2004 SOYBEAN RESEA-RCH REPORT - 3r F ~ rV -~ k op Al.- ~ 4 a. Research Report 27 May 2005 Agricultural Experiment Station Alabama Michael Weiss, Director Auburn University Auburn, Alabama Printed in cooperation with the Alabama Cooperative Extension System (Alabama A&iM University and Auburn University ACKNOWLEDGEMENTS This publication is a joint contribution of Auburn University, the Alabama Agricultural Experiment Station, and the USDA Agricultural Research Service. Research contained herein was partially funded by checkoff dollars through the Alabama Soybean Commission and private industry grants. All support is appreciated. CONFIDENTIAL REPORT Publication, display, or distribution of data contained herein should not be made without prior written approval. Mention of a trademark or product does not constitute a guarantee of the product by Auburn University and does not imply its approval to the exclusion of other products. Information contained herein is available to all persons regardless of race, color, sex, or national origin. Issued in furtherance of Cooperative Extension work in agricultureand home economics, Acts of May 8 andJune 30, 1914, and other related acts, in cooperation with the US. Department ofAgriculture. The Alabama Cooperative Extension System (Alabama A&M University and Auburn University) offers educationalprograms, materials,and equal opportunity employment to all people without regardto race, color, national origin, religion,sex, age, veteran status, or disability. ALABAMA AGRICULTURAL EXPERIMENT STATION CONTENTS VARIETY TRIALS Geneva/Coffee County Soybean Variety Demonstration, 2004 ................................................... 2004 High pH Group V Roundup Ready® Soybean Variety Demonstration in Hale County ............................ High pH Group V Conventional Soybean Varieties, 2004, in Pickens County ....................................... Evaluation of Forage and Oilseed Type Soybeans for Hay Production ............................................. Evaluation of Roundup Ready® Maturity Group VI and VII Soybean Varieties on High pH Soil in M ontgomery County, 2004 ........................................................... Evaluation of Soybean Varieties for Reniform Nematode Tolerance in Alabama, 2004 ................................ Evaluating Maturity Group III and IV Soybean Varieties at Different Planting Dates ................................. Response of Selected Soybean Varieties to the Reniform Nematode in the Greenhouse, 2004.........................9 Evaluation of Non-GMO Soybeans Varieties in West-Central Alabama ........................................... Breeding Improved Soybean Cultivars for Alabama .......................................................... page 5 5 6 6 7 7 8 12 12 DISEASE EVALUATIONS Evaluation of Quadris for Frogeye Leafspot Control on Soybeans, Tallassee, 2004 .................................. Evaluation of Quadris on Soybeans at Low Rates in West-Central Alabama ....................................... 14 15 4 2004 SOYBEAN RESEARCH REPORT CONTRIBUTORS D. M. Ball Professor and Extension Specialist Department of Agronomy and Soils Auburn University Auburn University, Alabama A. R. Blount Associate Professor North Florida REC, IFAS Marianna, Florida R. A. Dawkins Superintendent Sand Mountain Research and Extension Center Crossville, Alabama D. P. Delaney Extension Specialist IV Department of Agronomy and Soils Auburn University Auburn University, Alabama D. E. Derrick Regional Extension Agent Alabama Cooperative Extension System Centre, Alabama R. M. Durbin Superintendent E.V. Smith Research Center, Field Crops Unit Shorter, Alabama K. M. Glass Agricultural Program Associate Department of Agronomy and Soils Auburn University Auburn University, Alabama W. R. Goodman Associate Professor and Extension Specialist Department of Agricultural Economics and Rural Sociology Auburn University Auburn University, Alabama W. G Griffith Regional Extension Agent Alabama Cooperative Extension System Fayette, Alabama K. S. Lawrence Associate Professor Department of Entomology and Plant Pathology Auburn University Auburn University, Alabama C. D. Monks Professor and Extension Specialist Department of Agronomy and Soils Auburn University Auburn University, Alabama S. P. Nightengale Superintendent E.V. Smith Research Center, Plant Breeding Unit Tallassee, Alabama R. L. Petcher Regional Extension Agent Alabama Cooperative Extension System New Brockton, Alabama S. A. Poague M.S. Candidate Agriscience Education Auburn University, Alabama E. J. Sikora Professor and Extension Specialist Department of Entomology and Plant Pathology Auburn University Auburn University, Alabama S. R. Usery Graduate Research Assistant Entomology and Plant Pathology Auburn University 0. S. Wiggins County Agent Coordinator Pickens County Alabama Cooperative Extension System Gordo, Alabama D. B. Weaver Professor Department of Agronomy and Soils Auburn University Auburn University, Alabama R. P. Yates Regional Extension Agent Alabama Cooperative Extension System Linden, Alabama ALABAMA AGRICULTURAL EXPERIMENT STATION 5 VARIETY TRIALS Geneva/Coffee County Soybean Variety Demonstration, 