONAL TRIAL 2 MN19298RY 2 Red Norland W2978-3 2 3 ATND98459-1RY 3 CV01238-3RUS CV99073-1R 4 5 Missaukee (MSJ461-1) 3 ND8304-2 5 ND028842-1RY MSN170-A 7 3 MN96013-1RY 6 WV5843-6R W5015-12 8 9 WV4992-1RUS 10 Snowden 8 MN02616RY W5767-1R 8 9 ND8305-1 Atlantic 8 23 23 23 22 22 21 20 21 19 17 18 16 13 11 10 11 12 8 3 2 1 1 2 2 2 4 2 4 1 1 1 4 3 2 5 5 5 2 5 9 ADAPTATION TRIAL, CHIP-PROCESSING LINES AO0188-3C FL1879 MSR157-1Y MSQ440-2 MSR169-8Y MSP270-1 MSR128-4Y Snowden Boulder 4 7 3 6 8 8 10 5 11 21 18 19 17 16 14 13 15 9 3 2 1 2 3 5 4 5+ 1 3 12 2 3 1 2 3 2 2 1 3 3 3 1 2 2 PERCENT (%) BRUISE FREE AVERAGE SPOTS/TUBER 68 72 68 56 64 40 48 4 92 92 92 88 88 84 80 84 76 68 72 64 52 44 40 44 48 32 12 84 72 76 68 64 56 52 60 36 0.4 0.4 0.4 0.5 0.6 0.8 1.0 3.6 0.1 0.1 0.1 0.1 0.1 0.2 0.2 0.2 0.3 0.4 0.4 0.5 0.7 0.8 0.8 0.8 0.8 1.1 1.7 0.2 0.3 0.4 0.4 0.4 0.6 0.6 0.7 0.8 49 2009 BLACKSPOT BRUISE SUSCEPTIBILITY TEST SIMULATED BRUISE SAMPLES* NUMBER OF SPOTS PER TUBER ENTRY Pike Atlantic MSN190-2 MSR127-2 MSR161-2 MSR102-3 MSR058-1 MSN148-A 0 13 8 10 12 12 7 7 4 1 5 10 7 3 5 7 3 5 2 4 4 5 7 3 5 7 5 1 1 2 3 1 1 1 1 4 4 3 1 ADAPTATION TRIAL, TABLESTOCK LINES MSL211-3 MSM037-3 Yukon Gold MSS737-1Y MI Purple MSN215-2P MSI005-20Y MSS576-05SPL MSN105-1 MSS108-1 MSN230-1RY MSR217-1R Jacqueline Lee Onaway MSS176-1 MSL228-1SPL MSQ176-5 MSQ086-3 MSQ425-4PY MI Purple Red Sport MSQ279-1 MSR219-2R MSQ134-5 MSM182-1 Reba 24 24 24 23 21 21 21 22 22 21 20 19 18 19 19 16 15 16 16 16 16 13 13 10 10 3 4 5 6 5 4 8 10 6 7 5 5 9 8 10 12 1 1 1 1 3 1 3 3 3 4 4 1 5+ 1 1 2 2 3 3 3 2 2 4 2 6 8 1 1 1 1 1 1 1 1 4 1 2 2 1 2 PRELIMINARY TRIAL, CHIP-PROCESSING LINES MSS927-1 MST096-2Y MST169-07 MST202-5 24 24 23 22 1 1 2 2 1 PERCENT (%) BRUISE FREE AVERAGE SPOTS/TUBER 52 32 40 48 48 28 28 16 96 96 96 92 84 84 84 88 88 84 80 76 72 76 76 64 60 64 64 64 64 52 52 40 40 96 96 92 88 0.9 1.1 1.1 1.1 1.1 1.6 1.7 2.1 0.0 0.0 0.0 0.1 0.2 0.2 0.2 0.2 0.2 0.2 0.3 0.3 0.3 0.3 0.4 0.4 0.4 0.5 0.5 0.6 0.6 0.6 0.6 0.8 0.9 0.0 0.0 0.1 0.2 50 2009 BLACKSPOT BRUISE SUSCEPTIBILITY TEST SIMULATED BRUISE SAMPLES* ENTRY MST611-1Y MST412-3 CO00188-4W MST008-01 MST190-15Y MST429-3Y MST611-2 MSQ029-1 MST007-2 CO00197-3W MSM246-B MST222-5 MSS297-3 MSS165-2Y MST306-01 MST443-1 MST184-3 MST229-1 MSN111-4PP MSS258-1 MST458-04 MST443-2Y MSS428-2 MST193-4Y MSS934-4 MST220-08 MSS026-2Y MST424-3 Atlantic Snowden MST094-1 NUMBER OF SPOTS PER TUBER 0 21 21 20 20 19 17 17 15 14 17 15 14 16 13 12 13 15 6 9 10 13 12 11 11 13 8 6 9 8 6 7 1 4 3 4 4 5 6 6 8 10 4 7 9 5 9 9 10 5 4 11 10 6 6 7 7 4 10 12 7 8 11 4 2 1 1 1 1 2 2 2 1 3 2 1 3 1 4 2 2 4 3 4 4 4 4 3 4 4 4 4 3 1 3 4 5+ 1 1 1 1 2 1 3 1 1 2 1 2 1 1 2 1 3 3 3 5 3 3 3 4 3 7 1 1 1 3 PRELIMINARY TRIAL, TABLESTOCK LINES MSS199-A MSS514-1PP MST065-2 Reba MSR601-22 MST075-1R MSR297-A 23 23 23 22 22 21 20 2 2 2 3 2 4 5 1 PERCENT (%) BRUISE FREE AVERAGE SPOTS/TUBER 84 84 80 80 76 68 68 60 56 68 60 56 64 52 48 52 60 46 36 40 52 48 44 44 52 32 24 36 32 24 28 92 92 92 88 88 84 80 0.2 0.2 0.2 0.2 0.3 0.4 0.4 0.5 0.5 0.6 0.6 0.6 0.6 0.7 0.7 0.7 0.8 0.8 0.9 0.9 0.9 0.9 1.0 1.0 1.0 1.1 1.2 1.3 1.3 1.4 2.2 0.1 0.1 0.1 0.1 0.2 0.2 0.2 51 2009 BLACKSPOT BRUISE SUSCEPTIBILITY TEST SIMULATED BRUISE SAMPLES* NUMBER OF SPOTS PER TUBER 0 20 20 19 18 18 18 19 17 15 19 17 19 15 15 16 19 13 13 16 13 9 8 13 6 9 9 1 5 4 4 6 6 6 4 7 10 3 6 2 9 9 6 1 10 10 5 8 10 11 6 11 5 5 2 2 1 1 1 1 1 2 2 4 1 1 3 4 2 2 3 3 5 5 1 5 7 4 3 1 1 1 1 1 1 1 3 3 3 4 4 5+ 1 2 1 3 PERCENT (%) BRUISE FREE AVERAGE SPOTS/TUBER 80 80 76 72 72 72 76 68 60 76 68 76 60 60 64 76 52 52 64 52 36 32 52 24 36 36 0.2 0.3 0.3 0.3 0.3 0.3 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.5 0.5 0.6 0.6 0.6 0.7 0.9 1.0 1.1 1.2 1.3 1.6 ENTRY MST359-3 MSS206-2 ATTX961014-1RY MSR601-21 MSS070-B MST285-2 MSS544-1R MST123-1RY Midnight MSS483-1 MST033-2 MST145-1 CO00270-7W MST384-1PP MSR601-19 MST500-1 CO99076-6R MST235-2SPL MST377-2P MST065-1 CO99256-2R CO98012-5R Onaway MSR218-AR MSS487-2 Stirling 52 2009 BLACKSPOT BRUISE SUSCEPTIBILITY TEST SIMULATED BRUISE SAMPLES* NUMBER OF SPOTS PER TUBER 0 1 ENTRY USPB/SFA TRIAL CHECK SAMPLES (Not bruised) CO96141-4W NY138 NY139 ND7519-1 Kalkaska (MSJ036-A) CO97065-7W AF2291-10 W2717-5 Atlantic MSJ126-9Y Snowden CO97043-14W 9 8 7 10 10 13 11 6 8 7 7 7 16 15 16 12 10 8 8 12 8 9 9 7 2 2 1 2 4 3 4 3 6 4 5 6 USPB/SFA TRIAL BRUISE SAMPLES NY138 CO96141-4W Kalkaska (MSJ036-A) CO97065-7W W2717-5 MSJ126-9Y ND7519-1 NY139 Atlantic CO97043-14W AF2291-10 Snowden 17 11 9 13 9 10 6 1 5 4 2 0 5 11 9 3 8 8 5 13 6 6 7 3 1 2 4 4 4 1 8 4 4 7 6 5 3 1 1 1 1 2 3 3 1 4 1 1 2 4 4 4 5 5 5 3 6 8 4 5+ 1 1 2 1 1 1 1 1 2 3 3 6 1 2 1 1 1 1 2 3 2 1 3 PERCENT (%) BRUISE FREE AVERAGE SPOTS/TUBER 64 60 64 48 40 32 32 48 32 36 36 28 68 44 36 52 36 40 24 4 20 16 8 0 0.4 0.5 0.5 0.8 0.8 0.9 1.1 1.1 1.2 1.3 1.3 1.4 0.6 0.7 1.1 1.1 1.1 1.2 1.6 1.8 2.0 2.1 2.2 3.2 * Twenty or twenty-five A-size tuber samples were collected at harvest, held at 50 F at least 12 hours, and placed in a six-sided plywood drum and rotated ten times to produce simulated bruising. Samples were abrasive-peeled and scored 11/2/2009. The table is presented in ascending order of average number of spots per tuber. 53 Funding: Federal Grant, MPIC and USPB/SFA 2009 On-Farm Potato Variety Trials Chris Long, Dr. Dave Douches, Greg Steere, John Pullis (Presque Isle), Dr. Doo-Hong Min and Chris Kapp (Upper Peninsula) Introduction On-farm potato variety trials were conducted with 16 growers in 2009 at a total of 24 locations. Fourteen of the locations evaluated processing entries and ten evaluated fresh market entries. The processing cooperators were Crooks Farms, Inc. (Montcalm), Walther Farms, Inc. (St. Joseph), Lennard Ag. Co. (Monroe), County Line Potato Farms, Inc. (Allegan), Main Farms (Montcalm), Michigan State University (MSU), Montcalm Research Farm (Montcalm), Sackett Potatoes (Mecosta), Sackett Ranch (Montcalm) and Thorlund Brothers (Montcalm). The United States Potato Board/Snack Food Association (USPB / SFA) chip trial was at Sandyland Farms, LLC (Montcalm). Fresh market trial cooperators were Crawford Farms, Inc. (Montcalm), DuRussel’s Potato Farms, Inc. (Washtenaw), Elmaple Farms (Kalkaska), R & E Farms (Presque Isle), Horkey Bros. (Monroe), T.J.J. VanDamme Farms (Delta), Lennard Ag. Co. (St. Joseph), Sandyland Farms, LLC. (Montcalm) and Walther Farms, Inc. (Branch). Procedure There were seven types of processing trials conducted this year. The first type contained 13 entries which were compared with the check varieties Snowden, Pike and FL1879. This trial type was conducted at Main Farms, Lennard Ag. Co. and County Line Farms. Varieties in these trials were planted in 100’ strip plots. Seed spacing was grower dependent, but in general ranged from 9.5 to 11 inches. The second type of processing trial, referred to as a “Select” trial, contained seven lines which were compared to the variety in the field. In these trials, each variety was planted in a 15’ row plot. Seed spacing and row width were 10” and 34”, respectively. These trials were conducted on Crooks Farms, Inc. (Montcalm). The third processing trial format was conducted at Sackett Potatoes in Mecosta County. Two varieties were commercially planted in eight row plots 300 feet long. One 23’ yield dig was performed in each block at harvest. These varieties were planted at a 10” spacing. The fourth type was a four replication processing variety trial conducted at Walther Farms, Inc. (St. Joseph) in which 19 test varieties were compared to the check varieties Snowden, Pike, FL1867 and FL1833. The plots were 15’ by 34” and the seed was planted at 10” in-row spacing. The fifth type was the Box Bin trial at the Montcalm Research Farm in Montcalm County, MI. This trial contained 16 varieties compared against the check variety Snowden. All 17 varieties were planted in 34” wide rows, 600’ long with 10” in-row seed spacing. A single 23’ yield check was taken to evaluate each clone. The sixth type of chip trial contained large multiple acreage blocks of nine newly commercialized or soon to be commercialized varieties. Agronomic and production practices for these varieties were based on each individual grower’s production system. The variety and growers were: Crawford Farms, Inc. (Montcalm), Classic Russet; Horkey Bros. (Monroe), MSQ176-5 and MSM182-1; 54 Sandyland Farms LLC (Montcalm), Classic Russet and MSJ147-1; Sackett Potatoes (Mecosta), Kalkaska, MSJ147-1 and MSQ070-1; Sackett Ranch (Montcalm), CO95051- 7W; Thorlund Brothers (Montcalm), MSJ126-9Y; Elmaple Farms (Kalkaska), MSQ176- 5; R & E Farms (Presque Isle), Classic Russet; T.J.J. VanDamme Farms (Delta), Classic Russet and Lennard Ag. Co. (Monroe), MSH228-6. The USPB / SFA trial was the 7th chip processing trial type. For procedural details on this trial, reference the 2009 annual report published by the United States Potato Board. Within the fresh market trials, there were 38 entries evaluated. There were 8 to 28 lines planted at each of the following locations: Branch, Delta, Kalkaska, Monroe, Montcalm, Presque Isle, St. Joseph and Washtenaw counties. The varieties in each trial ranged from mostly round white varieties to mostly russet varieties. These varieties were generally planted in 100’ strip plots. A single 23’ yield check was taken to evaluate each clone in these strip trials. Seed spacing varied from 8 to 12 inches depending upon grower production practices and variety. At Walther Farms, Inc (Branch), replicated trials were evaluated. The plots were 15’ long by 34” wide and seed spacing was 12”. Four replications were evaluated per trial. The last freshpack trial type was the Russet Select Trial. The select russet trials were planted at three locations (Elmaple Farm (Kalkaska), Montcalm Research Farm (Montcalm) and Walther Farms, (St. Joseph)). Each russet variety was planted in one three row plot, that was thirty feet long with 34” wide row and 11-12” in-row spacing. A yield determination was made on 23 feet of the center row. Each select trial varied in the number of varieties tested. Results A. Processing Variety Trial Results A description of the processing varieties, their pedigree and scab ratings are listed in Table 1. The overall averages of the eight locations from Allegan, Mecosta, Monroe, Montcalm and St. Joseph counties are shown in Table 2. CO00197-3W; is a Colorado State University selection with good long term chip quality. In 2009, CO00197-3W yielded 449 cwt/A US#1 with 14% undersize (Table 2). Seed spacing should be widened for this clone to 11-12” in row spacing. Specific gravity was average to below average at 1.077. Internal quality was good and vine maturity was comparable to Snowden. This variety has susceptibility to common scab. MSL292-A; is a Michigan State University developed variety. In 2009, MSL292-A had an average yield at 429 cwt/A US#1 (Table 2). This variety had 91% marketable yield and a slightly below average specific gravity at 1.077. Raw internal tuber quality was good. A trace of pitted scab was noted. MSL292-A exhibited excellent chip quality out of the field and from storage in 2009 and early 2010. Processing Variety Highlights 55 MSQ070-1; is a MSU clone with common scab and late blight resistance. In 2009 on-farm trials, this variety yielded 429 cwt/A US#1 with a 1.090 specific gravity. There was 19% hollow heart reported across eight trial locations (Table 2). This variety had a vine maturity that was later than Snowden. Tuber type was very uniformly round and chip quality was good from mid to late season storage. This variety appeared to set well and could benefit from a slightly wider in-row seed spacing of 11 inches. MSQ279-1; is a MSU chipping clone with good long term chip quality. In 2009, this variety yielded 453 cwt/A US#1 with 91% of the total yield being marketable. The specific gravity was average (Table 2). The raw tuber quality was good with some late vine maturity reported. The in-row seed spacing could be reduced to 9 inches for this clone based on the large percent of oversize noted. NY139; this is a Cornell, New York developed clone. This variety continues to exhibit a strong yield and good size profile. In the 2009 processing potato variety trials, NY139 yielded 440 cwt/A US#1 over seven locations with a 95% marketable yield average (Table 2). The specific gravity of this clone was at the trial average of 1.080. No hollow heart was noted in 90 cut tubers. NY139 also performed very well in the 2009 USPB/SFA trial (Table 3). This clone yielded 455 cwt/A US#1 with a 99% marketable yield. The specific gravity was six points above the trial average at 1.087. Raw tuber internal quality was good. Vine maturity for this variety appeared to be medium-late to late. W2133-1; this clone was developed at the University of Wisconsin and has excellent mid to late storage season chip quality. It appeared to exhibit variable yield potential, but performed most consistently in environments where the growing season is longer. The variety does appear to have a late vine maturity that could be classified as later than Snowden. In 2009, W2133-1, when averaged across two southern Michigan locations, yielded 567 cwt/A US#1 with no hollow heart being observed (Table 2). The size profile and the specific gravity was at or slightly above average. This variety was susceptible to common scab. The long term storability and yield potential of this clone makes it attractive. B. USPB / SFA Chip Trial Results The Michigan location of the USPB / SFA chip trial was on Sandyland Farms, LLC in Montcalm County in 2009. Table 3 shows the yield, size distribution and specific gravity of the entries when compared with Atlantic and Snowden. Table 4 shows the at harvest raw tuber quality results. Table 5 shows the out of the field chip quality evaluations from samples processed and scored by Herr Foods, Inc., Nottingham, PA and Table 6 provides the blackspot bruise susceptibility of each entry. Table 7 provides a pre-harvest panel for each of the 12 varieties in the trial. This table compares tuber specific gravity, percent glucose and sucrose ratings taken on August 24th, 2009 for each variety. 56 USPB / SFA Chip Trial Highlights Atlantic and Snowden topped the yield chart in 2009 followed by a group of lines that yielded very similarly (Table 3). These lines are: AF2291-10, NY139, CO97043-14W, Kalkaska and NY138. NY139 had a large percentage of recorded oversize tubers (Table 3). The CO97043-14W, NY138, CO96141-4W and MSJ126-9Y had very low specific gravities. The variety in the 2009 trial that displayed the greatest potential for commercialization was NY139. Yield potential and specific gravity were excellent for NY139 (Table 3). This clone has a full season maturity and good chip quality. NY139 appeared to have some susceptible to black spot bruise (Table 6), but some tolerance to common scab. Table 5 shows some of the other varieties that did not have the highest yield performance, but had great chip quality, such as ND7519-1 and NY138. C. Fresh Market and Variety Trial Results A description of the freshpack varieties, their pedigree and scab ratings are listed in Table 8. Table 9 shows the overall average of ten locations: Branch, Delta, Kalkaska, Monroe, Montcalm (2), Presque Isle, St. Joseph (2) and Washtenaw counties. Fresh Market Variety Highlights Three round whites, one red skin and three russet lines are worthy of mention from the 2009 variety trials. They are MSL268-D, MSM182-1, MSQ176-5 (the round whites), CO99256-2R (the red variety) and the russets, A02062-1TERus, CO99053- 3Rus and Classic Russet (A95109-1). MSL268-D; this Michigan State University variety has nice tuber type with foliar late blight resistance. In 2009, MSL268-D yielded 425 cwt/A US#1 with a medium vine maturity (Table 9). The total yield of this variety was reported as 633 cwt/A. The percentage of “B” sized tubers and the specific gravity was higher than desired. This variety was also common scab susceptible. MSM182-1; this variety has strong PVY and foliar late blight resistance. In the 2009 freshpack variety trials, this clone had a 425cwt/A US#1 yield with a 1.073 specific gravity (Table 9). There were four hollow heart in 50 cut tubers and a trace of vascular discoloration observed. The skin type of this variety was bright and the tubers were very uniform in shape. MSQ176-5; this MSU clone has foliar late blight resistance and some common scab tolerance. The 2009 yield trial data showed this variety having a 427 cwt/A US#1 yield which represents 90% of the total yield reported (Table 9). This variety averaged a 1.071 specific gravity, a medium-late maturity and two hollow heart in fifty tubers cut. The tubers were generally bright skinned and uniformly round in appearance. 57 CO99256-2R; this is a red skinned selection from Colorado State University. In 2009, CO99256-2R yielded 445 cwt/A US#1 with an average specific gravity of 1.077 (Table 9). Vine maturity was medium-late with good internal quality. Tuber appearance was smooth with a very nice red color. Tuber type was round to more oval in the larger tubers. A02062-1TE; this University of Idaho selection had a 444 cwt/A US#1 yield, an average specific gravity of 1.076 and good internal quality (Table 9). The tuber appearance was long and blocky with a nice russeted skin. Vine maturity was medium. This was the most promising new russet selection evaluated in 2009. CO99053-3Rus; this Colorado State selection has good yield potential. In 2009, it yielded 409 cwt/A US#1 with 21 percent oversize. The average specific gravity for this variety was 1.077 (Table 9). The clone had 3 hollow heart in fifty cut tubers. The vine maturity appeared to be late. The tubers exhibited a uniform, medium russet skin. The variety appeared to be common scab tolerant, but exhibited a trace of alligator hide. This russet may be a dual purpose selection. Classic Russet (A95109-1); this clone is a USDA Aberdeen, ID release. It was named in early 2009 as Classic Russet. Over the 9 trial locations where it was tested, A95109-1 yielded 348 cwt/A US#1 with 19 percent oversize (Table 9). In- row seed spacing for this variety should be approximately 9 inches. The average specific gravity for Classic Russet was 1.073 with 10 of 120 cut tubers exhibiting hollow heart. Vine maturity was medium-late with a nice, uniform blocky tuber type. This variety exhibited strong common scab resistance. 58 2009 MSU Processing Potato Variety Trials Characteristics High yield, early maturing, high incidence of internal defects, check variety, high specific gravity Medium – high yield, mid-season maturity, nice round uniform tuber type, warm harvest recommended, medium high specific gravity Average yield, mid – late season maturity, good long term storability, low internal defects, vine rot susceptible, medium specific gravity Average yield, early to mid-season maturity, small size tuber profile, early storage check variety, some internal defects, medium specific gravity High yield, late maturity, late season storage check variety, reconditions well in storage, medium to high specific gravity High U.S. No. 1 yield, scaly buff skin, high High yielding, scaly buff chipper; smaller specific gravity tuber size Early blight resistant clone with good chipping quality, medium-late vine maturity, round to oblong, white netted tubers, specific gravity similar to Atlantic Medium-high yield potential. small tuber size, minimal grade defects, medium-early maturity, high specific gravity, some ability to recondition out of 40F High yield potential, small size profile, minimal grade defects, early maturity, medium-high specific gravity, some ability to recondition out of 40F Medium-high yield potential, minimal grade defects, medium-early maturity, medium- high specific gravity, ability to recondition out of 40F Low – average yield, medium to late maturity, high percent of US#1 tubers, low internal defects, medium specific gravity Average yield, early – mid maturity, oval tuber type, white skin, medium specific gravity Average to high yield, medium maturity, white skin, oblong tuber type, medium specific gravity Average to high yield, early maturity, white skin, round tuber type, medium specific gravity Entry Atlantic Kalkaska (MSJ036-A) Monticello Pike (NYE55-35) Snowden (W855) A00188-3C A01143-3C AF2291-10 CO00188-4W Pedigree Wauseon X B5141-6 (Lenape) A7961-1 X Zarevo Steuben X Kanona Allegany X Atlantic B5141-6 X Wischip A91790-13 X Dakota Pearl COA95070-8 X Chipeta SA8211-6 X EB8109-1 A90490-1W X BC0894-2W CO00197-3W A91790-13W X NDTX4930-5W CO00270-7W CO95051-7W CO96141-4W CO97043-14W CO97065-7W BC0894-2W X A91790-13W AC88456-6W X BC0894-2W BC0894-2 X AC87340-2 AC91817-5 X AC87340-2 AC92513-3 X Chipeta 2009 Scab Rating* 2.7 1.3 - 1.5 2.3 1.3 1.3 - 2.0 3.1 2.8 1.3 2.3 3.0 2.0 Scab rating based on 0-5 scale; 0 = most resistant and 5 = most susceptible. 59 High yield, early maturity, medium-high Characteristics specific gravity High yield, late maturity, large tuber type, late season storage, medium specific gravity, check variety Average yield, mid-season maturity, oval to oblong tubers, common scab and black spot bruise resistant, good chip quality out of late storage, medium to low specific gravity Average yield, mid-season maturity, round to oblong tuber type, good bruise tolerance, fresh or early season storage, highly susceptible to growth crack, medium-high specific gravity Above average yield, medium-late maturity, some scab resistance Average yield, mid-season maturity, blocky flat tuber type, shallow eyes, medium specific gravity Medium – high yield, cold chipper from 45º F, uniform A-size tubers, attractive appearance, good internal quality, long term storage potential, medium specific gravity Average yield, mid to late season maturity, good internal quality, very good chip quality late in storage, specific gravity similar to Snowden Entry FL1867 FL1879 FL1922 FL2053 Pedigree FL162 X Atlantic Snowden X FL1207 FL1533 X FL1207 FL1922 X FL1831 FL2137 FL2006 X FL1291 MSH228-6 MSC127-3 X OP MSJ126-9Y Penta X OP MSJ147-1 MSL007-B MSL292-A MSM037-3 MSN170-A Norvalley X S440 MSA105-1 X MSG227-2 Snowden X MSH098-2 MSE230-6 X ND2676-10 MSI055-5 X MSG227-2 MSP459-5 Marcy X NY121 MSQ070-1 MSQ279-1 MSK061-4 X Missaukee Boulder X Pike MSR061-1 W1201 X NY121 ND7519-1 - 2009 Scab Rating* - 2.0 - 1.8 - 1.3 1.3 1.7 1.0 2.3 1.3 1.3 1.8 1.3 1.4 1.1 - Average yield, early to mid-season maturity, uniform tuber type, medium specific gravity, scab resistant Above average yield, scab susceptible, late blight susceptible, medium-high specific gravity, long storage potential Large uniform blocky tubers, high yield, low specific gravity, some hollow heart Flattened blocky round type, some early bulking, scab resistant Bright chips, low incidence of defects, medium specific gravity Round tuber type, late maturity, scab and late blight resistant, high specific gravity, strong vine and roots High yield, large round tubers, good internal qualities Average yield, round tubers type with netted skin, low sugars, PVY resistant, moderate late blight resistance Below average yield, high specific gravity, small uniform tuber type, medium maturity *Scab rating based on 0-5 scale; 0 = most resistant and 5 = most susceptible 60 Entry NY138 (Y18-16) NY 139 (Y28-9) W2133-1 W2324-1 Pedigree Marcy X NY115 NY120 X NY115 Snowden X RHL 167 Snowden X S438 W2717-5 S440 X ND2828-15 W5015-12 Brodick X W1355-1 2009 Scab Rating* - 1.5 1.8 2.5 - - High yield, mid-late season maturity, medium specific gravity Medium to high yield, mid to late maturity, good internal quality, nice tuber type, 42-45º F cold chipper, medium specific gravity Very high yield, late maturity, uniform tuber type, strong vine vigor, medium to high specific gravity Round tuber type, medium yield, medium maturity, medium specific gravity, moderate scab susceptibility Relative high tuber set and yield, medium- late vine maturity, uniform size tubers, tubers tend toward flat shape, very flat in some environments Characteristics High yield, large uniform round tuber type, below average specific gravity, great chip quality *Scab rating based on 0-5 scale; 0 = most resistant and 5 = most susceptible 61 2009 Processing Potato Variety Trial Overall Average - Eight Locations Allegan, Mecosta, Monroe, Montcalm, St. Joseph Counties CWT/A PERCENT OF TOTAL1 NUMBER OF LOCATIONS 1 1 4 2 2 3 1 7 5 5 2 7 8 7 5 LINE FL2053 FL1867 MSM037-3 W2133-1 W2324-1 FL1879 FL1922 W5015-12 Snowden MSQ279-1 CO00197-3W NY139 MSQ070-1 MSL292-A MSL007-B US#1 TOTAL US#1 Bs 679 600 580 567 552 548 519 487 475 453 449 440 429 429 410 722 635 614 648 589 566 549 558 513 490 529 462 495 465 461 94 94 95 89 93 97 94 85 91 91 82 95 86 91 87 4 5 3 9 6 2 5 14 9 6 14 5 13 9 13 As 91 93 78 79 83 79 94 75 86 72 82 89 83 85 85 OV PO TUBER QUALITY2 SP GR SCORE3 HH VD IBS BC CHIP TOTAL CUT VINE VIGOR4 MATURITY5 VINE 3 1 17 10 10 18 0 10 4 19 0 6 3 6 2 2 1 2 2 1 1 1 1 1 3 4 0 1 0 0 1.088 1.079 1.070 1.081 1.089 1.074 1.072 1.085 1.082 1.077 1.077 1.080 1.090 1.077 1.080 1.0 1.0 1.3 1.0 1.0 1.2 1.0 1.0 1.1 1.4 1.0 1.0 1.1 1.1 1.1 0 0 4 0 4 1 0 8 4 2 0 0 19 1 0 0 0 1 2 2 1 2 6 11 3 4 8 4 6 3 0 0 0 1 0 6 1 3 0 0 0 0 4 5 0 0 0 1 0 2 1 0 0 0 0 0 0 2 2 0 30 30 60 30 20 50 30 90 70 70 40 90 100 90 70 2.5 2.5 3.6 3.6 3.8 3.2 1.8 3.3 3.3 3.4 2.3 3.5 2.9 3.7 2.6 3.7 2.7 3.8 4.2 3.3 3.1 3.8 4.0 3.5 4.6 3.5 3.1 4.2 3.0 3.6 COMMENTS tr pitted scab, oblong 3-YR AVG US#1 CWT/A 445 tr pitted scab, sheepnose in pickouts 514** large uniform blocky tubers, misshapen pickouts, gc & misshapen pickouts, 580* gc & misshapen pickouts, sl pitted scab 488** large size, tr pitted scab, misshapen pickouts tr surface & pitted scab, large tuber size, misshapen in pickouts oblong tuber type, gc in pickouts, pear shape heavy russet skin, gc & misshapen pickouts, tr pitted & surface scab sl pitted & surface scab, misshapen pickouts gc & sheepnose in pickouts, tr surface scab gc & misshapen in pickouts, sl pitted scab, 1 pythium leak tr surface scab, some pear shape, gc in pickouts round uniform tuber type, tr surface & pitted scab, misshapen pickouts round uniform type, some netting, sl pitted scab nice uniform type, misshapen pickouts, some netting & russeting 575 471 519* 487* 416 453* 449* 429** 429* 433** 330** 62 NUMBER OF LOCATIONS 4 1 5 2 5 2 4 5 4 2 5 3 1 1 LINE Pike Monticello MSH228-6 FL2137 MSN170-A CO00188-4W MSJ147-1 MSJ126-9Y CO95051-7W CO00270-7W MSP459-5 MSR061-1 AO0188-3C AO1143-3C 409 409 407 393 388 354 346 333 331 325 311 279 228 225 440 433 431 410 426 434 432 372 370 375 379 334 302 297 473 4 6 5 5 4 30 16 9 9 12 19 18 24 21 93 94 94 95 91 70 79 88 90 86 80 82 76 76 88 MEAN 426 CWT/A PERCENT OF TOTAL1 US#1 TOTAL US#1 Bs As 82 88 85 84 78 70 78 86 90 85 77 81 74 74 OV 11 6 9 11 13 0 1 2 0 1 3 1 2 2 TUBER QUALITY2 SP GR SCORE3 HH VD IBS BC CHIP TOTAL CUT VINE VIGOR4 MATURITY5 VINE PO 1.0 1.0 1.0 1.0 1.1 1.0 1.1 1.2 1.0 1.0 1.1 1.0 1.0 1.0 4 3 1 0 1 0 12 0 0 0 6 2 2 0 2 1 6 2 0 0 0 6 1 2 2 3 1 0 2 0 1 0 0 2 0 1 3 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 5 0 60 10 70 20 70 40 60 70 60 40 70 30 10 10 3.2 1.5 3.5 2.0 3.0 2.8 2.3 2.6 3.2 2.1 3.6 3.2 2.5 2.0 3.3 2.0 4.4 2.5 2.7 2.2 4.3 2.4 4.1 2.6 2.0 2.5 3.5 4.5 3 0 1 0 5 0 2 3 1 2 1 0 0 3 1.082 1.073 1.079 1.083 1.077 1.081 1.090 1.076 1.081 1.074 1.075 1.079 1.082 1.078 1.080 3-YR AVG US#1 CWT/A 370 384** 348 456** 388* 354* 307 350 303 325* 311* 279* 228* 225* COMMENTS gc & misshapen pickouts, 3 with heat necrosis tr surface and pitted scab flat, oval tuber type, tr surface scab, nice uniform type, tr surface scab gc, misshapen, knobs & points in pickouts, oval to oblong type small bright appearance, tr black leg, tr surface scab small, round uniform type, tr surface scab nice round uniform type, gc & misshapen pickouts sl surface & pitted scab, small round size tr pitted scab, misshapen pickouts, small size misshapen & deep apical eyes in pickouts, 3 pythium nice small round uniform type, some netting misshapen in pickouts tr = trace, sl = slight, N/A = not applicable SED = stem end defect, gc = growth crack 1SIZE Bs: < 1 7/8" 2TUBER QUALITY (number of tubers per total cut) 3CHIP COLOR SCORE - Snack Food Association Scale HH: Hollow Heart (Out of the field) 4VINE VIGOR RATING Date Taken: N/A As: 1 7/8" - 3.25" VD: Vascular Discoloration OV: > 3.25" IBS: Internal Brown Spot PO: Pickouts BC: Brown Center Ratings: 1 - 5 1: Excellent 5: Poor Ratings: 1 - 5 1: Slow Emergence 5: Early Emergence (vigorous vine, some flowering) 5VINE MATURITY RATING Date Taken: N/A Ratings: 1 - 5 1: Early (vines completely dead) 5: Late (vigorous vine, some flowering) *One-Year Average * *Two-Year Average 63 Table 3. Yield ,Size Distribution*, Specific Gravity Yield (cwt/A) Percent Size Distribution 523 512 480 462 472 486 458 444 420 414 395 370 453 TOTAL US#1 Small Mid-Size Large US#1 498 488 466 455 455 454 444 423 404 387 361 342 432 Entry Atlantic Snowden AF2291-10 NY139 CO97043-14W Kalkaska NY138 CO96141-4W CO97065-7W ND7519-1 W2717-5 MSJ126-9Y 96 95 97 99 96 93 97 96 96 93 91 92 95 *small <1 7/8"; mid-size 1 7/8"-3 1/4"; large >3 1/4" Table 4. At-Harvest Tuber Quality. Sandyland Farms, Howard City, Michigan. 16 6 11 26 11 4 19 13 15 3 9 11 12 80 89 86 73 85 89 78 83 81 90 82 81 83 2 5 3 1 3 6 3 3 3 5 4 3 3 MEAN Specific Culls Gravity 1.087 1.088 1.089 1.087 1.073 1.082 1.073 1.070 1.078 1.092 1.085 1.071 1.081 2 0 0 0 1 1 0 1 1 2 5 5 1.5 Internal Defects1 Total Cut Entry Atlantic Snowden AF2291-10 NY139 CO97043-14W Kalkaska NY138 CO96141-4W CO97065-7W ND7519-1 W2717-5 MSJ126-9Y 30 30 30 30 30 30 30 30 30 30 30 30 1Internal Defects. HH = hollow heart, VD = vascular discoloration, IBS = internal brown spot, BC = brown center. IBS 0 0 0 3 0 0 0 0 0 0 0 0 BC 1 0 0 0 0 2 0 0 6 0 9 0 HH 11 1 0 0 0 0 0 1 1 1 7 2 VD 0 7 7 4 5 5 0 3 0 2 3 11 64 Table 5. 2009 Post-Harvest Chip Quality1. Entry Atlantic Snowden AF2291-10 NY139 CO97043-14W Kalkaska NY138 CO96141-4W CO97065-7W ND7519-1 W2717-5 MSJ126-9Y Agtron Color 58.6 61.5 58.5 61.5 62.7 58.1 63.1 63.5 58.5 61.5 60.6 60.1 SFA2 Specific Color Gravity 1.077 1.081 1.085 1.079 1.079 1.076 1.068 1.073 1.078 1.079 1.081 1.068 3 2 2 1 2 4 1 2 2 1 3 4 Internal External Percent Chip Defects3 Total 26.3 14.0 15.0 12.4 19.8 27.2 12.0 14.9 18.8 9.7 15.6 11.6 23.6 7.3 13.0 3.3 15.4 26.2 8.5 10.0 12.7 1.4 8.1 8.7 2.7 6.7 2.0 9.1 4.4 1.0 3.5 4.9 6.1 8.3 7.5 2.9 1 Samples collected at harvest September 29th and processed by Herr Foods, Inc., Nottingham, PA on October 1, 2009 (2 days). Chip defects are included in Agtron and SFA samples. 2 SFA Color: 1 = lightest, 5 = darkest 3 Percent Chip Defects are a percentage by weight of the total sample; comprised of undesirable color, greening, internal defects and external defects. Table 6. Black Spot Bruise Test A. Check Samples1 B. Simulated Bruise Samples2 Entry Atlantic Snowden AF2291-10 NY139 CO97043-14W Kalkaska NY138 CO96141-4W CO97065-7W ND7519-1 W2717-5 MSJ126-9Y 7 6 4 1 8 6 3 7 5 1 2 1 1 Total # of Bruises Per Tuber 0 1 2 3 4 5 Tubers 8 9 8 11 4 1 16 7 1 1 7 10 10 4 1 15 8 2 16 9 8 13 3 1 12 10 2 12 6 3 2 9 1 2 7 4 3 1 1 25 25 25 25 25 25 25 25 25 25 25 25 Percent Average Bruise Bruises Per Free 32 36 32 64 28 40 60 64 32 48 48 36 Tuber 1.16 1.32 1.08 0.48 1.40 0.84 0.48 0.36 0.88 0.76 1.12 1.32 6 4 5 3 2 3 5 8 3 6 7 6 6 1 3 Total # of Bruises Per Tuber 0 1 2 3 4 5 Tubers 5 0 2 1 13 4 5 2 4 9 17 5 1 1 11 11 2 1 13 3 4 4 6 9 10 8 1 4 1 1 25 25 25 25 25 25 25 25 25 25 25 25 6 7 3 2 3 9 4 2 1 5 8 5 1 8 4 4 1 1 Tuber Percent Average Bruise Bruises Per Free 20 0 8 4 16 36 68 44 52 24 36 40 2.0 3.2 2.2 1.8 2.1 1.1 0.6 0.7 1.1 1.6 1.1 1.2 1Tuber samples collected at harvest and held at room temperature for later abrasive peeling and scoring. 2Tuber samples collected at harvest, held at 50ºF for at least 12 hours, then placed in a 6 sided plywood drum and rotated 10 times to produce simulated bruising. They were then held at room temperature for later abrasive peeling and scoring. 65 Table 7. Pre-Harvest Panels, 08/24/09 Average5 Entry Atlantic Snowden AF2291-10 NY139 CO97043-14W Kalkaska NY138 CO96141-4W CO97065-7W ND7519-1 W2717-5 MSJ126-9Y Canopy Number of Specific Glucose1 Sucrose2 Gravity 1.080 1.084 1.086 1.079 1.076 1.077 1.068 1.071 1.078 1.091 1.082 1.067 Tuber Rating Rating3 Uniform.4 Hills Stems Weight 5.50 0.381 4.56 0.391 5.92 0.748 6.01 0.613 0.559 5.62 4.41 1.892 7.60 0.598 5.23 0.202 4.61 0.454 0.686 4.26 4.31 0.735 0.716 5.42 90 95 95 90 90 80 90 90 80 50 90 90 % 0.001 0.002 0.005 0.003 0.005 0.015 0.003 0.001 0.002 0.002 0.004 0.002 85 90 90 90 80 60 90 80 65 75 70 60 3 5 5 4 4 4 5 5 5 3 4 6 17 21 16 11 15 7 10 14 23 15 10 15 1Percent Glucose is the percent of glucose by weight in a given amount of fresh tuber tissue. 2Sucrose Rating is the percent of sucrose by weight in a given amount of fresh tuber tissue X10. 3 The Canopy Rating is a percent rating of green foliage (0 is all brown, dead foliage, 100 is green, vigorous foliage). 4 The Canopy Uniformity is a percentage of how uniform the foliage health is at the date of observation. 5 The Average Tuber Weight is the total tuber weight collected, divided by the number of tubers reported in ounces. 66 2009 MSU Tablestock Potato Variety Trials Characteristics Average yield, oblong blocky russet, medium to late maturity, good tuber dormancy, above average specific gravity, tolerant to pythium leak and pink rot Above average yield, early to mid-season maturity, tubers are white flesh, long to slightly oblong, medium to heavy russetted skin, eyes are shallow, numerous and well distributed tuber set, medium specific gravity Below average yield, medium maturity, attractive appearance, fresh market use, low-medium specific gravity, storability concerns regarding soft rot susceptibility High yield, early maturity, yellow flesh Mid-season maturity, above average yield, round to oval appearance, resistant to PVX and PVY variety variety dormancy Entry Pedigree 2009 Scab Rating Canela Russet A83043-12 X A8784-3 0.7 CORN 8 Classic Russet Russet Norkotah Line Selection Blazer Russet X Summit Russet Elfe L 176/89/233 X Filea Eva (NY103) Goldrush (ND1538-1Rus) Katahdin (USDA 42667) Milva Onaway Reba (NY 87) Stuben X OP ND450-3Rus X Lemhi Russet USDA 40568 X USDA 24642 Beltsville 606-37 X McIntosh USDA X96-56 X Katahdin Monona X Allegany 1.0 1.3 - 3.0 1.0 1.0 - 1.6 2.0 Red Norland ND626 X Redkote - Russet Norkotah (ND534-4Rus) ND9526-4Rus X ND9687-5Rus 2.0 Satina Puntila X 99 73 - Long to oval tubers, heavy russet, check Mid-season maturity, high yielding check Very high yield, medium to late maturity, oblong tuber type, , scab resistant, late High yield, early maturity, round tuber type, low specific gravity, smooth skin, white flesh, eyes medium – deep, few internal defects, check variety High yield, bright tubers, low incidence of internal defects, mid to late season maturity, medium – low specific gravity Smooth to round medium oblong, deep red almost burgundy skin, white flesh. Early to very early maturity for tablestock, medium yield, low to very low specific gravity, resistant to: leaf roll, net necrosis, growth cracks, hollow heart, early blight, scab, PVA, PVY, rhizoctonia. Susceptible to greening, water damage, silver scurf and late blight, stores well – short dormancy, color tends to fade in storage. Average yield, mid-season maturity, long to oval tubers, heavy russet skin, check variety, low specific gravity High yield, medium maturity, short oval tubers, smooth yellow skin, yellow flesh color, long storage capabilities and when cooked or peeled has a high resistance to discoloration, scab resistant *Scab rating based on 0-5 scale; 0 = most resistant and 5 = most susceptible. 67 Characteristics High yield, oblong to long blocky tuber type, medium russet skin, masks PVY, medium specific gravity, possible Sencor & linuron susceptibility Long tuber type, medium-heavy russeting, higher U.S. No. 1 yields and larger tuber size than Russet Norkotah High yield, medium maturity, high specific gravity, oblong, dual purpose russet, large vine, blackspot resistant, late blight resistance High total & U.S. No. 1 yield, large tuber size, light – medium russeting scab & blackspot susceptibility, cold sweetening resistant High yield, mid-late maturity, oblong to long russetted tubers, generally nice appearance Good market yield, medium maturity, resistant to black spot bruise, little internal defects, good size profile, medium yield potential, dual purpose russet, medium specific gravity, good processing from storage, possible Sencor & Linuron Good appearance, small size, low specific gravity, possible Sencor & Linuron susceptibility susceptibility High yield, medium late maturity, large vine, medium specific gravity, long russet, dual purpose, blackspot resistant Medium yield, early maturity, medium sized vine, medium specific gravity, long russet, dual purpose, blackspot resistant Average yield, early maturing, nice round red type Medium high yield, very early-early maturity, small-medium sized vine, medium specific gravity, oblong russet, dual purpose, blackspot resistant Medium maturity, round red Entry Pedigree Silverton Russet (AC83064-6) A76147-2 X A 7875-5 2009 Scab Rating 1.3 A02062-1TERus A97201-4 X A97299-1 1.5 AC99375-1Rus AWN86514-2 X A89384-10 1.3 A01025-4Rus AOTX95265-4Rus A96095-3 X Premier Russet A89216-9 X A86102-6 CO95086-8Rus CO87009-4Rus X Silverton Russet CO98012-5R CO99053-3Rus CO99053-4Rus CO99076-6R CO99100-1Rus CO99256-2R MSL268-D MSM171-A MSM182-1 MSN105-1 A79543—4R X AC91844-2 AC91014-2 X Silverton Russet AC91014-2 X Silverton Russet AC91848-1 X Rio Colorado AC93047-1 X Silverton Russet Rio Colorado X Colorado Rose NY103 X Jacqueline Lee Stirling X MSE221-1 Stirling X NY121 MSG141-3 X Jacqueline Lee 1.0 1.3 - 1.8 1.5 1.5 2.5 1.3 1.8 2.5 2.3 2.9 2.0 Medium yield, late blight resistance, round to oval tuber type High yield, late maturity, smooth shape, large round tuber type, superior skin type, late blight resistant, low specific gravity PVY & late blight resistance, low specific gravity Average yield, early maturity, large heavy set tuber type, bright skin, medium specific gravity, moderate late blight resistance *Scab rating based on 0-5 scale; 0 = most resistant and 5 = most susceptible. 