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7. Turfgrass Benefits and Issues

Author

Stier, John C., primary, Steinke, Kurt, additional, Ervin, Erik H., additional, Higginson, Francis R., additional, and McMaugh, Peter E., additional

Published
2015
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10. Lawn Fertilization for Cool Season Grasses

Author

Goatley, Michael, Ervin, Erik H., and Heckendorn, Steven E.

Subjects
Lawns and turf, Soil testing
Abstract

Describes vegetable weevils, common host plants, their life history, damage to crops, and methods of control. 452-717 P

Published
2021

11. Improving Soil Moisture Assessment of Turfgrass Systems Utilizing Field Radiometry

Author

Roberson, Travis L., Badzmierowski, Mike J., Stewart, Ryan D., Ervin, Erik H., Askew, Shawn D., McCall, David S., Roberson, Travis L., Badzmierowski, Mike J., Stewart, Ryan D., Ervin, Erik H., Askew, Shawn D., and McCall, David S.

Abstract

The need for water conservation continues to increase as global freshwater resources dwindle. Turfgrass mangers are adapting to these concerns by implementing new tools to reduce water consumption. Time-domain reflectometer (TDR) soil moisture sensors can decrease water usage when scheduling irrigation, but nonuniformity across unsampled locations creates irrigation inefficiencies. Remote sensing data have been used to estimate soil moisture stress in turfgrass systems through the normalized difference vegetation index (NDVI). However, numerous stressors other than moisture constraints impact NDVI values. The water band index (WBI) is an alternative index that uses narrowband, near-infrared light reflectance to estimate moisture limitations within the plant canopy. The green-to-red ratio index (GRI) is a vegetation index that has been proposed as a cheaper alternative to WBI as it can be measured using digital values of visible light instead of relying on more costly hyperspectral reflectance measurements. A replicated 2 × 3 factorial experimental design was used to repeatedly measure turf canopy reflectance and soil moisture over time as soils dried. Pots of ‘007’ creeping bentgrass (CBG) and ‘Latitude 36’ hybrid bermudagrass (HBG) were grown on three soil textures: United States Golf Association (USGA) 90:10 sand, loam, and clay. Reflectance data were collected hourly between 07:00 and 19:00 using a hyperspectral radiometer and volumetric water content (VWC) data were collected continuously using an embedded soil moisture sensor from soil saturation until complete turf necrosis by drought stress. The WBI had the strongest relationship to VWC (r = 0.62) compared to GRI (r = 0.56) and NDVI (r = 0.47). The WBI and GRI identified significant moisture stress approximately 28 h earlier than NDVI (p = 0.0010). Those metrics also predicted moisture stress prior to fifty percent visual estimation of wilt (p = 0.0317), with lead times of 1

Published
2021
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15. Environmental Best Management Practices for Virginia's Golf Courses

Author

Schoenholtz, Stephen H., Goatley, Michael, Ervin, Erik H., Hodges, Steven C., Hipkins, Perry L., McCall, David S., Askew, Shawn D., Youngman, Roger R., Hipkins, Patricia A., Grisso, Robert D., Muckley, Glenn, George, Lester, Ballard, Mike, Roadley, Chuck, Lajoie, Matt, Rodriguez, Mark, Habel, Robert, Sexton, Tim, Buchen, Terry, and Virginia Cooperative Extension

Subjects
Water quality, ComputerApplications_MISCELLANEOUS, ComputingMilieux_COMPUTERSANDEDUCATION, Turf, Environmental Quality, Golf courses, Best management practices, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries)
Abstract

Provides recommendations for Virginia golf courses, emphasizing water quality protection.