2004 D. P. Delaney and R. L. Petcher One of the most critical decisions a soybean producer makes each year is which variety to plant. On-farm field trials are important to verify University research and to show how different varieties perform under typical management practices in producers' fields. Eight Maturity Group III and IV and 11 MG V soybean cultivars, all Roundup Ready®, were planted with conventional tillage after winter grazing near Enterprise, Alabama, on the farm of Tim and Clay Wise. Group III and IV varieties were planted in 20-inch rows in approximately quarter-acre blocks on April 28, 2004, while Group V varieties were drilled in halfacre blocks on May 6, 2004, in the same field. Weeds were controlled by two broadcast applications of Roundup Ultra Max® at 26 ounces per acre post-emergence at the appropriate stage for each block. Sodium chlorate was applied to the Group V soybeans to desiccate late-emerging weeds. Rainfall was excellent, and was reflected in excellent yields, particularly for the early maturing cultivars (Table 1). Group III and IV plots were harvested with the producer's combine and a weigh wagon on September 5, 2004, while Group V plots (Table 2) were harvested on October 5, 2004. Yields were adjusted to 13 percent moisture and 60 pounds per bushel. TABLE 1. GENEVA/COFFEE COUNTY GROUP III AND IV RR SOYBEAN VARIETIES r pi Ente: vere Variety Maturity Bu/A group @ 13.0% III 42.6 Asgrow 3602 RR III 49.1 Asgrow 3702 RR Iii 44.9 Dyna-Gro 3373 R R III 42.4 Dyna-Gro 3390 R R RR) IV 50.1 Pioneer 94B13 (F IV 56.6 Pioneer 94M1 (RR) IV 45.8 Asgrow 4403 RR IV 74.0 Pioneer 94M90 ( RR) TABLE 2. GENEVA/COFFEE COUNTY GROUP V RR yiev ention 5OYBEAN VARIETIES GTOv th on biv wer Maturity s Bu/A Variety @ 13.0% group p~ov block I IV UIIl V 44.8 Asgrow 5301 RR adjv halin Pioneer 95B42 (RR) 42.3 V 44.7 V DPL 5414 (RR) Iv ND 42.7 V DPL 5644 RR V 41.2 Dyna-Gro 3562 nRR V 37.4 DPL 5634 RR V 29.3 Dyna-Gro 38K57 RR V 43.1 DPL 5806 RR V 35.6 Pioneer 95M80 (RR) V 26.9 Asgrow AG 5901 RR V 44.3 DPL 5915 RR 2004 High pH Group V Roundup Ready® Soybean Variety Demonstration in Hale County D.P. Delaney, R. P. Yates, and E. J. Sikora One of the most critical decisions a soybean producer makes each year is which variety to plant. Yield and other traits such as disease resistance can vary substantially between vari2004 HALE COUNTY HIGH PH GROUP V RRR SOYBEANS Frogeye** Bu/A Iron chlorosis* June 22 July14 Aug. 25 @13.0% 9 6 34.7 Asgrow 5501 RR 8 48.4 6 6 4 Pioneer 95M80 Deltapine 5414 RR 5 7 2 48.1 Deltapine 5806 RR 7 5 5 30.5 Pioneer 95B42 6 5 8 30.6 Deltapine 5644 RR 5 7 2 35.3 Pioneer 95B53 5 8 7 21.6 Deltapine 5634 RR 4 2 1 50.6 Asgrow 5501 RR 6 5 6 *Chlorosis rating 10 = dead. *Frogeye leafspot 10 = 100% leaf area infection. eties in response to their environment. On-farm field trials are important to verify University research and to show how different varieties perform under typical producer management practices. Eight Maturity Group V soybean cultivars, all Roundup Ready®, were planted on May 27, 2004, in Hale County near Gallion on Ken Diller's farm. The Black Belt soil had an initial pH of 7.8 to 7.9, making it prone to iron chlorosis problems. All varieties were planted in eight 30-inch rows, in strips 20 feet wide and 460 to 500 feet long. A streak of light chalky soil was evident in the middle third of each strip. Weather conditions were conducive to development of iron chlorosis in early summer and frogeye leaf spot (Cercospora sojina) in late summer. Plots were rated on June 22, July 14, and August 25, 2004, (see the table) as needed. Plots were harvested with the producer's combine and a weigh wagon on October 7, 2004, and yields were adjusted to 13 percent moisture and 60 pounds per bushel, as shown in the table. 6 2004 SOYBEAN RESEARCH REPORT High pH Group V Conventional Soybean Varieties, 2004, in Pickens County D. P. Delaney, E. J. Sikora, O. S. Wiggins, and W. G. Griffith One of the most critical decisions a soybean producer makes each year is which variety to plant. A problem in Alabama unique to Black Belt soils is iron chlorosis on high pH soils. Variety selection is the only practical way to control this problem on these soils. On-farm field trials are important to verify University research and to show how different varieties perform under typical producer management practices. Nine conventional (non-GMO) Maturity Group V soybeans were planted at the Dee River Ranch near Aliceville, Alabama, on a high pH Black Belt soil. Each variety was planted on May 30, 2004, in six to 12 30-inch rows in blocks of approximately half- to three-quarters-acre each. Plots were harvested on October 7, 2004, using the producer's combine and yield monitor (see the table). 