68 Entry Pedigree MSQ086-3 MSQ176-5 Onaway X Missaukee (MSJ461-1) MSI152-A X Missaukee (MSJ461-1) 2009 Scab Rating 2.5 1.8 ND5002-3R ND3504-3R X NorDonna 0.3 PA03NM5-1Rus TX112 TX278 TX296 W5767-1R W7098-2Rus Blazer Russet X PA98NM21-14 Russet Norkotah Line Selection Russet Norkotah Line Selection Russet Norkotah Line Selection MN96101-1 X MN86105 A7961-1 X Goldrush 1.0 1.0 1.0 1.0 - 1.3 Characteristics Good yield potential, nice round white, medium maturity, late blight resistance, good internal quality High yield potential, round, bright white skin, late blight resistance, good bulking, nice round type Medium yield, medium late maturity, bright red skin, very white flesh, round to oblong, block tuber, low internal defects, low specific gravity, scab tolerant, susceptible to PVY and silver scurf, sensitivity to metribuzin applications Oblong-long tuber type, medium russeting, some growth cracks, possible corky ringspot / Columbia root-knot nematode resistance Similar to CORN 8 Similar to CORN 8 Similar to CORN 8 Dark red skin, white flesh, large tuber size, good yield potential, relatively deep eyes, very large canopy, medium-late vine maturity *Scab rating based on 0-5 scale; 0 = most resistant and 5 = most susceptible. Medium yield, blocky tuber type, tendency to produce off-shape tubers, golden russeting, very scab resistant, very large canopy, late vine maturity, low specific gravity 69 Branch, Delta, Kalkaska, Monroe, Montcalm, Presque Isle, St. Joseph & Washtenaw Counties 2009 Freshpack Potato Variety Trial Overall Averages - Ten Locations NUMBER OF LOCATIONS 1 2 1 1 6 1 6 5 5 3 2 2 5 5 5 3 2 1 2 LINE TX296 TX278 TX112 CO95086-8Rus CORN 8 Elfe Silverton Russet MSM171-A Reba CO99256-2R AO2062-1TERus Katahdin MSQ176-5 MSL268-D MSM182-1 W5767-1R CO99053-3Rus Satina AO1025-4Rus CWT/A US#1 TOTAL 632 598 582 556 480 478 459 452 450 445 444 432 427 425 425 418 409 387 376 757 713 707 654 568 304 541 484 477 525 559 457 474 633 498 465 557 463 565 US#1 PERCENT OF TOTAL1 Bs OV As PO SP GR 83 83 82 85 80 82 84 94 94 84 79 95 90 74 84 90 72 83 66 12 10 11 11 12 2 11 3 5 15 15 4 8 23 12 6 21 4 26 49 47 49 61 64 60 59 76 71 84 62 73 72 70 82 68 51 73 58 34 36 33 24 16 22 26 18 23 0 17 22 18 4 2 22 21 10 8 5 7 7 4 8 1.058 1.069 1.060 N/A 1.072 16 1.058 5 3 1 1 6 1 2 3 4 4 7 13 8 1.072 1.058 1.070 1.077 1.076 1.063 1.071 1.079 1.073 1.079 1.077 1.065 1.071 HH 11 25 14 8 20 0 6 8 3 0 0 0 2 2 4 3 3 0 0 TUBER QUALITY2 VD IBS TOTAL CUT VINE VIGOR3 MATURITY4 VINE BC 4 6 3 2 7 0 7 6 3 4 3 2 3 4 1 0 7 0 1 0 0 1 0 0 0 0 3 2 1 0 3 0 1 6 0 0 0 0 1 0 0 0 0 0 0 0 2 0 0 0 1 0 0 2 0 1 0 40 50 40 40 90 10 90 50 50 30 20 20 50 50 50 30 50 10 20 4.0 3.9 4.4 4.6 4.2 4.0 4.1 3.5 4.0 3.7 3.3 3.3 2.6 3.8 3.7 4.2 3.9 5.0 3.8 3.0 3.6 3.0 3.0 2.6 3.5 3.5 1.8 2.9 3.8 3.3 3.5 3.3 2.7 3.0 3.0 4.2 3.5 2.8 COMMENTS alligator hide, misshapen and knobs in pickouts, sl pitted scab gc and misshapen in pickouts, tr pitted and surface scab, some alligator hide sl pitted scab, knobs in pickouts dark heavy russeting, nice type, gc and knobs in pickouts nice tuber type, misshapen & knobs in pickouts, gc, misshapen & knobs in pickouts, uniform oval tuber type some netting, gc & misshapen in pickouts, sl pitted scab tr pitted & surface scab, misshapen pickouts nice oval tuber type, bright smooth skin, tr surface scab, gc & knobs in pickouts nice size and type, heavy russet skinknobs in pickouts, no scab moderate scab, large tuber type sl to moderate surface scab, bright skin, some netting, knobs in pickouts nice tuber type, misshapen, knobs & gc in pickouts smooth skin, uniform round type, some moderate pitted & surface scab, knobs in pickouts gc, misshapen & knobs in pickouts, tr surface scab good size profile, dark heavy russeting, gc, misshapen & knobs in pickouts significant tuber rot light russeting, moderate surface scab, not uniform type 3-YR AVG US#1 CWT/A 514** 598* 473** 417 388 478* 382 420 422 445* 444* 420 427* 382 428** 418* 466** 387* 376* 70 CWT/A US#1 TOTAL 367 367 361 357 348 347 346 339 327 316 313 312 311 306 304 294 248 240 223 392 486 568 428 458 448 494 464 427 489 456 355 436 400 379 340 481 355 285 294 485 US#1 PERCENT OF TOTAL1 Bs OV As 76 65 83 78 78 70 73 79 66 69 88 70 79 80 89 59 70 84 78 18 21 14 20 11 4 20 18 27 26 10 28 13 19 10 35 26 2 17 61 48 83 76 59 60 60 77 43 60 81 63 54 78 88 50 70 45 70 15 17 0 2 19 10 13 2 23 9 7 7 25 2 1 9 0 39 8 PO 6 14 3 2 11 26 7 3 8 5 2 2 8 1 1 6 4 14 5 NUMBER OF LOCATIONS 9 2 2 3 9 1 2 5 2 2 2 2 8 5 1 2 1 1 3 LINE Russet Norkotah GoldRush Red Norland CO98012-5R Classic Russet Milva CO99100-1Rus MSN105-1 W7098-2Rus CO99053-4Rus ND5002-3R PA03NM5-1Rus Canela Russet MSQ086-3 Onaway AC99375-1Rus AOTX95265-4Rus Eva CO99076-6R MEAN 1SIZE Bs: < 1 7/8" or < 4 oz. SP GR 1.071 HH 15 1.069 1.057 1.077 1 0 0 7 1 3 3 1.073 10 17 1.062 1.073 1.081 1.065 0 8 0 0 1.074 10 1.078 1.075 0 1 1.086 14 1.076 1.064 0 0 1.083 18 0 0 1 1.074 1.067 1.077 1.071 0 4 5 0 0 9 1 7 3 4 4 0 0 2 2TUBER QUALITY (number of tubers per total cut) HH: Hollow Heart 3VINE VIGOR RATING Date Taken: N/A As: 1 7/8" - 3.25" or 4 - 10 oz. VD: Vascular Discoloration Ratings: 1 - 5 OV: > 3.25" or > 10 oz. IBS: Internal Brown Spot 1: Slow Emergence PO: Pickouts BC: Brown Center 5: Early Emergence (vigorous vine, some flowering) TUBER QUALITY2 VD IBS TOTAL CUT VINE VIGOR3 MATURITY4 VINE BC COMMENTS uniform type, gc, knobs & misshapen in pickouts,some moderate pitted & surface scab round tuber type, small size, gc & misshapen pickouts gc, knobs & misshapen in pickouts, light red skin color small tuber type, bright red smooth skin, thin skinned nice flesh, misshapen & knobs in pickouts, nice size & tuber type severe points 3-YR AVG US#1 CWT/A 344 407** 361* 318** 367 347* sl pitted & surface scab, gc & misshapen pickouts 354** not uniform tuber type, small, misshapen & gc in pickouts gc & knobs in pickouts, not enough russeting dark heavy russeting, gc, misshapen points and knobs in pickouts, sl pitted scab gc, knobs and misshapen pickouts, bright red skin color, oval tuber type sl surface and pitted scab, misshapen pickouts nice type, misshapen & knobs in pickouts, some alligator hide tr surface scab tr surface scab, misshapen pickouts small size, misshapen pickouts misshapen pickouts, one glassy end misshapen nice flesh and skin color, gc & knobs in pickouts tr = trace, sl = slight, N/A = not applicable SED = stem end defect, gc = growth crack 324 327* 387** 217** 312* 330 306* 359 347** 406 255** 223* *One-Year Average * *Two-Year Average 2.0 2.8 2.0 2.8 3.3 4.5 1.8 2.5 2.8 2.1 3.8 3.8 3.8 3.7 1.0 4.4 2.0 3.5 3.0 3 0 0 0 6 0 0 0 0 2 0 0 1 1 0 2 0 0 0 0 0 0 0 1 0 0 1 0 5 0 0 0 2 0 1 0 1 2 120 20 20 30 120 10 50 50 20 50 20 20 110 50 10 50 10 10 30 4.1 4.0 4.5 3.8 3.6 5.0 4.8 4.4 3.5 4.4 3.3 3.8 3.0 3.6 5.0 4.5 4.5 3.0 3.2 4MATURITY RATING Date Taken: N/A Ratings: 1 - 5 1: Early (vines completely dead) 5: Late (vigorous vine, some flowering) 71 Funded by MPIC Tolerance of Potato Mini-tubers to PRE and POST Herbicide Applications. Calvin F. Glaspie, Wesley J. Everman, Chris Long and Andrew J. Chomas, Department of Crop and Soil Sciences Michigan State University, East Lansing MI 48824. Demand for disease free potato seed in Michigan is high due to a large economic return upon planting disease and virus free seed potatoes. Using aseptically grown plants produced from issue culture, potato mini-tubers can be planted as a clean seed source. However, many generally accepted cultural practices for managing mini-tubers are adopted from cut seed piece, including weed management programs. Field trials were conducted at the Montcalm Research Farm in 2009 to evaluate the effect of labeled herbicide programs on three cultivars of potato mini-tubers. Potato cultivars Atlantic, Frito Lay (FL) 1867 and FL 1922 were planted in 34-inch rows, 2.5 inches deep at 8 inch spacing and hilled at planting. Fifteen herbicide treatments were arranged in a strip plot design with four replications. Treatments included, S-metolachlor at 1.27 lb ai/A, pendimethalin at 0.71 lb ai/A, metribuzin at 0.5 lb ai/A, linuron at 0.5 lb ai/A, rimsulfuron at .023 lb ai/A, dimethenamid at 0.66 lb ai/A, imazosulfuron at 0.4 lb ai/A, linuron at 0.5 lb ai/A plus S-metolachlor at 1.27 lb ai/A, linuron at 0.5 lb ai/A plus S-metolachlor at 1.27 lb ai/A plus metribuzin at 0.09 lb ai/A, metribuzin at 0.09 lb ai/A plus S-metolachlor at 1.27 lb ai/A plus pendimethalin at 0.24 lb ai/A, metribuzin at 0.09 lb ai/A plus S-metolachlor at 1.27 lb ai/A plus pendimethalin at 0.24 lb ai/A plus glyphosate at 0.77 lb ai/A plus ammonium sulfate at 3.4 lb/A, linuron at 0.5 lb ai/A plus S-metolachlor at 1.27 lb ai/A followed by rimsulfuron at 0.016 lb ai/A plus non-ionic surfactant at 0.05 gal/A, linuron at 0.5 lb ai/A plus S-metolachlor at 1.27 lb ai/A followed by rimsulfuron at 0.016 lb ai/A plus metribuzin at 0.25 lb ai/A plus non-ionic surfactant at 0.05 gal/A, KIH-485 at 1.26 lb ai/A and a non-treated control. Production practices were similar to those used in commercial seed production in Michigan, with plots maintained weed free by hand. Visual injury was rated throughout the season on a 0-100% scale and yield data was collected at the end of the season for tuber count and tuber defects. Treatments displaying visual injury in both cultivars contained S-metolachlor, pendimethalin, and dimethenamid. Treatments that caused yield reductions in all cultivars were V-10142. Several herbicide treatments appear to have sufficient crop safety to be used in mini-tuber production including metribuzin, and rimsulfuron. Treatments of imazosulfuron and KIH-485 can reduce seed potato yields. Treatment combinations with S-metolachlor showed early season injury and yield reductions. 72 Funded by AgChem Industry Weed Control in Potato with Reflex. Wesley J. Everman and Andrew J. Chomas. Department of Crop and Soil Sciences, Michigan State University, East Lansing, MI 48824. Interest in alternative herbicides for weed control has led several companies to investigate potato tolerance to herbicides labeled in other row crops. A study was conducted at Montcalm Research Farm to investigate the tolerance of potatoes to fomesafen (Reflex). The studies consisted of 12 treatments arranged in a randomized complete block design with four replications at MRF and three at Stockbridge. The treatments consisted of PRE applications of Reflex at 1 pt/A, Reflex at 2 pt/A, Dual Magnum at 1 pt/A, Reflex at 1 pt plus Dual Magnum at 1 pt, Boundary at 1.5 pt/A, Boundary at 1.5 pt plus Reflex at 1 pt, Boundary at 1.5 pt plus Reflex at 0.5 pt, Dual Magnum at 1 pt plus Sencor at 4 oz/A, Dual Magnum at 1 pt plus Matrix at 1 oz/A and at cracking applications of Reflex at 2 pt and Boundary at 1.5 pt plus Reflex at 1 pt. A non-treated control plot was included for comparison. Timing of application was not a major factor in weed control in 2009. Reflex has postemergence activity on many weed species; however, common lambsquarters control is often reduced when Reflex was applied as a delayed preemergence application (at cracking). Overall weed control in 2009 was excellent. Control of common lambsquarters control was enhanced when Boundary was added in combination with Reflex. It will be important to include a herbicide that provides postemergence control of common lambsquarters if Reflex is used as a delayed preemergence application in most years. Potato tolerance was excellent, with minimal injury observed most likely due to the cool wet weather we experienced. 73 68 F 5 2 B B CRACK 40 65 F 73 MSU Weed Science Research Program WEED CONTROL IN POTATO WITH REFLEX, 2009 Trial ID: PO209 Study Dir.: Andy Chomas Conducted: MONTCALM RSH FARM Investigator: Christy Sprague Date Planted: 5/11/09 Row Spacing: 34 IN Variety: SNOWDEN No. of Reps: 4 Population: 1/FT % OM: 2.7 Soil Type: Loamy Sand pH: 5.6 Plot Size: 10 X 20 FT Design: RANDOMIZED COMPLETE BLOCK Tillage: Spring Disc 3X. Spring Chisel. Field Cultivated. Fertilizer: 20 gal/A of 19-17-0, 12 gal/A of 10-34-0 in Row. 23 gal/A of 28% N at Cultivation. 23 gal/A of 28%N at Hilling. 100 lbs/A of 46-0-0 Broadcast. Application Description A PRE Application Timing: 5/11/09 5/29/09 Date Treated: 5:00 PM 10:30 AM Time Treated: 80 % Cloud Cover: 61 F Air Temp., Unit: % Relative Humidity: 30 Wind Speed/Unit/Dir: 6 mph SW 2 mph W Soil Temp., Unit: Soil/Leaf Surface M: Soil Moist (1=w 5=d): 5 Crop Stage at Each Application Crop Name: SOLTU SOLTU Stage (L): CRACK Weed Stage at Each Application Weed 1 Name: ANGR ANGR Height (In.): Stage (L): Weed 2 Name: CHEAL CHEAL Height (In.): Stage (L): Weed 3 Name: AMARE AMARE Height (In.): Stage (L): Weed 4 Name: ABUTH ABUTH Height (In.): Stage (L): Weed 5 Name: ECHCG ECHCG Weed 6 Name: MELAL MELAL Weed Density (plants/sq. ft.) Date: 5/29/09 Weed Name: Density: Date: 5/29/09 CHEAL Weed Name: Density: 6 Date: 5/29/09 AMARE Weed Name: Density: <1 Date: 5/29/09 ABUTH Weed Name: Density: <1 Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B MPH Type Size Height Spacing Width GPA Carrier PSI 30 3.5 FF 3.5 FF 30 120" 20 H2O 120" 20 H2O 8003 18" 8003 18" B .25 1 .25-1(.5) Cot-2(1) .25-5(.3) Cot-2(1) .25 Cot Type BKPK BKPK A A 1 ANGR 2 20" 20" 74 0 0 0 0 Reflex 100 100 Reflex 100 100 Reflex 2 2 1 2 L L 86 95 0 0 0 pt/a PRE pt/a PRE Rate Grow Non-Treated ANGR control MSU Weed Science Research Program Form Form Conc Type Rate Unit Stg WEED CONTROL IN POTATO WITH REFLEX, 2009 Trial ID: PO209 Study Dir.: Andy Chomas Conducted: MONTCALM RSH FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 2 3 4 Dual Magnum 7.62 L 5 L 5 Dual Magnum 7.62 L 6 7 7 8 8 9 Dual Magnum 7.62 L 9 10 Dual Magnum 7.62 L 10 Matrix 11 Reflex 12 Boundary 12 Reflex LSD (P=.05) Standard Deviation CV 1.5 pt/a CRACK 4 1 pt/a CRACK 1.5 pt/a PRE 0.5 pt/a PRE 1.5 pt/a PRE 1 pt/a PRE 1 25 WG 1 4.9 3.4 297.65 pt/a PRE oz/a PRE pt/a PRE oz/a PRE pt/a PRE pt/a PRE Boundary Reflex Boundary Reflex 18.8 13.0 15.94 26.1 18.0 21.58 1.5 pt/a PRE pt/a CRACK 6 11.8 8.2 9.11 4.3 3.0 3.29 pt/a PRE Boundary 6.5 2 0 0 6.5 2 6.5 2 Sencor 0 0 1 1 1 0 3 6.5 EC 74 96 75 91 83 96 76 98 68 95 EC L EC L 75 DF EC L 100 100 100 2 L 2 95 100 99 100 100 96 93 100 98 100 100 86 100 91 98 92 89 100 99 100 100 100 1 4 1 99 95 94 2 1 3 0 3 5 5 3 13 0 4 11 3 0 0 0 0 0 0 0 0 0 0 0 0 1 3 0 3 5 5 3 13 0 4 11 3 0 71 84 71 96 72 90 86 96 95 100 100 7.6 5.3 130.36 0.0 0.0 0.0 7.6 5.3 130.36 22.2 15.4 19.27 CHEAL control AMARE ABUTH control SOLTU injury percent percent percent percent percent percent percent 6/3/09 6/10/09 7 DACRK 7 DACRK 7 DACRK 7 DACRK 7 DACRK 7 DACRK 14 DACRK 14 DACRK 14 DACRK 14 DACRK 1 CHEAL control percent 6/10/09 SOLTU injury percent 6/10/09 SOLTU discolor percent 6/10/09 ECHCG control SOLTU stunt control 6/3/09 6/3/09 6/3/09 6/3/09 6/3/09 10 5 4 9 6 2 7 8 3 0 100 100 100 100 100 100 94 100 100 88 100 11.8 8.2 9.06 75 ECHCG control percent 6/10/09 AMARE control percent 6/10/09 14 DACRK 14 DACRK 14 DACRK 14 DACRK 27 DACRK 27 DACRK 27 DACRK 27 DACRK 54 DACRK 54 DACRK 11 MELAL control percent 6/10/09 CHEAL control percent 6/23/09 ABUTH control percent 6/23/09 ANGR control percent 6/23/09 AMARE control percent 6/23/09 ANGR control percent 7/20/09 SOLTU injury percent 7/20/09 16 12 13 19 14 15 17 18 20 0 0 0 0 0 Reflex 2 Reflex Reflex L L 100 100 2 2 65 93 80 96 1 2 1 1 1 pt/a PRE pt/a PRE Rate Grow Non-Treated MSU Weed Science Research Program ABUTH control percent 6/10/09 Form Form Conc Type Rate Unit Stg WEED CONTROL IN POTATO WITH REFLEX, 2009 Trial ID: PO209 Study Dir.: Andy Chomas Conducted: MONTCALM RSH FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 2 3 4 Dual Magnum 7.62 L 5 L 5 Dual Magnum 7.62 L 6 7 7 8 8 9 Dual Magnum 7.62 L 9 10 Dual Magnum 7.62 L 10 Matrix 11 Reflex 12 Boundary 12 Reflex LSD (P=.05) Standard Deviation CV 1.5 pt/a CRACK 100 1 1.5 pt/a PRE 0.5 pt/a PRE 1.5 pt/a PRE 1 pt/a PRE 1 25 WG 1 pt/a PRE oz/a PRE pt/a PRE oz/a PRE pt/a PRE pt/a PRE Boundary Reflex Boundary Reflex pt/a CRACK 100 18.9 13.1 14.64 26.5 18.4 23.21 19.1 13.2 15.75 22.2 15.4 20.01 1.5 pt/a PRE pt/a CRACK pt/a PRE Boundary 6.5 EC 53 93 90 73 70 78 76 90 93 91 10 78 79 83 98 99 68 83 93 96 71 90 EC L EC L 75 DF 6.5 2 6.5 2 100 100 100 100 L EC L 100 96 98 100 78 100 95 100 2 6.5 2 94 80 80 86 100 95 98 99 100 89 1 4 2 100 88 Sencor 95 0 100 100 75 100 90 100 2 85 100 70 100 83 100 0 98 99 98 100 100 95 100 100 100 100 100 100 100 100 98 100 98 100 99 95 98 0 0 0 0 0 0 0 0 0 0 0 0 0 69 65 88 91 88 80 89 84 76 59 75 15.6 10.8 12.23 27.9 19.3 22.33 4.8 3.3 3.68 0.0 0.0 0.0 21.3 14.8 20.52 24.4 16.9 22.61 76 0 0 Reflex 2 Reflex Reflex 2.1925 0 96 1.7413 45 2 2 L L 46 75 54 72 1 2 1 1 1 pt/a PRE pt/a PRE Rate Grow Non-Treated MSU Weed Science Research Program Form Form Conc Type Rate Unit Stg WEED CONTROL IN POTATO WITH REFLEX, 2009 Trial ID: PO209 Study Dir.: Andy Chomas Conducted: MONTCALM RSH FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 2 3 4 Dual Magnum 7.62 L 5 L 5 Dual Magnum 7.62 L 6 7 7 8 8 9 Dual Magnum 7.62 L 9 10 Dual Magnum 7.62 L 10 Matrix 11 Reflex 12 Boundary 12 Reflex LSD (P=.05) Standard Deviation CV 1.00975 23.4 0.69932 16.2 35.44 35.87 1.5 pt/a CRACK 87 1 1.5 pt/a PRE 0.5 pt/a PRE 1.5 pt/a PRE 1 pt/a PRE 1 25 WG 1 pt/a PRE oz/a PRE pt/a PRE oz/a PRE pt/a PRE pt/a PRE Boundary Reflex Boundary Reflex 26.8 18.6 31.36 22.1 15.3 17.61 38.4 26.6 35.78 pt/a CRACK 86 1.5 pt/a PRE pt/a CRACK pt/a PRE Boundary 6.5 2 6.5 2 6.5 EC 58 72 45 48 58 50 51 35 90 99 83 97 35 74 50 64 33 48 63 59 EC L EC L 75 DF 1.8450 44 1.7388 43 1.9613 50 100 100 L EC L 6.5 2 100 65 100 99 100 2.4213 70 96 97 1.8750 1.5413 1.5025 2.3888 1 4 2 100 100 68 94 2.0738 2.1138 Sencor 2 SOLTU AMARE control percent 7/20/09 ABUTH control percent 7/20/09 CHEAL control percent 7/20/09 54 DACRK 54 DACRK 54 DACRK HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST 21 SOLTU SOLTU <1 7/8" <1 7/8" PickOut kilogram count 9/1/09 9/1/09 SOLTU PickOut Grade A Grade A dry kilogram count 9/1/09 9/1/09 kilogram count 9/1/09 9/1/09 SOLTU SOLTU SOLTU 9/1/09 24 27 29 22 23 30 28 26 25 0 0 0 0 0 0 0 0 0 0 0 0 1 0 1 0 0 0 1 0 0 0 0 0 4.0713 5.1850 6.1263 3.8825 6.2213 4.5825 4.7613 44 58 63 40 62 48 52 4.0713 5.1850 6.1263 3.8825 6.2213 4.5825 4.7613 8.4088 80 5.7450 6.5838 63 6.5838 5.0900 57 5.0900 8.0825 7.5338 72 79 8.0825 7.5338 0.1 0.1 305.05 0.9 0.6 259.69 3.36617 27.6 2.33129 19.1 32.07 39.67 3.64321 2.52316 44.61 77 Reflex 32 33 34 35 Reflex Reflex 2 2 2 L L pt/a PRE pt/a PRE pt/a PRE 1 2 1 1 1 Rate Grow Non-Treated 0 0 0 0 0 1 0 0 2 0 0 0 0 0 0 0.49750 1.0884031 0.41713 1.0877796 0.30600 1.0867735 0.32050 1.0865670 MSU Weed Science Research Program Form Form Conc Type Rate Unit Stg SOLTU SPEC. GRAV. HH 9/1/09 SOLTU wet 9/1/09 HARVEST HARVEST 31 WEED CONTROL IN POTATO WITH REFLEX, 2009 Trial ID: PO209 Study Dir.: Andy Chomas Conducted: MONTCALM RSH FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 2 3 4 Dual Magnum 7.62 L 5 L 5 Dual Magnum 7.62 L 6 7 7 8 8 9 Dual Magnum 7.62 L 9 10 Dual Magnum 7.62 L 10 Matrix 11 Reflex 12 Boundary 12 Reflex LSD (P=.05) Standard Deviation CV ARM Action Codes T1 = ([30])/([30]-[31]) 0.291159 0.00775012 0.3 0.201646 0.00536744 0.2 45.14 1.5 pt/a CRACK 0.58213 1.0839484 1 pt/a CRACK 0.49625 1.0860866 0.50975 1.0839401 0.45313 1.0820409 0.37438 1.0858561 0.40325 1.0864125 pt/a CRACK 0.64888 1.0883949 1.5 pt/a PRE 0.5 pt/a PRE 1.5 pt/a PRE 1 pt/a PRE 1 25 WG 1 0.35125 1.0804309 1.4 1.0 119.97 pt/a PRE oz/a PRE pt/a PRE oz/a PRE pt/a PRE pt/a PRE Boundary Reflex Boundary Reflex 1.5 pt/a PRE EC L EC L Boundary 6.5 2 6.5 2 0 0 0 0 0 0 75 DF 6.5 EC 1 1 1 1 1 0 1 L EC L 2 6.5 2 1 4 2 497.27 Sencor 0 0 0 0 0 0 0 0 0.49 0.4 0.3 411.94 SOLTU 0-10 9/1/09 HARVEST HARVEST HARVEST SOLTU VD 0-10 9/1/09 SOLTU IBS 0-10 9/1/09 78 Funded by AgChem Industry Weed Control in Potato with Rimsulfuron Formulations. Wesley J. Everman and Andrew J. Chomas. Department of Crop and Soil Sciences, Michigan State University, East Lansing, MI 48824. A study investigating the tolerance of potato to applications of rimsulfuron formulations was conducted in 2009 at the Montcalm Research Farm. This study compared 1 oz and 1.5 oz of two formulations of rimsulfuron applied PRE, at cracking, or POST. The results indicate there were no differences in weed control observed between the two formulations for any application timing. 79 B CRACK POST C MSU Weed Science Research Program WEED CONTROL IN POTATO WITH RIMSULFURON FORMULATIONS, 2009 Trial ID: P0309 Study Dir.: Conducted: MONTCALM RSCH FARM Investigator: Christy Sprague Date Planted: 5/11/09 Row Spacing: 34 IN Variety: SNOWDEN No. of Reps: 4 Population: 1/FT % OM: 2.7 Soil Type: Loamy Sand pH: 5.6 Plot Size: 10 X 20 FT Design: RANDOMIZED COMPLETE BLOCK Tillage: Spring Disc 3X. Spring Chisel. Field Cultivated. Fertilizer: 20 gal/A of 19-17-0, 12 gal/A of 10-34-0 in Row. 23 gal/A of 28% N at Cultivation. 23 gal/A of 28%N at Hilling. 100 lbs/A of 46-0-0 Broadcast. Application Description A PRE Application Timing: 5/26/09 6/10/09 7/14/09 Date Treated: 3:37 PM 2:10 PM 9:30 AM Time Treated: 100 % Cloud Cover: Air Temp., Unit: 75 F % Relative Humidity: 44.6 Wind Speed/Unit/Dir: 3 mph E 0 mph 0 mph 61 F 70 F 66 F Soil Temp., Unit: Soil/Leaf Surface M: Soil Moist (1=w 5=d): 2 Crop Stage at Each Application Crop Name: SOLTU SOLTU SOLTU Weed Stage at Each Application Weed 1 Name: ANGR ANGR ANGR Weed 2 Name: CHEAL CHEAL CHEAL Weed 3 Name: AMARE AMARE AMARE Weed 4 Name: ABUTH ABUTH ABUTH Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B C MPH Type Size Height Spacing Width GPA Carrier PSI 3.5 FF 30 30 3.5 FF 3.5 FF 30 120" 20 H2O 120" 20 H2O 120" 20 H2O 8003 18" 8003 18" 8003 18" Type BKPK BKPK BKPK 5 66 F 42 40 83 F 52 3 3 4 A B C A B C 20" 20" 20" 80 CHEAL control percent 6/16/09 SOLTU injury percent 6/16/09 21 DAPRE 21 DAPRE 21 DAPRE 21 DAPRE 21 DAPRE 44 DAPRE 44 DAPRE 44 DAPRE 44 DAPRE 1 AMARE control percent 6/16/09 ABUTH control percent 6/16/09 AMARE control percent 7/8/09 SOLTU injury percent 7/8/09 CHEAL control percent 7/8/09 ANGR control percent 7/8/09 3 4 2 6 7 9 8 5 98 DF Stg 100 DF 1 100 90 80 oz/a PRE oz/a PRE 1.5 oz/a PRE 0 0 1 1 Rate Grow 25 WG 1 25 WG 1.5 oz/a ANGR control percent 6/16/09 Form Form Conc Type Rate Unit MSU Weed Science Research Program WEED CONTROL IN POTATO WITH RIMSULFURON FORMULATIONS, 2009 Trial ID: P0309 Study Dir.: Conducted: MONTCALM RSCH FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 MANA Rimsulfuron 25 2 Matrix 3 MANA Rimsulfuron 25 4 Matrix 5 MANA Rimsulfuron 25 5 6 Matrix 6 7 MANA Rimsulfuron 25 7 8 Matrix 8 9 10 MANA Rimsulfuron 25 11 Matrix 12 MANA Rimsulfuron 25 13 Matrix LSD (P=.05) Standard Deviation CV 25 WG 1.5 oz/a POST 0.2 % v/v POST 1 0.2 % v/v POST 1.5 oz/a POST 0.2 % v/v POST POST 0.2 % v/v POST 25 WG 1.5 oz/a CRACK 1 25 WG 1 1.5 oz/a CRACK 0 1.7 1.1 324.19 POST 0 23.5 16.1 25.92 oz/a CRACK 0 oz/a CRACK 1 25 WG 1 1.2 0.8 0.94 2.4 1.7 2.03 Non-Treated Activator 90 Activator 90 Activator 90 Activator 90 DF L DF L L 55 70 46 65 oz/a oz/a 96 20 PRE 100 1 100 100 100 100 100 100 100 100 100 100 99 100 100 90 0 DF 0 0 0 DF L 30 100 89 81 81 91 0 80 88 76 94 19.7 13.5 17.35 0 0 0 0 0 0 0 0 0 0 0 0 0 0.0 0.0 0.0 100 96 100 100 0 0 0 0 0 100 100 100 100 1.7 1.2 2.0 63 51 59 55 0 0 0 0 0 24 24 33 39 88 93 98 96 0 0 0 0 0 98 98 98 98 9.9 6.9 26.06 4.3 3.0 5.14 81 Stg PRE DF 1 74 73 84 79 73 62 78 88 84 86 85 86 86 oz/a PRE oz/a PRE Rate Grow 25 WG 1 1.5 oz/a PRE 25 WG 1.5 oz/a Form Form Conc Type Rate Unit MSU Weed Science Research Program WEED CONTROL IN POTATO WITH RIMSULFURON FORMULATIONS, 2009 Trial ID: P0309 Study Dir.: Conducted: MONTCALM RSCH FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 MANA Rimsulfuron 25 2 Matrix 3 MANA Rimsulfuron 25 4 Matrix 5 MANA Rimsulfuron 25 5 6 Matrix 6 7 MANA Rimsulfuron 25 7 8 Matrix 8 9 10 MANA Rimsulfuron 25 11 Matrix 12 MANA Rimsulfuron 25 13 Matrix LSD (P=.05) Standard Deviation CV 25 WG 1.5 oz/a 1 0.2 % v/v POST 1.5 oz/a 0.2 % v/v POST 25 WG 1.5 oz/a CRACK 65 25 WG 1 1.5 oz/a CRACK 75 POST 0 POST 0 POST 0 POST 0 0.2 % v/v POST 0.2 % v/v POST oz/a CRACK 60 oz/a CRACK 65 22.4 15.7 35.58 20.8 14.5 32.39 25 WG 1 10.1 7.1 9.45 Non-Treated Activator 90 Activator 90 Activator 90 Activator 90 0.0 0.0 0.0 81 95 35 35 53 41 86 83 83 89 77 28 88 76 76 80 100 100 100 100 100 100 100 100 0 65 86 L DF L 38 40 69 88 70 77 100 68 63 0 25 0 0 L DF 100 100 oz/a oz/a DF DF L 1 DF 100 0 CHEAL control AMARE ABUTH control CHEAL ANGR control control percent percent percent percent percent percent 8/12/09 8/12/09 8/12/09 8/12/09 8/27/09 8/27/09 ABUTH control percent 7/8/09 44 DAPRE 29 DAPO 29 DAPO 29 DAPO 29 DAPO 44 DAPO 44 DAPO 10 SOLTU injury control 15 12 14 16 11 13 0 0 0 0 0 0 0 0 0 0 0 0 0 69 60 78 79 8 18 25 13 3 15 13 43 31 0.0 0.0 0.0 21.8 15.3 43.94 28.0 19.6 26.43 82 Funded by Industry Herbicide Effect on Growth Cracks in FL2053 Potato. Wesley J. Everman, Chris Long, and Andrew J. Chomas. Department of Crop and Soil Sciences, Michigan State University, East Lansing, MI 48824. Herbicide growth cracks are a concern for potato producers, especially those growing the chipping variety FL2053. Due to concerns that herbicides may be contributing to the occurrence and severity of growth cracks in FL2053, a study was conducted near Three Rivers, MI and at the Montcalm Research Farm in 2009 to investigate several herbicides applied to FL2053 both preemergence and postemergence. Preemergence herbicide treatments consisted of Dual Magnum at 1.33 pt/A plus Sencor at 0.33 lb/A plus Prowl H2O at 0.5 pt/A and Dual Magnum at 1.33 pt/A plus Sencor at 0.33 lb/A plus Lorox at 1 pt/A. Postemergence herbicide options included Sencor at 0.33 lb/A plus NIS at 0.25%, Matrix at 1 oz/A plus NIS, Sencor at 0.33 lb plus Matrix at 1 oz plus NIS, or no POST herbicide. Treatments were applied in a factorial arrangement of PRE followed by POST herbicide options. Preemergence treatments were made after planting, and postemergence applications were made at canopy closure. Growth crack occurrence and severity were evaluated at harvest, after which tubers were graded. Results from both locations indicate there was no correlation between growth crack occurrence or severity and herbicide application. While the primary cause of growth cracks is yet to be determined, multiple stress factors and time of stress induction may play a role in growth crack occurrence. 83 B 22 B POST 40 79 F 53 MSU Weed Science Research Program Herbicide Effect on Growth Cracks in Production Potato, 2009 Trial ID: P0409 Study Dir.: Andy Chomas Conducted: MONTCALM RSCH FAM Investigator: Christy Sprague Date Planted: 5/11/09 Row Spacing: 34 IN Variety: FL 2053 No. of Reps: 4 Population: 1/FT % OM: 1.5 Soil Type: Loamy Sand pH: 5.6 Plot Size: 10 X 25 FT Design: FACTORIAL Tillage: Spring Disc 3X. Spring Chisel. Field Cultivated. Fertilizer: 20 gal/A of 19-17-0, 12 gal/A of 10-34-0 in Row. 23 gal/A of 28% N at Cultivation. 23 gal/A of 28%N at Hilling. 100 lbs/A of 46-0-0 Broadcast. Application Description A PRE Application Timing: 5/11/09 7/8/09 Date Treated: 2:30 PM 9:20 AM Time Treated: 60 % Cloud Cover: 59 F Air Temp., Unit: % Relative Humidity: 37 Wind Speed/Unit/Dir: 7 mph W 2 mph S 68 F 64 F Soil Temp., Unit: Soil/Leaf Surface M: 4 Soil Moist (1=w 5=d): 4 Crop Stage at Each Application Crop Name: SOLTU SOLTU Height (In.): Weed Stage at Each Application Weed 1 Name: ANGR ANGR Height (In.): Stage (L): Weed 2 Name: CHEAL CHEAL Height (In.): Stage (L): Weed 3 Name: AMARE AMARE Height (In.): Stage (L): Weed 4 Name: AMBEL AMBEL Weed 5 Name: ABUTH ABUTH Weed Density (plants/sq. ft.) Date: 7/8/09 ANGR Weed Name: Density: 16 Date: 7/8/09 Weed Name: CHEAL Density: 20 Date: 7/8/09 AMARE Weed Name: Density: 8 Date: 7/8/09 AMBEL Weed Name: Density: 0 Date: 7/8/09 ABUTH Weed Name: Density: 0 Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B MPH Type Size Height Spacing Width GPA Carrier PSI 30 3.5 FF 3.5 FF 30 120" 20 H2O 100" 20 H2O B .25-1(1) 1-3(1) .25-2(1) Cot-2(2) .25-2(1) Cot-2(2) 8003 18" 8003 24" Type BKPK BKPK 20" 20" 4 4 A A 1 84 50 53 3 0.5800 4 5 2 2 Activator 90 L Activator 90 L 0.8113 6 1.0988 9 75 3.8 75 Sencor Prowl H2O MSU Weed Science Research Program Sencor Prowl H2O Sencor Activator 90 Form Form Conc Type Rate Unit Rate Grow 1 Stg 1.33 pt/a 0.33 lb/a 0.5 pt/a 0.33 lb/a oz/a 75 3.8 25 WG 1 75 3.8 75 25 WG 1 1.33 pt/a 0.33 lb/a 0.5 pt/a oz/a PRE 2.3900 PRE PRE POST 0.25 % v/v POST PRE 2.4075 1.33 pt/a PRE 0.33 lb/a PRE 0.5 pt/a 0.33 lb/a POST 0.25 % v/v POST PRE 2.5613 PRE PRE POST POST 0.25 % v/v POST Herbicide Effect on Growth Cracks in Production Potato, 2009 Trial ID: P0409 Study Dir.: Andy Chomas Conducted: MONTCALM RSCH FAM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 Dual Magnum 7.62 EC DF 1 1 L DF 1 1 L 2 Dual Magnum 7.62 EC DF 2 2 L 2 Matrix 2 3 Dual Magnum 7.62 EC Sencor DF 3 Prowl H2O 3 L 3 DF Sencor 3 Matrix 3 4 Dual Magnum 7.62 EC DF 4 L 4 4 5 Dual Magnum 7.62 EC 5 DF DF 5 DF 5 5 L 6 Dual Magnum 7.62 EC Sencor 6 DF 6 DF Lorox 6 Matrix 6 7 Dual Magnum 7.62 EC Sencor 7 DF DF Lorox 7 7 Sencor DF 7 Matrix 7 8 Dual Magnum 7.62 EC DF 8 DF 8 8 9 Matrix 9 10 Handweeded LSD (P=.05) Standard Deviation CV PRE 1.9100 PRE PRE POST POST 0.25 % v/v POST 1.33 pt/a 0.33 lb/a 75 lb/a 50 1 25 WG 1 oz/a PRE 2.3838 PRE PRE POST 0.25 % v/v POST PRE 1.8475 1.33 pt/a PRE 0.33 lb/a PRE 1 lb/a 0.33 lb/a POST 0.25 % v/v POST 75 50 75 25 WG 1 PRE 2.1638 PRE PRE POST PRE 2.1275 PRE PRE POST 1.33 pt/a 0.33 lb/a 1 lb/a 0.33 lb/a oz/a 1.11595 21.8 0.76910 15.0 34.01 32.47 Sencor Lorox Sencor Activator 90 0.78651 5.2 0.54206 3.6 67.14 61.24 1.33 pt/a 0.33 lb/a lb/a 1 1.33 pt/a 0.33 lb/a 0.5 pt/a Sencor Lorox Non-Treated Sencor Prowl H2O Non-Treated 25 WG 1 L oz/a POST 2.3525 44 0.25 % v/v POST 0.8 0.6 28.82 2.4688 53 0.7363 5 0.9338 6 0.5813 4 0.4838 4 1.0350 6 42 0.7013 5 2 2 2 Activator 90 L Activator 90 L 1.1125 9 2 2 2 2 75 3.8 75 50 75 43 38 Activator 90 53 38 75 50 SOLTU SOLTU <1 7/8" <1 7/8" kilogram count 8/27/09 8/27/09 HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST SOLTU SOLTU PO crack PO crack severity* PickOut kilogram count 8/27/09 8/27/09 SOLTU SOLTU oversize oversize Grade A kilogram count kilogram 8/27/09 8/27/09 0-3 8/27/09 8/27/09 SOLTU PickOut 8/27/09 8/27/09 kilogram count SOLTU SOLTU SOLTU 2 50 5 2 6 0.0000 7 0 8 0 9 0 10 14.2175 0.1750 0 0 0 16.3825 0.0000 0 0 0 15.2188 0.0388 0 0.0000 0 0 0 0 0 18.3188 15.8075 0.0550 0 0 0 19.2375 0.0000 0 0 0 14.5938 0.0000 0 0.0000 0 0.0675 0 0 0 0 0 1 0 0.18335 0.4 0.12636 0.3 375.8 298.14 0.3 0.2 632.46 0.7 0.5 632.46 19.2313 19.0338 17.8750 4.22467 2.91159 17.14 85 121.3 9.6288 0.83963 1.0956200 0 141.3 8.6663 0.76688 1.0971104 2 138.5 9.2813 0.80600 1.0951620 0 L L 75 3.8 Stg 11 12 13 14 Activator 90 Activator 90 SOLTU 75 3.8 75 Rate Grow Sencor Prowl H2O SOLTU wet 8/27/09 8/27/09 MSU Weed Science Research Program Sencor Prowl H2O Non-Treated Form Form Conc Type Rate Unit Sencor Prowl H2O Sencor Activator 90 1.33 pt/a 0.33 lb/a 0.5 pt/a 0.33 lb/a oz/a SOLTU Grade A dry count 75 3.8 25 WG 1 75 3.8 75 25 WG 1 1.33 pt/a 0.33 lb/a 0.5 pt/a oz/a PRE 222.1 PRE PRE POST 0.25 % v/v POST PRE 192.8 1.33 pt/a PRE 0.33 lb/a PRE 0.5 pt/a 0.33 lb/a POST 0.25 % v/v POST PRE 206.4 PRE PRE POST POST 0.25 % v/v POST SOLTU yield CWT 8/27/09 8/27/09 HARVEST HARVEST HARVEST HARVEST HARVEST Herbicide Effect on Growth Cracks in Production Potato, 2009 Trial ID: P0409 Study Dir.: Andy Chomas Conducted: MONTCALM RSCH FAM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 Dual Magnum 7.62 EC DF 1 1 L DF 1 1 L 2 Dual Magnum 7.62 EC DF 2 2 L 2 Matrix 2 3 Dual Magnum 7.62 EC Sencor DF 3 Prowl H2O 3 L 3 DF Sencor 3 Matrix 3 4 Dual Magnum 7.62 EC DF 4 L 4 4 5 Dual Magnum 7.62 EC 5 DF DF 5 DF 5 5 L 6 Dual Magnum 7.62 EC Sencor 6 DF 6 DF Lorox 6 Matrix 6 7 Dual Magnum 7.62 EC Sencor 7 DF DF Lorox 7 7 Sencor DF 7 Matrix 7 8 Dual Magnum 7.62 EC DF 8 DF 8 8 9 Matrix 9 10 Handweeded LSD (P=.05) Standard Deviation CV ARM Action Codes TY2 = 13.55932*[10] T1 = ([C13])/([C13]-[C14]) 1.33 pt/a 0.33 lb/a 75 lb/a 50 1 25 WG 1 oz/a PRE 260.8 PRE PRE POST 0.25 % v/v POST 1.33 pt/a 0.33 lb/a 1 lb/a 0.33 lb/a oz/a PRE 197.9 PRE PRE POST POST 0.25 % v/v POST PRE 214.3 1.33 pt/a PRE 0.33 lb/a PRE 1 lb/a 0.33 lb/a POST 0.25 % v/v POST 75 50 75 25 WG 1 PRE 260.8 PRE PRE POST PRE 248.4 PRE PRE POST Sencor Lorox Sencor Activator 90 1.33 pt/a 0.33 lb/a lb/a 1 1.33 pt/a 0.33 lb/a 0.5 pt/a Sencor Lorox Non-Treated 25 WG 1 L oz/a POST 258.1 160.5 0.25 % v/v POST 57.28 39.48 17.14 35.33 24.35 16.77 Activator 90 Activator 90 Activator 90 75 50 75 L L 75 50 9.7225 0.85213 1.0958688 1 242.4 147.0 9.6038 0.84550 1.0965496 1 1.32164 0.128576 0.00361148 2.3 0.91086 0.088613 0.00248899 1.6 9.82 10.91 0.23 228.7 155.0 8.6025 0.76388 1.0973925 1 136.5 9.0750 0.80050 1.0968406 0 164.8 10.4075 0.89650 1.0938526 1 125.3 8.1488 0.70713 1.0950276 1 162.0 9.5938 0.84525 1.0965859 0 SOLTU SPEC. GRAV HH 8/27/09 SOLTU 0-10 8/27/09 HARVEST HARVEST HARVEST SOLTU VD 0-10 8/27/09 SOLTU IBS 0-10 8/27/09 15 16 17 0 18 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0.6 0.4 380.06 0.2 0.2 632.46 86 MSU Weed Science Research Program Herbicide Effect on Growth Cracks in Production Potato, 2009 Trial ID: P1409 Study Dir.: Andy Chomas Conducted: WALTHER FARM Investigator: Christy Sprague Date Planted: 4/27/09 Row Spacing: IN Variety: FL 2053 No. of Reps: 3 Population: % OM: Soil Type: pH: Plot Size: 10 X 25 FT Design: FACTORIAL Application Description B A PRE Application Timing: 4/29/09 Date Treated: 6:00 PM Time Treated: 100 % Cloud Cover: 62 F Air Temp., Unit: % Relative Humidity: 55 Wind Speed/Unit/Dir: 5 mph Soil Temp., Unit: 59 F Soil/Leaf Surface M: 2 Soil Moist (1=w 5=d): 3 Crop Stage at Each Application Crop Name: SOLTU SOLTU Application Equipment Appl Sprayer Speed Nozzle MPH Type A 3.5 XR8003 Type BKPK A B 87 SOLTU SOLTU <1 7/8" <1 7/8" kilogram count 9/22/09 9/22/09 HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST SOLTU SOLTU oversize oversize Grade A Grade A kilogram count 9/22/09 9/22/09 SOLTU SOLTU PO crack PO crack PickOut kilogram count 9/22/09 9/22/09 kilogram count 9/22/09 9/22/09 kilogram count 9/22/09 9/22/09 SOLTU PickOut SOLTU SOLTU SOLTU L 26 0.5833 2 23 3 0.1783 4 1 5 1.1167 Activator 90 L 30 0.0000 0 0.5233 Activator 90 0.3533 2 75 3.8 75 Sencor Prowl H2O MSU Weed Science Research Program Sencor Prowl H2O Sencor Activator 90 1.33 pt/a 0.33 lb/a 0.5 pt/a 0.33 lb/a oz/a Form Form Conc Type Rate Unit Rate Grow 1 Stg 75 3.8 25 WG 1 75 3.8 75 25 WG 1 1.33 pt/a 0.33 lb/a 0.5 pt/a oz/a PRE 1.0883 PRE PRE POST 0.25 % v/v POST PRE 1.0883 1.33 pt/a PRE 0.33 lb/a PRE 0.5 pt/a 0.33 lb/a POST 0.25 % v/v POST PRE 1.3467 PRE PRE POST POST 0.25 % v/v POST Herbicide Effect on Growth Cracks in Production Potato, 2009 Trial ID: P1409 Study Dir.: Andy Chomas Conducted: WALTHER FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 Dual Magnum 7.62 EC DF 1 1 L DF 1 1 L 2 Dual Magnum 7.62 EC DF 2 2 L 2 Matrix 2 3 Dual Magnum 7.62 EC Sencor DF 3 Prowl H2O 3 L 3 DF Sencor 3 Matrix 3 4 Dual Magnum 7.62 EC DF 4 L 4 4 5 Dual Magnum 7.62 EC 5 DF DF 5 DF 5 5 L 6 Dual Magnum 7.62 EC Sencor 6 DF 6 DF Lorox 6 Matrix 6 7 Dual Magnum 7.62 EC Sencor 7 DF DF Lorox 7 7 Sencor DF 7 Matrix 7 8 Dual Magnum 7.62 EC DF 8 DF 8 8 LSD (P=.05) Standard Deviation CV PRE 1.2733 PRE PRE POST POST 0.25 % v/v POST 1.33 pt/a 0.33 lb/a 75 lb/a 50 1 25 WG 1 oz/a PRE 1.1833 PRE PRE POST 0.25 % v/v POST PRE 1.4333 1.33 pt/a PRE 0.33 lb/a PRE 1 lb/a 0.33 lb/a POST 0.25 % v/v POST 75 50 75 25 WG 1 PRE 1.4050 PRE PRE PRE 1.0583 PRE PRE 1.33 pt/a 0.33 lb/a 1 lb/a 0.33 lb/a oz/a 0.62612 14.1 0.35750 8.1 28.96 28.29 0.27651 0.9 0.15788 0.5 96.66 81.01 Sencor Lorox Sencor Activator 90 1.33 pt/a 0.33 lb/a lb/a 1 1.33 pt/a 0.33 lb/a 0.5 pt/a Sencor Lorox Non-Treated Sencor Prowl H2O Non-Treated 26 0.0367 0 28 0.1233 1 34 0.2683 1 29 0.1300 1 33 0.2167 1 Activator 90 L Activator 90 L 75 3.8 75 50 75 75 50 0.4567 0.2950 6 3 7 8 9 10 7.3550 38 26.8917 146 4 5.9583 14 29.5517 173 2 8.4517 20 21.1100 132 2 2 7.9307 18 26.0750 148 6.7550 16 26.9550 158 1 7.1283 16 27.3717 152 2 8.5983 21 25.3343 152 1 8.4500 20 26.7833 139 0.2250 0.5733 0.1800 0.64673 3.1 0.36927 1.8 74.73 83.11 4.28312 16.9 2.44556 9.7 32.27 47.28 7.13250 51.0 4.07249 29.1 19.42 15.51 88 SOLTU SOLTU SPEC. GRAV. HH 9/22/09 HARVEST 0-10 9/22/09 HARVEST HARVEST SOLTU VD 0-10 9/22/09 13 14 0.0 15 0.3 0.3 1.3 1.0 1.0 Activator 90 L Stg 11 12 Activator 90 75 3.8 75 Rate Grow Sencor Prowl H2O MSU Weed Science Research Program Form Form Conc Type Rate Unit Sencor Prowl H2O Sencor Activator 90 1.33 pt/a 0.33 lb/a 0.5 pt/a 0.33 lb/a oz/a 75 3.8 25 WG 1 L 75 3.8 75 25 WG 1 SOLTU wet SOLTU dry 9/22/09 9/22/09 HARVEST HARVEST 1.33 pt/a 0.33 lb/a 0.5 pt/a oz/a PRE 10.3500 0.90833339 1.0962595 PRE PRE POST 0.25 % v/v POST PRE 11.2733 0.97166673 1.0942961 1.33 pt/a PRE 0.33 lb/a PRE 0.5 pt/a 0.33 lb/a POST 0.25 % v/v POST PRE 10.3150 0.90416679 1.0960938 PRE PRE POST POST 0.25 % v/v POST Herbicide Effect on Growth Cracks in Production Potato, 2009 Trial ID: P1409 Study Dir.: Andy Chomas Conducted: WALTHER FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 Dual Magnum 7.62 EC DF 1 1 L DF 1 1 L 2 Dual Magnum 7.62 EC DF 2 2 L 2 Matrix 2 3 Dual Magnum 7.62 EC Sencor DF 3 Prowl H2O 3 L 3 DF Sencor 3 Matrix 3 4 Dual Magnum 7.62 EC DF 4 L 4 4 5 Dual Magnum 7.62 EC 5 DF DF 5 DF 5 5 L 6 Dual Magnum 7.62 EC Sencor 6 DF 6 DF Lorox 6 Matrix 6 7 Dual Magnum 7.62 EC Sencor 7 DF DF Lorox 7 7 Sencor DF 7 Matrix 7 8 Dual Magnum 7.62 EC DF 8 DF 8 8 LSD (P=.05) Standard Deviation CV ARM Action Codes T1 = ([11])/([11]-[12]) 1.33 pt/a 0.33 lb/a 75 lb/a 50 1 25 WG 1 oz/a PRE 11.4300 0.99816684 1.0956647 PRE PRE POST 0.25 % v/v POST 1.33 pt/a 0.33 lb/a 1 lb/a 0.33 lb/a oz/a PRE 9.4983 PRE PRE POST POST 0.25 % v/v POST PRE 9.1333 1.33 pt/a PRE 0.33 lb/a PRE 1 lb/a 0.33 lb/a POST 0.25 % v/v POST 1.72637 0.167378502 0.00567225 2.21 0.98572 0.095569218 0.00323872 1.26 126.3 9.82 75 50 75 25 WG 1 PRE 9.8217 PRE PRE PRE 8.5133 PRE PRE Sencor Lorox Sencor Activator 90 1.33 pt/a 0.33 lb/a 0.5 pt/a 1.33 pt/a 0.33 lb/a lb/a 1 Sencor Prowl H2O Non-Treated Sencor Lorox Non-Treated 75 50 0.82283344 1.0906361 1.0 11.03 0.3 Activator 90 L Activator 90 L 75 3.8 75 50 75 0.77716674 1.0925081 0.0 2.0 2.0 1.7 0.7 0.81066682 1.0933971 2.0 0.7 0.73633344 1.0949454 2.0 0.0 1.84 1.05 104.94 89 Funded by AgChem Industry and MAES Tolerance of herbicides in Silverton Potatoes. Wesley J. Everman and Andrew J. Chomas. Department of Crop and Soil Sciences, Michigan State University, East Lansing, MI 48824. Incidences of injury last season in Silverton Russet potatoes following applications of linuron (Lorox) led to interest in determining the factors contributing to the observed injury. In order to determine what effect the timing of herbicide applications has on injury and yield, Lorox and Sencor were applied to Silverton Russets planted at three different times. Silverton Russets were planted April 24, May 8, and May 20, 2009. Herbicide treatments consisted of at cracking applications of Lorox (1.5 lb/A), Sencor (0.5 lb/A), and Lorox (1.5 lb/A) plus Sencor (0. 