Published
2019

16. Antioxidant metabolism variation associated with alkali-salt tolerance in thirty switchgrass (Panicum virgatum) lines

Author

Hu, Guofu, Liu, Yiming, Duo, Tianqi, Zhao, Bingyu Y., Cui, Guowen, Ji, Jing, Kuang, Xiao, Ervin, Erik H., Zhang, Xunzhong, and School of Plant and Environmental Sciences

Subjects
food and beverages
Abstract

Soil salinization is a major factor limiting crop growth and development in many areas. Switchgrass (Panicum virgatum L.) is an important warm-season grass species used for biofuel production. The objective of this study was to investigate antioxidant metabolism, proline, and protein variation associated with alkali-salt tolerance among 30 switchgrass lines and identify metabolic markers for evaluating alkali-salt tolerance of switchgrass lines. The grass lines were transplanted into plastic pots containing fine sand. When the plants reached E5 developmental stage, they were subjected to either alkali-salt stress treatment (150 mM Na+ and pH of 9.5) or control (no alkali-salt stress) for 20 d. The 30 switchgrass lines differed in alkali-salt tolerance as determined by the level of leaf malondialdehyde (MDA), antioxidant enzyme activity [(superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX)], proline and protein. Alkali-salt stress increased MDA, proline, SOD, reduced CAT activity, but its effect on protein and APX varied depending on lines. Wide variations in the five parameters existed among the 30 lines. In general, the lines with higher CAT activity and lower proline content under alkali-salt stress had less MDA, exhibiting better alkali-salt tolerance. Among the five parameters, CAT can be considered as valuable metabolic markers for assessment of switchgrass tolerance to alkali-salt stress. Natural Science Fund of Heilongjiang Province [LC2016009]; U.S. Department of Energy; U.S. Department of Agriculture's Plant Feedstocks Genomics for Bioenergy Program [DE-SC0008338]; Virginia Tech's Virginia Agricultural Experiment Station [VA135872] This research was funded by The Natural Science Fund of Heilongjiang Province (LC2016009) (GH) and U.S. Department of Energy and U.S. Department of Agriculture's Plant Feedstocks Genomics for Bioenergy Program (DE-SC0008338 to XZ and BZ). The study was also partially supported by Virginia Tech's Virginia Agricultural Experiment Station (VA135872 to BZ).

Published
2018

19. Physiological Mechanism of Enhancing Salt Stress Tolerance of Perennial Ryegrass by 24-Epibrassinolide

Author

Wu, Wenli, Zhang, Qiang, Ervin, Erik H., Yang, Zhiping, Zhang, Xunzhong, and School of Plant and Environmental Sciences

Subjects
antioxidant, hormones, perennial ryegrass, food and beverages, ion, 24-epibrassinolide, salt stress
Abstract

Brassinosteroids (BR) regulate plant tolerance to salt stress but the mechanisms underlying are not fully understood. This study was to investigate physiological mechanisms of 24-epibrassinolide (EBR)'s impact on salt stress tolerance in perennial ryegrass (Lolium perenne L.) The grass seedlings were treated with EBR at 0, 10, and 100 nM, and subjected to salt stress (250 mM NaCl). The grass irrigated with regular water without EBR served as the control. Salt stress increased leaf electrolyte leakage (EL), malondialdehyde (MDA), and reduced photosynthetic rate (Pn). Exogenous EBR reduced EL and MDA, increased Pn, chlorophyll content, and stomatal conductance (gs). The EBR applications also alleviated decline of superoxide dismutase (SOD) and catalase (CAT) and ascorbate peroxidase (APX) activity when compared to salt treatment alone. Salt stress increased leaf abscisic acid (ABA) and gibberellin A4 (GA4) content but reduced indole-3-acetic acid (IAA), zeatin riboside (ZR), isopentenyl adenosine (iPA), and salicylic acid (SA). Exogenous EBR at 10 nm and 100 nM increased ABA, and iPA content under salt stress. The EBR treatment at 100 nM also increased leaf IAA, ZR, JA, and SA. In addition, EBR treatments increased leaf proline and ions (K+, Mg2+, and Ca2+) content, and reduced Na+/K+ in leaf tissues. The results of this study suggest that EBR treatment may improve salt stress tolerance by increasing the level of selected hormones and antioxidant enzyme (SOD and CAT) activity, promoting accumulation of proline and ions (K+, Ca2+, and Mg2+) in perennial ryegrass. Turfgrass Field Testing Fund China's International Science and Technology Cooperation Fund [2015DFA90990] This study was supported by Turfgrass Field Testing Fund (EE and XZ) and partially supported by China's International Science and Technology Cooperation Fund (2015DFA90990) (QZ and ZY). We would like to thank Kevin Liu and Naina Sharma for the help with lab assay.