2004 PICKENS COUNTY CONVENTIONAL GROUP V SOYBEAN VARIETY TRIAL Frogeye Stem canker Yield ---Iron chlorosis--c L 1 IBrand Variety June 22 Aug. 8 Aug. 8 Aug. 8 Bu/A DeltaKing DK 5870 1.0 0 1 0 45.0 Public Freedom 1.5 2 0 0 42.9 Public Caviness 1.5 0 1 3 38.6 Public Anand 2.5 0 1 0 34.6 0 0 31.4 Pioneer 9594 1.0 0 Public Hutcheson 1.0 2 1 0 40.9 Deltapine DP 5989 0.5 1 0 0 48.7 Deltapine DP 5110S 1.0 2 1 0 40.5 *Ratings: 0 = no symptoms, 5 = very high Evaluation of Forage and Oilseed Type Soybeans for Hay Production D.P. Delaney, D. M. Ball, A. R. Blount, R. A. Dawkins, and R. M. Durbin There is a need for high quality forage for cattle and other livestock in Alabama, particularly in late summer, when perennial grasses are often affected by dry weather and are of low quality. Research was conducted on the use of new and old forage types as well as adapted oilseed soybean cultivars to fill this need. Two experiment station tests were conducted during 2004 to evaluate the use of new and old forage cultivars, as well as adapted oilseed types for forage production. Seven varieties, with four replications of each, were planted on May 12 with conventional tillage at the Sand Mountain Research and Extension Center (SMREC) in Crossville, Alabama. The same test was planted no-till into a killed rye cover crop on May 24 at the E.V. Smith Research Center (EVSRC) Field Crops Unit in Shorter. An additional Maturity Group V forage cultivar, Tara, was added to the tests in 2004. Each variety was harvested at its early pod stage, to optimize quality and quantity of forage. Biloxi, an older forage variety, was harvested at early bloom due to leaf drop and foliar disease. Harvest began on July 30 at EVSRC and August 3 at SMREC. Results are presented in the table. Tyrone, a tall-growing forage type, was numerically higher, but not significantly better than Kuell or Stonewall, late oilseed types, at SMREC. At EVSRC, late summer dry weather limited yields. Kuell, Stonewall, and Tyrone were again not significantly different from each other, or from Hinson or Tara. At both locations, Biloxi appeared promising, but then suffered severe leaf loss FORAGE SOYBEAN YIELDS AT Variety Tyrone Laredo Hinson Biloxi Kuell SMREC AND EVSR, 2004 Dry matter yield, Ton/A EVSRC SMREC 6.0 3.4 4.8 2.8 4.3 3.4 3.4 2.7 5.8 3.5 Type Forage Forage LJ-Oilseed Forage MG 8 - Oilseed Stonewall Tara MG 7 - Oilseed MG 5 - Forage 5.9 4.7 3.7 3.3 LSD (P=0.10) 0.9 0.6 just before harvest from foliar disease. Quality tests are under way to determine the relative value of each variety for animal feed. These tests show that adapted late maturity oilseed varieties can be as productive for forage use as specific forage lines. ALABAMA AGRICULTURAL EXPERIMENT STATION 7 Evaluation of Roundup Ready® Maturity Group VI and VII Soybean Varieties on High pH Soil in Montgomery County, 2004 E. J. Sikora, D. P. Delaney, and K. S. Lawrence Eight maturity Group VI and VII Roundup Ready® soybean varieties of varying or unknown iron chlorosis tolerance were planted on May 25, 2004, in Montgomery County, Alabama. The field was a typical Black Belt clay soil, with soil pH varying through the field, including several areas of white EVALUATION OF ROUND-UP READYS, MATURITY GROUP VI AND VII SOYBEAN VARIETIES ON HIGH PH SOIL, MONTGOMERY COUNTY, 2004 Variety Yield Iron Frogeye Bu/A @13% chlorosis* leaf spot Asgrow 6202 RR 24.2 2 1 DP 7870 RR 23.0 3 0 Asgrow 7601 RR 22.5 2 0 DP 6880 RR 20.9 2 0 DP 6299 RR 15.0 4 1 DP 6215 RR 13.9 4 0 Pioneer 96M20 12.4 2 0 DP 7220 RR 2.1 5 2 * Iron chlorosis and frogeye leafspot ratings were based on a 0-5 scale with 0 = no symptoms, 1= trace severity, 2 = low severity, 3 = moderate severity, 4 = high severity, and 5 = very high severity. calcitic soil. Commercially available varieties were planted, including Asgrow 6202 RR, DP 7870 RR, Asgrow 7601RR, DP 6880 RR, DP 6299 RR, DP 6215 RR, Pioneer 96M20, and DP 7220 RR. Plots were each 24 to 32 rows of 30-inch spacing and approximately one-third mile in length. The experiment was scouted periodically for insect pests using established scouting procedures. Iron chlorosis symptom severity was determined on July 23, 2004, when the majority of varieties were at the R3 developmental stage. Frogeye leafspot ratings were taken on August 23, 2004. The experiment was harvested on November 10, 2004, using the producer's combine and a weigh wagon. Yields were adjusted to 13 percent moisture and 60 bushels per acre. Planting and harvest were each delayed up to three weeks due to wet conditions. These delays, combined with dry weather in late summer, likely resulted in the relatively poor yields and the poor seed quality (data not shown) observed in the experiment. Three of the four lowest yielding varieties also received the highest iron chlorosis severity ratings. DP 7220 RR had the highest iron chlorosis rating and plants were extremely stunted as a result. This variety, which yielded only 2.1 bushels per acre on this soil, also had the highest frogeye leaf spot rating among the varieties evaluated. Evaluation of Soybean Varieties for Reniform Nematode Tolerance in Alabama, 2004 K. S. Lawrence, D. P.Delaney, C. D. Monks, D. E. Derrick, and W. R. Goodman Seven soybean varieties were evaluated for tolerance to the reniform nematode (Rotylenchulus reniformis) in a naturally infested producer's field in Cherokee county near Centre, Alabama. The field had a history of reniform nematode infestation and the soil type was a loam. Soybeans plots were nine rows, 18 feet long, with an eight-inch-wide row spacing and were arranged in a randomized complete