5 lb/A). All herbicide treatments were compared with a non-treated control treatment, with all plots maintained weed-free by hand weeding. Each treatment was replicated four times. Irrigation and other potato crop management practices utilized closely mirror practices followed by producers. Potato injury was evaluated and plots were harvested with marketable yields determined. At all planting dates, the greatest injury was observed where Lorox was included in the application. Injury persisted longer where potatoes were planted earliest, April 24. Injury symptoms observed following all treatments dissipated by mid-June. Differences in Silverton Russet yield corresponded more closely to time of planting than to herbicide selection. 90 MSU Weed Science Research Program TOLERANCE OF HERBICIDE IN SILVERTON POTATOES, 2009 Trial ID: P0709 Study Dir.: Conducted: MONTCALM RSCH FM Investigator: Christy Sprague Date Planted: 4/24/09 Row Spacing: 34 IN Variety: SILVERTON No. of Reps: 4 Population: 1/FT % OM: 1.2 Soil Type: Loamy Sand pH: 5.7 Plot Size: 9 X 25 FT Design: SPLIT-PLOT Tillage: Spring Disc 3X. Spring Chisel. Field Cultivated. Fertilizer: 20 gal/A of 19-17-0, 12 gal/A of 10-34-0 in Row. 23 gal/A of 28% N at Cultivation. 23 gal/A of 28%N at Hilling. 100 lbs/A of 46-0-0 Broadcast. Application Description B A PRE T1 PRE T2&3 Application Timing: 5/17/09 5/20/09 Date Treated: 10:20 AM Time Treated: 25 0 % Cloud Cover: 77 F 52 F Air Temp., Unit: % Relative Humidity: 42 50 Wind Speed/Unit/Dir: 6 mph NW 8 mph SW Soil Temp., Unit: Soil/Leaf Surface M: 5 Soil Moist (1=w 5=d): 3 Crop Stage at Each Application Crop Name: SOLTU SOLTU Height (In.): N/A N/A Weed Stage at Each Application Weed 1 Name: CHEAL CHEAL Height (In.): Stage (L): Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B Comments: TIMING STUDY HAD THREE PLANTING DATES: TIMING 1: 4/24/09 TIMING 2: 5/8/09 TIMING 3: 5/20/09 MPH Type Size Height Spacing Width GPA Carrier PSI 3.5 FF 30 30 3.5 FF 120" 20 H2O 120" 20 H2O 8003 18" 8003 18" 63 F 5 4 Type BKPK BKPK 20" 20" 46 F A B A B .5 2 91 SOLTU SOLTU SOLTU SOLTU SOLTU SOLTU SOLTU SOLTU SOLTU SOLTU SOLTU SOLTU emerge stunt percent percent percent percent percent percent percent percent percent percent percent pounds 5/29/09 5/29/09 5/29/09 5/29/09 6/3/09 6/3/09 6/3/09 6/10/09 6/10/09 6/10/09 6/16/09 8/19/09 12 DA-A 12 DA-A 12 DA-A 12 DA-A 17 DA-A 17 DA-A 17 DA-A 24 DA-A 24 DA-A 24 DA-A 30 DA-A HARVEST discolor injury discolor injury discolor injury injury stunt stunt yield 10 11 12 Stg 50 75 5 14 0.5 50 75 3 12 2 11 5 14 4 23 6 14 4 5 0 6 3 5 5 8 DF DF 90 94 1.5 96 DF DF 1.5 0.5 lb ai/a PRE lb ai/a PRE PLANTING 1 Sencor PLANTING 1 Lorox PLANTING 1 Non-Treated Rate Grow 1 lb ai/a PRE lb ai/a PRE MSU Weed Science Research Program PLANTING 1 Lorox Sencor Form Form Conc Type Rate Unit TOLERANCE OF HERBICIDE IN SILVERTON POTATOES, 2009 Trial ID: P0709 Study Dir.: Conducted: MONTCALM RSCH FM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 1 2 2 3 3 3 4 4 5 5 6 6 7 7 7 8 8 9 9 10 PLANTING 3 10 Sencor 11 PLANTING 3 11 Lorox 11 Sencor 12 PLANTING 3 12 Non-Treated LSD (P=.05) Standard Deviation CV 10.7 6.7 106.67 93.69 PLANTING 2 Lorox Sencor lb ai/a PRE lb ai/a PRE lb ai/a PRE lb ai/a PRE PLANTING 2 Non-Treated PLANTING 2 Sencor PLANTING 3 Lorox PLANTING 2 Lorox lb ai/a PRE lb ai/a PRE lb ai/a PRE lb ai/a PRE 15.6 9.7 91.09 5.4 3.4 3.57 1.5 0.5 1.5 0.5 DF DF DF DF 6.6 4.2 0 0 0 0 DF DF DF DF 1.5 0.5 1.5 0.5 4 9 50 75 50 75 50 75 3 10 96 1 0 1 5 50 75 3 7 28 5 10 8 8 3 9 0 8 3 9 8 14 5 0 6 5 0 0 0 0 9 0 0 0 0 10 0 3 9 8 14 15 0 14 18 5 15 5 10 10 5 10 10 5 5 1 1 2 0 0 2 0 1 1 2 2 0 25.40 29.45 26.05 27.55 35.80 38.80 41.05 35.75 26.60 27.85 27.05 33.40 5.6 3.8 109.19 100.28 82.37 10.5 7.1 9.1 6.2 8.377 8.4 5.8 5.801 143.76 118.74 115.08 181.66 18.58 14.5 10.1 9.1 6.3 2.1 1.4 92 1.5 0.5 50 75 50 75 181.3 156.4 Rate Grow 1.5 0.5 DF DF 160.4 lb ai/a PRE lb ai/a PRE PLANTING 2 Lorox PLANTING 1 Sencor PLANTING 1 Lorox PLANTING 1 Non-Treated lb ai/a PRE lb ai/a PRE MSU Weed Science Research Program PLANTING 1 Lorox Sencor Form Form Conc Type Rate Unit SOLTU yield CWT 8/19/09 HARVEST TOLERANCE OF HERBICIDE IN SILVERTON POTATOES, 2009 Trial ID: P0709 Study Dir.: Conducted: MONTCALM RSCH FM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 1 2 2 3 3 3 4 4 5 5 6 6 7 7 7 8 8 9 9 10 PLANTING 3 10 Sencor 11 PLANTING 3 11 Lorox 11 Sencor 12 PLANTING 3 12 Non-Treated LSD (P=.05) Standard Deviation CV ARM Action Codes TY1 = 6.15689*[12] PLANTING 2 Lorox Sencor lb ai/a PRE lb ai/a PRE lb ai/a PRE lb ai/a PRE PLANTING 2 Non-Treated PLANTING 2 Sencor PLANTING 3 Lorox lb ai/a PRE lb ai/a PRE lb ai/a PRE lb ai/a PRE 166.5 51.57 35.72 18.58 252.7 DF DF DF DF DF DF 1.5 0.5 1.5 0.5 1.5 0.5 169.6 220.4 163.8 171.5 220.1 238.9 50 75 50 75 50 75 50 75 205.6 1.5 0.5 Stg 13 DF DF DF DF 93 Funded by MAES Herbicide Timing Effect on Weed Control in Potato. Wesley J. Everman and Andrew J. Chomas. Department of Crop and Soil Sciences, Michigan State University, East Lansing, MI 48824. Herbicide application timing is an important consideration in any cropping system, and is of special importance in potatoes which have limited postemergence herbicide options. Through interactions with industry personnel and growers, it seems the common timing of preemergence herbicide application is often as near to potato cracking as possible, often with applications coming after potatoes have emerged. In order to determine what effect the timing of herbicide applications has on weed control and yield herbicide products were applied to Snowden. Herbicide treatments consisted of Dual II Magnum (1 pt/A) plus Lorox (1 lb/A), Dual II Magnum (1 pt/A) plus Lorox (1 lb/A) plus Sencor (0.125 lb/A), Dual II Magnum (1 pt/A) plus Lorox (1 lb/A) followed by Matrix (1 oz/A) plus NIS (0.25% v/v), and Dual II Magnum (1 pt/A) plus Lorox (1 lb/A) followed by Matrix (1 oz/A) plus Sencor (0.33 lb/A) plus NIS (0.25% v/v). Application timings were at planting 10 DAP and 21 DAP. All herbicide treatments were compared with a non-treated control treatment. Each treatment was replicated four times. Irrigation and other potato crop management practices utilized closely mirror practices followed by producers. Weed control was evaluated, and plots were harvested and marketable yields determined. Weed control was similar when herbicides were applied at 10 and 21 DAP, regardless of herbicides used or presence of a postemergence application. However, at planting preemergence treatments followed by a postemergence application showed slightly lower levels of control when compared to later application timings. The results of this study, combined with results from 2008, indicate that initial herbicide application timing may depend on weather and growing conditions. 94 MSU Weed Science Research Program Potato Timing Study, Montcalm, 2008 Trial ID: P0809 Study Dir.: Conducted: Montcalm Investigator: Christy Sprague Date Planted: 5/11/09 Row Spacing: 34 IN Variety: SNOWDEN No. of Reps: 4 Population: 1/FT % OM: 1.1 Soil Type: Loamy Sand pH: 6.0 Plot Size: 10 X 25 FT Design: FACTORIAL Tillage: Spring Disc 3X. Spring Chisel. Field Cultivated. Fertilizer: 20 gal/A of 19-17-0, 12 gal/A of 10-34-0 in Row. 23 gal/A of 28% N at Cultivation. 23 gal/A of 28%N at Hilling. 100 lbs/A of 46-0-0 Broadcast. Application Description A 0 DAP Application Timing: 5/11/09 5/20/09 5/29/09 7/14/09 Date Treated: 4:15 PM 9:54 PM 10:00 AM 10:00 AM Time Treated: 50 % Cloud Cover: 68 F Air Temp., Unit: % Relative Humidity: 37 Wind Speed/Unit/Dir: 6 mph SW 8 mph SW 2 mph W 0 mph 63 F 66 F Soil Temp., Unit: Soil/Leaf Surface M: Soil Moist (1=w 5=d): Crop Stage at Each Application Crop Name: SOLTU SOLTU SOLTU SOLTU Stage (L): Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B C D Comments: Spray solution was Buffered to a pH of 6.0 MPH Type Size Height Spacing Width GPA Carrier PSI 3.5 FF 30 30 3.5 FF 30 3.5 FF 3.5 FF 30 100" 20 H2O 100" 20 H2O 100" 20 H2O 100" 20 H2O 8003 18" 8003 18" 8003 18" 8003 28" C 21 DAP POST D Type BKPK BKPK BKPK BKPK C D CRACK A B 40 65 F 73 5 68 F 42 20" 20" 20" 20" B 10 DAP 0 76 F 50 63 F 5 4 68 F 5 4 95 CHEAL control CHEAL control ANGR control CHEAL SOLTU injury control percent percent percent percent percent percent percent percent percent percent percent 7/14/09 7/14/09 7/14/09 7/28/09 7/28/09 7/28/09 7/28/09 7/28/09 8/12/09 8/12/09 8/12/09 AT POST AT POST AT POST 14 DAPO 14 DAPO 14 DAPO 14 DAPO 14 DAPO 29 DAPO 29 DAPO 29 DAPO 1 AMARE ANGR control POROL control POLCO control SOLTU injury ANGR control control 10 11 3 2 4 5 6 7 8 9 Stg 82 0 DAP 0 DAP 10 DAP 10 DAP DF L L Lorox 50 DF 60 73 77 99 83 84 45 83 82 83 51 86 86 50 DF 50 75 DF DF 0 DAP Lorox 0 DAP 100 100 Activator 90 Activator 90 Rate Grow pt/a lb/a Lorox Sencor pt/a lb/a oz/a 1 1 0.33 pt/a lb/a lb/a oz/a 0 DAP 0 0 DAP 0 DAP MSU Weed Science Research Program 0 DAP 0 0 DAP 0 DAP 0 DAP pt/a 1 1 lb/a 0.125 lb/a DF DF 50 75 25 WG 1 Form Form Conc Type Rate Unit 1 50 1 25 WG 1 0 DAP 0 0 DAP 0 DAP POST 0.25 % v/v POST 0 DAP 0 0 DAP 0 DAP POST POST 0.25 % v/v POST Potato Timing Study, Montcalm, 2008 Trial ID: P0809 Study Dir.: Conducted: Montcalm Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 1 Dual Magnum 7.62 L 1 2 2 Dual Magnum 7.62 L 2 2 3 3 Dual Magnum 7.62 L 3 Lorox 3 Matrix 3 4 4 Dual Magnum 7.62 L Lorox 4 4 Sencor 4 Matrix 4 5 5 Dual Magnum 7.62 L 5 6 6 Dual Magnum 7.62 L 6 6 7 7 Dual Magnum 7.62 L 7 Lorox 7 Matrix 7 8 8 Dual Magnum 7.62 L Lorox 8 8 Sencor 8 Matrix 8 9 9 Dual Magnum 7.62 L 9 10 21 DAP 10 Dual Magnum 7.62 L 10 Lorox 10 Sencor 11 21 DAP 11 Dual Magnum 7.62 L 11 Lorox 11 Matrix 11 Activator 90 12 21 DAP 12 Dual Magnum 7.62 L 12 Lorox 12 Sencor 12 Matrix 12 Activator 90 21 DAP 0 21 DAP 21 DAP POST POST 0.25 % v/v POST pt/a lb/a lb/a oz/a 10 DAP 0 10 DAP 10 DAP POST POST 0.25 % v/v POST 21 DAP 0 21 DAP 21 DAP POST 0.25 % v/v POST 10 DAP 0 10 DAP 10 DAP POST 0.25 % v/v POST 1 50 1 25 WG 1 1 50 1 25 WG 1 50 75 25 WG 1 50 75 25 WG 1 pt/a 1 1 lb/a 0.125 lb/a pt/a 1 1 lb/a 0.125 lb/a 21 DAP 0 21 DAP 21 DAP 21 DAP 10 DAP 0 10 DAP 10 DAP 10 DAP 21 DAP 0 21 DAP 21 DAP 10 DAP 0 10 DAP 10 DAP pt/a lb/a lb/a oz/a 1 1 0.33 1 1 0.33 pt/a lb/a oz/a pt/a lb/a oz/a Lorox Sencor pt/a lb/a pt/a lb/a Activator 90 DF DF L DF DF L Activator 90 50 75 DF DF 50 75 DF DF 91 91 87 65 92 98 90 79 92 91 91 94 96 99 90 89 99 50 DF 73 73 83 94 94 98 21 DAP Lorox 87 90 70 100 90 96 94 99 DF L 1 1 1 1 1 1 10 DAP 10 DAP DF L 60 0 48 43 33 48 0 0 73 71 65 66 75 40 71 5 88 85 100 86 100 0 95 91 87 84 66 68 63 44 0 0 76 70 65 68 100 86 90 4 90 90 100 86 100 3 94 95 73 68 53 60 78 20 0 0 74 72 71 78 100 100 95 6 98 99 100 100 100 3 96 100 100 96 MSU Weed Science Research Program Potato Timing Study, Montcalm, 2008 Trial ID: P0809 Study Dir.: Conducted: Montcalm Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name LSD (P=.05) Standard Deviation CV Form Form Conc Type Rate Unit CHEAL control ANGR control CHEAL control 29.9 20.7 23.48 25.9 18.0 22.4 3.5 2.4 2.73 4.2 2.9 3.28 Rate Grow 0.0 0.0 0.0 Stg 2 3 31.1 21.5 26.81 39.4 27.3 39.8 35.9 24.9 35.87 6.1 4.2 252.37 11.1 7.7 9.35 13.0 9.0 10.94 CHEAL SOLTU injury control percent percent percent percent percent percent percent percent percent percent percent 7/14/09 7/14/09 7/14/09 7/28/09 7/28/09 7/28/09 7/28/09 7/28/09 8/12/09 8/12/09 8/12/09 AT POST AT POST AT POST 14 DAPO 14 DAPO 14 DAPO 14 DAPO 14 DAPO 29 DAPO 29 DAPO 29 DAPO 1 AMARE ANGR control POROL control POLCO control SOLTU injury ANGR control control 10 11 9 4 6 5 7 8 97 0 DAP 0 DAP 1 1 50 DF 84 34 10 DAP 10 DAP 74 100 DF L L 70 81 Lorox 50 DF 86 98 20 13 75 25 50 75 DF DF 0 DAP Lorox 0 DAP Activator 90 100 75 100 98 Activator 90 Rate Grow pt/a lb/a Lorox Sencor pt/a lb/a oz/a 1 1 0.33 pt/a lb/a lb/a oz/a 0 DAP 90 0 DAP 0 DAP MSU Weed Science Research Program pt/a 1 1 lb/a 0.125 lb/a 0 DAP 81 0 DAP 0 DAP 0 DAP Form Form Conc Type Rate Unit DF DF 50 75 25 WG 1 1 50 1 25 WG 1 0 DAP 99 0 DAP 0 DAP POST 0.25 % v/v POST 0 DAP 100 0 DAP 0 DAP POST POST 0.25 % v/v POST Potato Timing Study, Montcalm, 2008 Trial ID: P0809 Study Dir.: Conducted: Montcalm Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 1 Dual Magnum 7.62 L 1 2 2 Dual Magnum 7.62 L 2 2 3 3 Dual Magnum 7.62 L 3 Lorox 3 Matrix 3 4 4 Dual Magnum 7.62 L Lorox 4 4 Sencor 4 Matrix 4 5 5 Dual Magnum 7.62 L 5 6 6 Dual Magnum 7.62 L 6 6 7 7 Dual Magnum 7.62 L 7 Lorox 7 Matrix 7 8 8 Dual Magnum 7.62 L Lorox 8 8 Sencor 8 Matrix 8 9 9 Dual Magnum 7.62 L 9 10 21 DAP 10 Dual Magnum 7.62 L 10 Lorox 10 Sencor 11 21 DAP 11 Dual Magnum 7.62 L 11 Lorox 11 Matrix 11 Activator 90 12 21 DAP 12 Dual Magnum 7.62 L 12 Lorox 12 Sencor 12 Matrix 12 Activator 90 21 DAP 100 21 DAP 21 DAP POST POST 0.25 % v/v POST 10 DAP 100 10 DAP 10 DAP POST POST 0.25 % v/v POST 21 DAP 100 21 DAP 21 DAP POST 0.25 % v/v POST 10 DAP 98 10 DAP 10 DAP POST 0.25 % v/v POST 1 50 1 25 WG 1 1 50 1 25 WG 1 50 75 25 WG 1 DF DF 50 75 25 WG 1 21 DAP 93 21 DAP 21 DAP 21 DAP 10 DAP 90 10 DAP 10 DAP 10 DAP pt/a 1 1 lb/a 0.125 lb/a pt/a 1 1 lb/a 0.125 lb/a 21 DAP 93 21 DAP 21 DAP 10 DAP 92 10 DAP 10 DAP pt/a lb/a lb/a oz/a pt/a lb/a lb/a oz/a 1 1 0.33 1 1 0.33 pt/a lb/a oz/a pt/a lb/a oz/a Lorox Sencor pt/a lb/a pt/a lb/a Activator 90 DF DF L 100 98 100 98 100 58 100 100 100 100 100 38 100 90 50 75 DF DF 50 75 DF DF 98 35 97 96 45 32 Activator 90 Lorox 50 DF 98 96 40 31 95 95 25 94 DF L L 99 99 97 100 1 1 1 1 10 DAP 10 DAP 21 DAP DF L POLPE control CHEAL control POLCO control AMARE control percent percent percent percent percent percent 8/12/09 8/12/09 8/12/09 8/27/09 8/27/09 8/27/09 9/17/09 9/17/09 29 DAPO 29 DAPO 29 DAPO 44 DAPO 44 DAPO 44 DAPO HARVEST HARVEST HARVEST HARVEST 12 SOLTU SOLTU oversize oversize kilogram count 9/17/09 9/17/09 POLCO SOLTU control <1 7/8" <1 7/8" ANGR control kilogram count SOLTU 19 18 17 16 15 13 14 20 21 Stg 3 4.1090 79.5 0.0000 0 33 5.0835 95.4 -0.0210 0 21 4.7985 101.0 0.0827 0 84 5.2125 95.8 0.0000 0 40 5.5428 96.8 0.0080 0 83 4.0943 73.8 0.3505 0 73 4.7293 77.3 0.0000 0 96 6.1605 113.5 0.1588 0 74 5.1975 92.0 0.0000 0 73 4.3950 98.2 -0.0067 0 88 4.8728 86.3 0.1188 0 100 4.5050 178.8 0.0000 0 98 MSU Weed Science Research Program Potato Timing Study, Montcalm, 2008 Trial ID: P0809 Study Dir.: Conducted: Montcalm Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name LSD (P=.05) Standard Deviation CV Form Form Conc Type Rate Unit ANGR control CHEAL control 23.9 16.6 25.63 21.5 14.9 15.26 30.0 20.8 33.86 16.5 11.4 12.44 11.9 8.2 8.7 Rate Grow Stg 13 POLPE control POLCO control AMARE control percent percent percent percent percent percent 8/12/09 8/12/09 8/12/09 8/27/09 8/27/09 8/27/09 9/17/09 9/17/09 29 DAPO 29 DAPO 29 DAPO 44 DAPO 44 DAPO 44 DAPO HARVEST HARVEST HARVEST HARVEST 12 SOLTU SOLTU oversize oversize kilogram count 9/17/09 9/17/09 POLCO SOLTU control <1 7/8" <1 7/8" kilogram count SOLTU 17 15 14 16 19 21 18 20 38.9 27.0 42.32 1.52143 74.01 1.05214 51.18 21.51 51.69 0.37215 0.4 0.25736 0.3 446.97 350.61 99 SOLTU SOLTU SOLTU Grade A Grade A dry kilogram count 9/17/09 9/17/09 HARVEST HARVEST HARVEST HARVEST HARVEST 22 9/17/09 9/17/09 SOLTU wet SOLTU SPEC. GRAV. HH 9/17/09 25 26 24 23 Stg 76 1.0754509 10.1173 0.7670 1.0821638 0 DAP DF L 1 1 50 DF 10 DAP 10 DAP Activator 90 0 DAP Activator 90 L Lorox 50 DF 50 75 DF DF 0 DAP Lorox 0 DAP Rate Grow pt/a lb/a Lorox Sencor 10.1738 0.7810 10.0018 0.7038 8.3798 0.6412 9.9905 0.7618 pt/a lb/a oz/a 1 1 0.33 pt/a lb/a lb/a oz/a MSU Weed Science Research Program pt/a 1 1 lb/a 0.125 lb/a Form Form Conc Type Rate Unit DF DF 50 75 25 WG 1 0 DAP 9.7564 0 DAP 0 DAP 0 DAP 0 DAP 17.6218 177 0 DAP 0 DAP 1 50 1 25 WG 1 0 DAP 12.1491 105 0 DAP 0 DAP POST 0.25 % v/v POST 0 DAP 10.1738 89 0 DAP 0 DAP POST POST 0.25 % v/v POST Potato Timing Study, Montcalm, 2008 Trial ID: P0809 Study Dir.: Conducted: Montcalm Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 1 Dual Magnum 7.62 L 1 2 2 Dual Magnum 7.62 L 2 2 3 3 Dual Magnum 7.62 L 3 Lorox 3 Matrix 3 4 4 Dual Magnum 7.62 L Lorox 4 4 Sencor 4 Matrix 4 5 5 Dual Magnum 7.62 L 5 6 6 Dual Magnum 7.62 L 6 6 7 7 Dual Magnum 7.62 L 7 Lorox 7 Matrix 7 8 8 Dual Magnum 7.62 L Lorox 8 8 Sencor 8 Matrix 8 9 9 Dual Magnum 7.62 L 9 10 21 DAP 10 Dual Magnum 7.62 L 10 Lorox 10 Sencor 11 21 DAP 11 Dual Magnum 7.62 L 11 Lorox 11 Matrix 11 Activator 90 12 21 DAP 12 Dual Magnum 7.62 L 12 Lorox 12 Sencor 12 Matrix 12 Activator 90 10 DAP 10.1575 105 10 DAP 10 DAP POST POST 0.25 % v/v POST 21 DAP 10.0838 90 21 DAP 21 DAP POST POST 0.25 % v/v POST 10 DAP 16.0698 133 10 DAP 10 DAP POST 0.25 % v/v POST 21 DAP 11.4893 94 21 DAP 21 DAP POST 0.25 % v/v POST 10 DAP 14.9955 118 10 DAP 10 DAP 10 DAP 21 DAP 11.0737 91 21 DAP 21 DAP 21 DAP 1 50 1 25 WG 1 1 50 1 25 WG 1 21 DAP 13.9338 119 21 DAP 21 DAP 10 DAP 11.4286 103 10 DAP 10 DAP DF DF 50 75 25 WG 1 DF DF 50 75 25 WG 1 L pt/a 1 1 lb/a 0.125 lb/a pt/a 1 1 lb/a 0.125 lb/a pt/a lb/a lb/a oz/a pt/a lb/a lb/a oz/a 1 1 0.33 1 1 0.33 pt/a lb/a oz/a pt/a lb/a oz/a 7.3070 0.5643 9.9506 0.8046 9.8053 0.7548 10.7860 0.8130 Lorox Sencor pt/a lb/a pt/a lb/a Activator 90 50 75 DF DF 50 75 DF DF Lorox 50 DF Activator 90 10 DAP DF L L DF L 1 1 1 1 21 DAP 10 DAP 1.0822811 1.0828825 1.0830363 1.0877403 1.0833509 1.0836302 1.0816194 9.7858 0.7223 1.0796920 9.4723 0.7253 1.0831549 10.0838 0.7755 1.0834646 SOLTU SOLTU VD 0-10 0-10 9/17/09 9/17/09 HARVEST HARVEST HARVEST SOLTU BC 0-10 9/17/09 27 0 0 0 28 3 2 3 29 0 0 0 0 5 0 1 0 0 3 4 4 0 0 0 0 3 0 0 1 0 4 3 3 0 0 0 0 4 0 100 MSU Weed Science Research Program Potato Timing Study, Montcalm, 2008 Trial ID: P0809 Study Dir.: Conducted: Montcalm Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name LSD (P=.05) Standard Deviation CV ARM Action Codes T1 = ([24])/([24]-[25]) SOLTU Grade A Grade A dry kilogram count 9/17/09 9/17/09 HARVEST HARVEST HARVEST HARVEST HARVEST 22 5.26150 44.1 3.63857 30.5 29.32 28.15 Form Form Conc Type Rate Unit 9/17/09 9/17/09 SOLTU wet SOLTU SOLTU Rate Grow Stg 23 24 25 26 SOLTU SPEC. GRAV. HH 9/17/09 SOLTU SOLTU VD 0-10 0-10 9/17/09 9/17/09 HARVEST HARVEST HARVEST SOLTU BC 0-10 9/17/09 27 28 29 2.08632 0.16638 0.00533230 0.7 1.44279 0.11506 0.00368753 0.5 14.94 15.66 0.34 254.61 2.3 1.6 49.15 0.2 0.1 692.82 101 Funding: Agrochemical Industry Seed Treatment Trials 2008-2009. W. W. Kirk, R. L Schafer and P. Tumbalam Department of Plant Pathology, Michigan State University, East Lansing, MI 48824 Seed treatments and seed plus foliar treatments for control of seed- and soil-borne Rhizoctonia, 2008. Potatoes with Rhizoctonia solani (black scurf), 2- 5% tuber surface area infected, were selected for the trials. Potato seed was prepared for planting by cutting and treating with fungicidal seed treatments two days prior to planting. Seed were planted at the Michigan State University Muck Soils Experimental Station, Bath, MI on 4 Jun into two-row by 20-ft plots (ca. 10-in between plants to give a target population of 50 plants at 34-in row spacing) replicated four times in a randomized complete block design. The two-row beds were separated by a five-foot unplanted row. Dust formulations were measured and added to cut seed pieces in a Gustafson revolving drum seed treater and mixed for two minutes to ensure even spread of the fungicide. Fungicides applied as pre-planting potato seed liquid treatments were applied in water suspension at a rate of 0.2 pt/cwt onto the exposed seed tuber surfaces, with the entire seed surface being coated in the Gustafson seed treater. In- furrow at-planting applications were delivered at 8 pt H2O/A in a 7” band using a single XR11003VS nozzle at 30 p.s.i. Foliar applications were applied with a R&D spray boom delivering 25 gal/A (80 p.s.i.) and using three XR11003VS nozzles per row. Fertilizer was drilled into plots before planting, formulated according to results of soil tests. Additional nitrogen (final N 28 lb/A) was applied to the growing crop with irrigation 45 DAP (days after planting). Previcur Flex was applied at 0.7 pt/A on a seven-day interval, total of four applications, starting one day after inoculation of adjacent plots with Phytophthora infestans. Weeds were controlled by hilling and with Dual 8E at 2 pt/A 10 DAP, Basagran at 2 pt/A 20 and 40 DAP and Poast at 1.5 pt/A 58 DAP. Insects were controlled with Admire 2F at 1.25 pt/A at planting, Sevin 80S at 1.25 lb/A 31 and 55 DAP, Thiodan 3 EC at 2.33 pt/A 65 and 87 DAP and Pounce 3.2EC at 8 oz/A 48 DAP. Vines were killed with Reglone 2EC (1 pt/A on 20 Sep). Plots (20-ft row) were harvested on 16 Oct and individual treatments were weighed and graded. Four plants per plot were harvested 10-days after the final treatment application (13 Jul) and the percentage of stems and stolons with greater than 5% of the total surface area were counted. An index of below ground health was evaluated 35 DAP on a scale of 0 - 5 where 0 = no symptoms of stem canker, 1 = 1 – 5%, 2 = 6 – 10%, 3 = 11 – 20%, 4 = 21 – 50%, 5 = 50 – 100% of the surface of roots, stolons and stem affected by Rhizoctonia. Samples of 50 tubers per plot were harvested 14 days after desiccation and assessed for black scurf (R. solani) incidence (%) and severity 40 days after harvest. Severity of black scurf was measured as an index calculated by counting the number of tubers (n = 50) falling into each class 0 = 0%; 1 = 1 - 5%; 2 = 6 -10%; 3 = 11 - 15; 4 >15% surface area of tuber covered with sclerotia. The number in each class is multiplied by the class number and summed. The sum is multiplied by a constant to express as a percentage. Indices of 0 - 25 represent 0 - 5%; 26 - 50 represent 6 - 10%; 51 - 75 represent 11 - 15% and 75 - 100 >15% surface area covered with sclerotia. Meteorological variables were measured with a Campbell weather station located at the farm, latitude 42.8269 and longitude -84.365deg. Maximum, minimum and average daily air temperature (oF) were 81.2, 25.3 and 53.1 and 0-d with maximum temperature >90oF (May); 91.9, 39.6 and 66.7 and 1-d with maximum temperature >90oF (Jun); 89.9, 38.3 and 68.5 and 0-d with maximum temperature >90oF (Jul); 87.9, 35.5 and 65.6 and 0-d with maximum temperature >90oF (Aug); 91.7, 33.3 and 59.3 and 1-d with maximum temperature >90oF (Sep). Maximum, minimum and average daily soil temperature (oF) were 78.0, 41.4 and 58.1 (May); 81.6, 52.6 and 67.7 (Jun); 82.2, 55.8 and 71.1 (Jul); 85.7, 55.2 and 71.4 (Aug); 81.8, 51.6 and 65.3 (Sep). Maximum, minimum and average soil moisture (% of field capacity) 80.2, 74.0 and 76.6 (May); 91.1, 73.5 and 81.5 (Jun); 100.8, 77.0 and 83.2 (Jul); 97.0, 76.5 and 81.0 (Aug); 123.1 (flooding), 76.6 and 84.3 (Sep). Precipitation was 1.08 in. (May), 3.59 in. (Jun), 3.69 in. (Jul), 1.56 in. (Aug) and 7.02 in. (Sep). Plots were irrigated to supplement precipitation to about 0.1 in./A/4 day period with overhead sprinkle irrigation. No treatment affected final plant stand. Seven treatments resulted in significantly improved seed emergence rates 31 DAP (RAUEPC values greater than 14.2) compared to the untreated check (RAUEPC = 9.4). Marketable yield and total ranged from 236 to 324 cwt/A (untreated check = 255 cwt/A) and 265 to 354 cwt/A (untreated check = 288 cwt/A), respectively, but no treatments were significantly different from the untreated check or from the standard commercial seed treatment Maxim FS. No treatment affected the total number of stolons or stem number per plant. Treatments with less than 51.6% incidences of stems with >5% girdling due to Rhizoctonia stem canker were significantly different from the untreated check. No treatments had significantly less stolon canker incidence in comparison to Maxim FS or the untreated check. Treatments resulting in less than 42.5% incidence of tubers with black scurf were significantly lower than the untreated check. Treatments with less than 38.8% incidence of tubers with black scurf were not significantly different from Maxim FS. Treatments with less than 19.1% severity index of tubers with black scurf were significantly lower than the untreated check (29.4%). Treatments with less than 16.3% severity index of tubers with black scurf were not significantly different from Maxim FS (6.3%). Seed treatments and seed treatment plus fungicide applications of fungicides were not phytotoxic. 102 Treatment and rate/1000 row feet and rate/cwt potato seed Maxim 4FS 0.16 fl oz/cwt (Ay)… LEM 17 200EC 0.67 fl oz (B)….... LEM 17 200EC 1.15 fl oz (B)….... LEM 17 200EC 1.6 fl oz (B)…….. LEM 200SC 1.6 fl oz (B)………… Quadris 2.08SC 0.4 fl oz (B)…….. Evito 4FL 0.26 fl oz (B)………..... BUPOT-1 3.4SC 0.3 fl oz/cwt (A).. BUPOT-1 3.4SC 0.5 fl oz/cwt (A).. BUPOT-3 3.4SC 0.3 fl oz/cwt (A).. BUPOT-3 3.4SC 0.5 fl oz/cwt (A).. BUPOT-5 3.4SC 0.3 fl oz/cwt (A).. BUPOT-5 3.4SC 0.5 fl oz/cwt (A).. BUPOT-7 3.4SC 0.3 fl oz/cwt (A).. BUPOT-7 3.4SC 0.5 fl oz/cwt (A).. WE1042-1 6DS 0.75 lb/cwt (A)….. WE1043-1 6DS 0.75 lb/cwt (A)….. WE1044-1 6DS 0.75 lb/cwt (A)….. Untreated Check………………..... HSD0.05 Funding: Agrochemical Industry Final plant stand Yield (cwt/A) (%) ax a a a a a a a a a a a a a a a a a a 84.5 89.0 90.5 91.5 87.5 87.0 88.0 85.5 89.5 91.0 85.5 85.0 89.0 87.5 88.0 91.0 84.5 89.5 68.0 14.18 RAUEPCz 11.1 bcd ab 15.1 a 16.6 abc 14.2 a-d 13.6 ab 14.6 a 16.9 13.2 a-d 12.2 bcd 15.2 10.4 11.3 bcd 10.3 13.0 13.5 14.4 13.4 12.8 cd a-d a-d abc a-d a-d ab cd 9.4 d US1 a a a a a a a a a a a a a a a a a a a 278 257 324 290 280 286 293 317 305 264 286 254 236 270 275 252 270 275 255 Total a a a a a a a a a a a a a a a a a a a 310 286 354 321 311 316 325 351 337 296 319 288 265 306 307 284 309 305 288 4.26 59.6 61.0 Stems (35 DAP) Stolons (35 DAP) Root and lower stem canker index Tuber black scurf Severity scale (0 - 100) 6.3 d cd 12.8 16.3 bcd e Num ber/ plant 8.4 7.3 7.1 7.8 8.9 9.4 7.7 7.6 7.1 7.8 6.9 8.0 7.7 8.4 8.3 8.1 7.6 8.9 9.5 1.95 Girdlingv 35 DAPu (0 – 5) f ef 7.2 d Incidence (%) 20 35 b-f 42.5 bcd ef 21.3 37.5 b-f 33.8 b-f 26.3 def 22.5 Num -ber 3.8 3.6 4.1 3.8 3.9 4.3 3.6 4.4 4.2 3.9 4.1 3.6 4.3 4.2 4.2 3.5 3.8 3.9 4.6 1.10 Percent infectedw 31.7 d-g 29.5 d-g 42.0 cde 34.3 def 21.0 fg 16.7 g 24.3 fg 26.8 e-g 63.1 ab 51.6 bc 55.3 abc 33.0 d-f 40.9 c-e 44.0 cd 33.2 d-f 42.1 cde 41.4 cde 30.8 d-f 71.7 15.81 Treatment and rate/1000 row feet and rate/cwt potato seedz Maxim 4FS 0.16 fl oz/cwt (A)…… LEM 17 200EC 0.67 fl oz (B)….... LEM 17 200EC 1.15 fl oz (B)….... LEM 17 200EC 1.6 fl oz (B)……. LEM 200SC 1.6 fl oz (B)……….. Quadris 2.08SC 0.4 fl oz (B)……. Evito 4FL 0.26 fl oz (B)……….... BUPOT-1 3.4SC 0.3 fl oz/cwt (A). BUPOT-1 3.4SC 0.5 fl oz/cwt (A). BUPOT-3 3.4SC 0.3 fl oz/cwt (A). BUPOT-3 3.4SC 0.5 fl oz/cwt (A). BUPOT-5 3.4SC 0.3 fl oz/cwt (A). BUPOT-5 3.4SC 0.5 fl oz/cwt (A). BUPOT-7 3.4SC 0.3 fl oz/cwt (A). BUPOT-7 3.4SC 0.5 fl oz/cwt (A). WE1042-1 6DS 0.75 lb/cwt (A)…. WE1043-1 6DS 0.75 lb/cwt (A)…. WE1043-1 6DS 0.75 lb/cwt (A)…. Untreated Check……………….... HSD0.05 z RAUEPC = Relative area under the emergence progress curve measured from planting to 31 days after planting y Application dates: A= 4 Jun (liquid formulations for seed piece application at 0.2 pt/cwt; B= 4 Jun (in-furrow); C= 29 Jun (banded over row). x Values followed by the same letter are not significantly different at p = 0.05 (Honest Significant Difference; Tukey Multiple Comparison). w Stems with greater than 5% of area with stem canker due to Rhizoctonia solani. v Stolons with greater than 5% of area with stolon canker due to Rhizoctonia solani. u An index of below ground health was evaluated 35 DAP on a scale of 0 - 5 (see text) a-e 1.7 1.3 c-e 1.5 b-e 1.3 cde 1.0 e 1.1 de 1.0 1.4 b-e 2.1 ab a-d 1.9 a-e 1.7 a-e 1.7 a 2.3 2.0 abc a-d 1.9 a-d 1.9 a-d 1.8 1.7 a-e 2.3 a 0.75 > 5% a a a a a a a a a a a a a a a a a a a 6.5 4.5 12.4 9.9 7.0 7.6 7.8 4.1 19.8 8.7 7.5 4.2 6.3 10.5 9.3 8.9 11.5 9.2 15.9 25 def 38.8 b-f 26.3 def 36.3 b-f 32.5 b-f 28.8 c-f 40 b-e 51.3 ab 36.3 b-f 46.3 abc a 65.0 19.96 10.05 15.3 bcd 12.8 12.2 8.8 9.1 cd cd cd cd cd 14.7 bcd 10.0 13.8 bcd 12.8 8.8 cd cd ab 14.1 bcd 24.1 15.0 bcd 19.1 abc 29.4 a 10.33 a 103 Funding: Agrochemical Industry Seed treatments and seed plus foliar treatments for control of seed- and soil-borne Rhizoctonia, 2009. Potatoes with Rhizoctonia solani (black scurf), 2- 5% tuber surface area infected, were selected for the trials. Potato seed was prepared for planting by cutting and treating with fungicidal seed treatments two days prior to planting. Seed was planted at the Michigan State University Muck Soils Experimental Station, Bath, MI on 4 Jun into two-row by 20-ft plots (ca. 10-in between plants to give a target population of 50 plants at 34-in row spacing) replicated four times in a randomized complete block design. Due to flooding (see meteorological data below) the plots were destroyed and replanted on 8 Jul. The two-row beds were separated by a five-foot unplanted row. Dust formulations were measured and added to cut seed pieces in a Gustafson revolving drum seed treater and mixed for two minutes to ensure even spread of the fungicide. Fungicides applied as pre-planting potato seed liquid treatments were applied in water suspension at a rate of 0.2 pt/cwt onto the exposed seed tuber surfaces, with the entire seed surface being coated in the Gustafson seed treater. In- furrow at-planting applications were delivered at 8 pt H2O/A in a 7” band using a single XR11003VS nozzle at 30 p.s.i. Foliar applications of Previcur Flex 0.7 pt/A + Bravo WS 6SC 1.5 pt/A were applied for maintenance on a 7-day schedule from 10 Aug to 15 Sep with a R&D spray boom delivering 25 gal/A (80 p.s.i.) and using three XR11003VS nozzles per row. Fertilizer was drilled into plots before planting, formulated according to results of soil tests. Additional nitrogen (final N 28 lb/A) was applied to the growing crop with irrigation 45 DAP (days after planting). Weeds were controlled by hilling and with Dual 8E at 2 pt/A 10 DAP, Basagran at 2 pt/A 20 and 40 DAP and Poast at 1.5 pt/A 48 DAP. Insects were controlled with Admire 2F at 1.25 pt/A at planting (except where CruiserMaxx and Valent formulations were applied), Sevin 80S at 1.25 lb/A 31 and 55 DAP, Thiodan 3 EC at 2.33 pt/A 65 DAP and Pounce 3.2EC at 8 oz/A 48 DAP. Vines were killed with Reglone 2EC (1 pt/A on 20 Sep). Plots (20-ft row) were harvested on 16 Oct however there was insufficient tuber development to justify yield analyses. Four plants per plot were harvested 105 DAP and the percentage of stems and stolons with greater than 5% of the total surface area were counted. An index of below ground health was evaluated 35 DAP on a scale of 0 - 5 where 0 = no symptoms of stem canker, 1 = 1 – 10%, 2 = 11 – 20%, 3 = 21 – 30%, 4 = 31 – 50%, 5 = 51 – 100% of the surface of roots, stolons and stem affected by Rhizoctonia calculated by adding the % incidence and % severity and dividing by 2. Samples of 20 tubers per plot were harvested 14 days after desiccation and assessed for black scurf (R. solani) incidence (%) and severity 40 days after harvest. Severity of black scurf was measured as an index calculated by counting the number of tubers (n = 50) falling in class 0 = 0%; 1 = 1 - 5%; 2 = 6 -10%; 3 = 11 - 15; 4 >15% surface area of tuber covered with sclerotia. The number in each class is multiplied by the class number and summed. The sum is multiplied by a constant to express as a percentage. Indices of 0 - 25 represent 0 - 5%; 26 - 50 represent 6 - 10%; 51 - 75 represent 11 - 15% and 75 - 100 >15% surface area covered with sclerotia. Meteorological variables were measured with a Campbell weather station located at the farm, latitude 42.8269 and longitude -84.365deg. Maximum, minimum and average daily air temperature (oF) were 84.2, 28.9 and 55.9 and 0-d with maximum temperature >90oF (May); 95.8, 35.9 and 64.9 and 2-d with maximum temperature >90oF (Jun); 82.9, 40.1 and 64.2 and 0-d with maximum temperature >90oF (Jul); 91.5, 37.4 and 67.0 and 2-d with maximum temperature >90oF (Aug); 83.1, 31.8 and 60.4 and 0-d with maximum temperature >90oF (Sep); 62.7, 23.8 and 44.5 and 0-d with maximum temperature >90oF (to 15 Oct). Maximum, minimum and average daily soil temperature (oF) were 68.1, 47.4 and 57.9 (May); 78.7, 55.9 and 66.6 (Jun); 73.3, 61.4 and 67.4 (Jul); 75.6, 59.7 and 69.2 (Aug); 68.4, 55.9 and 63.6 (Sep); 56.3, 45.6 and 51.8oF (to 15 Oct). Maximum, minimum and average soil moisture (% of field capacity) 77.2, 62.4 and 66.9 (May); 77.0, 60.8 and 67.2 (Jun); 76.7, 58.2 and 63.7 (Jul); 75.0, 55.1 and 61.7 (Aug); 58.7, 52.1 and 54.2 (Sep); 57.4, 52.5 and 54.5oF (to 15 Oct). Precipitation was 2.98 in. (May), 5.76 in. (Jun), 5.62 in. (Jul), 5.25 in. (Aug), 1.09 in. (Sep) and 1.25 in. to 15 Oct. Plots were irrigated to supplement precipitation to about 0.1 in./A/4 day period with overhead sprinkle irrigation. The plots were flooded in Jun due to extensive rainfall. Seed tubers were treated and plots were replanted on 8 Jul after the soil had dried sufficiently. The plots flooded again in late Jul and again in mid Aug. Emergence was reduced by these events. The final plant stand in the untreated control (63.0%) was not significantly different from any of the treatments, which ranged from 63.0 to 76.5%. No significant differences in seed emergence at 31 DAP (RAUEPC values ranged from 21.5 to 31.2 with the untreated control = 21.5), were observed. Marketable yield and total yield were not measured due to insufficient development of tubers. Only Maxim had significantly greater stems/plant in comparison to the untreated control (5.0 stems/plant) and LEM17 200EC 1.63 fl oz had significantly fewer. No differences were found among the treatments in terms of stolon number per stem, which ranged from 7.6 to 10.6; (untreated control = 7.9). All treatments had significantly lower incidence of stems with >5% girdling due to Rhizoctonia stem canker in comparison to the untreated control (71.2%). All treatments had significantly less stolon canker in comparison to the untreated control (61.5%). Treatments resulting in greater than 43.3% stems/plant girdled had significantly higher canker incidence in comparison to Maxim MZ, the standard commercial seed treatment (34.4%). The overall severity index of root and lower stem canker indicated that treatments with an index value lower than 4.3 had significantly less Rhizoctonia stem and stolon canker than the untreated control (4.9). No treatments had significantly less Rhizoctonia stem and stolon canker in comparison with Maxim MZ (3.4). Two treatments (LEM17 200EC 1.63 fl oz and YT6692.08SC 0.85 fl oz) resulted in significantly lower tuber black scurf incidence than the use of Quadris. Only one treatment (Actinovate) showed no significant reduction in tuber black scurf incidence relative to the untreated control. The severity of tuber black scurf in all treatments was significantly less than in the untreated control (37.8%). No treatments were significantly different in comparison to Maxim MZ (19.7). No phytotoxicity was observed in any treatment. 