Published
2017

20. Managing Landscapes to Meet Emerging Global Challenges

Author

Badgley, Brian D., Daniels, W. Lee, Day, Susan D., Eick, Matthew J., Ervin, Erik H., Steele, Meredith K., Stewart, Ryan D., Strahm, Brian D., Xia, Kang, and Zipper, Carl E.

Abstract

Our vision is to create a program dedicated to accelerating innovation that improves the quality, efficiency, and resilience of human dominated landscapes, including our cities, farms, and industrial lands. Humans dramatically alter and manipulate the global landscape for food and fiber production, mineral extraction, urban development, waste disposal and many other purposes. Impacts to essential ecosystem functions and values range from local (e.g. mining and land development) to global (e.g. carbon emissions) with a clear need for development of appropriate management systems for their mitigation. By using a systems approach that interfaces environmental scientists and ecologists with relevant disciplines, this proposed signature area within Global Systems Science (GSS) will build upon existing group strengths in soil remediation, water quality, hydrology, urban soils, land reclamation, agroecosystem management, forest ecology, wetland restoration, soil-waste management and integrated modeling across multiple spatial and temporal scales to develop a more holistic approach to landscape management. We will also...

Published
2017

21. Influence of synthetic phthalocyanine pigments on light reflectance of creeping bentgrass.

Author

McCall, David S., Sullivan, Dana G., Zhang, Xunzhong, Martin, S. Bruce, Wong, Alexander, and Ervin, Erik H.

Subjects
PHTHALOCYANINES, AGROSTIS, REFLECTANCE, GOLF course managers, LIGHT absorption
Abstract

The use of synthetic pigment‐containing products on golf playing surfaces by golf course superintendents has increased dramatically to provide green color and improve stress tolerance. Most turf colorants are synthesized from various phthalocyanine pigments, which share visible spectral properties with green plant tissue. Vegetation indices, such as normalized difference (NDVI), are commonly used by researchers to quantify plant health or turf quality. Research reports indicate that turf canopy reflectance is sometimes positively and sometimes negatively affected by synthetic pigments. The specific spectral wavelength used for vegetation indices varies by sensor type, which may explain these inconsistencies. A greater understanding of light absorption characteristics of synthetic pigments is needed. Therefore, the research objectives were to determine the spectral properties of synthetic phthalocyanine pigment‐containing products alone and to quantify their influence on light reflected from treated creeping bentgrass canopies. Narrow bandwidth (1.5 nm) reflectance was collected from across visible and near‐infrared spectra using a handheld field spectroradiometer (PSR‐1100F, Spectral Evolution) to develop spectral signatures of pigmented products alone, healthy turf, and healthy turf treated with pigmented products. Synthetic pigment‐containing products strongly absorbed near‐infrared light but did not affect photosynthetically active spectra. Some products tested influenced reflectance of ultraviolet A radiation. Endogenous chlorophyll concentrations 7 d after treatment were not altered by products tested. Spectral characteristics of NDVI and similar reflectance measurements of creeping bentgrass quality using near‐infrared light may be negatively affected when the turf is treated with phthalocyanine pigment‐containing products. [ABSTRACT FROM AUTHOR]

Published
2021
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23. Antioxidant metabolism variation associated with alkali-salt tolerance in thirty switchgrass (Panicum virgatum) lines

Author

School of Plant and Environmental Sciences, Hu, Guofu, Liu, Yiming, Duo, Tianqi, Zhao, Bingyu Y., Cui, Guowen, Ji, Jing, Kuang, Xiao, Ervin, Erik H., Zhang, Xunzhong, School of Plant and Environmental Sciences, Hu, Guofu, Liu, Yiming, Duo, Tianqi, Zhao, Bingyu Y., Cui, Guowen, Ji, Jing, Kuang, Xiao, Ervin, Erik H., and Zhang, Xunzhong