block design with four replications. Blocks were separated by a 10-foot alley. All plots were maintained throughout the season with standard herbicide, insecticide, and fertility production practices as recommended by the Alabama Cooperative Extension System. Population densities of the reniform nematode were determined at planting and at harvest. Ten soil cores, one-inch in diameter and eight inches deep, were collected from the two center rows of each plot in a systematic sampling pattern. Nematodes were extracted using the gravity sieving and sucrose centrifugation technique. The center five feet of each plot was harvested October 28, 2004. Data were statistically analyzed by GLM and means compared using Fisher's protected least significant difference test (P=0.05). Reniform nematode disease pressure was low in 2004 as temperature and moisture levels were ideal throughout the season. Pre-plant populations of the reniform nematode averaged 275 vermiforms per 150 cubic centimeters (cm 3) of soil and increased to more than 1,400 nematodes per 150 cm 3 of soil by harvest Plant height was not different between soybean varieties nor influenced by nematicide application. Yields were not significantly affected by the application of a nematicide. Pioneer 95B42RR produced the highest yields, averaging 95.15 bushels per acre between treated and nontreated plots, and it supported the highest population of reniform nematodes. Pioneer 95M80 averaged 93.6 bushels per acre; however this variety supported the lowest population of reniform nematodes (see table). 8 2004 SOYBEAN RESEARCH REPORT EVALUATION OF SOYBEAN VARIETIES FOR RENIFORM NEMATODE TOLERANCE INALABAMA, 2004 Yield Plant height Rotylenchulus reniformis/ Bu/A In. 150cc soil Nematicide No nematicide Nematicide No nematicide Nematicide No nematicide Garst 5812 R/N 84.6 cde 86.6 b-e 44.8 43.3 1159.0 abc 753.3 b-e DP 5915 RR 89.2 e 90.1 a-d 34.3 36.9 656.5 cde 1062.3 a-d SS RT 5930 91.3 abc 91.2 abc 35.2 33.5 502.3 de 1371.3 ab SS RT 5999 N 80.3 de 79.9 e 42.8 41.1 907.8 a-e 850.0 a-e ES XVT 41 RR 87.7 a-e 96.8 a 43.3 43.8 1159.0 abc 1120.3 a-d Pioneer 95B42 RR 93.6 abc 96.7 a 39.4 40.1 1467.8 a 1043.0 a-d Pioneer 95M80 91.2 abc 96.0 ab 40.8 38.4 405.5 e 734.0 cde LSD (P<0.05) 9.85 3.51 536.8 Nematicide Evaluating Maturity Group III and IV Soybean Varieties at Different Planting Dates D.P. Delaney, K. S. Lawrence, E. J. Sikora, S. P. Nightengale, S. A. Poague, and K. M. Glass Soybeans are traditionally planted in late April through June in Alabama, with Maturity Group (MG) V to VIII cultivars. This combination often places the critical blooming and pod fill stage during moisture deficit periods in late summer. Research in Mississippi has shown that early maturing varieties from MG III and IV, planted early, may mature before soil moisture deficits become critical, and out yield later soybeans. Approximately 60 percent of soybeans in Mississippi were planted with early varieties in 2004, but little work has been done in Alabama with this system and adapted varieties. In 2004, a test was conducted at the Plant Breeding Unit (PBU) of the E.V. Smith Research Center near Tallassee, Alabama, to evaluate use of early maturing soybean varieties (Groups III and IV) under Alabama conditions, with the goal of avoiding late summer heat and moisture stress. Four cultivars from Maturity Group III and four cultivars from MG IV, ranging from 3.3 to 4.9, were planted on two planting dates. All varieties were planted with conventional tillage in seven seveninch rows on April 6 and again on April 27, 2004. Four replications in a split-plot design were used. Plots were maintained weed-free with recommended herbicides. One application of fungicide was made during early to mid pod-fill. Bloom dates, plant height at initial bloom and maturity, and height to the lowest pod were recorded during the season. Each variety was combined at maturity, with five harvest dates from August 6 to September 13. Yields were adjusted to 13 percent moisture and 60 bushels per acre (Table 1), and samples taken for seed quality (Table 2). Yields were generally very good, due to plentiful rainfall in 2004. The late planting date, however, yielded better than the early planting by 17 bushels per acre. The Group III varieties in particular improved in yield from the first to the second planting. Blooming began before May 21 for these earliest varieties, when many plants were less than 18 inches tall. Although some additional growth and height was gained before maturity, full canopy closure was not reached on these very early maturing plots. Stand was also somewhat poorer for the early planting, due to low soil temperatures after planting. Very low (average) pod heights of two inches for some varieties would also make it difficult for producers to harvest without a very level soil surface and excellent header height control. Treatments varied in fungus infection (Table 2). The latest maturing treatments were harvested immediately before and after Hurricane Ivan, which may account for the high percentage of infection with the Diaporthiesp. + Phomopsis sp. complex. TABLE 1. YIELDS AND HEIGHTS FOR GROUP Ill AND