104 Treatment rate/cwt potato seed (A)z and rate/1000 row feet (B) LEM17 200EC 0.72 fl oz (Bx)……… LEM17 200EC 1.63 fl oz (B)………. LEM17 200EC 3.26 fl oz (B)………. YT669 2.08SC 0.85 fl oz (B)………. YT669 2.08SC 1.27 fl oz (B)………. LEM17 200EC 1.25 fl oz (A)………. Quadris 2.08SC 0.576 fl oz (B)…….. Maxim MZ 10.1DS 0.5 lb (A)……… Actinovate 0.0371WP 0.103 oz (B)… Untreated Control…………………... LSD0.05 Treatment rate/cwt potato seed (A)z LEM17 200EC 0.72 fl oz (B)………. LEM17 200EC 1.63 fl oz (B)………. LEM17 200EC 3.26 fl oz (B)………. YT669 2.08SC 0.85 fl oz (B)………. YT669 2.08SC 1.27 fl oz (B)………. LEM17 200EC 1.25 fl oz (A)………. 46.7 bc Quadris 2.08SC 0.041 fl oz (B)…….. 43.3 bcd Maxim MZ 10.1DS 0.5 lb (A)……… 34.4 d Actinovate 0.0371WP 0.103 oz (B)… 44.7 bc Untreated Control…………………... 71.2 a Funding: Agrochemical Industry Final plant stand (%) RAUEPCy Stem number/plant Stolon number/stem 70.0 72.0 76.5 72.0 69.0 70.0 71.0 71.0 66.5 63.0 aw a a a a a a a a a 22.8 31.2 28.7 26.7 24.4 26.5 21.9 27.1 27.6 21.5 a a a a a a a a a a 5.4 3.8 4.7 4.8 4.6 4.9 5.8 7.2 4.6 5.0 bc d cd bcd cd bcd b a cd bc 9.9 8.1 10.0 10.6 10.1 8.9 9.2 9.9 7.6 7.9 a a a a a a a a a a 7.97 8.44 1.11 2.24 Percent stem girdlingv >5% Percent stolon girdlingu > 5% Root and lower stem canker index 35 DAPt (0 – 5) Tuber black scurf Incidence (%) Severity scale (0 - 100) 39.0 44.8 37.7 50.0 50.5 cd bc cd b b 47.1 bc 31.6 31.9 40.5 d d c 47.5 bc 49.8 39.9 25.1 27.3 61.5 b c d d a 4.1 3.8 3.8 4.3 4.3 4.3 3.8 3.4 3.8 4.9 bc cd cd b b b cd d cd a 48.8 bc 42.5 c 46.3 bc 40.0 c 47.5 47.5 bc bc 57.5 b 47.5 60.0 bc ab 73.8 a 17.5 bc 14.7 c 19.1 bc 15.6 c 19.4 20.0 bc bc 24.1 b 19.7 bc 23.4 37.8 b a 9.12 8.03 12.91 LSD0.05 z Application type; rate per 1000 row ft for in-furrow applications; rate per cwt of potato seed-piece application prior to planting; liquid formulations for seed piece application at 0.2 pt/cwt. y RAUEPC = Relative area under the emergence progress curve measured from planting to 31 days after planting. x Application dates: A= 8 Jul (liquid formulations for seed piece application at 0.2 pt/cwt); B= 8 Jul (in-furrow). w Values followed by the same letter are not significantly different at p = 0.05 (Fishers LSD). v Stems with greater than 5% of area with stem canker due to Rhizoctonia solani. u Stolons with greater than 5% of area with stolon canker due to Rhizoctonia solani. t An index of below ground health was evaluated 35 DAP on a scale of 0 - 5 where 0 = no symptoms of stem canker, 1 = 1 – 10%, 2 = 10 – 20%, 3 = 21 – 30%, 4 = 31 – 50%, 5 = 51 – 100% of the surface of roots, stolons and stem affected by Rhizoctonia. 0.39 6.51 105 A.S. Grandy MPIC 2009 Research Report Long-Term Research: Simultaneous Management of Disease Suppression and Soil Quality in Potatoes Introduction Potato cropping systems present two fundamental challenges: maintaining soil quality and keeping plant diseases below economic thresholds. We believe that these challenges are intertwined and that declines in organic matter and biological function may contribute to increased severity of soil diseases, such as potato common scab (Streptomyces scabies). Diseases are ubiquitous in Michigan potato production systems and their effects on yield or quality can be dramatic. Organic amendments, such as compost or manure, can build soil quality and may provide an additional line of defense against disease. Organic amendment applications, especially in sandy soils used to produce potatoes and many other vegetable crops have been shown to suppress a range of common plant diseases. Michigan potato producers have begun using compost and manure to build organic matter and associated functions but there has, to date, been little research on optimizing compost or manure application rates, timing, and quality to increase soil health and maximize yields and income. The key to broader deployment of these soil-building practices is to demonstrate their advantages and develop specific, economical recommendations for their use. My overall objective in 2009 was to examine the effects of different organic amendment application rates on soil quality, disease, and yield. Approach In 2009, we initiated a study investigating 7 different treatments (Table 1). The first set of treatments (treatments 1-3) receives a total of 6.8 tons of amendment C ha-1 (Herbruck chicken manure compost) during the experiment. This C is applied once (treatment 1), two (treatment 2), or four applications (treatment 3). Treatments 4-6 receive 13.6 tons of amendment C ha-1 applied at different frequencies, similar to treatments one through three. The seventh treatment is a control that receives no organic amendments. Plot management conforms to Michigan State University recommendations and the amendment is a chicken manure-based product from Herbruck’s, one of the primary suppliers to the MI potato industry. The site that we initiated this experiment on in 2009 has heavy scab pressure. In 2009 there was only one amendment application so soil and crop responses to the frequency of amendment applications cannot be assessed yet. Results and Discussion We found that aged chicken manure increased yields relative to the control (Figure 1). The highest yields were associated with the highest application rates. Treatments 1 (6.8 ton C ha-1), 4 (13.6 ton C ha-1) and 5 (6.8 ton C ha-1) had the highest yields of potatoes and also the highest amendment application rates. Some of the lower manure application rates gave marginally higher yields than the control treatment but the experiment needs to be repeated to confirm if these trends are stable through different environmental conditions. We also found that the lowest scab incidence was associated with treatments 1, 4, and 5 but the lower application rates had little effect on scab or vascular discoloration (Figure 2). In contrast, vascular discoloration seemed marginally higher in the treatments with the highest application rates. 106 Table 1. Organic amendment treatments that we use in the amendment rate x timing study at the Montcalm Research Farm. The potato variety that we use is Snowden. Total number of applicatio Timing of amendment applications Total C addition over entire experiment ton C ha-1 1) Initiation (early spring year 1) 1) Initiation (early spring year 1); 2) after wheat harvest (year 2) 1) Initiation (early spring year 1); 2) after potato harvest (year 1); 3) after wheat harvest (year 2); 4) prior to potato planting (year 3) same as above for 1 application same as above for 2 applications same as above for 4 applications . 6.8 6.8 6.8 13.6 13.6 13.6 0 ns 1 2 4 1 2 4 0 Rate of amendment addition ton C ha-1 6.8 3.4 1.7 13.6 6.8 3.4 0 Treatment 1 2 3 4 5 6 Control (7) Figure 1. Amendment effects on potato crop yield. See Table 1 for description of treatments. NP is an unfertilized treatment while treatment 7 is the conventionally managed control. Figure 2. Amendment effects on potato scab. See table 1 for description of treatments. NP is an unfertilized treatment while treatment 7 is the conventionally managed control. 107 Soil inorganic nitrogen, both ammonium and nitrate, were generally increased by organic amendments (Figure 3). In August, 2009, the highest soil nitrate and ammonium concentrations were found in treatment 4. Higher levels of nitrate were found in all of the amended treatments relative to the control and ammonium concentrations were also quite a bit higher in all of the amended treatments except treatment 3. It is likely that the organic amendment provides a source of N that begins mineralizing in June when the soil temperature is substantially warmer and continues releasing N during the growing season provided that supply is not exhausted and there is an adequate supply of soil water. NH4-N Aug 13th 2009 1 2 3 4 5 6 7 Mean±SE 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 l i o s / g N - 4 H N g u Soil biological processes were increased by amendment application but the extent of the increase varied. The highest microbial biomass carbon was found in treatment 5 and the highest microbial biomass nitrogen in treatments 4 and 5 (Figure 4). However, all of the treatments, except 1 and 2, exhibited higher microbial biomass nitrogen than the control. We also found that amendments tended to increase amendment soil enzyme activities but, interestingly, these increases were erratic (Figure 5). The highest application rate, treatment 4, exhibited consistently lower enzyme activities than some of the other amended treatments. We are in the process of analyzing data from the rest of the summer. It is too early to make any definitive conclusions from the limited data set we present here. In general, it appears that organic amendments applied at high rates can increase yields and decrease scab despite increasing pH. Indeed, the pH differences among the sites is interesting and we need to go and look more closely at whether these large differences occur throughout the season in response to amendments or whether the one date presented here is an anomaly (Figure 6). The greater microbial biomass Figure 3. Organic amendment effects on soil nitrate (top) and ammonium (bottom). See Table 1 for treatment details. carbon and nitrogen and higher enzyme activities in the amended plots suggest that this product does have the potential to significantly enhance soil biological activity. More research is needed to determine whether changes in soil nitrogen, biological activity, or some other factor resulted in the yield differences that we measured. We began this experiment in part wanting to determine whether low rates of organic amendment application could improve soil quality and yields. It is clear from this study that very high rates of application can improve soil quality and increase potato yields, at least in the short term. It is less clear from the limited data that we currently have available whether or not very low rates of application improve soil quality and yields. While there are indications that low application rates are nudging soils and yields in a positive direction it is too early tell what 108 T4 5 6 7 120 1 2 3 350 T1 T5 200 150 100 300 250 Jul 1st Jul 29th Jul 16th 0 Jun 2nd g / h / l o m n 50 0 T3 T6 100 T2 Jun 18th 80 60 40 20 T7 4 Trt , C B M g / C g u Mean±SE Aug 13th 2009 Aug 13th 2009 β 1,4 glucosidase the long-term implications will be. One key question is whether long-term low application rates can result in the kind of differences we see in the short term with higher rates. Figure 4. Amendment effects on microbial biomass carbon (top) and nitrogen (bottom). See Table 1 for amendment treatments. Figure 5. Amendment effects on soil enzymes. See Table 1 for amendment treatments. Mean±SE / g N g u , N B M 4 Trt Sep 23rd ) v / w 2 : 1 ( Aug 13th Aug 24th 7.0 6.8 6.2 6.0 5.8 1 2 5 6 7 H p 6.4 4 Trt 50 40 30 20 10 5 6 7.2 6.6 0 1 2 3 7 T1 T2 T3 T4 T5 T6 T7 Sep 9th Oct 13th 3 Mean±SE Figure 6. Amendment effects on pH. See Table 1 for amendment treatments. 109 Potato Insect Biology and Management Report to the Michigan Potato Industry Commission 14 January 2010 Adam M. Byrne, Walter L. Pett, Zsofia Szendrei, and Edward J. Grafius Outline. I. Resistance to Colorado potato beetle populations to imidacloprid and thiamethoxam was evaluated for field populations from Michigan, as well as other locations in the Midwest and locations in the northeastern U.S. II. Field insecticide evaluations of registered and experimental insecticides. I. Resistance of Colorado potato beetle populations to imidacloprid and thiamethoxam. Imidacloprid (Admire Pro®) and thiamethoxam (Platinum®, Actara®) continue to be the most common means of Colorado potato beetle control. Today, greater than 75% of the acres in the northeastern and midwestern United States are protected by these compounds (NASS 2006). Such consistent and heavy dependency on any compound sets the stage for resistance development. Further complicating the issue is the availability of generic imidacloprid formulations; these formulations drive down product cost, which will likely lead to even greater field exposure to these compounds. All of these reasons strongly support the need to continue monitoring resistance development and to encourage growers to adopt strong resistance management strategies. Our objectives were to continue gathering data on susceptibility to imidacloprid and thiamethoxam in Colorado potato beetle populations collected from commercial potato fields in Michigan and other regions of the United States. A second objective was to monitor the correlations between imidacloprid and thiamethoxam susceptibility. To accomplish these objectives, 27 Colorado potato beetle populations (13 Michigan populations, 12 populations collected in other states, and two laboratory populations) were bioassayed with imidacloprid and/or thiamethoxam. Methods During 2009, 13 Colorado potato beetle populations were collected from four Michigan counties (Isabella, Kalkaska, Mecosta, and Montcalm). Cooperators also provided single populations from Delaware, Minnesota, and New York; two populations from Maine and Virginia; and five populations from Wisconsin. Two laboratory strains were also tested (Table I.1). 110 Colorado potato beetle adults were either kept at room temperature (25±1° C) and fed foliage daily or, for longer term storage, kept in controlled environment chambers (11±1° C) and fed weekly. A preliminary screen was conducted on some populations (for populations tested in previous years, screening was sometimes not necessary) to determine relative susceptibility to imidacloprid and thiamethoxam by testing 15 beetles each with one concentration of insecticide/acetone solution. Based on the results from these screens, a range of five concentrations was selected for each population to be assayed and each bioassay was replicated up to three times. In each replicate, 7-15 beetles were treated with each concentration (three to five beetles per dish and two to three dishes per concentration). Beetles were treated with 1 µl of acetone/insecticide solution of known concentration applied to the ventral surface of the abdomen using a 50 µl Hamilton® microsyringe. Following treatment, beetles were placed in 100 mm diam. petri dishes lined with Whatman® No. 1 filter paper and provided with fresh potato foliage. They were kept at 25±1° C and the foliage and filter paper were checked daily and changed as needed. Beetle response was assessed 7 days post treatment. A beetle was classified as dead if its abdomen was shrunken, it did not move when its legs or tarsi were pinched, and its elytra were darkened. A beetle was classified as walking and healthy if it was able to grasp a pencil and walk forward normally. A beetle was classified as poisoned if its legs were extended and shaking, it was unable to right itself or grasp a pencil, and it was unable to walk forward normally at least one body length. Beetles that had died due to Beauvaria spp. infection were excluded from analysis; these beetles were easily recognized by their pale, petrified appearance and/or presence of white filamentous fungi. Dead and poisoned beetle numbers were pooled for analysis. Data were analyzed using standard log-probit analysis (SAS® System v9.1.3, SAS Institute 2006). Results The imidacloprid LD50 value (dose lethal to 50% of the beetles) for the susceptible laboratory strain (New Jersey) was 0.065 µg/beetle (Table I.2), slightly higher but still statistically similar to values from previous years. The LD50 values from the field for imidacloprid ranged from 0.403 µg/beetle (overwintered adults from Andersen Brothers field 41) to 2.297 µg/beetle (Paul Main field R5) for Michigan populations (Figure I.1) and from 0.069 µg/beetle (Crookston, MN) to 4.981 µg/beetle (Delaware, DE) for out-of- state populations (Figure I.2A, Table I.2). Significant levels of resistance to imidacloprid were again present in Michigan. All but one Michigan population tested was greater than 10-fold resistant to imidacloprid; between 10 and 20-fold is often where control problems begin to appear in the field. The proportion of Michigan samples showing greater than 10-fold resistance to imidacloprid was down slightly from 90% in 2008 to 85% in 2009. However, all samples had significantly higher LD50 values than the susceptible New Jersey strain. 111 A population from Delaware again showed very high levels of resistance to imidacloprid, consistent with findings from previous years. Populations tested from Maine and Virginia were less than 10-fold resistant, but still differed significantly from the susceptible; the lone Minnesota population tested was susceptible. The Wisconsin populations submitted to us for testing did not show high levels of resistance this season. However, elevated levels of resistance are still present in some areas of Wisconsin (pers. comm. Russell Groves, University of Wisconsin), but overall values remain lower than those recorded in Michigan. The thiamethoxam LD50 value for the susceptible laboratory strain (New Jersey) was 0.038 µg/beetle (Table I.3). The LD50 values for thiamethoxam ranged from 0.135 µg/beetle (overwintered adults from Andersen Brothers field 41) to 0.374 µg/beetle (Sackett Potatoes fields 154-155) for Michigan populations (Figure I.3) and from 0.048 µg/beetle (overwintered adults from Aroostook, ME) to 0.928 µg/beetle (Delaware, DE) for out-of-state populations (Figure I.2.B, Table I.3). As in 2008, no Michigan populations had greater than 10-fold resistance to thiamethoxam. However, as in 2008, all populations tested had LD50 values significantly higher than the susceptible New Jersey strain, up from 88% in 2007. Susceptibility to imidacloprid (as measured by LD50) in field-collected Colorado potato beetle populations was highly correlated with susceptibility to thiamethoxam (r2=0.73, Figure I.4). This result was also found in previous years (e.g. Grafius et al. 2004, 2005; Byrne et al. 2006, 2007, 2008). This high correlation is a strong indicator that alternation between imidacloprid and thiamethoxam would not be an effective or wise resistance management strategy. The NY-Sel laboratory strain has been selected for imidacloprid resistance. Adults from most generations were selected with imidacloprid doses causing 38-88% mortality. Survivors from selections were used to maintain the laboratory strains. Bioassays were conducted roughly every fourth generation, allowing us to follow resistance development under a high selection pressure scenario. The imidacloprid LD50 value for the NY-Sel was 9.957 µg/beetle, greater than 150-fold resistant, compared to the susceptible New Jersey strain. 112 Table I.1. Colorado potato beetle populations tested for susceptibility to imidacloprid and thiamethoxam in 2009. Michigan populations Andersen Brothers Farm Adults were collected by Mark Otto, Agri-Business Consultants, Inc. from commercial potato fields in Montcalm and Isabella Counties, MI. Field 2 Summer adults were collected on 1 August 2009. Source of beetles was overwintered adults from field 5 in Montcalm County that migrated to field 2. Field 41 Overwintered adults were collected on 19 June 2009 and summer adults on 1 August 2009 by Mark Otto, Agri-Business Consultants, Inc. from commercial potato field in Isabella County, MI. Kalkaska Summer adults were collected on 12 August 2009 by Russ Tiller, Bayer CropScience, from a commercial potato field in Excelcior Twp., Kalkaska County, MI. Montcalm Farm Summer adults were collected on 22 July 2009 from untreated potatoes at the Michigan State University Montcalm Potato Research Farm, Entrican, MI. Paul Main Farm Adults were collected by Mark Otto, Agri-Business Consultants, Inc. from commercial potato fields in Mecosta County. Field R5 Summer adults were collected on 30 August 2009. Source of beetles was overwintered beetles that probably migrated from R11 and reproduced in R5. Field R6 Summer adults were collected on 6 August 2009. Source of beetles was overwintered beetles from R17 that reproduced in R6. Sackett Potatoes Adults were collected by Mark Otto, Agri-Business Consultants, Inc., and Michigan State University researchers from commercial potato fields in Mecosta and Montcalm Counties, MI. Out-of-state populations Arlington, Wisconsin Summer adults were collected on 15 July 2009 by Russell Groves, University of Wisconsin, from potatoes at the Arlington Agricultural Experiment Station, Arlington, WI. Aroostook, Maine Overwintered adults were collected on 23 June 2009 and summer adults on 20 August 2009 by Gary Sewell, University of Maine, from untreated potato research plots near Presque Isle, ME. Coloma, Wisconsin Overwintered adults were collected on 17 June 2009 by Russell Groves, University of Wisconsin, from a commercial potato field in Coloma, WI. Crookston, Minnesota Overwintered adults were collected on 23 June 2009 by Ian MacRae, University of Minnesota, from an untreated potato field near Crookston, MN. Delaware, Delaware Summer adults were collected on 3 August 2009 by Joanne Whalen, University of Delaware, from a commercial potato field near Little Creek, DE, treated at planting with Platinum ® and with foliar application of SpinTor ®. Fields 2&30 Overwintered adults were collected on 11 June 2009. Field 5&8 Summer adults were collected on 12 August 2009. Field 15 Overwintered adults were collected on 15 June 2009. Field 75 Summer adults were collected on 12 August 2009. Field 103 Summer adults were collected on 11 August 2009. Fields 151&155 Overwintered adults were collected on 15 June 2009. Fields 154-155 Summer adults were collected on 12 August 2009. 113 Table I.1. cont’d. Colorado potato beetle populations tested for susceptibility to imidacloprid and thiamethoxam in 2009. Fryeburg, Maine Summer adults were collected on 13 August 2009 by Megan Patterson, from a commercial, organic potato field near Fryeburg, ME, treated with Entrust ® and Pyganic ®. Hancock Field C-19, Wisconsin Overwintered adults were collected on 17 June 2009 by Russell Groves, University of Wisconsin, from potato research plots in Hancock, WI. Hancock West Field H-53, Wisconsin Overwintered adults were collected on 15 June 2009 by Russell Groves, University of Wisconsin, from a commercial potato field near Hancock, WI. Jamesport, New York Overwintered adults were collected on 27 May 2009 by Sandra Menasha, Cornell Cooperative Extension, from a commercial potato field in Suffolk County, NY that was treated at planting with Admire ® (0.35 fl oz/A) and with foliar applications of SpinTor ® and Kryocide ®. New Church, Virginia Overwintered adults were collected on 15 May 2009 by Tom Kuhar, Virginia Polytechnic Institute and State University, from a commercial potato field near New Church, VA that was treated with Platinum ® and Regent ® at planting. Painter, Virginia Overwintered adutls were collected on 12-13 May 2009 by Tom Kuhar, Virginia Polytechnic Institute and State University, from a potato field in Painter, VA that was treated with Platinum ® at planting. Plover, Wisconsin Overwintered adults were collected on 24 June 2009 by Russell Groves, University of Wisconsin, from a commercial potato field near Plover, WI. Laboratory strains New Jersey Adults obtained in 2008 from the Phillip Alampi Beneficial Insects Rearing Laboratory, New Jersey Department of Agriculture and since reared at Michigan State University without contact to insecticides NY-Select Collected from Long Island, NY in 1997. Adults from most generations selected with imidacloprid doses targeting 60-80% mortality. 114 LD50 95% fiducial limits 2.2972 1.067 0.4701 1.3822 0.7062 2.1392 1.0062 0.6972 1.3922 0.5551 0.4031 1.9882 0.9722 0.5551 0.420-0.769 0.333-0.503 1.307-3.245 0.798-1.241 0.420-0.758 Table I.2. LD50 values (µg/beetle) and 95% fiducial limits for Colorado potato beetle populations treated with imidacloprid at 7 days after treatment. Michigan populations Andersen Brothers Field 2 Andersen Brothers Field 41 (winter) Andersen Brothers Field 41 (summer) Kalkaska Montcalm Paul Main Farm Field R5 Field R6 Sackett Potatoes Fields 2&30 Fields 5-8 Field 15 Field 75 Field 103 Fields 151&155 Fields 154-155 out-of-state populations Arlington, WI Aroostook, ME (winter) Aroostook, ME (summer) Coloma, WI Crookston, MN Delaware, DE Fryeburg, ME Hancock C-19, WI Hancock H-53, WI Jamesport, NY New Church, VA Plover, WI laboratory strains New Jersey NY-Sel 1 significantly greater than LD50 value for susceptible New Jersey strain 2 greater than 10 times the LD50 value for susceptible New Jersey strain 0.069-0.111 0.149-0.223 0.095-0.289 0.061-0.079 4.146-5.986 1.539-2.734 0.143-0.486 0.377-0.504 1.635-2.287 0.255-0.425 0.089 0.086 0.1811 0.1951 0.069 4.9812 1.9851 0.3471 0.4371 1.9242 0.3271 0.551 0.395-0.581 1.041-1.762 0.632-0.783 1.645-2.784 0.878-1.143 0.563-0.818 1.023-1.861 0.054-0.076 6.568-16.476 0.065 9.9572 1.859-3.198 * * * 115 Figure I.1. Susceptibility of Michigan field populations of Colorado potato beetle to imidacloprid. Colored bars represent LD50 values that were significantly greater than the LD50 value of the susceptible strain. Populations are arranged by collection date, the first four samples represent overwintering populations, the remaining samples were from the summer generation. 116 A. Imidacloprid B. Thiamethoxam Figure I.2. Susceptibility of field populations of Colorado potato beetle to imidacloprid (A) and thiamethoxam (B). Michigan values represented as a range from lowest to highest value. Colored bars represent LD50 values that were significantly greater than the LD50 value of the susceptible strain. 117 0.261-0.388 0.197-0.324 LD50 95% fiducial limits 0.3221 0.2661 0.1891 0.2551 0.1571 0.2421 0.2591 0.2631 0.3741 0.1771 0.1351 0.3611 0.1891 0.2111 0.142-0.220 0.118-0.156 0.306-0.428 0.163-0.224 0.172-0.264 Table I.3. LD50 values (µg/beetle) and 95% fiducial limits for Colorado potato beetle populations treated with thiamethoxam at 7 days after treatment. Michigan populations Andersen Brothers Field 2 Andersen Brothers Field 41 (winter) Andersen Brothers Field 41 (summer) Kalkaska Montcalm Paul Main Farm Field R5 Field R6 Sackett Potatoes Fields 2&30 Fields 5-8 Field 15 Field 75 Field 103 Fields 151&155 Fields 154-155 out-of-state populations Arlington, WI Aroostook, ME (winter) Aroostook, ME (summer) Coloma, WI Crookston, MN Delaware, DE Fryeburg, ME Hancock C-19, WI Hancock H-53, WI Jamesport, NY New Church, VA Painter, VA laboratory strains New Jersey NY-Sel 1 significantly greater than LD50 value for susceptible New Jersey strain 2 greater than 10 times the LD50 value for susceptible New Jersey strain 0.044-0.077 0.031-0.125 0.078-0.141 0.093-0.165 0.051-0.067 0.755-1.161 0.148-2.563 0.176-0.243 0.171-0.281 0.129-0.217 0.323-0.453 0.059 0.048 0.1011 0.1291 0.058 0.9282 0.2971 0.2061 0.2171 0.1751 0.3801 0.026 0.165-0.216 0.220-0.292 0.104-0.220 0.203-0.283 0.215-0.306 0.217-0.315 0.319-0.440 0.038 0.2641 * 0.017-0.064 0.220-0.313 118 Figure I.3. Susceptibility of Michigan field populations of Colorado potato beetle to thiamethoxam. All LD50 values were significantly greater than the LD50 value for the susceptible strain. Populations are arranged by collection date, the first four samples represent overwintering populations, the remaining were from the summer generation. Figure I.4. Correlation between susceptibility to imidacloprid and thiamethoxam for all field populations tested in 2009 (n=31). 119 II. Field insecticide evaluations of registered and experimental insecticides. The Colorado potato beetle is one of the most widespread and destructive insect pests to potato crops in the northeastern United States and Canada. Its ability to develop resistance to insecticides makes it very important to continue testing new chemistries and the efficacy of existing compounds. Such tests provide data on comparative effectiveness of products and data to support future registrations and use recommendations. Methods Twenty-one insecticide treatments plus an untreated check (Table II.1) were tested at the Michigan State University Montcalm Research Farm, Entrican, MI for control of Colorado potato beetle. ‘Atlantic’ seed pieces were planted 12 in. apart, with 34 in. row spacing on 12 May 2009. Treatments were replicated four times in a randomized complete block design. Plots were 40 ft long and three rows wide with untreated guard rows planted on either side of each plot. Admire Pro, Belay 2.13 SC, Capture LFR (infurrow portion), and Platinum 75 SG treatments were applied in-furrow at planting using a single-nozzle hand-held boom (30 gpa, 30 psi). Foliar treatments were first applied at greater than 50% egg hatch on 24 June. Subsequent first-generation sprays were applied on 2 & 16 July, depending on treatment (Table II.1). Post-spray counts of Colorado potato beetle adults, small larvae (1st and 2nd instars), and large larvae (3rd and 4th instars) of five randomly selected plants from the middle row of each plot were made 6 days after each foliar application. On 17 September, the middle row of each plot was harvested mechanically and the tubers were separated by size and weighed. Data were analyzed using two-way ANOVA (treatment and block) and significant differences were determined with Fisher’s Protected LSD test (p=0.05). Results There were significant differences between treated and untreated plots in the seasonal means of small larvae, large larvae, and adults (Table II.1). All treatments resulted in significantly fewer large larvae and adults than the untreated plots. All treatments also kept large larvae and adults below the economic threshold of one large larvae or adult per plant. However, overall beetle pressure was very low this summer, mostly due to a cold and late spring and the very protracted and reduced beetle emergence from diapause. This was best illustrated by the fact that adult numbers averaged below the economic threshold even on the untreated plots; large larvae, however, did average above the threshold in the untreated plots. There were also significant differences between treated and untreated plots with respect to overall yield (Table II.1). About half of the treatments (10 of 21) resulted in significantly higher yields than the untreated plots. The lack of beetle pressure this season likely masked any subtle differences in both insect numbers and overall yield that might have occurred between the various treatments. 120 Table II.1. Seasonal mean number of Colorado potato beetle egg masses, small larvae, large larvae, and adults per plant, and total yield. Adults Total Yield 21.3 bcde 0.1ab 0.1ab 23.4 bcde 21.5 bcde 0.1ab 23.1 bcde 0.1ab 17.8abcd 0.0a 0.1ab 26.6 e 26.2 e 0.1ab 20.9abcde 0.0ab 17.3abcd 0.1ab 0.1ab 22.0 bcde Small Larvae Large Larvae 0.0a 0.0a 0.0a 0.0a 0.8 bc 0.0a 0.0a 0.4ab 0.2ab 0.5ab 0.5 b 0.0a 0.0a 0.1ab 0.2ab 0.0a 0.0a 0.0a 0.0a 0.1ab Rate 5.5 oz/acre 7.0 fl oz/acre 8.7 fl oz/acre 4.5 fl oz/acre 1.75 fl oz/acre 9.6 fl oz/acre 12.0 fl oz/acre 3.0 fl oz/acre 3.3 oz/acre 25.5 fl oz/acre + 6.14 fl oz/acre 7.0 fl oz/acre 4.0 fl oz/acre 3.37 fl oz/acre 3.37 fl oz/acre 6.75 fl oz/acre 10.1 fl oz/acre 20.5 fl oz/acre 2.7 fl oz/acre 4.0 oz/acre Seasonal mean of 1st-generation (#/plant) Application dates 24 Jun, 2 Jul at planting at planting 24 Jun 24 Jun, 16 Jul at planting at planting 24 Jun 24 Jun at planting 24 Jun 24 Jun 24 Jun 24 Jun 24 Jun 24 Jun 24 Jun 24 Jun at planting 24 Jun 24 Jun, 16 Jul 24 Jun Treatment/formulation Actara 25 WG Admire Pro Admire Pro Agri-Flex 1.55 SC + NISa Agrimek 0.70 SC + NIS Belay 2.13 SC Belay 2.13 SC Belay 2.13 SC Blackhawk Capture LFR + Brigadier Coragen 17.0abc 19.8abcde Endigo 2.06 ZC + NIS 19.8abcde HGW86 10 OD HGW86 10 OD + MSOb 19.1abcde 16.7ab HGW86 10 OD 18.4abcd HGW86 10 OD 24.5 cde HGW86 10 OD 24.8 de Platinum 75 WG 23.4 bcde Voliam Flexi 40 WG + NIS 16.1ab Voliam Xpress 1.25 ZC + NIS 7.0 fl oz/acre 21.1abcde 3.2 fl oz/acre Warrior Untreated check 13.7a Means within a column followed by different letters are significantly different (P<0.05, Fisher’s Protected LSD). Data transformed for analysis with log (x+1), means presented in non-transformed units. a NIS applied at 0.25% v/v b MSO applied at 0.5% v/v 0.0a 0.2b 0.1ab 0.0ab 0.0ab 0.0a 0.0a 0.0ab 0.0ab 0.1ab 0.0a 0.8 c 0.0a 0.0a 0.0a 0.3ab 0.3ab 0.3ab 0.1a 0.0a 0.2a 0.0a 0.3ab 1.5 c 0.0a 0.0a 0.1ab 0.0a 0.0a 0.0a 0.0a 0.0a 0.0a 0.3ab 0.1ab 2.7 c 121 Literature citations: Anonymous. 2006. Agricultural chemical usage 2006 field crops summary. United States Department of Agriculture, National Agricultural Statistics Service. http://usda.mannlib.cornell.edu/usda/nass/AgriChemUsFC//2000s/2007/AgriChemUsFC- 05-16-2007_revision.pdf. (accessed 1 December 2009). Byrne, A., W. Pett, E. Grafius, and B. Bishop. 2006. Potato insect biology and management. Michigan Potato Research Report 37:106-125. Mich. Agric. Exper. Station, East Lansing, Michigan. Byrne, A., W. Pett, E. Grafius, and B. Bishop. 2007. Potato insect biology and management. Michigan Potato Research Report 38:120-142. Mich. Agric. Exper. Station, East Lansing, Michigan. Byrne, A. M., W. L. Pett, B. A. Bishop, and E. J. Grafius. 2008. Potato insect biology and management. Michigan Potato Research Report 39:108-128. Mich. Agric. Exper. Station, East Lansing, Michigan. Byrne, A. M., W. L. Pett, B. A. Bishop, and E. J. Grafius. 2009. Potato insect biology and management. Michigan Potato Research Report 40:152-168. Mich. Agric. Exper. Station, East Lansing, Michigan. Grafius, E., B. Bishop, W. Pett, A. Byrne, and E. Bramble. 2004. Potato insect biology and management. Michigan Potato Research Report 35:96-109. Mich. Agric. Exper. Station, East Lansing, Michigan. Grafius, E., W. Pett, B. Bishop, A. Byrne, and E. Bramble. 2005. Potato insect biology and management. Michigan Potato Research Reprot 36:42-56. Mich. Agric. Exper. Station, East Lansing, Michigan. SAS Institute. 2006. Base SAS® 9.1.3. Procedures Guide. SAS Institute, Cary, NC. 122 I. PROBLEM STATEMENT Excretion of 14C-thiamethoxam in Michigan Colorado potato beetles David Mota-Sanchez, and Mark E. Whalon. MSU, Department of Entomology Resistance to imidacloprid in a CPB population from Long Island, NY also resulted in cross-resistance to several neonicotinoids never used on the field including thiamethoxam, dinotefuran, chlothianidin, thiacloprid, and acetamiprid (Mota-Sanchez et al. 2006). Resistance to imidacloprid and cross-resistence to thiamethoxam and chlothianidin has been detected in other areas of the eastern US and Canada (Alyokhin et al. 2007, Alyokhin et al. 2008). In Michigan, CPB resistance to imidacloprid and low levels of resistance to thiamethoxam were detected in 2004 and more resistance cases have appeared close to the original site of detection (Grafius 2006). Intense insecticide resistance management efforts have been implemented including crop rotation and trap crop (Grafius 2006). Despite some resistance cases, many Colorado potato beetle populations are still susceptible to imidacloprid and other neonicotinoids including thiamethoxam. Taking a proactive approach at this point in time will help to preserve the efficiency of this class of chemicals. One of the key strategies to manage resistance is the determination of the mechanism of resistance of CPB thiamethoxam. Mechanism of resistance of CPB CPB resistance to imidacloprid does not confer the same level of resistance to thiamethoxam and other neonicotinoids (Dively 2006, Mota-Sanchez et al. 2006, Alyokhin et al. 2007). For instance, 300-fold resistance to imidacloprid resulted only in 15-fold resistance to thiamethoxam (Mota-Sanchez et al. 2006). Thiamethoxam is converted inside plants and insects to chlothianidin (Nauen et al. 2003). The former compound targets the nervous system, and perhaps this is the reason for low levels of resistance of CPB in comparison with imidacloprid. Research on the mechanism of CPB resistance to imidacloprid and thiamethoxam are essential to effectively manage resistance to neonicotinoids in Michigan. Our research approach is to use labeled compound (14C-thiamethoxam) to study the rate of excretion of this compound applied orally. The metabolism and suppression of metabolism of this labeled compound will provide insights to the mechanism of resistance to thiamethoxam of CPB populations from Michigan as compared to a susceptible strain. II.SPECIFIC OBJECTIVE Specific objectives: 1) Determine the rates of excretion of 14C-thiamethoxam in Michigan potato beetles treated with this compound. 