Abstract

Soil salinization is a major factor limiting crop growth and development in many areas. Switchgrass (Panicum virgatum L.) is an important warm-season grass species used for biofuel production. The objective of this study was to investigate antioxidant metabolism, proline, and protein variation associated with alkali-salt tolerance among 30 switchgrass lines and identify metabolic markers for evaluating alkali-salt tolerance of switchgrass lines. The grass lines were transplanted into plastic pots containing fine sand. When the plants reached E5 developmental stage, they were subjected to either alkali-salt stress treatment (150 mM Na+ and pH of 9.5) or control (no alkali-salt stress) for 20 d. The 30 switchgrass lines differed in alkali-salt tolerance as determined by the level of leaf malondialdehyde (MDA), antioxidant enzyme activity [(superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX)], proline and protein. Alkali-salt stress increased MDA, proline, SOD, reduced CAT activity, but its effect on protein and APX varied depending on lines. Wide variations in the five parameters existed among the 30 lines. In general, the lines with higher CAT activity and lower proline content under alkali-salt stress had less MDA, exhibiting better alkali-salt tolerance. Among the five parameters, CAT can be considered as valuable metabolic markers for assessment of switchgrass tolerance to alkali-salt stress.

Published
2018

30. Physiological Mechanism of Enhancing Salt Stress Tolerance of Perennial Ryegrass by 24-Epibrassinolide

Author

School of Plant and Environmental Sciences, Wu, Wenli, Zhang, Qiang, Ervin, Erik H., Yang, Zhiping, Zhang, Xunzhong, School of Plant and Environmental Sciences, Wu, Wenli, Zhang, Qiang, Ervin, Erik H., Yang, Zhiping, and Zhang, Xunzhong

Abstract

Brassinosteroids (BR) regulate plant tolerance to salt stress but the mechanisms underlying are not fully understood. This study was to investigate physiological mechanisms of 24-epibrassinolide (EBR)'s impact on salt stress tolerance in perennial ryegrass (Lolium perenne L.) The grass seedlings were treated with EBR at 0, 10, and 100 nM, and subjected to salt stress (250 mM NaCl). The grass irrigated with regular water without EBR served as the control. Salt stress increased leaf electrolyte leakage (EL), malondialdehyde (MDA), and reduced photosynthetic rate (Pn). Exogenous EBR reduced EL and MDA, increased Pn, chlorophyll content, and stomatal conductance (gs). The EBR applications also alleviated decline of superoxide dismutase (SOD) and catalase (CAT) and ascorbate peroxidase (APX) activity when compared to salt treatment alone. Salt stress increased leaf abscisic acid (ABA) and gibberellin A4 (GA4) content but reduced indole-3-acetic acid (IAA), zeatin riboside (ZR), isopentenyl adenosine (iPA), and salicylic acid (SA). Exogenous EBR at 10 nm and 100 nM increased ABA, and iPA content under salt stress. The EBR treatment at 100 nM also increased leaf IAA, ZR, JA, and SA. In addition, EBR treatments increased leaf proline and ions (K+, Mg2+, and Ca2+) content, and reduced Na+/K+ in leaf tissues. The results of this study suggest that EBR treatment may improve salt stress tolerance by increasing the level of selected hormones and antioxidant enzyme (SOD and CAT) activity, promoting accumulation of proline and ions (K+, Ca2+, and Mg2+) in perennial ryegrass.

Published
2017

31. MOESM10 of Assessment of drought tolerance of 49 switchgrass (Panicum virgatum) genotypes using physiological and morphological parameters

Author

Yiming Liu, Xunzhong Zhang, Tran, Hong, Shan, Liang, Jeongwoon Kim, Childs, Kevin, Ervin, Erik, Frazier, Taylor, and Bingyu Zhao

Abstract

Additional file 2. Effect of drought stress on morphological parameters at 30 d of experiment (n = 6), and effect of drought stress on morphological parameters of lowland and upland lines at 30 d of experiment, (n = 294). LL: leaf length; LW: leaf width; SL: leaf sheath length; SE: standard error.

Published
2015
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32. Ferrous sulfate for dollar spot suppression

Author

Shelton, Camden, McCall, David, Ervin, Erik, and Askew, Shawn

Subjects
Sulfates, Business, Sports, sporting goods and toys industry
Abstract

Researchers at Virginia Tech demonstrated in 2012 that ferrous sulfate applied at 1 lb./1,000 sq. ft. (20 percent ferrous sulfate-heptahydrate) can reduce dollar spot pressure without traditional fungicides. Because previously [...]