IV SOYBEANS, PBU 2004 Pod Total Yield June 4 height lowest ht. Bu/A height Cultivar @ 13% inch inch Inch Planting Date: DG 3373 NRR 47 DG 3390 NRR 49 AG 3702 RR 39 DP 3861 RR 49 Pioneer 94B13 RR 58 Pioneer 94M41 RR 60 DP 4724 RR 69 DP 4933 RR 46 Early April 19 23 19 22 17 20 18 23 20 24 21 25 16 25 19 32 2 2 2 2 2 2 3 4 3 3 2 3 3 6 4 8 1 29 2 4 Planting Date: Late April DG 3373 NRR 72 15 26 DG 3390 NRR 67 14 25 AG 3702 RR 59 13 24 DP 3861 RR 72 16 29 Pioneer 94B13 RR 75 16 30 Pioneer 94M41 RR 67 15 30 DP 4724 RR 67 13 31 DP 4933 RR 73 15 40 LSD (P=0.10) 10 2 3 CV 15 10 9 Early April Late April Planting Date Means 52 19 69 13 24 29 ALABAMAAGRICULTURAL EXPERIMENT STATION9 TABLE 2. SEED QUALITY FOR GROUP III AND IV SOYBEANS, % INFECTED SEED Alternaria Variety DG 3373 NRR DG 3390 NRR AG 3702 RR DP 3861 RR Pioneer 94B13 RR Pioneer 94M41 RR DP 4724 RR DP 4933 RR DG 3373 NRR DG 3390ONRR AG 3702RR DP 3861IRR Pioneer 94Bl3 RR Pioneer 94M41 RR DP 4724 RR DP 4933 RR LSD (P=0.10)_ alterata Aspergillus flavus Cercospora s 5 3 1 3 0 0 1 0 1 0 0 7 4 13 1 4 7 Diaporthie sp. + Phomopsis sp. Planting Date: Early April 0 4 0 13 0 9 1 1 17 2 0 4 0 3 3 0 0 3 7 13 2 4 4 1 9 Planting Date: Late April 6 5 0 3 3 2 0 1 7 4 4 5 18 27 15 14 32 8 10 10 2 16 21 26 52 8 --- ----- ---- ------~ r Response of Selected Soybean Varieties to the Rei K. S. Lawrence, D. R Delaney, K. M. Glass, and S. R. Usery Sixty-three soybean varieties were screened in a greenhouse for resistance to the reniform nematode. Each variety was planted into a 150 cc container in sterile soil. Prior to emergence each container was inoculated with 1000 vermiform reniform. Varieties were arranged in a randomized complete block design with four replications per test. Sixty days after planting, varieties were harvested. The roots were carefully removed from each pot and reniform eggs were extracted from the roots with a 10% NaOCl solution. The soil was extracted using the Baermann funnel technique. Reniform nematodes were determined using a stereo microscope. All varieties tested supported reproduction of the reniform nematode. Total reniform populations varied from a high of 29,245 for Ark. R 98-1817 to a low of 1204 for Deltapine 4933RR. Reproductive indexes (RI) indicate the ability of the variety to allow the reniform nematode to increase in population levels. An RI value of less than 1 indicates the nematode is not reproducing on the soybean variety. No varieties produced a RI value of less than 1; however, Deltapine 4933RR, G 6333RR/N, DK 5366RR, SS RT 4980, CG RC 5892, DKXT J548, Hutcheson, SS RT 5999, and Progeny 5660 RR all produced an RI of less than 2. This indicates the reniform nematode did not increase in population density as well on these varieties. Eighteen varieties produced an RI value of greater than 10, indicating the reniform nematode levels increased rapidly on these varieties (see table). Nematode in the Greenhouse, 2004 RESPONSE OF SELECTED SOYBEAN VARIETIES TO THE RENIFORM NEMATODE IN THE GREENHOUSE, 2004 -RotylenchulusreniformisVermiforms/ 150 cc soil MG /U Variety 11,588 AG 4403 MGIV 9,463 AG 4603 MGIV 7,725 AG 4903 MGIV 1,622 CG RC4464 MGIV 2298 CG RC4842 MGIV 2,318 CG RC4992 MGIV 1,854 DG 3443 MGIV 6,759 DK 4763RR MGIV 14,484 DK 4967RR MGIV MGIV d~~k DK 5366RR +wr\~ ~ ~~r\+ Al~/1rP~?~fT\~~ PRRLI 17159 OVtl ~ ~L~rL~ 310C Eggs/root system 1,g680 90 451 1,159 1,416 579 2,060 39 1,004 277 ~/tP~~ Total population 13,268 9,553 8,176 2,781 3,714 27897 3,914 6,798 15,488 11436 3i Reproductive index (RI) 13.3 9.6 8.2 2.8 3.7 2.9 3.9 6.8 15.5 1.4 continued 10 10 2004 SOYBEAN RESEARCH REPORT 2004 SOYBEAN RESEARCH REPORT RESPONSE OF SELECTED SOYBEAN VARIETIES TO THE RENIFORM NEMATODE IN THE GREENHOUSE, 2004, CONTINUED MG MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGIV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MG-V ------------------- ---------- renitormis ----HRotylenchulus Total Eggs/root Vermiforms! populatiorI 150 cc soil system DKB46-51 3,978 1,803 5,781 DKXTJ548 1,545 219 1,764 773 3,496 DP 4546 RR 2,723 4,319 3,418 901 DP 4724 RR 1,204 DP 4933 RR 644 560 1,584 6,412 G 4612RR/N 4,828 2,575 5,240 2,665 Garst XR49N99 3,927 6,206 2,279 P 94B74 RR 19,390 18926 464 P 94M7 837 8,433 P 94M9 7596 4,455 2,781 1,674 SS RT 446N SS RT 4502 N 8,182 3,605 4,577 2,240 386 2,626 SS RT 4810 N 888 644 1,532 SS RT 4980 2,427 515 SS RT 5001iN 1,912 1,288 7,159 5,871 SS RT513ON 29,245 26,651 2,594 UArk. R98-1817 3,573 2,607 966 USG 7482nRR 966 2,009 1,043 USG 7484nRR 2,259 1,873 386 USG 7489RR 193 8,497 8,304 USG 7494nRR 1,352 3,206 USG 7499nRR 1,854 5,021 1,352 6,373 AG 5301 4,182 2,302 1,880 AG 5903 1,030 7,036 6,006 AG 5903 ESV 4R 103 9,373 9,270 AG 5905 ESXT-4 Anand 2,957 402 2,556 G 22R/ 39 2,163 ANAND 2,124 418 11,619 11,201 G 42RIT/ CG RC 5003 G 82R/ 2,987 412 CG RO 5222 2,575 5,227 5,021 206 G 94R1 CG RO 5555 GasRO 5892 1,339 3,178 CG 51 R/ 1,839 HUCHSO CG RC 5892 180 1,725 1,545 OZAR 3,464 CG RC 5972 2,897 567 P 9B4 6,605 DG SX04159 5,601 1,004 2,742 2,124 618 DG SX04557 11,015 10,429 586 DK 5161IRR 6,704 1,792 4,912 DK 5967RR 90 5,498 5,408 DK 5967RR 3,6 3,06 619 DK B58-51 2,202 9,734 7,532 ,24 940 8,0 3,161 3,090 71 DKXTJ555 3,2450 