123 III. SPECIFIC METHODS AND PROCEDURES The rate of excretion and metabolism of thiamethoxam in Michigan resistant and susceptible populations were compared with a susceptible strain. Fractions of excreta, and internal body were extracted with solvents methanol and acetonitrile. Samples were dried with nitrogen and condensed samples were spotted and thin layer chromatography was used to determine the amount of thiamethoxam metabolism. Insects. Populations of CPB resistant to imidacloprid from Michigan as reported by Dr. E. Grafius were used in this study (Sackett farm). Dosing. 14C-thiamethoxam was applied via oral application , a procedure that closely approaches the form in which beetles come in contact with thiamethoxam when they feed in potato plants in the field: a low dose (700 dpm/beetle, about 5ng 14C- thiamethoxam/insect) in both the resistant and susceptible strains. After feeding, beetles were transferred to a 20 ml glass scintillation vial. Up to five beetles were held in a vial. Two time intervals were used (1h and 24h). At the end of each time interval, beetles were frozen at -20 C for an hour. Excretion. To calculate the amount of excreted 14C from thiamethoxam, holding vials for each time period were rinsed with 2 ml of methanol. An aliquot of 100 µl of acetone was put in a scintillation vial with 15 ml of cocktail fluid and were counted. Metabolism. Metabolism was determined in excreta and internal body at 1, and 24 h. Beetles were homogenized with acetonitrile using a high speed mechanical homogenizer (VirTishear). Following homogenization, tubes were centrifuged. The supernatant were decanted into a scintillation vial. An aliquot was taken from each extract to count the radioactivity. Aliquots from the excreted and internal samples were put in scintillation vials and dried with nitrogen in a to a volume of 100 µl. Samples were spotted on TLC plates. The plates were developed by using a mobile phase of single dimension system. After drying, the plates were covered by a thin mylar film (0.001 mm) and put in a phosphor screen. A day after exposure, the screen were scanned in a phosphorimager analyzer (BioRad). IV. RESULTS AND DISCUSSION. Excretion and Internal fractions. Excretion of 14C-thiamethoxam was faster in the resistant Michigan strain at 1 h after treatment (Fig 1). At 1 h after treatment the percentage of excreted radioactivity was about 5% for the susceptible, and 10% for the Michigan resistant strain, respectively. At 24 h after treatment, the excretion in both strains was about 28%. The amount of 14C-thiamethoxam in the internal fractions was 67% and 73% of the applied doses at 1h after treatment for the resistant Michigan beetles and the susceptible strain, respectively. At 24 h after treatment, the amount in the internal fractions was 39% in the resistant strain and 41 % in the susceptible strain, although the variability was high in both strains. Regarding the metabolism of thiamethoxam we have observed about 25% of the dose converted thiamethoxam to clothianidin in both strains at 24 h after treatment. Given the 124 high variability in this experiment we increased the number of replications and currently we are processing more samples. This can give us a better estimation of the differences in pharmacokinetics and metabolism of thiamethoxam in Michigan resistant beetles versus susceptible beetles, or perhaps the levels of resistance are still low to detect differences in the pharmacokinetics and metabolism studies. With respect to symptoms of intoxication, some intoxication was observed 1 h after treatment in the susceptible beetles, but these symptoms were mild in comparison to beetles treated with imidacloprid (previous experiments). In addition, we have observed less excretion and higher amount of 14C-thiamethoxam in the insect body than previous experiments with 14C-imidacloprid. Perhaps this is one the reasons of less levels of resistance in this insecticide in comparison with imidacloprid. Further experiments are critical to elucidate the mechanism of resistance of CPB to thiamethoxam and explain why CPB developed low levels of resistance to this compound in comparison with imidacloprid. By determining the mechanism of this low level of resistance, we could use this as a tool to manage the resistance of Colorado potato beetle to neonicotinoids. V. AKNOWLEDGEMENTS We deeply appreciate the kind support of the MPIC for this proposal and also the valuable help of Mark Otto, Adam Byrne and Ed Grafius to provide Michigan beetles. VI. LITERATURE CITED Alyokhin, A., M. Baker, D. Mota-Sanchez, E. Grafius, and G. Dively. 2008. Colorado Potato Beetle Resistance to Insecticides. Am. J. Pot Res. 85: 395-413. Alyokhin, A., G. Dively, M. Patterson, C. Castaldo, D. Rogers, M. Mahoney, and J. Wollam. 2007. Resistance and cross-resistance to imidacloprid and thiamethoxam in the Colorado potato beetle Leptinotarsa decemlineata. Pest Management Science 63: 32-41. Dively, P. G. 2006. Management of Resistance to Imidacloprid in Colorado Potato Beetles in the Northeastern U.S., Great Lakes Fruit, Vegetable and Farm Market EXPO. MSU, Grand Rapids, MI. Grafius, J. E. 2006. The Michigan Experience with Managing Colorado Potato Beetle, Great Lakes Fruit Vegetable and Farm Market EXPO. MSU, Grand Rapids, MI. Mota-Sanchez, D., R. M. Hollingworth, E. J. Grafius, and D. D. Moyer. 2006. Resistance and cross-resistance to neonicotinoid insecticides and spinosad in the Colorado potato beetle, Leptinotarsa decemlineata (Say) (Coleoptera : Chrysomelidae). Pest Management Science 62: 30-37. Nauen, R., U. Ebbinghaus-Kintscher, V. L. Salgado, and M. Kaussmann. 2003. Thiamethoxam is a neonicotinoid precursor converted to clothianidin in insects and plants. Pesticide Biochemistry and Physiology 76: 55-69. 125 t m a x o h e m a h t - i C 4 1 e s o d % 80 70 60 50 40 30 20 10 0 90 80 70 60 50 40 30 20 10 0 m a x o h t e m a h t - i C 4 1 e s o d % Resistant Michigan Susceptible strain 1 h 24 h Fig 1 Excretion of 14C-thiamethoxam Resistant Michigan Susceptible strain 1 h 24 h Fig2 Internal amount of 14-thiamethoxam 126 Funding: Agrochemical industry Fungicide Trials 2008-2009. W. W. Kirk, R. L Schafer and P. Tumbalam Department of Plant Pathology, Michigan State University, East Lansing, MI 48824 Evaluation of fungicide programs for potato late blight control: 2008. Potatoes (cut seed, treated with Maxim FS at 0.16 fl oz/cwt) were planted at the Michigan State University Muck Soils Experimental Station, Bath, MI on 25 May into two-row by 25-ft plots (34-in row spacing), separated by a five-foot unplanted row and replicated four times in a randomized complete block design. Plots were irrigated as needed with sprinklers and were hilled immediately before sprays began. All rows were inoculated (3.4 fl oz/25-ft row) with a zoospore suspension of Phytophthora infestans [US-8 biotype (insensitive to mefenoxam, A2 mating type)] at 104 spores/fl oz on 27 Jul. All fungicides in this trial were applied on a 7-day interval from 30 Jun to 27 Aug (9 applications) with an ATV rear- mounted R&D spray boom calibrated to deliver 25 gal/A (80 p.s.i.) using three XR11003VS nozzles per row. Weeds were controlled by hilling and with Dual 8E (2 pt/A on 25 May), Basagran (2 pt/A on 28 Jun and 11 Jul) and Poast (1.5 pt/A on 11 Jul). Insects were controlled with Admire 2F (20 fl oz/A at planting and on 28 Jun), Sevin 80S (1.25 lb/A on 11 and 25 Jul), Thiodan 3EC (2.33 pt/A on 1 and 21 Aug) and Pounce 3.2EC (8 oz/A on 11 Jul). Plots were rated visually for percentage foliar area affected by late blight on 30 Jul; 14, 21, 28 Aug and 4 Sep [13 days after final application (DAFA), 40 days after inoculation (DAI)] when there was about 100% foliar infection in the untreated plots. The relative area under the disease progress curve was calculated for each treatment from date of inoculation, 30 Jul to 5 Sep, a period of 36 days. Vines were killed with Reglone 2EC (1 pt/A on 6 Sep). Plots (2 x 25-ft row) were harvested on 17 Sep and individual treatments were weighed and graded. Samples of 50 tubers per plot were stored after harvest in the dark at 50oF and incidence of tuber late blight was evaluated after 40 days. Meteorological variables were measured with a Campbell weather station located at the farm, latitude 42.8269 and longitude -84.365deg. Maximum, minimum and average daily air temperature (oF) were 81.2, 25.3 and 53.1 (May); 91.9, 39.6 and 66.7 and 1-d with maximum temperature >90oF (Jun); 89.9, 38.3 and 68.5 (Jul); 87.9, 35.5 and 65.6 (Aug); 91.7, 33.3 and 59.3 and 1-d with maximum temperature >90oF (Sep). Maximum, minimum and average daily soil temperature (oF) were 78.0, 41.4 and 58.1 (May); 81.6, 52.6 and 67.7 (Jun); 82.2, 55.8 and 71.1 (Jul); 85.7, 55.2 and 71.4 (Aug); 81.8, 51.6 and 65.3 (Sep). Maximum, minimum and average soil moisture (% of field capacity) 80.2, 74.0 and 76.6 (May); 91.1, 73.5 and 81.5 (Jun); 100.8, 77.0 and 83.2 (Jul); 97.0, 76.5 and 81.0 (Aug); 123.1 (flooding), 76.6 and 84.3 (Sep). Maximum, minimum and average daily soil temperature (oF) were 78.0, 41.4 and 58.1 (May); 81.6, 52.6 and 67.7 (Jun); 82.2, 55.8 and 71.1 (Jul); 85.7, 55.2 and 71.4 (Aug); 81.8, 51.6 and 65.3 (Sep). Maximum, minimum and average relative humidity were 95.0, 16.0 and 62.8 (May); 95.6, 28.5 and 68.3 (Jun); 95.9, 29.1 and 69.4 (Jul); 96.3, 25.7 and 69.1 (Aug); 96.9, 28.8 and 73.7 (Sep). Precipitation was 1.08 in. (May), 3.59 in. (Jun), 3.69 in. (Jul), 1.56 in. (Aug) and 7.02 in. (Sep). The total number of late blight disease severity values (DSV) over the disease development period was 80 using 90% ambient %RH as bases for DSV accumulation. Plots were irrigated to supplement precipitation to about 0.1 in./A/4-day period with overhead sprinkle irrigation. Late blight developed steadily after inoculation and untreated controls reached 100% foliar infection by 5 Sep. Up to 40 DAI, all fungicide programs reduced foliar late blight significantly compared to the untreated control and up to 26 DAI were not significantly different from each other. All fungicide programs significantly reduced the average amount of foliar late blight over the season (RAUDPC, 0 to 40 DAI) compared to the untreated control. There were no significant differences in marketable or total yield among treatments. There were significant differences in the incidence of tuber late blight 40 days after harvest among treatments. The untreated check had 14.9% incidence of tuber blight and only treatments with 4.2% incidence or less had significantly less tuber blight than the untreated check. The Bravo WS program had 23.8% incidence of tuber blight, which was significantly higher than the untreated check. Phytotoxicity was not noted in any of the treatments. 127 Funding: Agrochemical industry Foliar late blight (%) Yield (cwt/A) Treatment and rate/A 5 Aug 9 DAIz 22 Aug 26 DAI 29 Aug 33 DAI 5 Sep 40 DAI 5 DAFAy RAUDPC Max = 100x 0 - 40 DAI Tuber blight (%)w Total 407 23.8a US1 326 0.2b 3.0 d 6.8c 0.8 d 0.4b 4.3 d 7.5c 1.1 d 296 347 14.6bc 0.1b 2.3 d 6.3c 0.7 d 323 397 4.0e 0.5b 2.8 d 11.8c 1.1 d 329 403 15.3bc 0.3b 2.5 d 9.5c 1.0 d 289 366 11.6cd BravoWS 6SC 1.5 pt (A-I)………………………...….. 0.0c Revus Top 4.17SC 5.5 fl oz + Induce SL 0.25 pt (A,B,D,G,E,H); BravoWS 6SC 1.5 pt (C,F, I)…………………………. 0.0c Revus Top 4.17SC 7.0 fl oz + Induce SL 0.25 pt (A,B,D,G,E,H); BravoWS 6SC 1.5 pt (C,F, I)…………………………. 0.0c JE 874 2.1 SE 0.5 pt + Curzate 60DF 3.2 oz + Manzate 1.5 lb (A,C,G,E,I); BravoWS 6SC 1.5 pt (B,D,F,H)………………………. 0.0c Revus Opti 3.67SC 2.5 pt + Induce SL 0.25 pt (A,C,E,G,I); BravoWS 6SC 1.5 pt (B,D,F,H)………………………. 0.0c Penncozeb 75DF 1.0 lb (A); Penncozeb 75DF 2.0 lb (B,C,D); Penncozeb 75DF 2.0 lb + Super Tin 80WP 3.25 oz (E,F,G,H,I)…………………. 0.0c Penncozeb 75DF 2.0 lb (A-I)……………………..…... 0.3bc TD 2368-01 4DF 3.0 lb (A-I)…………………...…….. 0.1c TD 2368-01 4DF 4.0 lb (A-I)…………………...…….. 0.5b Bravo WS 6SC pt (A,B,C,E,G,I); Ranman 3.33 SC 0.17 pt + Manzate 75DF 2.0 lb + NIS 0.125 pt (D,F,H)………………………………….. 0.0c Untreated......................................................................... 1.2a 0.6b 0.6b 0.8b 0.9b 11.3 c 10.0 c 12.5 c 18.8 b 36.3b 36.3b 38.8b 42.5b 3.8 c 3.7 c 4.1 bc 5.3 b 0.1b 5.5a 1.0 d 82.5 a 4.8c 100a 0.4 d 18.5 a 295 318 310 350 308 293 377 392 369 422 371 373 8.1cde 4.2de 15.0bc 19.5ab 13.5bc 14.9bc 7.36 HSD0.05 z Days after inoculation with Phytophthora infestans, US8, A2. y Days after final application of fungicide. x RAUDPC, relative area under the disease progress curve calculated from day of inoculation to last evaluation of late blight. w Incidence of tuber late blight after storage at 50oF. v Application dates: A= 30 Jun; B= 9 Jul; C= 16 Jul; D= 23 Jul; E= 30 Jul; F= 6 Aug; G= 13 Aug; H= 20 Aug; I = 27 Aug. u Values followed by the same letter are not significantly different at p = 0.05 (Tukey Multiple Comparison). 1.29 9.08 5.24 0.36 1.49 52.8 59.9 128 Funding: Agrochemical industry Evaluation of fungicide programs for brown leaf spot and early blight control: 2008. Potatoes (cut seed, treated with Maxim FS at 0.16 fl oz/cwt) were planted at the Michigan State University Muck Soils Experimental Station, Bath, MI on 25 May into two-row by 25-ft plots (34-in row spacing), separated by a five-foot unplanted row and replicated four times in a randomized complete block design. Plots were irrigated as needed with sprinklers and were hilled immediately before sprays began. All fungicides in this trial were applied on a 7-day interval from 30 Jun to 27 Aug (9 applications, unless otherwise indicated in the table) with an ATV rear-mounted R&D spray boom calibrated to deliver 25 gal/A (80 p.s.i.) using three XR11003VS nozzles per row. Potato late blight was prevented from movement into the plots from adjacent plots inoculated with Phytophthora infestans with weekly applications of Previcur Flex at 1.2 pt/A from early canopy closure on 7 Jul to 27 Aug. Weeds were controlled by hilling and with Dual 8E (2 pt/A on 25 May), Basagran (2 pt/A on 28 Jun and 11 Jul) and Poast (1.5 pt/A on 11 Jul). Insects were controlled with Admire 2F (20 fl oz/A at planting and on 28 Jun), Sevin 80S (1.25 lb/A on 11 and 25 Jul), Thiodan 3EC (2.33 pt/A on 1 and 21 Aug) and Pounce 3.2EC (8 oz/A on 11 Jul). Plots were rated visually for percentage foliar area affected by brown leaf spot and/or early blight on 14, 21, 28 Aug and 11 Sep [15 days after final application (DAFA), 28 days after the initial evaluation (DAIE)] when there was about 50% foliar infection in the untreated plots. The relative area under the disease progress curve was calculated for each treatment from DAIE, 14 Aug to 11 Sep, a period of 28 days. Vines were killed with Reglone 2EC (1 pt/A on 11 Sep). Plots (2 x 25-ft row) were harvested on 3 Oct and individual treatments were weighed and graded. Meteorological variables were measured with a Campbell weather station located at the farm, latitude 42.8269 and longitude -84.365deg. Maximum, minimum and average daily air temperature (oF) were 81.2, 25.3 and 53.1 (May); 91.9, 39.6 and 66. (Jun); 89.9, 38.3 and 68.5 (Jul); 87.9, 35.5 and 65.6 (Aug); 91.7, 33.3 and 59.3 (Sep). Maximum, minimum and average daily soil temperature (oF) were 78.0, 41.4 and 58.1 (May); 81.6, 52.6 and 67.7 (Jun); 82.2, 55.8 and 71.1 (Jul); 85.7, 55.2 and 71.4 (Aug); 81.8, 51.6 and 65.3 (Sep). Maximum, minimum and average soil moisture (% of field capacity) 80.2, 74.0 and 76.6 (May); 91.1, 73.5 and 81.5 (Jun); 100.8, 77.0 and 83.2 (Jul); 97.0, 76.5 and 81.0 (Aug); 123.1 (flooding), 76.6 and 84.3 (Sep). Maximum, minimum and average daily soil temperature (oF) were 78.0, 41.4 and 58.1 (May); 81.6, 52.6 and 67.7 (Jun); 82.2, 55.8 and 71.1 (Jul); 85.7, 55.2 and 71.4 (Aug); 81.8, 51.6 and 65.3 (Sep). Maximum, minimum and average relative humidity were 95.0, 16.0 and 62.8 (May); 95.6, 28.5 and 68.3 (Jun); 95.9, 29.1 and 69.4 (Jul); 96.3, 25.7 and 69.1 (Aug); 96.9, 28.8 and 73.7 (Sep). Precipitation was 1.08 in. (May), 3.59 in. (Jun), 3.69 in. (Jul), 1.56 in. (Aug) and 7.02 in. (Sep). Plots were irrigated to supplement precipitation to about 0.1 in./A/4-day period with overhead sprinkle irrigation. Early blight and brown leaf spot developed steadily during Aug and untreated controls reached about 50-70% foliar infection by 11 Sep. The proportion of early blight to brown leaf spot in the first two evaluations was about 90:10 but by the third and fourth evaluations was about 20:80. All fungicide programs reduced foliar early blight and brown leaf spot significantly compared to the untreated control to the middle of Sep when crops had to be desiccated to accommodate harvest prior to frost. All fungicide programs significantly reduced the average amount of foliar early blight and brown leaf spot (RAUDPC) compared to the untreated control over the evaluation period from 14 Aug to 11 Sep. There were significant differences in marketable and total yield among treatments and treatments with greater than 265 and 406 cwt/A US1 and total weight, respectively were significantly greater than the untreated controls. Phytotoxicity was not noted in any of the treatments. 129 Funding: Agrochemical industry Foliar early blight and brown leaf spot (%) 21 Aug 28 Aug 11 Sep 15 DAFAz RAUDPC Max = 100y 0 - 28 DAIEx Yield (cwt/A) US1 Total Treatment and rate/A Echo ZN 2.12 pt (A,C,E); Headline 2.09EC 6 fl oz + Echo ZN 1.5 pt (B,F); Endura 70WDG 2.5 oz + Echo ZN 1.5 pt (D); Dithane DF 2 lb (G,H,Iw)……………............................ 1.0abcv 14 Aug QFA 61 350EC 2.1 pt (A-I)…………............................ 0.8bcd LEM 17 200EC 16.8 fl oz (A,C,E,G,I); JE 874 2.1SE 6 fl oz + Manzate 75DF 1.5 lb (B,D,F,H)………………………. 0.5cde LEM 17 200EC 24 fl oz (A,C,E,G,I); JE 874 2.1SE 6 fl oz + Manzate 75DF 1.5 lb (B,D,F,H) 0.5cde LEM 17 200SC 16.8 fl oz (A,C,E,G,I); JE 874 2.1SE 6 fl oz + Manzate 75DF 1.5 lb (B,D,F,H) 0.8bcd Endura 2.5 oz (A,C,E,G,I); JE 874 2.1SE 6 fl oz + Manzate 75DF 1.5 lb (B,D,F,H) 0.0e 3.3cde 3.8 b-g 13.8e-i 1.5e 4.3 b-g 12.5f-i 5.8d-h 5.2gh 297a-e 281a-f 419a-e 392c-g 1.8de 1.8 g 9.5i 1.5e 2.5 efg 10.0hi 3.5h 3.9h 329ab 474a 265d-g 374d-g 2.3de 2.5 efg 12.5f-i 4.7gh 313a-d 425a-d 1.0e 3.0 d-g 11.3ghi 4.2gh 9.3c-f 300a-e 259d-h 412a-e 394c-g BravoWS 6SC 1.5 pt (A-I)……………………………. BravoWS 6SC 1.5 pt (A,B,F,H); Quash 50WG 2.5 oz (C,D,G,I); Endura 70WDG 5.5 oz (E)……………………………. 1.0abc 4.5bcd 8.0 b-e 20.0c-f 0.5cde 1.3e 2.3 fg 11.3ghi Headline 2.09EC 6 fl oz (A-H)……………….……….. 0.3de BravoWS 6SC 1.5 pt (A-H)………………….…..……. 0.8bcd 1.8de 5.5bc 2.5 efg 15.0d-i 7.8 b-f 21.3cde Quash 50WG 2.5 oz (C,D,G,I)………………………... 0.5cde 1.5e 3.0 d-g 18.8c-g Quash 50WG 1.5 oz (A-H)……………………………. 0.8bcd 2.8cde 6.0 b-g 20.0c-f Quash 50WG 2.0 oz (A-H)……………………………. 1.3ab 2.8cde 8.5 bcd 23.8c 10.0c Quash 2DC 3.0 oz (A-H)…………………...…………. 0.8bcd 1.5e 2.8 efg 20.0c-f Quash 2DC 4.0 oz (A-H)………………...……………. 0.8bcd 3.5cde 4.0 b-g 20.0c-f 4.0gh 5.2gh 9.7cde 6.3c-h 8.0c-g 6.5c-h 7.5c-h 5.9d-h 9.7cd 276b-f 284a-f 284a-f 293a-e 265c-g 281a-f 235fgh 275b-f 259d-h 254e-h 378d-g 402b-f 406b-f 417a-e 374d-g 415a-e 371d-g 424a-d 399b-f 377d-g Endura 70WDG 2.5 oz (A-H)…………………………. 0.8bcd Quadris 2.08SC 6.2 fl oz (A-H)……………………….. 0.5cde Revus Top 4.17SC 7 fl oz + Induce SL 0.25 pt (A,B,D,E); BravoWS 6SC 1.5 pt (C)……………………………… 0.8bcd Revus Top 4.17SC 7 fl oz + Induce SL 0.25 pt (A,B,D,E); Endura 70WDG 2.5 oz (C)……………………….…… 0.0e A31703 325SC 8 fl oz + Induce SL 0.25 pt (A,C,E); BravoWS 6SC 1.5 pt (B,D)…………………………… Endura 70WDG 2.5 oz (A,B,D,E); BravoWS 6SC 1.5 pt (C)……………………………… 0.5cde Tanos 50DF 6 oz + Manzate 75DF 1.5 lb (A,C,E); BravoWS 6SC 1.5 pt (B,D)…………………………… Sonata 500SC 4 pt + Biotune 1EC 4 fl oz + Dithane DF 1.5 lb (A,C,E); Headline 2.09EC 6 fl oz (B,D,F)……………………… 0.8bcd Evito 4FL 2 fl oz + Induce SL 0.25 pt + BravoWS 6SC 1.5 pt (A,C,E); BravoWS 6SC 1.5 pt (B,D,F,G,H)………………….… 0.8bcd 0.3de 0.0e Untreated………………………………………………. 1.5a 2.5de 2.3de 3.8 b-g 15.0d-i 9.3 b 22.5cd 3.3cde 3.5 c-g 16.3c-i 6.3c-h 260d-h 392c-g 2.0de 3.3 d-g 18.8c-g 6.4c-h 278b-f 405b-f 2.5de 4.3 b-g 16.3c-i 6.4c-h 322ab 433a-d 1.5e 3.5 c-g 20.0c-f 6.8c-h 287a-f 401b-f 2.0de 2.5 efg 20.0c-f 6.5c-h 296a-e 400b-f 2.5de 3.3 d-g 15.0d-i 5.7e-h 334a 463ab 1.3e 8.8a 2.8 efg 16.3c-i 27.5 a 66.3a 5.4fgh 29.3a 320abc 212gh 433a-d 332g HSD0.05 z Days after final application of fungicide. y RAUDPC, relative area under the disease progress curve calculated from day of inoculation to last evaluation of late blight. x DAIE, days after initial evaluation. w Application dates: A= 30 Jun; B= 8 Jul; C= 16 Jul; D= 23 Jul; E= 30 Jul; F= 6 Aug; G= 13 Aug; H= 20 Aug; I = 27 Aug. v Values followed by the same letter are not significantly different at p = 0.05 (Tukey Multiple Comparison). 55.3 4.02 0.69 7.60 2.99 5.53 64.2 130 Funding: Agrochemical industry Evaluation of chemigated fungicide programs for white mold control in potatoes, 2008. Potatoes (cut seed, treated with Maxim FS at 0.16 fl oz/cwt; FL1879 and Goldrush) were planted at the Michigan State University Muck Soils Experimental Station, Bath, MI on 28 May into eight-10 row by 50-ft plots per variety separated by a 15-ft gap on each side and replicated three times for a total of three replicated plots per treatment per variety. Plots were hilled immediately before sprays began. The trial was chemigated twice on a 14-day interval on 15 and 29 Jul with a Valley Irrigation overhead single span pivot delivering 5,000 gal water/A per application. Potato late blight was prevented from movement into the plots from adjacent plots inoculated with Phytophthora infestans with weekly applications of Previcur Flex at 1.2 pt/A from early canopy closure on 7 Jul to 27 Aug. Weeds were controlled by hilling and with Dual 8E (2 pt/A on 25 May), Basagran (2 pt/A on 28 Jun and 11 Jul) and Poast (1.5 pt/A on 11 Jul). Insects were controlled with Admire 2F (20 fl oz/A at planting and on 28 Jun), Sevin 80S (1.25 lb/A on 11 and 25 Jul), Thiodan 3EC (2.33 pt/A on 1 and 21 Aug) and Pounce 3.2EC (8 oz/A on 11 Jul). Plots were rated visually for percentage foliar area affected by white mold and bacterial stem blight on 15 and 20 Aug [17 and 22 days after final application (DAFA), 79 and 84 days after planting (DAP)]. Vines were killed with Reglone 2EC (1 pt/A on 6 Sep). Plots (2 x 25-ft row) were harvested on 7 Oct and individual treatments were weighed and graded. Meteorological variables were measured with a Campbell weather station located at the farm, latitude 42.8269 and longitude -84.365deg. Maximum, minimum and average daily air temperature (oF) were 81.2, 25.3 and 53.1 (May); 91.9, 39.6 and 66.7 and 1-d with maximum temperature >90oF (Jun); 89.9, 38.3 and 68.5 (Jul); 87.9, 35.5 and 65.6 (Aug); 91.7, 33.3 and 59.3 and 1-d with maximum temperature >90oF (Sep). Maximum, minimum and average daily soil temperature (oF) were 78.0, 41.4 and 58.1 (May); 81.6, 52.6 and 67.7 (Jun); 82.2, 55.8 and 71.1 (Jul); 85.7, 55.2 and 71.4 (Aug); 81.8, 51.6 and 65.3 (Sep). Maximum, minimum and average soil moisture (% of field capacity) 80.2, 74.0 and 76.6 (May); 91.1, 73.5 and 81.5 (Jun); 100.8, 77.0 and 83.2 (Jul); 97.0, 76.5 and 81.0 (Aug); 123.1 (flooding), 76.6 and 84.3 (Sep). Maximum, minimum and average daily soil temperatures (oF) were 78.0, 41.4 and 58.1 (May); 81.6, 52.6 and 67.7 (Jun); 82.2, 55.8 and 71.1 (Jul); 85.7, 55.2 and 71.4 (Aug); 81.8, 51.6 and 65.3 (Sep). Maximum, minimum and average relative humidity were 95.0, 16.0 and 62.8 (May); 95.6, 28.5 and 68.3 (Jun); 95.9, 29.1 and 69.4 (Jul); 96.3, 25.7 and 69.1 (Aug); 96.9, 28.8 and 73.7 (Sep). Precipitation was 1.08 in. (May), 3.59 in. (Jun), 3.69 in. (Jul), 1.56 in. (Aug) and 7.02 in. (Sep). Plots were irrigated to supplement precipitation to about 0.1 in./A/4-day period with overhead sprinkle irrigation. White mold severity (%) Despite frequent irrigation, white mold developed slowly during Aug and untreated controls reached 5.7 and 11.3% foliar infection by 20 Aug in FL1879 and Goldrush, respectively. In FL1879 and Goldrush, all treatments had significantly less white mold than the untreated control at the first evaluation but not the second. Bacterial vine rot developed during Aug and untreated controls reached 31.7% vine infection by 20 Aug in both FL1879 and Goldrush. There were no significant differences among treatments with respect to white mold or bacterial vine rot at either evaluation date. In FL1879, Endura had significantly greater total yield in comparison to the untreated control and LEM 17 but was not significantly different from Omega. There were no significant differences among any treatments with respect to total yield in Goldrush. Phytotoxicity was not noted in any of the treatments. Treatment and rate/acre FL1879 Omega 500F 8 fl oz (A,Bz)…………… Endura 7-WG 10 oz (A,B)…………… LEM 17 200EC 16.8 fl oz (A,B)……... Untreated............................................... LSD0.05 Goldrush Omega 500F 8 fl oz (A,B)…….……… Endura 7-WG 10 oz (A,B)…………… LEM 17 200EC 16.8 fl oz (A,B)……... Untreated............................................... LSD0.05 z Application dates: A= 15 Jul; B= 27 Jul. y Values followed by the same letter are not significantly different at P = 0.05 (Tukey Multiple Comparison). 6.7 b 7.3 b 13.3 b 21.7 a 388ab 400 a 352 b 352 b 1.0 by 1.0 b 1.3 b 2.3 a 16.7 a 18.3 a 30.0 a 31.7 a Bacterial vine rot severity (%) 3.7 a 2.0 a 6.7 a 5.7 a Total yield (cwt/A) 36.8 30.3 297a 281a 294a 261a 4.3 a 5.0 a 2.3 b 2.3 b 2.0 b 8.3 b 8.3 b 5.77 15.71 18.3 a 16.7 a 28.3 a 31.7 a 10.0 a 11.3 a 17.38 8/20 22 DAFA 8/15 17 DAFA 8/20 22 DAFA 8/15 17 DAFA 1.60 9.16 0.88 5.68 7.23 10.0 b 18.3 a 4.7 a 131 Funding: Agrochemical industry Evaluation of fungicide programs for potato late blight control: 2009 Potatoes (cut seed, treated with Maxim FS at 0.16 fl oz/cwt) were planted at the Michigan State University Muck Soils Experimental Station, Bath, MI on 25 May into two-row by 25-ft plots (34-in row spacing), separated by a five-foot unplanted row and replicated four times in a randomized complete block design. Plots were irrigated as needed with sprinklers and were hilled immediately before sprays began. All rows were inoculated (3.4 fl oz/25-ft row) with a zoospore suspension of Phytophthora infestans [US-8 biotype (insensitive to mefenoxam, A2 mating type)] at 104 spores/fl oz on 28 Jul. All fungicides in this trial were applied on a 7 to 13-day interval from 13 Jul to 7 Sep (8 applications) with an ATV rear- mounted R&D spray boom calibrated to deliver 25 gal/A (80 p.s.i.) using three XR11003VS nozzles per row. Weeds were controlled by hilling and with Dual 8E (2 pt/A on 3 Jun), Basagran (2 pt/A on 28 Jun and 11 Jul) and Poast (1.5 pt/A on 11 Jul). Insects were controlled with Admire 2F (20 fl oz/A at planting), Sevin 80S (1.25 lb/A on 11 and 25 Jul), Thiodan 3EC (2.33 pt/A on 1 and 21 Aug) and Pounce 3.2EC (8 oz/A on 11 Jul). Plots were rated visually for percentage foliar area affected by early blight and brown leaf spot on 20, 27 Aug and 8 and 15 Sep [8 days after final application (DAFA), 26 days after the initial evaluation (DAIE)]; Botrytis tan spot on 15 Sep and late blight on 10, 17 and 23 Sep [16 days after final application (DAFA), 57 days after inoculation (DAI)] when there was about 80% foliar infection in the untreated plots. The relative area under the early blight and brown leaf spot disease progress curves were calculated for each treatment from DAIE, 20 Aug to 15 Sep, a period of 26 days. The relative area under the late blight disease progress curve was calculated for each treatment from date first symptoms were noted, 20 Aug to 15 Sep, a period of 26 days. Vines were killed with Reglone 2EC (1 pt/A on 6 Sep). Plots (20-ft row) were harvested on 1 Oct however there was insufficient tuber development due to three separate flooding events to justify yield analyses. Samples of 50 tubers per plot were stored after harvest in the dark at 50oF and incidence of tuber late blight was evaluated after 40 days. Meteorological variables were measured with a Campbell weather station located at the farm, latitude 42.8269 and longitude -84.365deg. Maximum, minimum and average daily air temperature (oF) were 84.2, 28.9 and 55.9 and 0-d with maximum temperature >90oF (May); 95.8, 35.9 and 64.9 and 2-d with maximum temperature >90oF (Jun); 82.9, 40.1 and 64.2 (Jul); 91.5, 37.4 and 67.0 and 2-d with maximum temperature >90oF (Aug); 83.1, 31.8 and 60.4 (Sep); 62.7, 23.8 and 44.5 (to 15 Oct). Maximum, minimum and average daily soil temperature (oF) were 68.1, 47.4 and 57.9 (May); 78.7, 55.9 and 66.6 (Jun); 73.3, 61.4 and 67.4 (Jul); 75.6, 59.7 and 69.2 (Aug); 68.4, 55.9 and 63.6 (Sep); 56.3, 45.6 and 51.8oF (to 15 Oct). Maximum, minimum and average soil moisture (% of field capacity) 77.2, 62.4 and 66.9 (May); 77.0, 60.8 and 67.2 (Jun); 76.7, 58.2 and 63.7 (Jul); 75.0, 55.1 and 61.7 (Aug); 58.7, 52.1 and 54.2 (Sep); 57.4, 52.5 and 54.5oF (to 15 Oct). Precipitation was 2.98 in. (May), 5.76 in. (Jun), 5.62 in. (Jul), 5.25 in. (Aug), 1.09 in. (Sep) and 1.25 in. to 15 Oct. The total number of late blight disease severity values (DSV) over the disease development period was 51 using 90% ambient %RH as bases for DSV accumulation. Plots were irrigated to supplement precipitation to about 0.1 in./A/4 day period with overhead sprinkle irrigation. Early blight and brown leaf spot developed steadily during Aug and untreated controls reached about 15.8% foliar infection (combined diseases) by 15 Aug. Fungicide programs with foliar Alternaria less than 10.8% were significantly different from the untreated control. No programs were significantly different from the untreated check in terms of the Alternaria RAUDPC. Fungicide programs with Botrytis tan spot less than 21.3 were significantly different from the untreated control. Late blight developed slowly after inoculation and untreated controls reached on average 85% foliar infection by 23 Sep. Fungicide programs with foliar late blight less than 85% were significantly different from the untreated control. All fungicide programs had significantly lower RAUDPC values in comparison to the untreated control (23.2). There were significant differences in the incidence of tuber late blight on the 26 Oct (26 days after harvest) among treatments. The untreated check had 6.3% incidence of tuber blight but only treatments with less than 5.0% incidence had significantly less tuber blight than the untreated check. Phytotoxicity was not noted in any of the treatments. 132 Funding: Agrochemical industry Foliar Alternaria (%) Potato late blight Treatment and rate/A BravoWS 6SC 1.5 pt (A-Dv); Gavel 75DF 2 lb (E-H)……………….... BravoWS 6SC 1.5 pt (A-H)…………… Revus Top 4.17SC 7 fl oz + Induce SL 0.25 pt (A,B,D,E); BravoWS 6SC 1.5 pt (C,F,G,H)………. 15 Aug 7.5 7.8 du d 8.0 cd QRD709 1 pt (A-H)…………………… 11.0 a-d QRD709 2 pt (A-H)…………………… 7.5 d QRD709 3 pt (A-H)…………………… 14.3 ab Kocide 3000 46.1DF 1.75 lb (A-H)…… 12.5 a-d 8.5 cd RAUDPCz 26 DAIEy Foliar Botrytis Tan Spot (%) 15 Aug Foliar (%) 23 Sep 16 DAFAx RAUDPC 26 DAIE Tuber blight (%)w 4.8 4.3 4.1 5.1 3.9 5.9 4.9 4.2 a a a a a a a a 17.5 cd 15.0 fg 25.0 abc 12.5 g 2.0 2.3 g g 1.3 c 2.5 bc 16.3 d 17.5 cd 21.3 bcd 16.3 d 21.3 bcd 15.0 61.3 62.5 65.0 53.8 fg cd cd bc cd 2.4 g 9.0 10.7 11.2 8.5 de cd c e 22.5 bcd 23.8 efg 3.8 fg 1.3 c 5.0 2.5 ab bc 6.3 a 5.0 ab 1.3 c Untreated Check……………………….. 15.8 ab 13.3 abc 4.2 5.5 a a 22.5 bcd 25.0 ef 3.7 fg 26.3 ab 85.0 a 23.2 a 5.44 LSD0.05 2.03 z RAUDPC, relative area under the disease progress curve calculated from day of appearance of initial symptoms. y Days after initial symptoms observed and evaluated. x Days after final application of fungicide. w Incidence of tuber late blight after storage for 26 days at 50oF. v Application dates: A= 13 Jul; B= 20 Jul; C= 28 Jul; D= 10 Aug; E= 18 Aug; F= 25 Aug; G= 1 Sep; H= 7 Sep. u Values followed by the same letter are not significantly different at p = 0.05 (Fishers LSD). 2.60 8.01 11.32 0.0 6.3 c a 3.54 Tanos 50WG 2.75 oz (A-H)…………... Ranman 400SC 2.1 fl oz + Dithane 75DF 1.0 lb (A-H)……………. Ranman 400SC 2.1 fl oz + Dithane 75DF 2.0 lb (A-H)……………. Ranman 400SC 2.75 fl oz + Dithane 75DF 1.0 lb (A-H)……………. Ranman 400SC 2.75 fl oz + Dithane 75DF 2.0 lb (A-H)……………. Catamaran 5.2F 4.5 pt (A-D); Catamaran 5.2F 4.5 pt + Revus Top 4.17SC 7 fl oz (E,G); Catamaran 5.2F 5.5 pt (F,H)…………... Regalia Max 20SC 16 fl oz (A-H)…….. Regalia Max 20SC 8 fl oz + BravoWS 6SC 1.5 pt (A-H)………………………. Regalia Max 20SC 16 fl oz + BravoWS 6SC 1.5 pt (A-H)………………………. 8.3 cd 4.0 a 26.3 ab 14.3 fg 2.1 g 1.3 c 11.5 a-d 4.2 a 32.5 a 13.0 g 2.0 g 1.3 c 10.8 bcd 4.0 a 25.0 abc 16.8 fg 2.8 g 0.0 c 12.0 a-d 4.7 a 21.3 bcd 35.0 e 5.2 f 1.3 c 16.3 a 15.0 ab 5.7 5.9 a a 27.5 ab 23.8 bcd 51.3 85.0 d a 10.1 cde 14.2 b 2.5 5.0 bc ab 10.8 bcd 4.3 a 25.0 abc 76.3 ab 13.8 b 2.5 bc 133 Funding: Agrochemical industry Evaluation of fungicide programs for potato early blight, brown leaf spot and tan spot control: 2009. Potatoes (cut seed, treated with Maxim FS at 0.16 fl oz/cwt) were planted at the Michigan State University Muck Soils Experimental Station, Bath, MI on 25 May into two-row by 25-ft plots (34-in row spacing), separated by a five-foot unplanted row and replicated four times in a randomized complete block design. Plots were irrigated as needed with sprinklers and were hilled immediately before sprays began. All fungicides in this trial were applied on a 7-day interval from 24 Jun to 24 Aug (9 applications) with an ATV rear-mounted R&D spray boom calibrated to deliver 25 gal/A (80 p.s.i.) using three XR11003VS nozzles per row. Potato late blight was prevented from movement into the plots from adjacent plots inoculated with Phytophthora infestans with weekly applications of Previcur Flex at 1.2 pt/A from early canopy closure on 2 Jul to 24 Aug. Weeds were controlled by hilling and with Dual 8E (2 pt/A on 3 Jun), Basagran (2 pt/A on 28 Jun and 11 Jul) and Poast (1.5 pt/A on 11 Jul). Insects were controlled with Admire 2F (20 fl oz/A at planting), Sevin 80S (1.25 lb/A on 11 and 25 Jul), Thiodan 3EC (2.33 pt/A on 1 and 21 Aug) and Pounce 3.2EC (8 oz/A on 11 Jul). Plots were rated visually for combined percentage foliar area affected by early blight and brown leaf spot on 27 Aug and 8 and 15 Sep [3, 15 and 22 days after final application (DAFA), respectively and 22 days after the initial evaluation (DAIE)]; and Botrytis tan spot on 15 Sep. The relative area under the early blight and brown leaf spot disease progress curve was calculated for each treatment from DAIE, 20 Aug to 15 Sep, a period of 25 days. Vines were killed with Reglone 2EC (1 pt/A on 6 Sep). Plots (20-ft row) were harvested on 1 Oct, however there was insufficient tuber development due to three flooding events to justify yield analyses. Meteorological variables were measured with a Campbell weather station located at the farm, latitude 42.8269 and longitude -84.365deg. a. Meteorological variables were measured with a Campbell weather station located at the farm, latitude 42.8269 and longitude -84.365deg. Maximum, minimum and average daily air temperature (oF) were 84.2, 28.9 and 55.9 (May); 95.8, 35.9 and 64.9 and 2-d with maximum temperature >90oF (Jun); 82.9, 40.1 and 64 (Jul); 91.5, 37.4 and 67.0 and 2-d with maximum temperature >90oF (Aug); 83.1, 31.8 and 60.4 and 0-d with maximum temperature >90oF (Sep); 62.7, 23.8 and 44.5 (to 15 Oct). Maximum, minimum and average daily soil temperature (oF) were 68.1, 47.4 and 57.9 (May); 78.7, 55.9 and 66.6 (Jun); 73.3, 61.4 and 67.4 (Jul); 75.6, 59.7 and 69.2 (Aug); 68.4, 55.9 and 63.6 (Sep); 56.3, 45.6 and 51.8oF (to 15 Oct). Maximum, minimum and average soil moisture (% of field capacity) 77.2, 62.4 and 66.9 (May); 77.0, 60.8 and 67.2 (Jun); 76.7, 58.2 and 63.7 (Jul); 75.0, 55.1 and 61.7 (Aug); 58.7, 52.1 and 54.2 (Sep); 57.4, 52.5 and 54.5oF (to 15 Oct). Precipitation was 2.98 in. (May), 5.76 in. (Jun), 5.62 in. (Jul), 5.25 in. (Aug), 1.09 in. (Sep) and 1.25 in. to 15 Oct. Plots were irrigated to supplement precipitation to about 0.1 in./A/4 day period with overhead sprinkle irrigation. Early blight severity values accumulated from planting to 30 Sep were 3515. Weather conditions were conducive for the development of early blight and brown leaf spot and Botrytis tan spot. Early blight and brown leaf spot developed steadily during Aug and untreated controls reached about 15 and 32% foliar infection by 8 and 15 Sep, respectively. All treatments had significantly less combined early blight and brown leaf spot on each evaluation date and RAUDPC. All fungicide programs had significantly less foliar tan spot values than the untreated control (36.3%). Treatments with less than 13.8% foliar tan spot had the greatest level of control. Phytotoxicity was not noted in any of the treatments. 134 Funding: Agrochemical industry Treatment and rate/A Echo ZN 4.17SC 2.12 pt (A,C,E,Iw); Endura 7WG 6 oz + Echo ZN 4.17SC 1.5 pt (B,F); Headline 2.09EC 2.5 oz + Echo ZN 4.17SC 1.5 pt (D); Dithane Rainshield 75DF 2 lb + Super Tin 80WP 2.5 oz (G,H)…………………………. LEM17 200EC 12 fl oz (A,C,E,G,I); Tanos 50WG 6 oz + Manzate 75WG 1.5 lb (B,D,F,H)... LEM17 200EC 16 fl oz (A,C,E,G,I); Tanos 50WG 6 oz + Manzate 75WG 1.5 lb (B,D,F,H).. LEM17 200EC 24 fl oz (A,C,E,G,I); Tanos 50WG 6 oz + Manzate 75WG 1.5 lb (B,D,F,H)... Endura 7WG 2.5 oz (A,C,E,G,I); Tanos 50WG 6 oz + Manzate 75WG 1.5 lb (B,D,F,H).. USF2018A 500SC 11 fl oz (A-I)……………………… Echo ZN 4.17SC 2 pt (A,B,D,F,H); USF2018A 500SC 11 fl oz (C,E); Scala 606SC 7 fl oz + Echo ZN 4.17SC 1.5 pt (G,I)………………………….. Echo ZN 4.17SC 2 pt (A,B,D,F,H); USF2018A 500SC 6.84 fl oz (C,E); Scala 606SC 7 fl oz + Echo ZN 4.17SC 1.5 pt (G,I)...