2,9 348 16,802 1,584 18,386 DP 5414RR 2,8142 2,1 496 2,897 792 3,689 DP 5634RR 6,157 DP 5915RR 3,646 2,511 10,223 DP 5915RR 5,408 4,815 4,517 DPLX 5808RR 2,714 1,803 22.177 1911 3.05 3,174 2,704 470 DPX5808R 1,352 5,910 4,558 ES Ranger RR 5,660 296 3,064 ESXVT 19RR ESXVT 34RR ESqXVT 41IRR L !Ii Reproductive index (RI) 5.8 1.8 3.5 4.3 1.2 6.4 5.2 6.2 19.4 8.4 4.5 8.2 2.6 1.5 2.4 7.2 29.2 3.6 2 2.3 8.5 3.2 6.4 4.2 7 9.4 3 2.2 11.6 3.0 5.2 3.2 1.7 3.5 6.6 2.7 11.0 6.7 5.5 9.7 3.2 18.4 3.7 6.2 10.2 4.5 3.2 5.9 6.6 1 IVI~~ V IU~ EXPERIMENT STATION ALABAMA AGRICULTURAL L1-. ACPC I TI %#%. I ARAM V - IRAI wXPFRIMF 1T1%0ATIsN 11 RESPONSE OF SELECTED SOYBEAN VARIETIES TO THE RENIFORM NEMATODE IN THE GREENHOUSE, _. I IVL 2004, CONTINUED J1 .. MG MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGV MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVI MGVII MGVII MGVII MGVII MGVI MGVII MGVI MGVII MGVI MGVII MGVI MG VII MGVI MGVII MGVI MGVII MGVII MGVII MGVII MGVII Variety ~I P 95B97 P 95B97 P 95M80 Progeny 5250 RR Progeny 5404 RR Progeny 5503 RR Progeny 5660 RR Progeny 5703 RR Progeny 5714 RR Progeny 5822 RR SS RT 5302 SS RT 5450 SS RT 5540N SS RT 557N SS RT 5930 SS RT 5930N SS RT 5999 SS RT 5999N UArk. R 97-1634 USG 7553nRS USG 7562nRR USG 7582nRR AG 6202 AG 67-02 CG RC 6767 DG 37 M66 DKB 64-51 DP 6880RR G 6333RR/N G 66112RR/N Garst 6112 RR/N Musen P 96 M20 RR P 96M20 RR SS RT 6202 SS RT 6202N USG 62OnRR USG 7604nRR AG 7601 AG 7601 AU AX416 CG RC 7402 DESHA DG 34J71 DG SX04370 DP 7220 RR DP 7220RR DP 7870RR DP 7870RR H 7242RR MUSEN ---------- Rotylenchulus reniformisTotal Eggs/root Vermiforms/ population system 150 cc soil 10,915 8,150 2,766 8,742 1,094 7,648 6,624 251 6,373 2,479 258 2,221 7,776 2,446 5,330 3,296 515 2,781 1,854 579 1,275 4,288 966 3,322 5,646 258 5,388 3,657 644 3,013 4,989 161 4,828 2,182 251 1,931 4777 528 4,249 2,247 509 1,738 3,225 1,101 2,124 5,740 4,056 1,684 1,873 264 1,609 2,605 534 2,070 4,944 502 4,442 5,099 142 4,957 14,794 1,082 13,712 4,919 670 4,249 4,732 1,545 3,187 5,504 579 4,925 2,601 515 2,086 3,592 1,159 2,433 4,493 901 3,592 12,283 5,485 6,798 1,236 206 1,030 14,755 1,043 13,712 6,226 3,476 2,750 10,715 6,476 4,238 4,894 1,416 3,478 9,598 5,427 4,172 7,789 1,030 6,759 6,625 2,871 3,754 2,710 586 2,124 5,009 567 4,442 7,434 4,596 2,838 12,437 1,043 11,394 9,869 599 9,270 5,324 1,590 3,734 11,742 1,506 10,236 13,955 2,367 11,588 2,633 315 2,318 3,432 1,288 2,144 4,842 2,556 2,287 8,742 6,270 2,472 7,011 1,024 5,98JR7 Reproductive index (RI) 10.9 8.7 6.6 2.5 7.8 3.3 1.9 4.3 5.6 3.7 5.0 2.2 4.8 2.2 3.2 5.7 1.9 2.6 4.9 5.1 14.8 4.9 4.7 5.5 2.6 3.6 4.5 12.3 1.2 14.8 6.2 10.7 4.9 9.6 7.8 6.6 2.7 5.0 7.4 12.4 9.9 5.3 ,03.3 11.7 !,2.2 14.0 2.6 3.4 4.8 8.7 7.0 CI1 3 1\ 111\ 1 ~LL~Y 12 2004 SOYBEAN RESEARCH REPORT Evaluation of Non-GMO Soybeans Varieties in West-Central Alabama E. J. Sikora and D. P. Delaney The 2004 trial concluded a three-year project to evaluate non-GMO soybeans in Alabama. The trial was conducted at Dee River Ranch in Pickens County, Alabama, and included the varieties Hutcheson, Caviness, Asgrow 5547, Asgrow 5944, and Pioneer 9594. Each plot was planted with approximately 120,000 seed per acre treated with Apron Maxx + Moly at five ounces per 100 pounds. Plots were 24 rows wide and approximately 10 acres in size. There were three replications of each variety planted in a randomized complete block design. The trial was treated with the fungicide Quadris at five ounces acre at the R3 growth stage. The trial was scouted periodically for insect pests using established scouting procedures. Disease incidence and severity ratings were collected on August 6, 2004. Yield and seed quality were determined at harvest. TABLE 1. YIELD OF FIVE NoN-GMO SOYBEAN VARIETIES IN WEST-CENTRAL ALABAMA, 2002-2004 2003 2002 3-year avg. 2004 Bu/A Bu/A Bu/A Variety Bu/A 52.9 Caviness 44.5ab* 50.2a 64.1 53.1 Asgrow 5944 50.7a 46.9b 61.9 66.5 52.2 48.6a 41.4c Hutcheson 61.7 51.7 48.1a 45.3b Asgrow 5547 47.9ab 65.0 50.0 Pioneer 9594 37.1lb *Numbers followed by the same letter are not significantly different. The low yield observed with Pioneer 9594 may have been related to stem canker. Stem canker was a consistent problem on Pioneer 9594 in each year of the project. Stem canker was not observed on the other varieties included in the test. Yield among varieties varied from year-to-year (Table 1). The threeyear average indicated there was little difference in yield potential among Asgrow 5944, Caviness, Hutcheson, or Asgrow 5547. Pioneer 9594 produced between two to three bushels less than the other varieties. This reduction may partially be due to its susceptibility to stem canker. All varieties showed low to moderate levels of susceptibility to frogeye leafspot (Table 2). An application of Quadris at the R3 growth stage in 2004 likely prevented any significant yield loss from this disease. TABLE 2. STEM CANKER, FROGEYE LEAFSPOT AND CERCOSPORA LEAF BLIGHT RATINGS AND YIELD, 2004 Yield Disease ratings* (Aug. 6, 2004) Bu/A Stem canker Frogeye Cercospora Variety 44.5 1 0 2.0 Caviness 50.7 1 2.5 0 Asgrow 5944 48.6 1 1.5 0 Hutcheson 48.1 2 2.0 0 Asgrow 5547 37.1 1 2.0 2 Pioneer 9594 *Disease ratings 1 = trace, 2 = low level, 3 = moderate level, 4 = high level, 5 = very high level. Breeding Improved Soybean Cultivars for Alabama D. B. Weaver The testing and development of new soybean (Glycine max L.) cultivars continues to be an ongoing project of the Alabama Agricultural Experiment Station. Since its inception, the project has resulted in the release of three cultivars (Stonewall, Carver, and Kuell), two germplasm lines, and the release of a new Roundup-Ready® cultivar is pending. During 2004, we evaluated many experimental soybean lines including single-plant progeny rows (F5:6 lines), and many lines in later stages of development in initial and advance stages of testing. Fifty lines were tested in advanced trials at three locations, and 140 lines were tested in initial yield tests at one location. Auburn lines were also tested regionally in the USDA Uniform Cooperative tests, with four lines tested in each of the Preliminary VI and Preliminary VII tests and two lines tested in the Uniform VI tests. One of these was the top-yielding line in the test at the Tennessee Valley Research and Extension Center in Belle Mina. These are lower numbers than we usually test, but we are still recovering from the fire of 2002. Other populations are in various stages of development, with several FI and F3 populations having been sent for generation advance to the USDA winter nursery in Puerto Rico. We continue to make crosses during the summer, using the best of the publicly available material as parents. Foundation seed of Kuell were produced in 2004 and should be available to Registered and Certified Seed producers in 2005. This Maturity Group VIII cultivar continues to perform extremely well in state variety tests throughout the Southeast. Its vigorous production of vegetative mass and greater plant height make it an ideal cultivar for double-cropping. Seed quality is not as good as it should be in 2004 due to the effects of hurricane Ivan, but germination has been greater than 75 percent. Thirty bushels of Breeder seed of a new Roundup Ready® line with experimental designation AX416 was produced in 2004. We have received approval from the Variety Release Committee to release this line, but performance in the State Variety Tests in 2004 was disappointing, and a decision to release this line will be based on further testing in 2005. In cooperation with Clemson University, we conducted the third year of a test into the performance of experimental lines with the long-juvenile trait (lack of photoperiod response) at two planting dates, early (April) and late (July), in central Alabama. Soybean cultivars that do not begin reproductive growth in response to day length have the potential to expand the range of planting dates with no detrimental effects on yield. This trait would allow lines to be planted either very early to avoid late-summer drought, or planted late, in a double-crop- ALABAMA AGRICULTURAL EXPERIMENT STATION 13 ping system following small grains or maize. Experimental lines have produced well at both planting dates, and outperformed check cultivars in many cases. We also are continuing to be a cooperator in the USDA Uniform Cooperative Tests, growing 11 tests in three locations (Tallassee, Belle Mina, and Fairhope, Alabama) and evaluating a total of 219 public breeding lines of Maturity Groups V, VI, VII, and VIII in both Preliminary and Uniform Tests. This continues to be a major resource of genetic material, as well as a great testing network for evaluation of new genotypes. However, extensive resources, in terms of labor and materials, are required to conduct these tests. We receive no money from USDA. Most all of these tests conducted in the United States are supported by soybean checkoff funding. 14 2004 SOYBEAN RESEARCH REPORT DISEASE EVALUATIONS Evaluation of Quadris for Frogeye Leaf Spot Control on Soybeans, Tallassee, 2004 E. J. Sikora, D. P. Delaney, and K. S. Lawrence The fungicide Quadris has been shown to be effective in controlling frogeye leafspot, pod and stem blight, and aerial blight at the manufacturer's labeled rates (12-15 fluid ounces per acre). However, growers are hesitant to use Quadris at these rates due to its relatively high cost (approximately $2 per ounce per acre). This study evaluated Quadris applied at two plant growth stages to determine its efficacy at low rates against frogeye leafspot of soybean. DeltaPine DP 6299 RR soybean seed were planted on May 17, 2004, at the Plant Breeding Unit of the E. V. Smith Research Center in Tallassee, Alabama. There were six treatments, replicated four times in a randomized complete block design. Plots consisted of four 30-inch rows, 25 feet long, with the center two rows used for frogeye ratings and harvest. Treatments included: 1) Quadris applied at 3.1 ounces per acre at R3 (growth stage); EVALUATION OF Low RATES OF QUADRIS FOR CONTROL OF FROGEYE LEAFSPOT ON SOYBEANS, 2004 Treatment Growth Frogeye Yield Bu/A stage severity* Nonsprayed --3.5a** 48.7c control Dimilin 2 oz/A Quadris 3.1 oz/A + Dimilin 2 oz/A Quadris 6.2 oz /A + Dimilin 2 oz/A Quadris 3.1 oz/A + Dimilin 2 oz/A R3 R3 R3 R5 3.8a 1.4c 1.5c 3.1lb 55.5b 64.6a 64.5a 