… Endura 7WG 3.1 oz + Bravo WS 6SC 4.17SC 1.5 pt (A-I)…………………… Foliar Early Blight + Brown Leaf Spot (%) 27 Aug 3 DAFAz 8 Sep 15 Sep 15 DAFA 22 DAFA Foliar Early Foliar Blight + Botrytis Tan Brown Leaf Spot (%) Spot RAUDPCy 25 DAIEx 15 Sep 22 DAFA 2.3 c 3.0 e 8.8 d 3.5 d 7.5 cd 3.0 c 8.0 cde 11.3 d 6.0 cd 12.5 bcd 4.3 bc 8.5 cd 11.5 d 6.7 cd 18.8 b 4.0 bc 9.5 bcd 16.5 bcd 7.8 bc 15.0 b 2.8 3.3 c c 6.0 de 14.3 cd 7.0 cde 15.0 bcd 5.7 6.4 cd cd 13.8 bc 13.8 bc 4.0 bc 6.3 cde 15.3 bcd 6.3 cd 7.5 cd 6.3 b 11.5 bc 22.5 b 10.4 b 6.3 d Untreated………………………………………………. 10.8 a LSD0.05 z Days after final application of fungicide. y RAUDPC, relative area under the disease progress curve calculated from day of appearance of initial symptoms (DAIE). x DAIE, days after initial symptoms observed and evaluated. w Application dates: A= 24 Jun; B= 1 Jul; C= 8 Jul; D= 16 Jul; E= 22 Jul; F= 29 Jul; G= 5 Aug; H= 12 Aug; I= 24 Aug. v Values followed by the same letter are not significantly different at p = 0.05 (Fishers LSD). 3.55 8.03 2.45 5.39 6.3 b 14.0 b 28.8 a 21.5 bc 62.5 a 11.3 b 25.4 a 12.5 bcd 36.3 a 6.59 135 (cid:1) (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) Effect of different genotypes of Phytophthora infestans (Mont. de Bary) and temperature on tuber disease development W. Kirk, A. Rojas, P. Tumbalam, E. Gachango, P. Wharton, F. Abu-El Samen, D. Douches, J. Coombs, C. Thill, A. Thompson Abstract The interactions of different cultivars/Advance Breeding Lines (ABL) of potato with different genotypes of the potato late blight pathogen (Phytophthora infestans) at three storage temperatures on tuber late blight development were evaluated. The contribution of the medullar storage tissues was assessed rather than the periderm and outer cortical cell tissue. Tuber late blight severity measured as tuber darkening [mean Relative Average Reflectance Intensity {RARI (%)}] generally increased with temperature. There was little difference in tuber late blight development between 7 and 10oC treatments and in some combinations significantly more tissue darkening developed at 7 than at 10oC but little or no development occurred at 3oC. Resistance in tubers was observed only in Torridon and Stirling and to some extent Jacqueline Lee but the cultivar Missaukee had weak tuber resistance. The US-8 genotype isolates were the most aggressive in tubers in most years causing rapid and significantly more tuber damage than any other genotype of P. infestans and similar to the US-6, US-10 and US-14 isolates used in 2006. The variability of susceptibility of tubers to different genotypes of P. infestans has implications for plant breeding efforts in that the major emphasis in the past has been to breed for foliar resistance with limited emphasis on the reaction of the tuber. Introduction Potato late blight is the most important and most destructive disease of potato worldwide. The disease caused by the oomycete Phytophthora infestans (Mont. de Bary) is the greatest threat to the potato crop, accounting for significant annual losses in North America (Guenthner et al. 2001; Guenthner et al. 1999) and worldwide (Hijmans 2001). Tuber late blight results in tuber rotting both in the field and later in storage either in tubers intended for seed or consumption (Bonde and Schultz 1943; Johnson and Cummings 2009; Kirk et al. 1999; Lambert and Currier 1997; Melhus 1915; Murphy and McKay 1924; 1925; Olanya et al. 2009). Seed tubers infected with P. infestans will either rot in storage, after planting in the field or survive and initiate new epidemics of potato late blight (Doster et al. 1989; Dowley and O'Sullivan 1991; Kirk et al. 2009; Stevenson et al. 2007). The epidemiology of the foliar phase of the disease is correlated to infection in the tuber phase and vice versa (Bain et al. 1997). Tubers are usually infected by inoculum produced on the plant foliage that is subsequently washed down to the soil by water movement resulting from rainfall and irrigation (Andrivon 1995; Fry 2008; Porter et al. 2005; Stevenson et al. 2007). Tubers can become blighted shortly after the disease is established on the foliage. P. infestans survives in tubers where it rots tubers intended for commercial use (Niemira et al. 1999) or acts as primary source of inoculum for infection in the following growing season (Bonde and Schultz 1943). 136 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Three major components contribute to late blight resistance in tubers; 1) a physical barrier consisting of several layers of phellem cells, known as the periderm; 2) the outer cortical cell layers that retard the growth of lesions and can completely block hyphal growth; and 3) medulla storage tissues characterized by reduced hyphal growth and sporulation of P. infestans (Flier et al. 1998; Flier et al. 2001; Pathak and Clarke 1987). Recent work has indicated that the new immigrant P. infestans clones, especially the US-8 genotype, are more aggressive in tubers and sprouts (Kirk et al. 2001d; Lambert and Currier 1997). Historically, studies of the late blight pathogen on tubers were conducted when P. infestans populations were dominated by US-1, a clonal lineage (Goodwin et al. 1994). Today, populations of P. infestans have changed and tuber resistance studies need to continue because the US-8 genotype is now predominant and there is a gap in our understanding of these more aggressive genotypes. The dynamics of potato blight development in tubers are largely influenced by temperature (Kirk et al. 2001d) and can result in decay in storage at currently used processing storage temperatures (e.g. 10oC for chip-processing) or non-emergence of plants due to seed and sprout rot (Kirk et al. 2009). The objectives of interactions of different cultivars/Advanced Breeding Lines (ABL) of potato between different genotypes of P. infestans and storage temperature on tuber late blight development. this study were to evaluate the Materials and Methods Germplasm selection Potato breeding efforts at Michigan State University and other potato breeding programs in the US have resulted in potato cultivars that are largely resistant to foliar late blight (Douches et al. 2004; Kirk et al. 2001b; Kirk et al. 2001c) but not significantly less susceptible than other cultivars in terms of tuber blight resistance (Kirk et al. 2001c). Potato late blight resistance estimates for the cultivars/Advanced Breeding Lines (ABL) used in this study were breeders’ estimates and are given as foliar and tuber ratings below, respectively. US cultivars are exclusively rated against the US-8 genotype of P. infestans and were Jacqueline Lee [Resistant (R), Susceptible (S); Douches et al. (2001)]; Kalkaska [R,S; Douches et al. (2009)]; Missaukee [R,I; Douches et al. (2010)]; MSL171-A (R,R); MSL211-3 (R,I); MSL757-1 (R,I); MSL766-1 (R,I); MSM051-3 (R,I); MSM137-2 (I,I); MSM171-A (R,I); MSM182-1 (I,I); MSM183-AY (R,I); MSN105-1 (R,S); MN98642 (S,S); MN15620 (S,S); ND2470-27 (S,S); Dakota Diamond [S,S; Thompson et al. (2008)]; White Pearl [S,S; Groza et al. (2006)] and Megachip [S,S; Groza et al. (2007)]. Both UK cultivars Stirling and Torridon have a NIAB late blight resistance rating of 8 (foliage), 7 (tuber) equivalent to R,R in US scheme. All cultivars were classified as late maturing. Tubers for this study were obtained from the potato breeding programs at Michigan State University, University of Wisconsin, Madison, University of Minnesota and North Dakota State University. Potato tubers from cultivars/ABL harvested during the previous growing seasons were stored at 3oC in the dark at 90% relative humidity until used. Tubers for the experiments were within the size grade range 50-150 mm diameter (any plane). Visual examination of a random sample of tubers from each entry for disease symptoms indicated that tubers were free from late blight. The sample was further tested with the ELISA immuno-diagnostic Alert Multi-well kit (Alert Multiwell Kit - Phytophthora sp. Neogen 137 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Corporation, Lansing, MI, USA); P. infestans was not detected in any of the tubers. Prior to inoculation, all tubers were washed with water to remove soil. The tubers were then surface sterilized by soaking in 2% sodium hypochlorite (Clorox) solution for 30 min. Tubers were dried in a controlled environment with continuous airflow at 15oC in dry air (30% relative humidity) for 4 h prior to inoculation. Culturing of Phytophthora infestans and tuber inoculations Cultures of P. infestans isolates corresponding to clonal lineages US(cid:1)1 (Pi95-3), US(cid:1)1.7 [Pi88 (2002-06)], US-6 [Pi95-2 (2006-07)], US(cid:1)8 [Pi02-007 (2002-05), Pi06-02 (2006-07)], US(cid:1)10 [SR83-84 (2005-06), Banam AK (2006-07)], US(cid:1)11 (Pi96-1), US(cid:1)14 [Pi98-1 (2002-05), Pi00-001 (2006-07)] were selected based on the aggressiveness criteria (Young et al. 2009). The selected isolates were from the collection of W. Kirk (Michigan State University). These isolates were acquired from field infections from 1995 to 2006 on foliage and tubers of potatoes of commonly grown in Michigan, USA. Pathogenicity was determined on foliage and tubers in tuber and detached leaf tests (Young et al. 2009). Since the genotypes US-1, US-1.7 and US-11 are rare in the US only single isolates representative of the range of genotypes were selected for this study. The experiments were carried out in controlled environment chamber studies. The trials were conducted from 2002 to 2007 (total of five experiments). the surface of The isolates were grown in rye B media for 14 days in the dark at 18oC for sporangia production, and transferred to the light for 2 days to encourage sporulation. Sporangia and mycelium were harvested by flooding with cold sterile water (4oC) and gentle scraping of the culture using a rubber policeman. The mycelium/sporangia suspension was stirred with a magnetic stirrer for 1 h. The suspension was strained through four layers of cheesecloth and sporangia concentration was measured with a hemacytometer and adjusted to about 1 x 106 total sporangia ml-1 (discharged and non-discharged). The sporangial suspensions were stored for 6 h at 4oC to encourage zoospore release from the sporangia. Whole tuber inoculation with P. infestans Tuber late blight development caused by the different P. infestans genotypes on the tuber cultivars/ABL were evaluated at different commonly used post-harvest potato storage temperatures (3, 7 and 10oC) using whole tuber sub–peridermal inoculation. All tubers were washed in distilled H2O to remove soil. The tubers were then surface sterilized by soaking in 2% sodium hypochlorite solution for 4 h. Tubers were dried in a controlled environment with forced air ventilation at 5950 l min-1 at 15oC in dry air (30% relative humidity) for four hours prior to inoculation. The washed, surface-sterilized tubers were inoculated by a sub-peridermal injection of a sporangia suspension of 2 x 10-5 ml (delivering zoospores released from about 20 sporangia inoculation-1) with a hypodermic syringe and needle at the apical end of the tuber about 1 cm from the dominant sprout to a maximum depth of 1 cm. Ten tubers of each cultivar/ABL were inoculated with each P. infestans genotype per temperature. Ten control tubers per cultivar/ABL were inoculated with cold (4oC) sterile distilled H2O. After inoculation, tubers were placed in the dark in sterilized covered plastic crates and returned to controlled environment chambers [Percival Incubator (Model I-36LLVL, Geneva 138 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Scientific, LLC, PO Box 408, Fontana, WI)]. The chambers were set at 3, 7 or 10oC and 95% humidity and the sample tubers were incubated for 40 days until evaluation. The tuber tissue inoculation experiments were conducted in December 2002 to January 2003 and annually through December to January 2003 to 2008. Evaluation of tuber blight A digital image analysis technique was used to assess tuber tissue infection. The method was previously used and standardized (Kirk et al. 2001a; Niemira et al. 1999). The image files were analyzed using SigmaScan V3.0 (Jandel Scientific, San Rafael, CA). The area selection cut-off threshold was set to 10 light intensity units, limiting the determination to the non–dark parts of the image. The average reflective intensity (ARI) of all the pixels within the image gave a measurement of infection severity of the tuber tissue of each sample. The ARI was measured in sections from the apical, middle and basal regions of the tuber. The amount of late blight infected tissue per tuber was expressed as a single value (Mean ARI) calculated as the average ARI of the apical, middle and basal sections evaluated 40 days after inoculation (DAI). Data Analysis The presence of P. infestans in sample tubers was confirmed by ELISA (described above) and by isolating pure cultures of P. infestans from the infected tuber tissue and successful re-inoculation of potato tubers and leaves. The severity of tuber tissue infection was expressed relative to the ARI (described above) of the control tubers for each cultivar/ABL. The relative ARI (RARI) was calculated as: RARI(%) = 1(cid:1) (cid:3) (cid:7) (cid:4) treatment mean ARI mean ARI control (cid:5) (cid:8) (cid:2)100 (cid:6) RARI (%) has minimum value of zero (no symptoms) and maximum value of hundred (completely dark tuber surface). Data for all experiments were analyzed by analysis of variance (least squares method) using the JMP program version 7.0 (SAS Institute Inc., SAS Campus Drive, Cary, North Carolina 27513, USA). Treatment effects were determined by ANOVA and comparisons were made among different temperatures within different genotypes within individual cultivars/ABL for each year; among different genotypes within different temperatures and individual cultivars/ABL for each year; and among different cultivars/ABL within different genotypes within different storage temperatures for each year. Data were not combined across years as different genotypes of P. infestans and different cultivars/ABL were used in each year. Results Incubation of inoculated tubers at 10oC resulted in greatest tuber infection and tuber tissue discoloration within 40 days after inoculation (DAI) in 2003 regardless of genotype of Phytophthora infestans or cultivar/ABL although differences in some genotypes e.g. US- 1.7 were not significant (Fig. 1). In 2004, there were no differences between 7 and 10oC 139 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) although no measurable disease developed at 3oC. In 2005, tuber late blight only developed at 10oC (data not shown). In 2006, there were only differences between storage temperature treatments in US-8 and very little disease developed at 3 or 7oC (Fig. 1). In 2007, there was a general increase across all genotypes with increase in temperature. As an example, tubers of “White Pearl” inoculated with P. infestans isolate Pi-02-007 (US-8 genotype) and incubated at 10oC for 40 days resulted in significant tuber infection and a range of RARI (%) values (Fig. 2). The effect of genotype of P. infestans regardless of temperature in the different cultivars/ABL of potatoes showed a broad range of responses for each year (Fig. 3). The data are expressed as a percentage of the mean RARI (%) and individual sections have discrete values and are not cumulative (Fig. 3). Interactions among storage temperature, genotype aggressiveness and cultivar/ABL resistance were determined in these tests. The US(cid:1)8 genotype was the most aggressive, regardless of temperature in all years although in 2007, US-6, US-10 and US-14 caused a significant amount of tuber late blight regardless of temperature or cultivar/ABL (Fig. 4). Tuber late blight development 2003 In 2003, 10 cultivars/ABL were tested to measure the tuber response to inoculation with different genotypes of P. infestans (Table 1). The RARI (%) varied in the different cultivars/ABL among genotypes and the responses were reported relative to each genotype of P. infestans (Table 1). Among the tuber inoculations, the US(cid:1)8 genotype was most aggressive, followed by the US(cid:1)11 and US(cid:1)14 genotypes. The ABL “ND 2470-27” was the most susceptible to P. infestans genotypes with the highest RARI (%) value, and “Kalkaska” was the least susceptible cultivar/ABL in 2003 although still relatively susceptible to US-8 (Fig. 1, Table 1). “Jacqueline Lee” was particularly susceptible to US- 1 and US-8 in 2003 but relatively resistant to other genotypes of P. infestans (Table 1). Tuber late blight development 2004 The evaluation of P. infestans isolates in 2004 at different storage temperatures among different cultivars/ABL differed to that in measured in 2003. No disease was observed in inoculated tubers incubated at 3oC (Fig. 1, Table 2). There were no significant differences in tuber late blight development between 7 and 10oC. Overall, US(cid:1)8 was the most aggressive genotype and was significantly different from the other genotypes. “White Pearl” was the most susceptible cultivar overall and “Megachip” was the most resistant (Fig. 3, Table 2). Following US(cid:1)8, genotypes US(cid:1)14 and US(cid:1)11 caused moderate tuber late blight and US-1.7 caused moderate disease development at 10oC in “MN15620” (Table 2). Tuber late blight development 2005 In 2005, no tuber late blight developed at 3 or 7oC and data were collected only at 10oC. The US(cid:1)8 genotype was the most aggressive across the cultivars/ABL and genotypes US(cid:1)11 and US(cid:1)14 caused moderate tuber late blight (Figs. 3 and 4). “White Pearl” was the most susceptible cultivar and “Jacqueline Lee” and “Megachip” were the most resistant (Fig. 3 and Table 3). “Missaukee” was particularly susceptible to US-8 and not significantly different from “White Pearl” or “MN15620” (Table 3). 140 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Tuber late blight development 2006 Very little late blight developed in inoculated tubers in 2006 at 3, 7 or 10oC in cultivars/ABL inoculated with any genotype of P. infestans other than US-8. The US-8 genotype caused tuber late blight of which the severity increased with temperature from 3 to 10oC (Fig. 1). The US(cid:1)8 genotype was consistently aggressive on different cultivars regardless of temperature (Figs. 3 and 4). The most susceptible cultivar in 2006 was “Missaukee” and the most resistant were “Jacqueline Lee”, “Torridon” and “Stirling” (Fig. 3 and Table 4). “Missaukee” was very susceptible to US-8 but also moderately susceptible to US-11 in 2006 (Table 4). Tuber late blight development 2007 In 2007, new isolates of the US-10 and US-14 genotypes were used and largely tested on cultivars/ABL from the MSU breeding program. The amount of tuber late blight increased with temperature regardless of cultivar/ABL and the US-8, US-10 and US-11 genotypes were the most aggressive (Figs 1 and 4). The cultivars/ABL “MSM171-A”, Jacqueline Lee” and “Torridon” were the most resistant and “MSL211-3”, “Missaukee”, “MSM051-3” and MSN105-1” were the most susceptible (Fig. 3 and Table 5). Discussion The significance of tuber late blight in initiating storage problems has been reported in many studies (Kirk et al. 1999; Kirk et al. 2001d) and recently reviewed (Olanya et al. 2009). Infection of potato tubers by P. infestans may be initiated by zoospores, sporangia or oospores washed in precipitation or irrigation water from plant foliage and deposited in soil (Fry 2008). Although three major components contribute to late blight resistance in tubers; the phellem cells (periderm), the outer cortical cell layers and the medulla storage tissues characterized by reduced hyphal growth and sporulation of P. infestans (Pathak and Clarke 1987) in this study, only the contribution of the medullar storage tissues was assessed. Temperature has a profound influence on the physiology of potato tubers (Kaur et al. 2009; Knowles et al. 2009; Kumar 2009) and also on the pathology of tubers as pertaining to late blight (Kirk et al. 2001d; Lambert and Currier 1997). The inclusion of the three temperature conditions was intended to simulate late blight development in tubers stored for seed, table-stock and processing, 3, 7 and 10oC, respectively. In this study, tuber late blight severity measured as tuber darkening [RARI (%)] generally increased with temperature as previously reported (Kirk et al 2001d). However, in some years no late blight developed at 3 or 7oC even in susceptible cultivars/ABL. Temperature in the controlled environments was measured through the season with data loggers and while the temperature in the 7oC environment was consistently between 6 and 7oC in 2004-05 late blight developed only at 10oC, although in most other years disease developed at the 7oC storage treatment. The reason for the failure of late blight development in tubers is therefore unclear. Generally, there was little difference in tuber late blight development between 7 and 10oC treatments and in some combinations significantly more tissue darkening developed at 7 than at 10oC e.g. Jacqueline Lee by US-1 and US-11 (Table 2). In future experiments, it may be useful to incubate tubers from cooler temperatures at e.g. 10oC as 141 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) seed used for planting would be warmed prior to planting and as it is known that P. infestans can survive temperature exposure down to -3oC for 5 days (Kirk 2003) it is very likely that mycelium would spread through the tubers and infect sprouts. In addition, seed-borne inoculum of the late blight pathogen has been linked to the initiation of late blight disease in the field (Boyd 1974; 1980; Doster et al. 1989; Dowley and O'Sullivan 1991; Johnson and Cummings 2009; Johnson 2010; Keil et al. 2010; Kirk et al. 2009; Platt et al. 1999). Unlike foliage resistance, the genetics of tuber blight resistance have not been extensively studied (Olanya et al. 2009). Generally, cultivars with foliage blight resistance show some tuber blight resistance (Collins et al. 1999), but this depends on plant genotype ((cid:7)wie(cid:8)y(cid:6)ski and Zimnoch-Guzowska 2001) and in some instances the relationship does not hold (Kirk et al. 2001c; Platt and Tai 1998). In this study, the inoculation technique utilized aimed to examine the resistance of medulla storage tissues which is characterized by mainly by reduced hyphal growth of P. infestans and therefore tuber symptoms e.g. tissue necrosis (Pathak and Clarke 1987; Niemira et al. 1999; Flier et al. 2001; Kirk et al. 2001). Such resistance may be linked to major gene resistance as recently reviewed by (Olanya et al. 2009). Park et al. (2005) analyzed tuber resistance in three mapping populations carrying R genes or a major QTL for foliar resistance to late blight. In one mapping population, tuber blight resistance was inherited independently of foliar blight and the other two populations tuber and foliage resistance were linked. In these two populations, the R1 (or R1-like) gene acted on both foliage and tuber resistance. Resistance in both foliage and tubers is a very desirable trait in potatoes, but in this study only Torridon and Stirling appeared to have this quality and to some extent Jacqueline Lee (Douches et al. 2001). Jacqueline Lee and Missaukee (Douches et al. 2009) have strong foliar resistance to the US-8 genotype of P. infestans; but in this study Jacqueline Lee had only moderate or in the case of Missaukee weak resistance. This suggests that the genes responsible for foliage resistance are not present or at least active in the tubers. Inoculation with the US-8 genotype of P. infestans, the dominant genotype in North America (Young et al. 2009), resulted in significant tuber late blight development for most cultivars and ABL tested. These findings are in agreement with Lambert and Currier (1997) and Lambert et al. (1998) who found that the US-8 genotype isolates were the most aggressive in tubers causing rapid and significantly more tuber damage than any other genotype of P. infestans. In this study, the isolates of the US-10 and US-14 genotypes of P. infestans used in from 2005 to 2007 were as aggressive as the US-8 isolates used throughout. Results of recent tuber rot severity experiments demonstrated similar trends in cultivar susceptibility and genotype aggressiveness on plant emergence (Kirk et al. 2009). Data from the two experiments conducted were strongly negatively correlated, where cultivars/ABL that demonstrated the highest level of plant emergence had the least tuber rotting and vice-versa. Results from this study and that of (Kirk et al. 2009) circumstantially suggest that highly aggressive genotypes of P. infestans, such as the US-8 genotype, may produce limited primary inoculum due to severe tuber rotting and deterioration of tubers before emergence. However, this scenario will depend mostly on the 142 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) amount of inoculum of P. infestans found in or on potato tubers. In both studies, tuber seed pieces and stored tubers were exposed to an excessive amount of inoculum and results suggest that this amount of inoculum was sufficient to cause severe tuber rotting in some cultivars/ABL. The significant extent of tuber rotting and deterioration appears to be the primary symptom after inoculation with P. infestans. The variability of susceptibility of tubers to different genotypes of P. infestans has implications for plant breeding efforts in that the major emphasis in the past has been to breed for foliar resistance with limited emphasis on the reaction of the tuber. It is clear that at least as much emphasis should be apportioned to the tuber resistance phenotype. Acknowledgments This research was funded, in part, by the Michigan Agricultural Experiment Station GREEEN (Generating Research and Extension to meet Economic and Environmental Needs) Project GR 05/046, Michigan Potato Industry Commission, and supported in principal by the NCERA 211 (Quad State Potato Group) and CSREES Hatch Project Number MICL01966 and the Michigan Potato Industry Commission. Special thanks to Rob Schafer, Jarred Driscoll and Jay Estelle for technical expertise. References Andrivon, D. 1995. Biology, ecology, and epidemiology of the potato late blight pathogen Phytophthora infestans in soil. Phytopathology 85: 1053-1056. Bain, R.A., R.W. Fairclough, S.J. Holmes, and G.L. Ligertwood. 1997. The role of Phytophthora infestans inoculum from stem lesions in the infection of tubers. 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Impact of seed potatoes infected with Phytophthora infestans (US-1 or US-8 genotypes) on crop growth and disease. American Journal of Potato Research 76: 67-73. Platt, H.W., and G. Tai. 1998. Relationship between resistance to late blight in potato foliage and tubers of cultivars and breeding selections with different resistance levels. American Journal of Potato Research 75:173-178. Porter, L.D., N. Dasgupta, and D.A. Johnson. 2005. Effect of tuber depth and soil moisture on infection of potato tubers in soil by Phytophthora infestans. Plant Disease 89: 146-152. Stevenson, W.R., W.W. Kirk, and Z.K. Atallah. 2007. Management of foliar disease, early blight, late blight and white mold. In Potato Health Management, ed. D.A. Johnson, pp. 209-22. St. Paul, MN, USA: APS Press. (cid:7)wie(cid:8)y(cid:6)ski KM, and E. Zimnoch-Guzowska. 2001. Breeding potato cultivars with tubers resistant to Phytophthora infestans. Potato Research 44: 97-117. Thompson, A.L, B.L. Farnsworth, N.C. Gudmestad, G.A. Secor, D.A. Preston, J.R. Sowokinos, R. Glynn, and H. Hatterman. 2008. Dakota Diamond: an exceptionally high yielding chipping potato cultivar with long-term storage potential. American Journal of Potato Research. 85: 171-182. Young, G.K., L.R. Cooke, W.W. Kirk, P. Tumbalam, F.M. Perez, and K.L. Deahl. 2009. Influence of competition and host plant resistance on selection in Phytophthora infestans populations in Michigan State, USA and in Northern Ireland. Plant Pathology 58: 703-714. 147 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Figure 1. Main effect tuber responses of genotypes of P. infestans evaluated at three different temperatures representative of different storage regimes in tubers across cultivars and advanced breeding lines measured as mean Relative Average Reflection Intensity [RARI (%)]. The bars represent Fishers protected LSD0.05. 148 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Figure 2. Digital image of three tuber sections from four potato tubers of White Pearl inoculated with Phytophthora infestans isolate Pi-02-007 (US-8 genotype). Numbers indicate relative average reflective intensity [RARI (%)] for each tuber section cut at 25, 50 and 75% from and parallel to the inoculated surface; RARI values are relative to the non- inoculated control tubers of the same ABL 149 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Figure 3. Tuber late blight response as percentage of mean Relative Average Reflection Intensity [RARI (%)], of different cultivars and advanced breeding lines inoculated with different Phytophthora infestans genotypes across the three storage temperatures in A) 2003; B) 2004; C) 2005; D) 2006 and E) 2007. The bars represent Fisher’s protected LSD0.05; A) 2003 = 3.16, B) 2004 = 3.10, C) 2005 = 3.11, D) 2006 = 3.10, E) 2007 = 3.03. 150 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Figure 4. Main effects of different genotypes of Phytophthora infestans on tuber late blight on measured as mean Relative Average Reflection Intensity [RARI (%)] across different cultivars and Advanced Breeding Lines and storage temperature from 2003 to 2007. The bars represent Fisher’s protected LSD0.05. 151 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Table 1. The effect of storage temperature on tuber tissue late blight as mean Relative Average Reflection Intensity [RARI (%)] in different cultivars and advanced breeding lines (ABL) of potatoes after inoculation with different genotypes of Phytophthora infestans (2002 – 2003). Cultivar/ABL Storage Temperature (oC) US-1 Tuber tissue darkening caused by different genotypes of P. infestans [Mean RARI (% )a] US-8 US-11 US-14 i-k 2.30 3.67 f-k 3.25 g-k 1.53 3.12 h-k 5.17 e-k 4.51 f-k jk 14.80 b 3.05 US-1.7 i-k 1.36 f-k 3.74 jk 0.90 i-k 1.37 2.81 g-k 2.01 h-k 5.67 e-g 5.71 h-m f-k 11.86 30.87 a 23.41 bc 4.74 m 18.47 ab 10.67 e-h 7.69 10.05 h-m 14.74 d-h j-m 15.28 d-h 14.14 e-i lm 19.29 c-e 32.69 a 5.41 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 1.42 m 1.90 m 1.78 m 6.35 g-m 8.83 f-l 13.85 b-f 4.44 k-m 16.72 a-d 18.89 ab l-m 10.17 e-j 14.65 b-e 4.54 j-m 9.46 e-k 9.62 e-k 4.11 k-m 11.64 d-g 18.35 ab 3.25 Jacqueline Lee Kalkaska Megachip Missaukee MN15620 MN98642 ND 2470-27 Dakota Diamond White Pearl a Normalized tuber tissue darkening score expressed as RARI (%) = [1- Mean ARI treatment / Mean ARI control ] *100; % RARI has a minimum value of zero (no darkening, but if the value is negative the tuber tissue was lighter than the control) and maximum value of 100 (cut tuber surface is completely blackened). The numbers are derived from the mean average reflective intensity of three surfaces cut latitudinal at 25, 50 and 75% from the apex of n = 10 tubers per treatment combination. b Values followed by the same letter are not significantly different at p = 0.05 for comparisons of mean RARI values within different P. infestans genotypes of cultivar/ABL combinations and temperature treatments (Based on Fishers protected LSD). 2.78 b-e 2.78 b-e 2.77 b-e 0.70 e 1.84 c-e 2.17 c-e 5.21 a-d 3.42 b-e 5.29 a-d 2.70 b-e 1.86 c-e 3.94 a-e 2.30 b-e 3.57 b-e 2.69 b-e 2.98 b-e 2.26 b-e 5.66 a-c 7.72 a 1.94 c-e 3.22 b-e 1.37 de 2.31 b-e 2.24 b-e 1.66 de 3.90 a-e 2.45 b-e 12.65 a 10.54 a-c 3.11 g-k 9.37 a-d 5.86 d-g 0.65 k 11.07 ab f-i 4.64 1.30 i-k 5.17 e-h 5.33 e-h 2.01 h-k 3.75 f-k 1.92 h-k 4.42 f-j 7.16 c-f 4.67 f-i 2.12 h-k 10.48 a-c 8.64 b-e 9.14 c-e 2.49 i-k 5.85 e-j 8.05 c-f 0.86 k 6.38 d-i 11.37 bc 2.36 i-k 7.75 c-g 10.77 b-d i-k 10.57 b-d 24.58 a jk 1.42 3.25 g-k 7.71 c-h 2.10 i-k 9.53 c-e 10.60 b-d i-m 15.73 d-h 19.29 c-e 6.43 k-m 15.18 d-h 10.91 g-l 10.47 h-m 19.83 c-e 28.58 ab 10.20 h-m i-m 17.52 d-f j-m 6.81 f-j 12.39 16.32 d-g 12.21 c-f 13.77 b-f i-m 10.23 e-i 11.64 d-g 4.73 5.14 h-m 8.42 8.69 152 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Table 2. The effect of storage temperature on tuber tissue late blight as mean Relative Average Reflection Intensity [RARI (%)] in different cultivars and advanced breeding lines (ABL) of potatoes after inoculation with different genotypes of Phytophthora infestans (2003 – 2004). Tuber tissue darkening caused by different genotypes of P. infestans [Mean RARI (% )a] US-1.7 US-8 US-11 10 a Normalized tuber tissue darkening score expressed as RARI (%) = [1- Mean ARI treatment / Mean ARI control ] *100; % RARI has a minimum value of zero (no darkening, but if the value is negative the tuber tissue was lighter than the control) and maximum value of 100 (cut tuber surface is completely blackened). The numbers are derived from the mean average reflective intensity of three surfaces cut latitudinal at 25, 50 and 75% from the apex of n = 10 tubers per treatment combination. b Values followed by the same letter are not significantly different at p = 0.05 for comparisons of mean RARI values within different P. infestans genotypes of cultivar/ABL combinations and temperature treatments (Based on Fishers protected LSD). Cultivar/ABL Jacqueline Lee Kalkaska Megachip Missaukee MN15620 ND2470-27 Dakota Diamond White Pearl Temperature (oC) 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 US-1 0.00 gb 4.39 b 1.11 d-g 0.00 g 2.57 b-e 0.89 e-g 0.00 g 1.01 e-g 0.97 e-g 0.00 g 1.19 c-g fg 0.72 0.00 g 1.77 c-g 7.03 a 0.00 g 1.76 c-g 1.39 c-g 0.00 g 2.02 c-f 1.77 c-g 0.00 g 2.22 c-f 2.92 b-d f f f f 0.00 0.92 ef 1.47 c-f 0.00 1.25 d-f 1.35 d-f 0.00 1.22 d-f 1.37 d-f 0.00 1.18 d-f 0.76 ef f 0.00 0.83 ef 8.42 a f 0.00 0.84 ef 1.06 ef f 0.00 1.84 c-f 3.13 b-e 0.00 2.85 b-e 3.53 b-d f i 0.00 21.28 ef 26.49 b-e 0.00 i i fg 18.48 12.14 h i 0.00 14.27 gh 14.51 gh 0.00 31.16 ab 31.26 ab 0.00 27.38 b-d 34.34 a i 0.00 24.28 c-f 23.87 d-f 0.00 i i 19.73 19.78 fg fg i 0.00 24.13 c-f 27.50 b-d f f 0.00 5.47 c-e 1.27 ef f 0.00 1.50 ef 9.14 b-d 0.00 1.56 ef 2.59 ef f 0.00 1.89 ef 1.35 ef f 0.00 16.33 a 10.22 bc 0.00 13.11 ab 5.19 de 0.00 1.26 ef 2.13 ef f 0.00 8.67 b-d 8.41 b-d f f US-14 f 0.00 2.28 ef f 1.06 0.00 0.37 0.24 f f f f f 0.00 1.17 ef 2.98 d-f 0.00 1.59 ef 2.67 ef f 0.00 1.50 ef 7.47 cd 0.00 5.64 c-e 9.33 c f 0.00 1.58 ef 3.18 d-f 0.00 20.13 a 15.36 b f f 153 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Table 3. The effect of storage temperature on tuber tissue late blight as mean Relative Average Reflection Intensity [RARI (%)] in different cultivars and advanced breeding lines (ABL) of potatoes after inoculation with different genotypes of Phytophthora infestans (2004 – 2005). Cultivar/ABL Jacqueline Lee Kalkaska Megachip Missaukee MN15620 Dakota Diamond ND2470-27 White Pearl Temperature (oC) 10c 10 10 10 10 10 10 10 Tuber tissue darkening caused by different genotypes of P. infestans [Mean RARI (% )a] US-1 1.11 kb 1.52 k 0.97 k 0.72 k 0.92 k 1.77 k 1.39 k 2.92 i-k US-1.7 1.47 k 1.87 k 1.37 k 0.76 k 1.46 k 3.13 h-k 1.06 k 3.53 h-k US-8 US-11 US-14 9.02 f-i 13.51 d-f 14.51 d-f 31.26 a 28.35 ab 19.78 cd 23.87 bc 27.50 ab 1.27 k 10.47 e-g jk 2.59 1.35 k 15.50 de jk 2.13 5.19 g-k f-j 8.41 1.06 k 0.43 k 3.76 h-k jk 2.67 0.49 k 3.18 h-k 9.33 e-h 15.36 de a Normalized tuber tissue darkening score expressed as RARI (%) = [1- Mean ARI treatment / Mean ARI control ] *100; % RARI has a minimum value of zero (no darkening, but if the value is negative the tuber tissue was lighter than the control) and maximum value of 100 (cut tuber surface is completely blackened). The numbers are derived from the mean average reflective intensity of three surfaces cut latitudinal at 25, 50 and 75% from the apex of n = 10 tubers per treatment combination. b Values followed by the same letter are not significantly different at p = 0.05 for comparisons of mean RARI values among all P. infestans genotypes of cultivar/ABL combinations (Based on Fishers protected LSD). c No tuber tissue infection occurred at 3 or 7oC in 2004-05 tests. 154 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Table 4. The effect of storage temperature on tuber tissue late blight as mean Relative Average Reflection Intensity [RARI (%)] in different cultivars and advanced breeding lines (ABL) of potatoes after inoculation with different genotypes of Phytophthora infestans (2005 – 2006). Cultivar/ABL (ºC) Temperature Tuber tissue darkening caused by different genotypes of P. infestans [Mean RARI (% )a] US-1 US-8 US-10 US-11 US-14 Jacqueline Lee Missaukee MSL757-1 MSL766-1 MSM137-2 MSM171-A MSM182-1 Stirling Torridon 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3 7 10 3.45 a-e 2.22 a-f 0.89 ef 0.85 ef 0.08 f 1.04 d-f 4.10 a-d 1.02 d-f 2.08 b-f 1.71 c-f 2.88 a-f 0.30 ef 0.85 ef 0.44 ef 4.33 a-c 5.39 a 3.12 a-f 1.94 b-f 3.35 a-e 1.86 b-f 4.99 ab 3.10 a-f 0.47 ef 1.67 c-f 3.04 a-f 1.16 c-f 0.66 ef 5.20 h-k 7.19 h-k 11.30 f-i 19.32 d-f 26.91 a-d 35.27 ab 0.88 k 7.24 h-k 23.56 cd 9.63 g-k 26.21 b-d 27.03 a-d 22.03 de 23.81 cd 31.46 a-c 9.00 h-k 21.67 de 26.26 b-d 5.59 h-k f-j 1.63 4.36 10.76 35.95 a jk i-k 14.27 e-h i-k i-k 2.62 3.44 3.37 b-d 2.47 b-d 1.02 cd 1.97 b-d 1.99 b-d 1.29 cd 3.37 b-d 0.82 d 7.48 a 1.19 cd 2.76 b-d 5.73 ab 1.05 cd 1.59 cd 3.42 b-d 1.81 b-d 5.04 a-c 2.87 b-d 2.48 b-d 1.75 b-d 3.88 a-d 3.08 b-d 0.61 d 0.91 d 2.82 b-d 2.06 b-d 18.47 d-g 0.72 d 1.89 cd 3.18 b-d 0.36 cd 2.74 cd 3.77 bc 18.14 a 2.55 cd 1.38 cd 2.64 cd 1.01 cd 3.70 bc 1.35 cd 2.49 cd 2.67 cd 2.66 cd 2.26 cd 2.29 cd 1.08 cd 6.38 b 2.76 cd 6.26 b 3.73 bc 0.71 cd 1.47 cd 1.14 cd 2.23 cd 0.22 d 2.66 2.14 0.75 1.71 c-f 3.37 a-e 2.22 c-f 1.28 d-f 0.41 5.45 ab f 1.34 d-f 1.91 c-f 0.56 ef 0.64 ef 1.02 ef 4.58 a-c 3.14 a-f 2.29 c-f 1.00 ef 2.07 c-f 1.74 c-f 5.72 a 1.90 c-f f 0.41 0.71 ef 1.54 d-f 4.11 a-d 1.22 d-f a Normalized tuber tissue darkening score expressed as RARI (%) = [1- Mean ARI treatment / Mean ARI control ] *100; % RARI has a minimum value of zero (no darkening, but if the value is negative the tuber tissue was lighter than the control) and maximum value of 100 (cut tuber surface is completely blackened). The numbers are derived from the mean average reflective intensity of three surfaces cut latitudinal at 25, 50 and 75% from the apex of n = 10 tubers per treatment combination. b Values followed by the same letter are not significantly different at p = 0.05 for comparisons of mean RARI values within different P. infestans genotypes of cultivar/ABL combinations and temperature treatments (Based on Fishers protected LSD). 155 (cid:1) (cid:1) (cid:6)(cid:19)(cid:18)(cid:15)(cid:17)(cid:18)(cid:16)(cid:21)(cid:1)(cid:9)(cid:11)(cid:8)(cid:3)(cid:20)(cid:1)(cid:9)(cid:13)(cid:14)(cid:1)(cid:7)(cid:12)(cid:5)(cid:5)(cid:5)(cid:10)(cid:20)(cid:1)(cid:14)(cid:13)(cid:4)(cid:2)(cid:1) (cid:1) Table 5. The effect of storage temperature on tuber tissue late blight as mean Relative Average Reflection Intensity [RARI (%)] in different cultivars and advanced breeding lines (ABL) of potatoes after inoculation with different genotypes of Phytophthora infestans (2006 – 2007). Cultivar/ABL Jacqueline Lee Missaukee MSL183-AY MSL211-3 MSM051-3 MSM171-A MSN105-1 Torridon Temperature (oC) 3 7 10 3 7 10 3 7 10 3c 7 10 3 7 10 3 7 10 3 7 10 3 7 10 Tuber tissue darkening caused by different genotypes of P. infestans [Mean RARI (%)a] US-1 US-6 1.48 c-f 1.27 c-f 2.32 b-f 1.36 c-fb 1.87 b-f 5.60 a 2.36 b-f 3.13 b-d 1.04 d-f - 4.10 4.68 4.84 fg fg fg 13.09 de 13.85 cd 27.15 a fg fg fg 4.46 5.84 4.58 - 2.46 b-f 2.25 b-f 0.94 d-f 2.15 b-f 2.93 b-e 1.28 c-f 0.94 d-f 0.54 3.39 a-c 0.75 ef 3.92 ab 0.41 1.74 b-f 1.39 c-f f f 21.16 b 18.43 bc 8.63 ef 13.10 de 18.14 bc fg 3.95 3.00 g 1.82 g 21.90 b 22.71 ab 18.45 bc fg fg fg 3.81 5.39 4.10 US-8 4.44 5.56 ij i 15.00 e-g 17.44 d-f 20.74 cd 33.11 a 11.42 gh fg 14.73 24.42 b - fg 14.24 32.09 a 18.23 de 23.41 bc 31.64 a 7.79 hi 7.15 6.29 i i US-10 3.17 5.09 3.10 j ij j 18.40 c-e 20.60 b-e 32.47 a j 3.30 9.51 g-i 7.91 h-j - 19.91 b-e 22.04 bc 14.94 e-g 20.85 b-d 22.28 bc 3.66 3.07 2.35 j j j 18.47 de 20.93 b-d 30.67 a j i ij 1.45 5.85 4.76 15.31 d-f 25.29 b 25.59 b j f-h f-i 2.94 11.70 10.45 US-11 US-14 fg 1.90 fg 2.67 1.38 g 3.41 f-g 10.40 de 12.55 b-d 3.13 4.19 2.51 fg fg fg - fg 5.00 9.67 de 11.25 cd 15.86 ab 17.37 a fg 2.69 fg 3.60 fg 3.14 9.84 de 11.37 b-d 15.57 a-c fg 2.12 6.18 ef fg 4.76 3.35 kl 2.97 kl 7.69 h-k 12.14 e-h 17.84 c-e 24.15 ab 6.63 h-l 7.60 h-k i-l 6.00 - 17.13 cf 23.03 a-c 14.44 d-g 26.69 a 28.00 a 2.33 kl j-l 4.59 f-i 11.80 15.48 d-g 18.33 b-d 27.10 a l 1.23 1.99 kl 10.46 g-j a Normalized tuber tissue darkening score expressed as RARI (%) = [1- Mean ARI treatment / Mean ARI control ] *100; % RARI has a minimum value of zero (no darkening, but if the value is negative the tuber tissue was lighter than the control) and maximum value of 100 (cut tuber surface is completely blackened). The numbers are derived from the mean average reflective intensity of three surfaces cut latitudinal at 25, 50 and 75% from the apex of n = 10 tubers per treatment combination. b Values followed by the same letter are not significantly different at p = 0.05 for comparisons of mean RARI values within different P. infestans genotypes of cultivar/ABL combinations and temperature treatments (Based on Fishers protected LSD). c Insufficient tubers of MSL 211-3 to inoculate and store at 3oC. (cid:1) 156 Funding: MPIC/Agrochemical Industry USDA/ARS Evaluation and comparison of biofungicides and fungicides for the control of post harvest potato tuber diseases. E. Gachango, W. W. Kirk, P. S. Wharton, R. Schafer and P. Tumbalam. Department of Plant Pathology, Michigan State University, East Lansing, MI 48824. Summary Potatoes are susceptible to a variety of storage pathogens, including late blight (Phytophthora infestans), Fusarium dry rot (Fusarium sambucinum), Pythium leak (Pythium ultimum) and silver scurf (Helminthosporium solani). Current recommendations for potato storage diseases include sanitation and exclusion as the primary controls for these pathogens in storage facilities. Few fungicides are registered for direct application to tubers for control of these important pathogens and few compounds are available for potato tuber treatment in storage, including chlorine-based disinfectants such as, sodium hypochlorite, calcium hypochlorite and chlorine dioxide. In recent years several new biofungicides based on the biocontrol bacteria Bacillus subtilis (Serenade) and B. pumilis (Sonata) have been registered or are awaiting EPA approval for use on potato, and have shown promise in the control of seed and soil borne diseases such as late blight, black scurf and pink rot. These products have been evaluated for the control of pathogens under post-harvest potato tuber storage conditions. Thus, studies were initiated to evaluate the efficacy of these biofungicides for the control of potato storage pathogens under post-harvest conditions. For a comparison, several commercial storage products Phostrol (sodium, potassium and ammonium phosphates), and Oxidate (hydrogen dioxide) and experimental treatments such as Quadris (azoxystrobin) and mixtures of azoxystrobin and fludioxinil (Maxim) at different rates + thiabendazole (Mertect) and more recently difenoconazole were evaluated for their effectiveness under storage conditions. Preliminary results show that in general the conventional fungicides (azoxystrobin, fludioxinil and difenoconazole) provided the most effective disease control. The biofungicides provided moderate control. The objective of these trials was to continue the evaluation of fungicides and biofungicides against the most common storage disease encountered in Michigan potato production. Materials and Methods Experiments were carried out in November 2009 with potato cultivars “FL1879”, and “Dark Red Norland”. The tests were carried out at two storage temperatures used in the potato industry; 10oC (49oF), chip processing and 4oC (39oF), table stock and seed. The cultivars used in the 10oC test were cv. FL1879 a chip processing cultivar; cv. Dark Red Norland at 4oC a red skinned table-stock cultivar. Potatoes free from visible diseases [except cv. Dark Red Norland that was uniformly infected with H. solani (Hs, silver scurf, 20% of surface area affected) at the time of application] were selected for the trials from tubers harvested in October 2006. Tubers were prepared for inoculation with Phytophthora infestans (Pi), P. erythroseptica (Pe), Pythium ultimum (Py), and Fusarium sambucinum (Fs) by grazing with a single light stroke with a wire brush, sufficient to abrade the skin of the tubers to a depth of 0.01 mm. Solutions (1 x 103/ml ) of sporangia/zoosporangia of Pi (late blight), oospores/sporangia of Pe (pink rot), oospores of Py (Pythium leak), and macroconidia of Fs (dry rot) were prepared from cultures of the pathogens previously isolated from potato tubers in Michigan. All pathogens were 157 Funding: MPIC/Agrochemical Industry USDA/ARS grown in Potato Dextrose Nutrient Broth for 20 days prior to preparation of inoculum solutions. Two non-treated controls, either inoculated with one of the pathogens or non- inoculated were included in the trial. Inoculated and damaged/inoculated tubers, (50/replicate/treatment; total 200 tubers/treatment) were sprayed with 10 ml of pathogen suspension, for a final dosage of about 0.25 ml per tuber. Tubers were stored for 2-d after inoculation at 20°C before treatment. Fungicides were applied as liquid treatments in a water suspension with a single R&D XR11003VS spray nozzle at a rate of 1L/ton at 50 psi onto the tuber surfaces, with the entire tuber surface being coated. After inoculation, tubers were incubated in the dark in plastic boxes at 10°C or 4oC (depending on cultivar and disease combination) for 90 (oomycete pathogens and dry rot) to xxx days. The oomycete diseases were evaluated as the percent incidence of tubers with any signs or symptoms of the pathogen. Tubers with surface sporulation, discoloration of the skin or blackened/dead sprouts were considered infected. The remaining tubers were cut open and the number of tubers with symptoms or signs of the individual pathogens were counted to determine incidence of disease. Dry rot was and silver scurf disease severity was assessed using a disease severity index. Disease severity classes were determined as class 0 = 0%; 1 = 1 - 10%; 2 = 11 - 20%; 3 = 21 - 50; 4 > 51 – 100% internal area of tuber tissue with disease (dry rot) or surface area affected (silver scurf). The disease severity index was then calculated as the number in each class multiplied by the class number and summed. The sum was then multiplied by a constant to express severity on a 0 – 100 scale. Data were analyzed by two-way ANOVA using ARM software (Version 7, Gylling Data Management) and mean separation calculated using Fisher’s protected least significant difference (LSD) test at P= 0.05. Results and Conclusions In the late blight test at 10oC, late blight developed in several treatments and the inoculated check had 58.8% incidence (Table 1). No late blight developed in the non- inoculated check. Treatments with less than 58.8% incidence of late blight were significantly different from the inoculated check. Treatments with greater than 10.0% incidence of late blight were significantly different from the non-inoculated check. In the pink rot test at 10oC, pink rot developed in several treatments and the inoculated check had 65.0% incidence (Table 2). No pink rot developed in the non-inoculated check. Treatments with less than 65.0% incidence of pink rot were significantly different from the inoculated check. Treatments with greater than 7.5% incidence of pink rot were significantly different from the non-inoculated check. In the pythium leak test at 10oC, pythium developed in several treatments and the inoculated check had 60.0% incidence (Table 3). No pythium developed in the non- inoculated check. Treatments with less than 60.0% incidence of pythium were significantly different from the inoculated check. Treatments with greater than 6.3% incidence of pythium were significantly different from the non-inoculated check. 158 Funding: MPIC/Agrochemical Industry USDA/ARS In the Fusarium dry rot studies at 10oC Fusarium dry rot developed in several treatments and the inoculated check had 70% incidence and 31.9-severity index (Table 4). The non- inoculated check had significantly less dry rot incidence and severity than the inoculated check. Treatments with less than 56.3% incidence of dry rot were significantly different from the inoculated check. Treatments with greater than 13.8% dry rot incidence were significantly different from the non-inoculated check. Treatments with less than 24.1 dry rot severity index were significantly different from the inoculated check. Treatments with greater than 5.9 dry rot severity index were significantly different from the non- inoculated check. In the silver scurf leak test at 4oC on Dark Red Norland, severe silver scurf developed in several treatments and the inoculated check had 93.1% incidence of silver scurf (percentage of tubers in class 0) and 55.6% severity index (Table 5). Although the percentage incidence and severity were relatively high in all treatments, they were all significantly lower than the untreated check. In this study, the oomycetes were not all controlled equally by the same programs. For example, Ranman 400SC 0.25 fl oz gave excellent control of late blight and pythium leak but was moderately effective against pink rot. GWN-4700 alone and in mixture was effective against all three oomycetes and not significantly different from the standard program, Phostrol. Late blight was well controlled by many products including WE1042- 1, which was possibly related to the inoculation technique in that the pathogen had not fully penetrated the lenticels by the time the fungicides/biofungicides were applied. This was also true of the Pythium study but the rate of growth and penetration of Phytophthora erythroseptica may have been at a rate great enough for the infection to occur and establish prior to the application of the products. The biological controls were generally les effective than the best chemical controls but still provide some useful reduction in the establishment of the oomycetes. For example, BUPots-4 in the Pythium trial and the late blight trial and BuPots-1 in the pink rot trial. In the dry rot trial, the three-way mixtures of fludioxinil, azoxystrobin and difenoconazole produced excellent control and at all rates of the fungicides (especially at the highest mixture rate of difenoconazole). While treatment with fludioxinil and azoxystrobin together or difenoconazole alone provided effective but numerically less dry rot control than the three-way mixtures although in terms of severity there was no significant difference among treatments. The biological control products in some cases provided a moderate reduction in incidence and severity of dry rot. In the silver scurf trial, azoxystrobin plus fludioxinil and all rates of difenoconazole in the three-way mixtures of fludioxinil, azoxystrobin and difenoconazole produced the best control but only suppressed the development of silver scurf. WE1042-1 75DS and the biological control products provided a moderate reduction in incidence and severity of silver scurf. 159 Funding: MPIC/Agrochemical Industry USDA/ARS Table 1. Incidence of tubers with potato late blight stored at 10oC for 90 days after treatment with fungicides/biofungicides. Treatments and rate of application per cwt of tubers Non-inoculated check…………………………………………… Inoculated check………………………………………………… Ranman 400SC 0.025 fl oz……………………………………... Ranman 400SC 0.05 fl oz………………………………………. Ranman 400SC 0.125 fl oz……………………………………... Ranman 400SC 0.25 fl oz………………………………………. Phostrol 53.6SC 1.28 fl oz……………………………………… Oxidate 27SC 0.125 fl oz……………………………………….. GWN-4700 80WP 0.14 oz……………………………………… GWN-4700 80WP 0.14 oz + Phostrol 53.6SC 1.28 fl oz………. GWN-4700 80WP 0.14 oz + Phostrol 53.6SC 1.28 fl ozc……… GWN-4700 80WP 0.14 oz + A8574 360FSd 0.03 fl oz………… GWN-4700 80WP 0.14 oz + A9859 230SCd 0.03 fl oz………… GWN-4700 80WP 0.14 oz + A8574 360FS 0.03 fl oz + A9859 230SC 0.03 fl oz………………………………………… 09 BuPots-1 100L 0.2 fl oz……………………………………... 09 BuPots-2 100WS 1.52 oz……………………………………. 09 BuPots-3 100WS 1.52 oz……………………………………. 09 BuPots-4 100LS 0.2 fl oz……………………………………. 09 BuPots-5 100LS 0.3 fl oz……………………………………. WE1042-1 75DS 1 lb…………………………………………… ME02-7008A 100D 1 lb………………………………………… ME03-5709A 100D 1 lb………………………………………… W103-5B 100D 1 lb…………………………………………….. ND04-1A 100D 1 lb…………………………………………….. Vermiculite 100D 1 lb…………………………………………... LSD0.05 Late blight incidence (%)a 0.0 lb 58.8 a 11.3 f-k 7.5 h-l 10.0 g-l l 0.0 jkl 3.8 i-l 6.3 12.5 f-j 15.0 e-i 6.3 i-l 7.5 h-l 3.8 jkl 1.3 kl 18.8 d-g 17.5 d-h 23.8 de 7.5 h-l 13.8 e-j jkl 26.3 cd 23.8 de 36.3 bc 21.3 def 37.5 b 3.8 10.13 a Late blight incidence (%); tubers with any symptoms and signs of Phytophthora infestans. b Values followed by the same letter are not significantly different at P = 0.05 level according to Fisher’s protected least significant difference (LSD) test. c Applied in 4 pt H2O/ton tubers. d A8574D= difenoconazole; A9859= fludioxinil. 160 Funding: MPIC/Agrochemical Industry USDA/ARS Table 2. Incidence of tubers with pink rot stored at 10oC for 90 days after treatment with fungicides/biofungicides. Treatments and rate of application per cwt of tubers Non-inoculated check…………………………………………… Inoculated check………………………………………………… Ranman 400SC 0.025 fl oz……………………………………... Ranman 400SC 0.05 fl oz………………………………………. Ranman 400SC 0.125 fl oz……………………………………... Ranman 400SC 0.25 fl oz………………………………………. Phostrol 53.6SC 1.28 fl oz……………………………………… Oxidate 27SC 0.125 fl oz……………………………………….. GWN-4700 80WP 0.14 oz……………………………………… GWN-4700 80WP 0.14 oz + Phostrol 53.6SC 1.28 fl oz………. GWN-4700 80WP 0.14 oz + Phostrol 53.6SC 1.28 fl ozc……… GWN-4700 80WP 0.14 oz + A8574 360FSd 0.03 fl oz………… GWN-4700 80WP 0.14 oz + A9859 230SCd 0.03 fl oz………… GWN-4700 80WP 0.14 oz + A8574 360FS 0.03 fl oz + A9859 230SC 0.03 fl oz………………………………………… 09 BuPots-1 100L 0.2 fl oz……………………………………... 09 BuPots-2 100WS 1.52 oz……………………………………. 09 BuPots-3 100WS 1.52 oz……………………………………. 09 BuPots-4 100LS 0.2 fl oz……………………………………. 09 BuPots-5 100LS 0.3 fl oz……………………………………. WE1042-1 75DS 1 lb…………………………………………… ME02-7008A 100D 1 lb………………………………………… ME03-5709A 100D 1 lb………………………………………… W103-5B 100D 1 lb…………………………………………….. ND04-1A 100D 1 lb…………………………………………….. Vermiculite 100D 1 lb…………………………………………... Vermiculite 100D 1 lb LSD0.05 Pink Rot incidence (%)a 0.0 k 65.0 a 13.8 f-i 18.8 efg 20.0 ef 20.0 ef 10.0 hij jk ij ijk 11.3 g-j 10.0 hij 3.8 8.8 7.5 8.8 ij 8.8 7.5 ij ijk 10.0 hij 21.3 def 22.5 de 17.5 e-h 21.3 def 8.8 ij 28.8 cd 35.0 c 28.8 cd 33.8 c 53.8 b 8.02 a Late blight incidence (%); tubers with any symptoms and signs of Phytophthora infestans. b Values followed by the same letter are not significantly different at P = 0.05 level according to Fisher’s protected least significant difference (LSD) test. c Applied in 4 pt H2O/ton tubers. d A8574D= difenoconazole; A9859= fludioxinil. 161 Funding: MPIC/Agrochemical Industry USDA/ARS Table 3. Incidence of tubers with pythium leak stored at 10oC for 90 days after treatment with fungicides/biofungicides. Treatments and rate of application per cwt of tubers Non-inoculated check…………………………………………… Inoculated check………………………………………………… Ranman 400SC 0.025 fl oz……………………………………... Ranman 400SC 0.05 fl oz………………………………………. Ranman 400SC 0.125 fl oz……………………………………... Ranman 400SC 0.25 fl oz………………………………………. Phostrol 53.6SC 1.28 fl oz……………………………………… Oxidate 27SC 0.125 fl oz……………………………………….. GWN-4700 80WP 0.14 oz……………………………………… GWN-4700 80WP 0.14 oz + Phostrol 53.6SC 1.28 fl oz………. GWN-4700 80WP 0.14 oz + Phostrol 53.6SC 1.28 fl ozc……… GWN-4700 80WP 0.14 oz + A8574 360FSd 0.03 fl oz………… GWN-4700 80WP 0.14 oz + A9859 230SCd 0.03 fl oz………… GWN-4700 80WP 0.14 oz + A8574 360FS 0.03 fl oz + A9859 230SC 0.03 fl oz………………………………………… 09 BuPots-1 100L 0.2 fl oz……………………………………... 09 BuPots-2 100WS 1.52 oz……………………………………. 09 BuPots-3 100WS 1.52 oz……………………………………. 09 BuPots-4 100LS 0.2 fl oz……………………………………. 09 BuPots-5 100LS 0.3 fl oz……………………………………. WE1042-1 75DS 1 lb…………………………………………… ME02-7008A 100D 1 lb………………………………………… ME03-5709A 100D 1 lb………………………………………… W103-5B 100D 1 lb…………………………………………….. ND04-1A 100D 1 lb…………………………………………….. Vermiculite 100D 1 lb…………………………………………... LSD0.05 Pink Rot incidence (%)a 0.0 k 60.0 a 8.8 g-j 13.8 e-h 8.8 g-j ijk 6.3 jk 3.8 5.0 ijk 7.5 hij 6.3 ijk jk 3.8 ijk 6.3 6.3 ijk 6.3 ijk 15.0 d-g 13.8 e-h 15.0 d-g 11.3 f-i 17.5 def ijk 18.8 de 20.0 de 27.5 c 21.3 cd 35.0 b 6.3 7.25 a Late blight incidence (%); tubers with any symptoms and signs of Phytophthora infestans. b Values followed by the same letter are not significantly different at P = 0.05 level according to Fisher’s protected least significant difference (LSD) test. c Applied in 4 pt H2O/ton tubers. d A8574D= difenoconazole; A9859= fludioxinil. 162 Funding: MPIC/Agrochemical Industry USDA/ARS Table 4. Severity and incidence of tubers with Fusarium dry rot 90 days after treatment with fungicides/biofungicides at 10oC. Treatments and rate of application per cwt of tubers Non-inoculated check………………………………………… Inoculated check……………………………………………… A12705 250SCc 0.03 fl oz + A9859 230SCc 0.03 fl oz………. A8574D 360FSc 0.015 fl oz…………………………………... A12705P 250SC 0.03 fl oz + A8574D 360FS 0.0075 fl oz + A9859 230SC 0.03 fl oz………………………………………. A12705P 250SC 0.03 fl oz + A8574D 360FS 0.015 fl oz + A9859 230SC 0.03 fl oz………………………………………. A12705P 250SC 0.03 fl oz + A8574D 360FS 0.0226 fl oz + A9859 230SC 0.03 fl oz………………………………………. A12705P 250SC 0.03 fl oz + A8574D 360FS 0.03 fl oz + A9859 230SC 0.03 fl oz………………………………………. 09 BuPots-1 100L 0.2 fl oz…………………………………… 09 BuPots-2 100WS 1.52 oz………………………………….. 09 BuPots-3 100WS 1.52 oz………………………………….. 09 BuPots-4 100LS 0.2 fl oz………………………………….. 09 BuPots-5 100LS 0.3 fl oz………………………………….. WE1042-1 75DS 1 lb…………………………………………. ME02-7008A 100D 1 lb……………………………………… ME03-5709A 100D 1 lb……………………………………… W103-5B 100D 1 lb………………………………………….. ND04-1A 100D 1 lb………………………………………….. Vermiculite 100D 1 lb………………………………………... LSD0.05 Dry rot Incidence (%) Dry rot Severity indexa 2.5 fb 70.0 a 22.5 d 20.0 de 13.8 def 7.5 ef 8.8 def 3.8 f 62.5 abc 61.3 abc 53.8 c 52.5 c 68.8 ab 55.0 bc 51.3 c 51.3 c 56.3 abc 50.0 c 68.8 ab 0.6 f 30.6 ab 5.9 5.0 f f 4.4 f 2.2 f 2.8 f 0.9 f 29.1 abc 26.9 a-e 22.2 cde 20.9 cde 31.9 a 22.5 b-e 20.3 de 20.3 de 24.1 a-e 19.7 e 28.1 a-d 8.33 a Severity classes were determined as class 0 = 0%; 1 = 1 - 10%; 2 = 11 - 20%; 3 = 21 - 50; 4 > 51 – 100% internal area of tuber tissue with disease and incidence is percentage of tubers in class 1 - 4. b Values followed by the same letter are not significantly different at P = 0.05 level according to Fisher’s protected least significant difference (LSD) test. c A12705= azoxystrobin; A8574D= difenoconazole; A9859= fludioxinil. 14.33 163 Funding: MPIC/Agrochemical Industry USDA/ARS Table 5. Severity and incidence of tubers with silver scurf 101 days after treatment with fungicides/biofungicides at 4oC. Treatments and rate of application per cwt of tubers Non-inoculated check………………………………………… A12705 250SCc 0.03 fl oz + A9859 230SCc 0.03 fl oz………. A8574D 360FSc 0.015 fl oz…………………………………... A12705P 250SC 0.03 fl oz + A8574D 360FS 0.0075 fl oz + A9859 230SC 0.03 fl oz………………………………………. A12705P 250SC 0.03 fl oz + A8574D 360FS 0.015 fl oz + A9859 230SC 0.03 fl oz………………………………………. A12705P 250SC 0.03 fl oz + A8574D 360FS 0.0226 fl oz + A9859 230SC 0.03 fl oz………………………………………. A12705P 250SC 0.03 fl oz + A8574D 360FS 0.03 fl oz + A9859 230SC 0.03 fl oz………………………………………. 09 BuPots-1 100L 0.2 fl oz…………………………………… 09 BuPots-2 100WS 1.52 oz………………………………….. 09 BuPots-3 100WS 1.52 oz………………………………….. 09 BuPots-4 100LS 0.2 fl oz………………………………….. 09 BuPots-5 100LS 0.3 fl oz………………………………….. WE1042-1 75DS 1 lb…………………………………………. LSD0.05 Silver scurf incidence (%) ab 93.1 85.6 b 69.7 gh Silver scurf Severity indexa (%) 55.6 a 43.2 de 32.2 h 74.1 fg 32.3 gh 84.7 bcd 36.6 fg 80.9 cde 36.9 f 66.3 h 86.9 b 85.0 bc 78.1 ef 85.9 b 80.3 de 84.1 bcd 33.0 fgh 46.3 b-e 49.0 b 44.5 cde 47.7 bc 42.4 e 47.5 bcd a Severity classes were determined as class 0 = 0%; 1 = 1 - 10%; 2 = 11 - 20%; 3 = 21 - 50; 4 > 51 – 100% internal area of tuber tissue with disease and incidence is percentage of tubers in class 1 - 4. b Values followed by the same letter are not significantly different at P = 0.05 level according to Fisher’s protected least significant difference (LSD) test. c A12705= azoxystrobin; A8574D= difenoconazole; A9859= fludioxinil. 164 2009 Research Report to Michigan Potato Industry Commission Research Committee Characterization of Streptomyces Species That Cause Potato Common Scab in Michigan Soil and Determination of Microbial Structure of Disease Suppressive Soil PI: Jianjun (Jay) Hao, Assistant Professor Department of Plant Pathology Michigan State University Common scab is the most important soilborne disease in the potato industry. It is Collaborators: David Douches, William Kirk, Chris Long, Ray Hammerschmidt Project personnel: Anthony Adesemoye, Qingxiao Meng INTRODUCTION caused by multiple Streptomyces species, but S. scabies is documented as a predominant pathogen worldwide. Knowing what species is distributed in the soil helps the production to make a strategic plan for disease management. We were to investigate potato field in Michigan and determine if there are more species or diversified groups of the pathogen. We also studied disease suppressive soil, and looked for microorganisms that are contributing to the suppressiveness. Our objectives were to (1) Characterize the new pathogenic Streptomyces sp. strain; (2) Survey Michigan soil for Streptomyces genetic diversity and geographic distribution; and (3) Characterize the soil that suppresses pathogenic Streptomyces spp.. PROCEDURE 1. Characterize the new pathogenic Streptomyces sp. strain with common scab symptoms, using Streptomyces selective media STR. Other Streptomyces species have been collected from National Center for Agricultural Utilization Research. DNA extraction from Streptomyces were done by using DNeasy kit (Qiagen Inc, Valencia, CA). The 16S rRNA gene was amplified from DNA of Streptomyces isolates by PCR using primers 16S-1F and 16s-1R. Analysis of the presence of gene characteristic of the pathogenic island (PAI) genes were carried out by PCR using primers specific to the txtAB, tomA gene and the nec-1. Streptomyces isolates were obtained from Michigan potato field or potato tubers Pathogenicity of Streptomyces spp. was confirmed by a fast assay by inoculating it onto potato tuber slices, and further confirmed in the greenhouse. Inocula were made in vermiculite, which was mixed in potting soil before potato tubers were seeded. Thaxtomin production was examined using the following method: 200 ml of oatmeal broth with trace elements were inoculated with 200 µl of a concentrated spore suspension of Streptomyces strains. The culture was incubated at 28 °C for 7 days, centrifuged, and the supernatant was extracted two times with equal volume of ethyl acetate. The combined ethyl acetate extracts were evaporated and the yellow residue was taken up in methanol. The suspension was analysed using high performance liquid chromatography/Quattro Micro.   165 2. Survey Michigan soil for Streptomyces spp. genetic diversity and geographic distribution. Potato tubers with typical scab symptoms were collected from various locations in representative Michigan potato production areas. Scab lesions were excised with a scalpel, surface sterilized with 0.62% of NaOCl, and macerated. The tissue was spread on the STR media. After incubation at 28 °C for 7 to 10 days, Streptomyces spp. were picked and pure cultures were obtained after serial transfers to new media plates. Morphological and molecular methods were used for identification of the isolates. Molecular identification was done by PCR amplification of the 16S rRNA gene from DNA of Streptomyces isolates using primers 16S-1F and 16s-1R.The pathogenicity and virulence of the isolated Streptomyces were determined by using PCR with marker genes, including nec1, txtAB, and tomA. The frequency and virulence of each species were analyzed by location and potato cultivar. 3. Characterize the soil that suppresses pathogenic Streptomyces spp. Ten-inch pots were filled with potting soil on the bottom (1/3 of total volume), while the upper 2/3’s of the pot was filled with the different soil treatments. Two soil treatment methods were used to conduct this study. In the first method, soil was a mixture of different ratios of potting soil and suppressive soil: 0, 20, 40, 60, 80 and 100% of suppressive soil by volume. In the second method, the suppressive soil was treated with various temperatures for 30 min: room temperature, 30, 45, 60, 75, 90 and 121 °C. S. scabies inocula were mixed into the soils in pots. At harvesting, potato tubers were evaluated for scab symptom. A spiral autoplate was used for microbial population enumeration. Semi-selective media include STR for Streptomyces, S1 for florescent Pseudomonas, 1/10 Tryptic soy agar with fungicides for general bacteria, and Rose bengal agar for total fungi. Bacillus was enumerated on 1/10 TSA with the soil dilution is heated at 80°C for 30 min. Terminal restriction fragment length polymorphism (T-RFLP) analysis was used for characterizing the microbial community structure, focusing on bacterial populations. Total microbial DNA was extracted from the soils. 16S rDNA of bacteria was amplified using PCR. The PCR products were digested separately with MspI and RsaI restriction enzymes. Fragment size analysis was carried out on an ABI PRISM® 3130xl Genetic Analyzer (Applied Biosystems, UK). T-RFLP profiles were generated from the Genetic Analyzer data using GeneMapper software (ABI, UK). The binary data were analyzed using cluster analysis. The Streptomyces and other bacterial isolates were tested by a co-plate assay for inhibition to pathogenic Streptomyces scabies in vitro. Plates were examined for the presence of inhibition zones, and colonies that exhibited inhibition zones were re- isolated from the original plate, cultured, and stored for further tests. These isolates will also be examined for pathogenicity on potato tuber slices. RESULT We have characterized a new Streptomyces strain DS3024. It causes scab symptoms on potato tubers, as S. scabies does (Fig. 1). DS3024 has marker gene txtAB and tomA, but lacks of nec1. It can survive at low pH condition (pH=4.5) (Table 1).   166 It is distinct from any other known streptomycete pathogens phylogenetically (Fig. 2). The data on diversity indicated that pathogenic Streptomyces spp. in Michigan is diversified. S. scabies is predominant, but other species may exist, for example, S. stelliscabiei (Table 2). More data is currently being analysed that will provide more information. The disease suppressive soil was identified to be due to biological factors. Increasing the ratio of suppressive soil in the pot significantly decreased the disease severity and increased plant growth both in radish and potato (Fig. 3 to 5); higher temperature treatment caused higher disease severity (Fig. 5). T-RFLP result showed that the disease suppressive soil has distinct microbial profile compared to disease conducive soil (Fig. 6). Further studies are needed to identify the microorganisms that contribute to the disease suppression. Several bacteria isolated from the disease suppressive soil showed strong inhibition to Streptomyces spp. that were pathogenic to potatoes. These can be potential biological control agents for managing potato common scab. Publications – Hao, J. J., Meng, Q. X., Yin, J. F., and Kirk, W. W. 2009. Characterization of a new Streptomyces strain, DS3024, that causes potato common scab. Plant Dis. 93:1329-1334. – MENG, Q., Yin, J. Hammerschmidt, R., Kirk, W., Hao, J. 2009. Characterization of a naturally occurred suppressive soil to potato common scab in Michigan. Phytopathology 99:S84 – MPIC bulletin, 2009. Table 1. Characterization of DS3024 ATCC49173 New York Orange brown S. scabies DS3024 MSU, MI Dark brown Ref. Sp.ME02.6979.3a + + + + 5.8 + + - + 4.5 Isolate Location Color on YME 16S rRNA TxtAB TomA Nec1 Pathogenesis on potato Lowest pH for growth   167 Table 2. Characterization of Streptomyces species isolated from Michigan soil Isolate 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 Streptomyces spp. + + + + + + + + + + + + + + + + + + + + + + + S. scabies - - - - - - - - - + + + + + + + + + + + + + + S. stelliscabiei - - + + + + + + + - - - + + + - - - - - - - - Nec1 - - - - - - - - - + + + + + + + + + + + + + + - - + + + + + + + - TxtAB Table 3. Frequency of bacterial isolates showing antibiotic characteristics and pathogenicity from different soils. - - - - - + + + + + + + + Soil type Frequency of antagonistic isolates against S. scabies (%) Symptom positive (%) Bacillus spp. Streptomyces spp. Suppressive soil 26.3 Disease conducive soil 19.5 13.5 14.8 8.9 12.9   168 Figure 1. Comparison of Streptomyces spp., from left to right: S. scabies (ATCC isolate 49173), DS3024, and control. Upper panel: inoculation of bacterial suspension on potato tuber slices; lower panel: inoculation of bacterial suspension in soil that cause scab symptoms on potato tubers. All the three isolates produce thaxtomin. Figure 2. Phylogenetic tree of Streptomyces spp..   169 0 0.5 1 1.5 2  0 0.6 1.2 1.8 2.4 3    ) 5 ­ 0 (   e r o c s e s a e s i D     ) 5 ­ 0 (   e r o c s e s a e s s i D   50   ) m c (   .   c r i c r e b u T   ) 5 ­ 0 (   e r o c s e s a e s i D   0 1.5 3 4.5 6  0 0.4 0.8 1.2 1.6 2  0 25 % suppressive soil Figure 3. Effect of soil mixing on scab severity in radish. y = ‐0.2882x + 1.6959  R² = 0.92  75 100 AS  25S  50S  75S  SS  y = ‐0.5019x + 2.9289  R² = 0.94672  y = 0.8293x + 1.4609  R² = 0.88  SS  25S  50S  75S  AS  y = 0.4x ‐ 0.5444  R² = 0.96429  Figure 4. Effect of siol mixture on disease severity in radish. AS: autoclaved suppressive soil, 25S, 50S, 75S, and SS are soil mixed with 25, 50, 70, and 100% of suppressive soil. 0  20  40  60  80  100  40  60  70  80  90  120  % suppressive soil  Figure 5. Effect of soil mixture (left panel) and temperature treatment (right panel) on disease severity in potato. Temperature (C)    170 Figure 6. Profiles of two types of soils characterized using T-RFLP. D soil = disease conducive soil; and S soil = disease suppressive soil. Figure 7. Effect of bacterial isolates from disease suppressive soil on Streptomyces scabies. All isolates were Bacillus spp. (left to right: BCA1 to BCA6). Figure 8. Effect of BCA3 isolated from disease suppressive soil on the growth of Streptomyces spp. (left to right: S. aureofaciens, S. scabies, S. acidiscabies, AC-1, 0095, and DS3024).   171 2008‐2009 Corky Ring‐Spot Disease of Potato Research  Loren Wernette, George Bird, Willie Kirk, Karl Richie and John Davenport    There are many diseases that cause economic losses in potato production.  Many of these are  well known in Michigan.  A disease that was not detected in MI until very recently is Corky Ring‐Spot  Disease of Potato (CRSD). This is caused by a Tobravirus  (Tobacco Rattle Virus) known as TRV.  It is a  tubular shaped virus that historically has caused dark necrotic corky tissue to form in mature tubers.   These areas are usually found in arcs or rings and can sometimes be seen on the skin of tubers in ring  patterns.  It has also been reported from other geographic locations and in greenhouses as foliar  symptoms in the shape of chevrons.  This virus is transported (vectored) to plant roots by stubby‐root  nematodes (Trichodorus, Paratrichodorus).  In MI there are seven known species of stubby‐root  nematodes, with several of them known to be vectors of TRV.  Stubby‐root nematode populations are  commonly found in agriculture fields and have a wide host range.  This includes all the main cash crops  grown in MI, as well as most weed species.  TRV also has a wide host range, surviving on corn, wheat,  soybeans, and most weed species.  These alternative hosts for both the vector and the virus help the  virus persist in the soil for many years.  In research outside of MI, it has been shown that the most  effective chemical controls are Telone II and Vydate. The objective of this MPIC‐funded research was to  identify effective chemical controls for CRSD in MI.  The studies were conducted in 2008 and 2009 on a  14 acre field molecularly confirmed to have the disease in 2007.  This field was managed by Walther’s F  Potato Farms and is located in White Pigeon MI.  The trial for the 2008 study consisted of 16 treatments  replicated 5 times for a total of 80 plots (Table 1).    Table 1.  2008 CRSD research treatments and rates.   Treatment  Rate(lb/A)  Control  Vydate C‐LV at plant (low)  Vydate C‐LV at plant (high)  Vydate C‐LV at plant(low) + Post emergence  Metam Sodium  Metam Sodium + Vydate C‐LV at plant (low)  Metam Sodium + Vydate C‐LV at plant (high)  Metam Sodium + Vydate C‐LV at plant(low)+ post emergence  Telone II  Telone II + Vydate C‐LV at plant(low)  Telone II + Vydate C‐LV at plant (high)  Telone II + Vydate C‐LV at plant(low) +post emergence  Metam Sodium + Telone II  Metam Sodium + Telone II + Vydate C‐LV at plant (low)  Metam Sodium + Telone II + Vydate C‐LV at plant (high)  Metam Sodium + Telone II + Vydate C‐LV at plant(low) +post emergence  0.0  0.5  1.0  2.0  158.25  158.75  159.05  160.25  177.3  177.8  178.3  179.3  335.55  336.05  336.55  337.55  172  Telone II was applied in the fall of 2007 by Hendrix and Dail Inc. at the 18 gal/A.  Metam sodium was  applied in the spring of 2008 by John Davenport at 37.5 gal/A, the most commonly applied rate for  potato growers in MI.  The Vydate C‐LV was applied in‐furrow on pre‐established hills two weeds prior  to planting to ensure there was no phytotoxicity effects on the newly planted potatoes. Frito Lay cv  1879 were planted at the end of May.  