54.5b 2) Quadris applied at 3.1 ounces per acre at R5; 3) Quadris applied at 6.2 ounces per acre at R3; 4) Quadris applied at 6.2 ounces per acre at R5; 5) Dimilin 2L applied alone at 2.0 ounces per acre at R3; and 6) a nontreated control. All treatments with the exception of the control received an application of Dimilin 2L at 2.0 ounces acre at R3. Some evidence suggests that Dimilin (an insecticide) may control frogeye leafspot and may increase yield in the absence of disease. Disease severity was rated on August 13 and harvest occurred on October 6, 2004. Yields were adjusted to 13 percent moisture and 60 bushels per acre. Frogeye was observed in plots prior to the initial R3 applications (July 23). Results show that frogeye severity was significantly less when Quadris at either 3.1 or 6.2 ounces per acre plus Dimilin 2L, was applied at R3, just after the onset of frogeye symptoms (see the table). These treatments also produced significantly higher yields than all other treatments. Frogeye severity was significantly less when Quadris at both 3.1 and 6.2 ounces per acre plus Dimilin, was applied at R5 (August 6) compared to Dimilin alone and to the nonsprayed control. However there were no significant differences in yield among the Dimilin treatment and the 3.1- and 6.2-ounce Quadris treatments applied at R5. All treatments had significantly higher yields than the nonsprayed control. There were no apparent differences in seed quality measured by post-harvest fungal contamination (data not shown). Results suggest that an early season application of Quadris at relatively low rates at the R3 growth stage prior to, or at the onset of, frogeye leafspot symptoms can reduce frogeye severity and significantly increase yields. Application of Quadris at low rates at R5 can also reduce frogeye severity and increase yields compared to nontreated soybeans, but yield increases are not as great as soybeans treated at R3. Dimilin applied alone at R3 did not reduce frogeye severity but did increase yields compared to the untreated control, indicating that the insecticide had a beneficial effect other than controlling frogeye. Quadris 6.2 oz/A + Dimilin 2 oz/A R5 2.9b 56.8b *Rating scale was 0-9 with 9 representing the highest frogeye leafspot damage. **Numbers followed by a different letter are significantly different. ALABAMA AGRICULTURAL EXPERIMENT STATION 15 Evaluation of Quadris on Soybeans at Low Rates in West-Central Alabama E. J. Sikora, K. S. Lawrence, and D. P. Delaney The fungicide Quadris has been shown to be effective in controlling frog-eye leafspot, pod and stem blight, and aerial blight at the manufacturer's labeled rates (12 to 15 fluid ounces per acre). However, growers are hesitant to use Quadris at these rates due to its relatively high cost (approximately $2 per ounce per acre). Field observations and preliminary results from research conducted in the Southeast suggest Quadris may be effective at relatively low rates (3.1 to 6.2 ounces per acre) if applied prior to disease onset. A large-scale field trial was conducted at the Dee River Ranch in Pickens County, Alabama, in 2004. The trial was planted on April 7, 2004, with the soybean variety Hutcheson. The trial consisted of three treatments, replicated two times, in a randomized complete block. Each block was approximately 6.4 acres in size. Treatments included: 1) Quadris at 3.1 ounces per acre plus Dimilin 2L at 2 ounces per acre, 2) Quadris at 6.2 ounces per acre plus Dimilin 2L at 2 ounces per acre, or 3) Dimilin 2L at 2 ounces per acre. All treatments were applied on July 11 at the R3 growth stage, in 19 gallons of water per acre using a Case IH 4260 sprayer. Trace levels of frogeye leafspot were observed in the trial at the time of application. Cercospora leaf blight and Rhizoctonia aerial blight developed in the trial, but as with frogeye leafspot, remained at relatively low levels for the duration of the test. The trial was evaluated on July 18, July 25, and August 10, but there were no significant differences in disease severity among treatments (data not shown). Plots were harvested on September 22 and yield was determined. A sample from each block was evaluated for post-harvest fimungal colonization. There were no apparent differences in yield among the treatments (see the table ). Low levels of foliar disease did not allow for a good examination of the treatments' disease control capabilities. However, it did appear that applications of Quadris at the R3 growth stage at both the 3.1 and 6.2 ounces per acre rate did reduce post-harvest seed colonization of pathogenic fungi compared to Dimilin alone. EVALUATION OF Low RATES OF QUADRIS FOR REDUCTION IN POST-HARVEST FUNGAL COLONIZATION OF SOYBEANS, 2004 ---------------- Percent seed colonized-------------Treatment Yield Cercospora Fusarium Phomopsis Bu/A kikuchii oxysporum sp. Dimilin 2 oz 57.8 34 12.5 13 Quadris 3.1 oz + Dimilin 2 oz 58.5 13 7.0 3 Quadris 6.2 oz + Dimilin 2 oz 59.4 10 2.5 8 With an acr-icaittiral leiiarci stilli lC Ci Alnhi n-LIIas ersit) "CIASe thle nleeds ield 7 cr op, is es;toek. Icerl rest ionl ill F\ lf \akhallina ct/eli of the a state hm~i stke inl this r let l pt