Post emergence applications of Vydate C‐LV were made by Rob  Schafer at regular intervals throughout the growing season at a rate of 2.1 pints/A.  The 2008 tuber  harvest consisted of digging 20 ft of row from every plot with Chris Long’s one row digger.  The tubers  were then placed in crates and transported to the Clarksville Research Station and stored at 55˚F.  One  month following harvest, all the potatoes were weighed to determine yield and ten tubers were  selected from each plot and cut from stem end to bud end to visually inspect for CRSD symptoms.  Any  tubers that expressed symptoms were taken to Dr. William Kirk’s lab and RT‐PCR was used to confirm  that the agent of infection was Tobacco Rattle Virus.  Two additional symptom ratings were made.  In 2009, the research was repeated with some modifications.  The trial was done on the  adjacent side of the field , where corn was grown 2008.  In 2009, soybeans were grown on the east side  with potatoes on the west side.  The 2009 trial consisted of 24 total plots, with seven treatments that  were replicated three or four times.  Each plot was 180 feet long and 32 feet wide. Walther’s planted  Frito Lay cv 1879 on May 30 and managed insect and disease pressure and nutrient requirements  throughout the season.  The 2009 treatments included metam sodium and Vydate C‐LV at different  timings and combinations (Table 2).  Telone II was not used for several reasons.  It has almost no market  share in the MI potato industry.  It also was not available at the time we needed it for application, and  we did not see significant results using it in 2008.  Metam sodium was applied at the maximum labeled  rate of 75 gal/A  by John Davenport in April, prior to planting.   Two weeks prior to planting,  the in  furrow application of Vydate C‐LV was applied to the pre‐ formed hills by Rob Shafer at a rate of 4  pints/A.  Following planting, four more applications of Vydate C‐LV were applied as a foliar spray at  2pints/A.  The first was made at tuber initiation and then at two week intervals until four treatments  was reached.  Throughout the season, five soil samples were taken in all 24 plots and analyzed to  determine stubby‐root nematode populations.  The samples were taken before fumigation with  Sectagon 42, before application of Vydate C‐LV in furrow,  before second foliar application of Vydate C‐ LV, before the fourth foliar application of Vydate C‐LV, and at harvest.  The nematodes were extracted  using the centrifugal flotation method.    Table 2. 2009 CRSD control research treatments and chemical rates.  Treatments  Control  Vydate C‐LV  4 Foliar applications Vydate C‐LV  Vydate C‐LV in furrow + 2 Foliar applications Vydate C‐LV  Vydate C‐LV in furrow + 4 Foliar applications Vydate C‐LV  Metam Sodium  Metam Sodium +Vydate C‐LV in furrow + 4 Foliar applications  Vydate C‐LV      Lbs Active Ingredient/A  0.0  1.89  3.77  3.77  5.66  316.5  322.16  173 Tuber harvest was conducted on the 5th of October.  Chris Long’s one row potato digger was  used to dig four ten foot sections of row from each plot.  Each ten foot section was labeled and crated  separately.  The 96 crates were then transported to Clarksville Research station where they were kept at  55˚F.  One month after the beginning of storage, the weights of the potatoes from each crate was  measured and the yield determined.  Ten tubers were also selected at random from each crate and cut  from bud end to stem end to visually determine if symptoms of CRSD were present.  This visual rating  was done three more times after this, with one additional sampling to be done in March of 2010.  Data  from the last sampling date are not included in this report.  Results and Discussion  In 2008, yields ranged from 397 to 496 cwt per acre (Table 3).  These yields were quite high for  MI which has an average state yield of 350 cwt.  This was probably due to the low incidence of potato  early die.  It also indicates that CRSD did not affect tuber weight (Table 3).  Table 3.  2008 CRSD research tuber yield (cwt/acre).  Treatment  Yield (cwt)  Control  Vydate C‐LV at plant (low)  Vydate C‐LV at plant (high)  Vydate C‐LV at plant(low) + Post emergence  Metam Sodium  Metam Sodium + Vydate C‐LV at plant (low)  Metam Sodium + Vydate C‐LV at plant (high)  Metam Sodium + Vydate C‐LV at plant(low)+ post emergence  Telone II  Telone II + Vydate C‐LV at plant(low)  Telone II + Vydate C‐LV at plant (high)  Telone II + Vydate C‐LV at plant(low) +post emergence  Metam Sodium + Telone II  Metam Sodium + Telone II + Vydate C‐LV at plant (low)  Metam Sodium + Telone II + Vydate C‐LV at plant (high)  Metam Sodium + Telone II + Vydate C‐LV at plant(low) +post emergence  424  459  466  451  460  443  459  481  397  496  447  469  478  478  456  463       The symptom expression data (Table 4) shows that there is a general  trend (Figure 1.)  that the more chemical applied the less CRSD symptom expression observed.  Symptom expression  ranged from 0.0% in many of the treatments to 12.5% in the control and the Vydate in‐furrow at the low  rate.  The treatments that showed symptom expression were located throughout the field, with no  noticeable hotspots.  Soil samples taken thoughout the season showed a very low population of stubby‐ root nematode, which is not surprising due to the fact that the vector threshold is two nematodes per  100 cc of soil and the stubby‐root nematode does not prefer to feed on potato roots.    174 Table 4.  2008 CRSD research symptom expression.  Treatment  Symptom (%)  Control  Vydate C‐LV at plant (low)  Vydate C‐LV at plant (high)  Vydate C‐LV at plant(low) + Post emergence  Metam Sodium  Metam Sodium + Vydate C‐LV at plant (low)  Metam Sodium + Vydate C‐LV at plant (high)  Metam Sodium + Vydate C‐LV at plant(low)+ post emergence  Telone II  Telone II + Vydate C‐LV at plant(low)  Telone II + Vydate C‐LV at plant (high)  Telone II + Vydate C‐LV at plant(low) +post emergence  Metam Sodium + Telone II  Metam Sodium + Telone II + Vydate C‐LV at plant (low)  Metam Sodium + Telone II + Vydate C‐LV at plant (high)  Metam Sodium + Telone II + Vydate C‐LV at plant(low) +post emergence            12.5  12.5  7.5  2.5  2.5  0.0  5.0  0.0  0.0  5.0  2.5  0.0  2.5  0.0  0.0  2.5      175 The 2009 results were similar to those of 2008 (Table 5).  The highest yields were 488 cwt/A and  the lowest 442 cwt/acre.  The yield data also indicatethe trend that the more lb/acre of active ingredient  applied the higher the tuber yield.  This could have to do with the ability for metam sodium to have  fungicidal properties at the 75gal/A rate.  This would help to alleviate some of the potato early die stress  that would normally be a yield limiting factor.  An additional component  was to determine the  relationship between symptom expression and length of storage.  Symptoms expression varies among  treatments, ranging from 0 to 4.4% (Figure 2).  Symptom expression appeared to increased in storage.   Table 5. 2009 CRSD research tuber yields.  Treatments  Control  Vydate C‐LV  4 Foliar applications Vydate C‐LV  Vydate C‐LV in furrow + 2 Foliar applications Vydate C‐LV  Vydate C‐LV in furrow + 4 Foliar applications Vydate C‐LV  Metam Sodium  Metam Sodium +Vydate C‐LV in furrow + 4 Foliar applications  Vydate C‐LV    Figure 2. 2009 CRSD symptom expression.  Yield (cwt)  449  445  442  478  474  488  484        176 As with all virus diseases, the best way to prevent CRSD is through the use of TRV‐free    certified seed and TRV/SRN‐free equipment.  Once a given site is infested with both TRN and  SRN, the only current economically viable options are to use both a pre‐plant soil fumigant and a  post‐plant non‐fumigant nematicide.  In the 2008‐2009 MI trial, the 75 gal/acre metham sodium  treatment was more successful than the lower rate of metham sodium or the use of Telone II.   While symptom expression appeared to increase in storage, the current data are not statistically  significant for this attribute.   While CRSD had a negative impact on marketable tubers, it did not  reduce overall tuber tonnage.  177 2009 Michigan Metam Sodium Atmospheric Emission Study George Bird, Ben Kudwa, David Sullivan, Loren Wernette and Mark Otto The following is a pre-print of an abstract that has been submitted for a paper that will be presented at the 2010 Annual Meeting of The Potato Association of America. Soil fumigants, including metam sodium are under going the Environmental Protection Agency (EPA) re-registration process. Buffer zones designed to prevent off-site exposure were proposed as part of the Re-registration Eligibility Decision (RED). The RED buffer zone recommendation was based on research conducted at relatively high soil and air temperatures in Bakersfield, California (CA). The proposed RED buffer zones for shank injected metham sodium have the potential to reduce Michigan (MI) potato acreage by about 30%. In MI potato production, metham sodium is applied in late fall under cool soil and air temperatures. The MI potato industry believed that RED buffer zones should be based on atmospheric emission data from current application technology and local environmental conditions. In 2009, they funded a research project designed to develop an atmospheric emission data set for metham sodium applied by shank injection under cool soil and air temperatures. The research included both a post-application cultipaker dry seal and a wet seal with irrigation water. Two one-acre plots, 1.3 miles apart, were used. The quality assurance component mandated that no other fumigation be conducted in the Township during the time of trial. Prior to metham sodium application, Sullivan Environmental Consulting Inc. (SEC) assembled charcoal sorbent atmospheric monitoring sensors and weather stations at both sites. Metham sodium was applied at 75 gal/acre with a commercial shank injection fumigator at a 12-inch soil depth. The atmospheric emission monitoring sensors were activated prior to application of metham sodium and maintained active until 96 hours post-application. At both sites, the applicator was followed immediately by a cultipacker. One of the sites also received a post-application water seal of 0.33 inches. Metham sodium was extracted from the charcoal sorbent tubes and quantitatively analyzed using gas chromatography. The highest peak emissions were slightly greater than 2 micrograms per meter square per second, compared to more than 50 micrograms per meter square per second for the CA. When a water seal was included, the peak emission was less than 0.5 micrograms per meter square per second. These data were presented to EPA by MI potato growers and SEC on 25 Feb. 2010. The project was replicated by the Wisconsin potato industry and support was provided by both Minnesota and North Dakota. Dr. Bird has been selected to provide the quality assurance component of an additional replication of the research which will take place the next to last week of March 2010. 178 Effect of 1,4-SIGHT® post-harvest potato dormancy treatment on sugars of stored chip stock in Michigan Funding: 1,4-Sight Group Chris Long and Greg Steere Introduction: This is a brief summary of the 2008-2009 storage trial conducted at Sackett Potatoes, Mecosta Co., MI. In this trial, 1,4-Sight was applied to three chip processing varieties and the tubers were evaluated for adverse sugar accumulation resulting from the Dimethylnaptheline (DMN) application. The experiments began in late September 2008 and concluded in late March 2009. At the start of this experiment, Dimethylnaptheline was also being evaluated for its ability to reduce tuber weight loss in storage and increase tuber dormancy. Due to tuber rot in FL1833 and sample loss resulting from bin shipment of Pike and FL1922, accurate tuber weight loss values were not collected. Results: Please see attached graphs of sugar concentration vs. pile temperature and a graph of chip color and color defects for each variety tested. Discussion: The variety FL1833 was used as a long-term storage variety in this trial in 2007-2008 and again here in 2008-2009. DMN was applied to the treated samples of FL1833 on October 28th, 2008. Early in the experiment, the sucrose concentrations in the pile, in the untreated and in the treated samples, tracked very closely to each other (Figure 1). On January 26th 2009 the sugar quality of these samples began to diverge. During the months of January and February the treated sample had a significantly higher sucrose level than either the pile or untreated samples (Figure 1). In late March when this bin of FL1833’s was shipped, the treated and pile sucrose levels were very similar. It is hard to explain why the sucrose level in the untreated sample did not rise in synchronization with the pile and treated samples. Glucose levels in the treated samples were generally higher than the glucose levels in the pile and the untreated samples. Based on the chip color, it was difficult to say if there were any treatment effects (Figure 2). The percent chip color defects for the pile and untreated samples appeared to be similar, but the treated sample contained a considerably higher percentage of color related defects in late March 2009. CIPC was applied to all FL1833 samples approximately six weeks after the DMN application. There was no observed effect of the DMN on sugar quality of the pile, untreated or treated samples 60 days after application. During this two month period, an 179 impact of the DMN product would have be expected if it was going to influence tuber quality. Pike was tested in this experiment because it is a short term storage variety with excellent early chip quality. It is generally put into storage early in the storage season when the tuber temperatures are high (70ºF). Pike may greatly benefit from a DMN application early in storage. Also, the DMN application does not require the added heat as in a CIPC application, thus preventing any possible storage loss due to additional elevated storage temperatures. CIPC is not typically applied until the tubers have suberized where as the DMN may be applied a week after tubers have been placed in storage. The DMN was applied to these treated samples on September 26th, 2008. The tubers had a pulp temperature of 65.6 ºF at the time of DMN application. The sugar concentrations of the samples tracked in a similar and consistent pattern for both sucrose and glucose across treatments with the exception of the untreated sample sucrose which was slightly elevated in December (Figure 3). Chip color was identical for all treatments (Figure 4). There was some slight variability between the color related chip defects in the pile and untreated samples. The treated sample had the highest percent of color defects on January 26th, 2009. Just as in the FL1833 variety, the DMN did not influence tuber sugar quality in the Pike variety, but it was notable that the treated samples for each variety contained the greatest number of color related defects at the end of the storage season. The FL1922 variety was chosen because of its excellent long term storability. This variety was treated with DMN on October 17th, 2008. Of the three varieties tested, this variety exhibited the least amount of variability in sugar concentration, resulting in good chip color and minimal chip color defects (Figures 5-6). These observations are consistent with same experiment conducted during the 2007-2008 storage season. The sucrose levels of the three treatments tracked very closely and the glucose levels were identical. This also held true for the chip color and color defects. The treated FL1922 sample exhibited little deviation from the control as related to chip color and color defects. The DMN application appeared to have no negative influence on chip quality for this variety. Overall: For the three varieties tested, no negative effect of the DMN application was observed on tuber chip quality. In two cases, with the FL1833 and Pike varieties, there was some variation in chip color defects across treatments, but not in the SFA color scoring. This variation in chip color defects is difficult to correlate to the DMN application because it occurred across all treatments and did not occur in a uniform pattern. There was some variability in sugar concentration observed for both FL1833 and Pike across all treatments. In general, this variation is typical of the sugar analysis process. No consistent trend was observed that would lead one to believe that DMN was involved in causing this variation. In the FL1922 variety, there was almost no variability observed in sugar concentration or chip color or color related defects. No negative effect of the DMN application was observed on the sugar quality of the FL1922 variety in this study. 180 Dormancy Observations: The dormancy enhancement of the DMN product was inconclusive in the variety Pike based on two observations made 66 and 94 days after treatment. The efficacy of this product was most likely diminished after 60 days. No CIPC was applied to the Pike variety and only one application of DMN was made at the start of the experiment. Both FL1833 and FL1922 were treated with CIPC six weeks after the DMN application. No dormancy break was noted in any of the FL1922 or the FL1833 treatments. DMN appears to have a short window of dormancy enhancement that can, in turn, be reduced by large volumes of fresh air exchange in the storage environment. Weight Loss Observations: The effect of a DMN application on tuber weight loss is of interest in order to reduce pressure bruising and tuber shrinkage but was not able to be evaluated in this study. 181 THE EFFECT OF ON THE STORAGE SUGAR PROFILES OF FL1833 Figure 1 1 0.9 0.8 ) % ( 0.7 I N O T A R T N E C N O C R A G U S 0.6 0.5 0.4 0.3 0.2 0.1 0 70 60 50 40 30 20 10 0 ) F ° ( E R U T A R E P M E T 11/3/2008 12/1/2008 12/29/2008 1/26/2009 2/23/2009 3/23/2009 SAMPLE DATE FL1833 Pile Glucose % FL1833 Pile Sucrose % FL1833 Average Pile Temperature FL1833 UT Barrel Glucose% FL1833 UT Barrel Sucrose % FL1833 Treated Barrel Glucose % FL1833 Treated Barrel Sucrose % 182 Figure 2 THE EFFECT OF ON FL1833 CHIP COLOR AND COLOR DEFECTS (%) R O L O C P H C A F S I 2 1.5 1 0.5 0 48 45 42 39 36 33 30 27 24 21 18 15 12 9 6 3 0 ) % ( S T C E F E D R O L O C 11/3/2008 12/1/2008 12/29/2008 1/26/2009 2/23/2009 3/23/2009 SAMPLE DATE FL1833 Pile SFA Chip Color FL1833 Pile Color Defects (%) FL1833 UT Barrel SFA Chip Color FL1833 UT Barrel Color Defects (%) FL1833 Treated Barrel SFA Chip Color FL1833 Treated Barrel Color Defects (%) 183 Figure 3 THE EFFECT OF ON THE STORAGE PROFILES OF PIKE ) % ( I N O T A R T N E C N O C R A G U S 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 11/3/2008 12/1/2008 12/29/2008 1/26/2009 Pike Pile Glucose % Pike Pile Sucrose % Pike Average Pile Temperature SAMPLE DATE Pike UT Barrel Glucose% Pike UT Barrel Sucrose % Pike Treated Barrel Glucose % Pike Treated Barrel Sucrose % 70 60 50 40 30 20 10 0 ) F ° ( E R U T A R E P M E T 184 Figure 4 THE EFFECT OF ON PIKE CHIP COLOR AND COLOR DEFECTS (%) R O L O C P H C A F S I 2 1.5 1 0.5 0 15 12 9 6 3 0 ) % ( S T C E F E D R O L O C 11/3/2008 12/1/2008 12/29/2008 1/26/2009 SAMPLE DATE Pike Pile SFA Chip Color Pike Pile Color Defects (%) Pike UT Barrel SFA Chip Color Pike UT Barrel Color Defects (%) Pike Treated Barrel SFA Chip Color Pike Treated Barrel Color Defects (%) 185 THE EFFECT OF ON THE STORAGE PROFILES OF FL1922 Figure 5 0.7 0.6 ) % ( 0.5 I N O T A R T N E C N O C R A G U S 0.4 0.3 0.2 0.1 0 70 60 50 40 30 20 10 0 ) F ° ( E R U T A R E P M E T 10/28/2008 11/17/2008 12/15/2008 SAMPLE DATE 1/12/2009 2/9/2009 FL1922 Pile Glucose % FL1922 Pile Sucrose % FL1922 Average Pile Temperature FL1922 UT Barrel Glucose% FL1922 UT Barrel Sucrose % FL1922 Treated Barrel Glucose % FL1922 Treated Barrel Sucrose % 186 Figure 6 THE EFFECT OF ON FL1922 CHIP COLOR AND COLOR DEFECTS (%) R O L O C P H C A F S I 2 1.5 1 0.5 0 15 12 9 6 3 0 ) % ( S T C E F E D R O L O C 10/28/2008 11/17/2008 12/15/2008 SAMPLE DATE 1/12/2009 2/9/2009 FL1922 Pile SFA Chip Color FL1922 Pile Color Defects (%) FL1922 UT Barrel SFA Chip Color FL1922 UT Barrel Color Defects (%) FL1922 Treated Barrel SFA Chip Color FL1922 Treated Barrel Color Defects (%) 187 Funded by AgChem Industry Vine Desiccation in Potato with Vida. Wesley J. Everman and Andrew J. Chomas. Department of Crop and Soil Sciences, Michigan State University, East Lansing, MI 48824. A study was conducted in 2009 to evaluate the efficacy of Vida applied as a vine kill product. The study was conducted at the Montcalm Research Farm and in a grower field near Morley, MI. Treatments included Vida at 5.5 fl oz plus Reglone at 1 pt plus NIS at 0.5%, Vida at 5.5 fl oz plus Reglone at 2 pt plus NIS at 0.5%, Vida at 5.5 fl oz plus COC at 1% followed by (fb) Vida at 5.5 fl oz plus COC at 1%, Vida at 5.5 fl oz plus COC at 1% fb Reglone at 2 pt plus NIS at 0.5%, Reglone at 2 pt plus NIS at 0.5% fb Vida at 5.5 fl oz plus COC at 1%, Vida at 2.75 fl oz plus Reglone at 1 pt plus NIS at 0.5% fb Vida at 2.75 fl oz plus Reglone at 1 pt plus NIS at 0.5%, Vida at 5.5 fl oz plus Reglone at 1 pt plus NIS at 0.5% fb Vida at 5.5 fl oz plus Reglone at 1 pt plus NIS at 0.5%, Vida at 5.5 fl oz plus Reglone at 2 pt plus NIS at 0.5% fb Vida at 5.5 fl oz plus Reglone at 2 pt plus NIS at 0.5%, and Reglone at 2 pt plus NIS at 0.5% fb Reglone at 2 pt plus NIS at 0.5%. All herbicide treatments were compared with a non-treated control treatment. Each treatment was replicated four times. Irrigation and other potato crop management practices utilized closely mirror practices followed by producers. Vine kill was 100% for all treatments at 28 days after application, excluding the Vida fb Vida treatment, which provided 88% vine kill. 188 MSU Weed Science Research Program VINE DESICCATION IN POTATO WITH VIDA, 2009 Trial ID: PO909 Study Dir.: Conducted: MONTCALM RSCH STA. Investigator: Christy Sprague Date Planted: 5/11/09 Row Spacing: 34 IN Variety: SNOWDEN No. of Reps: 4 Population: 1/FT % OM: 1.1 Soil Type: Loamy Sand pH: 6.0 Plot Size: 10 X 20 FT Design: RANDOMIZED COMPLETE BLOCK Tillage: Spring Disc 3X. Spring Chisel. Field Cultivated. Fertilizer: 20 gal/A of 19-17-0, 12 gal/A of 10-34-0 in Row. 23 gal/A of 28% N at Cultivation. 23 gal/A of 28%N at Hilling. 100 lbs/A of 46-0-0 Broadcast. Application Description A SEN Application Timing: 8/12/09 8/19/09 Date Treated: 11:00 AM 11:15 AM Time Treated: 0 % Cloud Cover: 78 F Air Temp., Unit: % Relative Humidity: 71 Wind Speed/Unit/Dir: 2 mph SW 2 mph SE Soil Temp., Unit: Soil/Leaf Surface M: 5 Soil Moist (1=w 5=d): 3 Crop Stage at Each Application Crop Name: SOLTU SOLTU Height (In.): Weed Stage at Each Application Weed 1 Name: ANGR ANGR Weed 2 Name: CHEAL CHEAL Weed 3 Name: POROL POROL Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B MPH Type Size Height Spacing Width GPA Carrier PSI 3.5 FF 30 30 3.5 FF 100" 20 H2O 120" 20 H2O 8003 29" 8003 33" 70 F 5 5 A B 18 18 B YELL 20 79 F 46 73 F A B Type BKPK BKPK 20" 20" 189 Stg pt/a 93 4 92 5 96 66 98 86 91 98 98 3 95 2 95 71 98 Vida Vida 100 100 100 100 CHEAL control ANGR control SOLTU injury .208 L L .208 L L MSU Weed Science Research Program .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L fl oz/a SEN 89 pt/a 5.5 1 SEN 0.5 % v/v SEN fl oz/a SEN 91 pt/a 5.5 2 SEN 0.5 % v/v SEN Form Form Conc Type Rate Unit Rate Grow 1 Vida .208 L L L Reglone 2 Activator 90 L fl oz/a SEN 55 5.5 1 % v/v SEN 2 YELL 0.5 % v/v YELL fl oz/a SEN 46 5.5 1 % v/v SEN 5.5 fl oz/a YELL 1 % v/v YELL POROL SOLTU injury control percent percent percent percent percent 8/15/09 8/19/09 8/19/09 8/19/09 8/19/09 3 DASEN 7 DASEN 7 DASEN 7 DASEN 7 DASEN VINE DESICCATION IN POTATO WITH VIDA, 2009 Trial ID: PO909 Study Dir.: Conducted: MONTCALM RSCH STA. Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 1 1 2 2 2 3 3 Herbimax 3 3 Herbimax 4 4 Herbimax 4 4 5 5 5 5 Herbimax 6 6 6 6 6 6 7 7 7 7 7 7 8 8 8 8 8 8 9 9 9 9 10 Non-Treated LSD (P=.05) Standard Deviation CV 2.75 fl oz/a SEN 80 1 SEN 0.5 % v/v SEN 2.75 fl oz/a YELL 1 YELL 0.5 % v/v YELL fl oz/a SEN 83 pt/a 5.5 SEN 1 0.5 % v/v SEN fl oz/a YELL 5.5 1 pt/a YELL 0.5 % v/v YELL fl oz/a SEN 96 pt/a 5.5 2 SEN 0.5 % v/v SEN fl oz/a YELL 5.5 2 pt/a YELL 0.5 % v/v YELL .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L .208 L Vida 2 L Reglone Activator 90 L .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L pt/a 2 0.5 % v/v SEN 5.5 fl oz/a YELL 1 % v/v YELL pt/a 2 0.5 % v/v SEN 2 YELL 0.5 % v/v YELL pt/a Reglone 2 Activator 90 Reglone 2 Activator 90 Reglone 2 Activator 90 Vida L L .208 L L 15.4 10.6 14.47 10.6 7.3 9.53 10.5 7.2 8.41 5.9 4.0 4.55 7.1 4.9 5.74 21 99 100 90 95 94 95 96 100 90 98 L L L L 89 88 95 SEN 86 94 SEN 86 83 92 96 0 0 0 0 pt/a pt/a 93 100 190 B YELL MSU Weed Science Research Program VINE DESICCATION IN POTATO WITH VIDA II, 2009 Trial ID: P1509 Study Dir.: Andy Chomas Conducted: SandyLand Investigator: Christy Sprague Date Planted: Row Spacing: IN Variety: MSJ147-1 No. of Reps: 4 Population: % OM: Soil Type: pH: Plot Size: 10 X 20 FT Design: RANDOMIZED COMPLETE BLOCK Application Description A SEN Application Timing: 9/8/09 9/15/09 Date Treated: 12:15 PM Time Treated: 30 % Cloud Cover: 76 F Air Temp., Unit: 56 % Relative Humidity: 3 mph N Wind Speed/Unit/Dir: Soil/Leaf Surface M: 5 Soil Moist (1=w 5=d): 5 Crop Stage at Each Application Crop Name: SOLTU SOLTU Height (In.): Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B Comments: Spray solution was buffered to a pH of 6.0. MPH Type Size Height Spacing Width GPA Carrier PSI 3.5 FF 30 30 3.5 FF 100 20 H20 100" 20 H2O B 21-18(12) A Type BKPK BKPK 8003 30" 8003 30" 20" 20" 191 pt/a 97 Stg 2 75 3 91 4 92 5 100 35 90 75 88 93 99 79 90 96 100 34 56 Vida Vida SOLTU control .208 L L .208 L L MSU Weed Science Research Program SOLTU control percent 9/30/09 SOLTU control percent 10/6/09 .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L fl oz/a SEN 76 pt/a 5.5 1 SEN 0.5 % v/v SEN fl oz/a SEN 83 pt/a 5.5 2 SEN 0.5 % v/v SEN Form Form Conc Type Rate Unit Rate Grow 1 Vida .208 L L L Reglone 2 Activator 90 L fl oz/a SEN 11 5.5 1 % v/v SEN 2 YELL 0.5 % v/v YELL fl oz/a SEN 15 5.5 1 % v/v SEN 5.5 fl oz/a YELL 1 % v/v YELL SOLTU SOLTU control control percent percent percent 9/11/09 9/15/09 9/22/09 3 DASEN 7 DASEN 14 DASEN 22 DASEN 28 DASEN VINE DESICCATION IN POTATO WITH VIDA II, 2009 Trial ID: P1509 Study Dir.: Andy Chomas Conducted: SandyLand Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 1 1 2 2 2 3 3 Herbimax 3 3 Herbimax 4 4 Herbimax 4 4 5 5 5 5 Herbimax 6 6 6 6 6 6 7 7 7 7 7 7 8 8 8 8 8 8 9 9 9 9 10 Non-Treated LSD (P=.05) Standard Deviation CV 2.75 fl oz/a SEN 79 1 SEN 0.5 % v/v SEN 2.75 fl oz/a YELL 1 YELL 0.5 % v/v YELL fl oz/a SEN 90 pt/a 5.5 SEN 1 0.5 % v/v SEN fl oz/a YELL 5.5 1 pt/a YELL 0.5 % v/v YELL fl oz/a SEN 90 pt/a 5.5 2 SEN 0.5 % v/v SEN fl oz/a YELL 5.5 2 pt/a YELL 0.5 % v/v YELL .208 L Vida 2 L Reglone Activator 90 L .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L pt/a 2 0.5 % v/v SEN 5.5 fl oz/a YELL 1 % v/v YELL pt/a 2 0.5 % v/v SEN 2 YELL 0.5 % v/v YELL pt/a Reglone 2 Activator 90 Reglone 2 Activator 90 Reglone 2 Activator 90 Vida L L .208 L L 68 2.3 1.6 1.65 43 5.7 3.9 4.39 23 5.1 3.5 4.23 0 100 100 100 100 SEN 93 82 100 100 SEN 92 87 98 6.9 4.8 7.48 9.0 6.2 9.91 97 100 81 95 99 100 pt/a pt/a 78 95 86 99 L L L L 0 192 MSU Weed Science Research Program VINE DESICCATION IN POTATO WITH VIDA III, 2009 Trial ID: P1609 Study Dir.: Andy Chomas Conducted: Walthers Farm Investigator: Christy Sprague Date Planted: 5/25/09 Row Spacing: 34 IN Variety: No. of Reps: 4 Population: % OM: Soil Type: pH: Plot Size: 10 X 20 FT Design: RANDOMIZED COMPLETE BLOCK Application Description A SEN Application Timing: 9/10/09 9/17/09 Date Treated: 1:00 PM 12:30 PM Time Treated: 20 % Cloud Cover: 75 F Air Temp., Unit: % Relative Humidity: 68 Wind Speed/Unit/Dir: 3 mph 3 mph Soil Temp., Unit: 78 F 68 F Soil/Leaf Surface M: 5 Soil Moist (1=w 5=d): 3 Crop Stage at Each Application Crop Name: SOLTU Height (In.): Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B Comments: 3 ROW PLOTS Spray solution was buffered to a pH of 6.0. MPH Type Size Height Spacing Width GPA Carrier PSI 30 3.5 FF 3.5 FF 30 100" 20 H2O 100" 20 H2O 8003 16" 8003 35" A 14-24(18) 12-24(18) B SOLTU B YELL 10 74 F 40 5 4 Type BKPK BKPK 20" 20" 193 Stg pt/a 74 39 2 53 Vida Vida .208 L L .208 L L MSU Weed Science Research Program .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L fl oz/a SEN 64 pt/a 5.5 1 SEN 0.5 % v/v SEN fl oz/a SEN 68 pt/a 5.5 2 SEN 0.5 % v/v SEN Form Form Conc Type Rate Unit Rate Grow 1 Vida .208 L L L Reglone 2 Activator 90 L fl oz/a SEN 29 5.5 1 % v/v SEN 2 YELL 0.5 % v/v YELL fl oz/a SEN 30 5.5 1 % v/v SEN 5.5 fl oz/a YELL 1 % v/v YELL SOLTU SOLTU control control percent percent 9/17/09 9/22/09 7 DASEN 5 DAYELL VINE DESICCATION IN POTATO WITH VIDA III, 2009 Trial ID: P1609 Study Dir.: Andy Chomas Conducted: Walthers Farm Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 1 1 2 2 2 3 3 Herbimax 3 3 Herbimax 4 4 Herbimax 4 4 5 5 5 5 Herbimax 6 6 6 6 6 6 7 7 7 7 7 7 8 8 8 8 8 8 9 9 9 9 10 Non-Treated LSD (P=.05) Standard Deviation CV 2.75 fl oz/a SEN 71 1 SEN 0.5 % v/v SEN 2.75 fl oz/a YELL 1 YELL 0.5 % v/v YELL .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L fl oz/a SEN 64 pt/a 5.5 SEN 1 0.5 % v/v SEN fl oz/a YELL 5.5 1 pt/a YELL 0.5 % v/v YELL fl oz/a SEN 71 pt/a 5.5 2 SEN 0.5 % v/v SEN fl oz/a YELL 5.5 2 pt/a YELL 0.5 % v/v YELL .208 L Vida L Reglone 2 Activator 90 L .208 L Vida L Reglone 2 Activator 90 L .208 L Vida 2 L Reglone Activator 90 L .208 L Vida L Reglone 2 Activator 90 L pt/a 2 0.5 % v/v SEN 5.5 fl oz/a YELL 1 % v/v YELL pt/a 2 0.5 % v/v SEN 2 YELL 0.5 % v/v YELL pt/a Reglone 2 Activator 90 Reglone 2 Activator 90 Reglone 2 Activator 90 Vida L L .208 L L 13.5 9.3 17.22 14.1 9.7 12.22 L L L L SEN 74 SEN 70 1 86 pt/a pt/a 81 95 91 89 95 91 194 Vine Desiccation in Potato. Funded by AgChem Industry Wesley J. Everman, Chris Long, and Andrew J. Chomas. Department of Crop and Soil Sciences, Michigan State University, East Lansing, MI 48824. A study was initiated in 2008 and continued in 2009 to investigate the effects of vine kill herbicides on storage quality. Vine kill herbicides act rapidly to desiccate foliage from potato plants prior to harvest. Four herbicides representing 3 classes of herbicides are currently labeled for use as vine kill in potato. We routinely investigate the effectiveness of potato vine kill products in the field; however the effects of vine kill products on tuber quality and storage have not been extensively investigated. There are many physiological effects of herbicides on plant growth and development, and investigating the effects of vine kill herbicides will help determine if storage life and tuber quality are compromised. We evaluated the effect of several available vine kill herbicides and one experimental compound under evaluation on tuber quality at harvest including grade and internal defects, and are determining the effect of vine kill herbicides on potato storage life and chipping quality. Herbicide products were applied on Snowden to test effectiveness of vine kill with herbicide treatments consisting of 1) Rely at 28.7 oz/A 2) Rely + AMS at 3 lb/A 3) Reglone at 1 pt/A followed by Reglone at 1 pt 4) BAS 800 at 0.5 oz/A 5) BAS 800 at 1 oz/A 6) BAS 800 at 2 oz/A 7) BAS 800 at 4 oz/A 8) Aim at 3.2 oz/A 9) Aim at 3.2 oz/A fb Aim at 3.2 oz/A. All herbicide treatments were compared with a non-treated control treatment. Vine kill was evaluated weekly after treatment until harvest. Plots were harvested after vine kill and marketable yield was determined. No yield effects were observed due to treatment, and all products resulted in excellent vine kill at the time of harvest. Tubers were then placed by treatment into storage in the new potato storage unit. Tuber samples were taken on a monthly basis to determine sugar levels, internal defects, and chip quality. Results of this research will determine if storage quality and life is affected by herbicide treatments for vine kill. 195 MSU Weed Science Research Program VINE DESICCATION AND STORAGE IN POTATO, 2009 Trial ID: P0509 Study Dir.: Conducted: MONTCALM RSH FARM Investigator: Christy Sprague Date Planted: 5/11/09 Row Spacing: 34 IN Variety: SNOWDEN No. of Reps: 4 Population: 1/FT % OM: 1.2 Soil Type: Loamy Sand pH: 5.4 Plot Size: 10 X 30 FT Design: RANDOMIZED COMPLETE BLOCK Tillage: Spring Disc 3X. Spring Chisel. Field Cultivated. Fertilizer: 20 gal/A of 19-17-0, 12 gal/A of 10-34-0 in Row. 23 gal/A of 28% N at Cultivation. 23 gal/A of 28%N at Hilling. 100 lbs/A of 46-0-0 Broadcast. Application Description A SEN Application Timing: 8/19/09 8/27/09 Date Treated: 10:30 AM Time Treated: 20 % Cloud Cover: 79 F Air Temp., Unit: % Relative Humidity: 46 Wind Speed/Unit/Dir: 2 mph SE Soil Temp., Unit: Soil/Leaf Surface M: 5 Soil Moist (1=w 5=d): 5 Crop Stage at Each Application Crop Name: SOLTU SOLTU Height (In.): Application Equipment Appl Sprayer Speed Nozzle Nozzle Nozzle Nozzle Boom A B MPH Type Size Height Spacing Width GPA Carrier PSI 3.5 FF 30 30 3.5 FF 120" 20 H2O 120" 20 H20 8003 33" 8003 Type BKPK BKPK 20" 20" B YELL 70 F A B 18 18 196 SOLTU control SOLTU SOLTU control control percent percent percent 8/27/09 9/1/09 9/8/09 7 DASEN 5 DAYEL 12 DAYEL HARVEST HARVEST HARVEST HARVEST HARVEST HARVEST SOLTU SOLTU <1 7/8" <1 7/8" PickOut kilogram count 9/22/09 SOLTU SOLTU oversize oversize kilogram count SOLTU PickOut 9/22/09 9/22/09 9/22/09 9/22/09 kilogram count SOLTU 9/22/09 2 2 1.67 L 28.7 3 2 88 Untreated Rely 200 90 3 4 SEN 98 3.6625 3.2175 2.1250 100 99 pt/a pt/a 1.67 L 28.7 fl oz/a SEN 99 100 100 100 Grow Stg 1 fl oz/a lb/100 gal SEN MSU Weed Science Research Program Reglone Activator 90 Reglone Activator 90 Form Form Rate Conc Type Rate Unit 1 0.25 % v/v 1 0.25 % v/v Rely 200 Ammonium Sulfate 100 DF VINE DESICCATION AND STORAGE IN POTATO, 2009 Trial ID: P0509 Study Dir.: Conducted: MONTCALM RSH FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 2 3 3 4 4 4 4 5 Sharpen 5 Herbimax 5 6 Sharpen 6 Herbimax 6 7 Sharpen 7 Herbimax 7 8 Sharpen 8 Herbimax 8 9 Aim 9 MSO 10 Aim 10 MSO 10 Aim 10 MSO LSD (P=.05) Standard Deviation CV 0.025 lb ai/a 1 % v/v 0.032 lb ai/a 1 % v/v SEN 97 SEN YELL YELL SEN 95 SEN YELL YELL SEN 100 SEN SEN SEN 100 SEN SEN Ammonium Sulfate 100 DF Ammonium Sulfate 100 DF Ammonium Sulfate 100 DF Ammonium Sulfate 100 DF SEN 98 SEN SEN SEN 97 SEN SEN 0.032 lb ai/a 1 % v/v fl oz/a % v/v % w/w fl oz/a % v/v % w/w fl oz/a % v/v % w/w fl oz/a % v/v % w/w 1 1 2 2 1 2 4 1 2 L L L L L L L L L L L L L L L L L L SEN 95 SEN 4.0 2.8 2.86 3.2 2.2 2.25 100 100 2 2 2 98 99 100 3.2788 100 4.5513 100 2.6875 100 4.3050 100 2.0113 0.0 0.0 0.0 99 100 3.3788 0.5 1 2 2.9 2.9 2.9 2.9 99 96 99 3.5188 5 44.5 54.8 44.8 6 0.0000 0.0000 0.0000 7 0 0 0 8 0.000 0.148 0.123 40.3 0.0000 0 0.000 9 0 1 0 0 60.3 0.0000 0 0.000 0 49.3 0.0000 0 0.000 0 58.3 0.0000 0 0.000 0 57.0 0.1488 1 0.000 0 55.0 0.0000 0 0.000 55.5 0.0000 0 0.000 0 0 2.53880 26.72 1.74971 18.41 35.45 53.45 0.13651 0.5 0.09408 0.3 632.46 632.46 0.1791 0.1235 457.23 0.5 0.4 478.34 197 SOLTU SOLTU Grade A dry count 9/22/09 HARVEST HARVEST HARVEST HARVEST SOLTU SPEC. GRAV. HH 9/22/09 9/22/09 9/22/09 SOLTU wet SOLTU VD 0-10 0-10 9/22/09 9/22/09 HARVEST HARVEST SOLTU 11 12 13 14 15 16 9.5963 0.78475 1.0891491 9.8700 0.74975 1.0831081 8.9875 0.72950 1.0883448 9.4763 0.77688 1.0891869 2 2 1.67 L 1.67 L Rely 200 28.7 3 Untreated pt/a pt/a 28.7 fl oz/a 22.1012519 159 Grow Stg 10 SEN 20.1337510 178 SEN 21.9650023 182 fl oz/a lb/100 gal SEN MSU Weed Science Research Program Reglone Activator 90 Reglone Activator 90 Form Form Rate Conc Type Rate Unit 1 0.25 % v/v 1 0.25 % v/v SOLTU Grade A kilogram 9/22/09 HARVEST Rely 200 Ammonium Sulfate 100 DF SEN 17.6237524 172 SEN YELL YELL VINE DESICCATION AND STORAGE IN POTATO, 2009 Trial ID: P0509 Study Dir.: Conducted: MONTCALM RSH FARM Investigator: Christy Sprague Weed Code Crop Code Rating Data Type Rating Unit Rating Date Trt-Eval Interval Trt Treatment No. Name 1 2 3 3 4 4 4 4 5 Sharpen 5 Herbimax 5 6 Sharpen 6 Herbimax 6 7 Sharpen 7 Herbimax 7 8 Sharpen 8 Herbimax 8 9 Aim 9 MSO 10 Aim 10 MSO 10 Aim 10 MSO LSD (P=.05) Standard Deviation CV ARM Action Codes T1 = ([12])/([12]-[13]) SEN 22.4500011 202 SEN YELL YELL SEN 16.6150014 161 SEN SEN SEN 19.3675022 170 SEN SEN SEN 15.3712507 143 SEN SEN SEN 20.0362512 167 SEN SEN 0.025 lb ai/a 1 % v/v 0.032 lb ai/a 1 % v/v 6.22607866 43.7 4.29093785 30.1 17.6 21.83 SEN 20.8987524 182 SEN Ammonium Sulfate 100 DF Ammonium Sulfate 100 DF Ammonium Sulfate 100 DF Ammonium Sulfate 100 DF 0.032 lb ai/a 1 % v/v fl oz/a % v/v % w/w fl oz/a % v/v % w/w fl oz/a % v/v % w/w fl oz/a % v/v % w/w 1 1 2 2 1 2 4 1 2 2 2 2 L L L L L L 0.5 1 2 L L L L L L L L L L L L 2.9 2.9 2.9 2.9 8.6500 0.65813 1.0821524 9.7150 0.73788 1.0829724 8.6925 0.65763 1.0830008 9.6513 0.79325 1.0895522 9.7800 0.82563 1.0922733 10.5200 0.90300 1.0927483 1 0 0 0 0 0 0 0 0 0 4 2 6 4 5 3 5 4 5 3 3.1 2.1 53.0 2.76942 0.241073 0.01134400 0.7 1.90865 0.166144 0.00781814 0.5 20.1 21.81 0.72 483.05 198