Published
2017

34. Physiological Evaluation of Alkali-Salt Tolerance of Thirty Switchgrass (Panicum virgatum) Lines

Author

Hu, Guofu, Liu, Yiming, Zhang, Xunzhong, Yao, Fengjiao, Huang, Yan, Ervin, Erik H., Zhao, Bingyu Y., Hu, Guofu, Liu, Yiming, Zhang, Xunzhong, Yao, Fengjiao, Huang, Yan, Ervin, Erik H., and Zhao, Bingyu Y.

Abstract

Soil salt-alkalization is a major limiting factor for crop production in many regions. Switchgrass (Panicum virgatum L.) is a warm-season C4 perennial rhizomatous bunchgrass and a target lignocellulosic biofuel species. The objective of this study was to evaluate relative alkali-salt tolerance among 30 switchgrass lines. Tillers of each switchgrass line were transplanted into pots filled with fine sand. Two months after transplanting, plants at E5 developmental stage were grown in either half strength Hoagland’s nutrient solution with 0 mM Na+ (control) or half strength Hoagland’s nutrient solution with 150 mM Na+ and pH of 9.5 (alkali-salt stress treatment) for 20 d. Alkali-salt stress damaged cell membranes [higher electrolyte leakage (EL) ], reduced leaf relative water content (RWC), net photosynthetic rate (Pn), stomatal conductance (gs), and transpiration rate (Tr). An alkali-salt stress tolerance trait index (ASTTI) for each parameter was calculated based on the ratio of the value under alkali-salt stress and the value under non-stress conditions for each parameter of each line. Relative alkali-salt tolerance was determined based on principal components analysis and cluster analysis of the physiological parameters and their ASTTI values. Significant differences in alkali-salt stress tolerance were found among the 30 lines. Lowland lines TEM-SEC, Alamo, TEM-SLC and Kanlow were classified as alkali-salt tolerant. In contrast, three lowland lines (AM-314/MS-155, BN-13645-64) and two upland lines (Caddo and Blackwell-1) were classified as alkali-salt sensitive. The results suggest wide variations exist in alkali-salt stress tolerance among the 30 switchgrass lines. The approach of using a combination of principal components and cluster analysis of the physiological parameters and related ASTTI is feasible for evaluating alkali-salt tolerance in switchgrass.

Published
2015
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35. Assessment of drought tolerance of 49 switchgrass (Panicum virgatum) genotypes using physiological and morphological parameters

Author

Liu, Yiming, Zhang, Xunzhong, Tran, Hong T., Shan, Liang, Kim, Jeongwoon, Childs, Kevin L., Ervin, Erik H., Frazier, Taylor P., Zhao, Bingyu Y., Liu, Yiming, Zhang, Xunzhong, Tran, Hong T., Shan, Liang, Kim, Jeongwoon, Childs, Kevin L., Ervin, Erik H., Frazier, Taylor P., and Zhao, Bingyu Y.

Abstract

Background Switchgrass (Panicum virgatum L.) is a warm-season C4 grass that is a target lignocellulosic biofuel species. In many regions, drought stress is one of the major limiting factors for switchgrass growth. The objective of this study was to evaluate the drought tolerance of 49 switchgrass genotypes. The relative drought stress tolerance was determined based on a set of parameters including plant height, leaf length, leaf width, leaf sheath length, leaf relative water content (RWC), electrolyte leakage (EL), photosynthetic rate (Pn), stomatal conductance (g s), transpiration rate (Tr), intercellular CO2 concentration (Ci), and water use efficiency (WUE). Results SRAP marker analysis determined that the selected 49 switchgrass genotypes represent a diverse genetic pool of switchgrass germplasm. Principal component analysis (PCA) and drought stress indexes (DSI) of each physiological parameter showed significant differences in the drought stress tolerance among the 49 genotypes. Heatmap and PCA data revealed that physiological parameters are more sensitive than morphological parameters in distinguishing the control and drought treatments. Metabolite profiling data found that under drought stress, the five best drought-tolerant genotypes tended to have higher levels of abscisic acid (ABA), spermine, trehalose, and fructose in comparison to the five most drought-sensitive genotypes. Conclusion Based on PCA ranking value, the genotypes TEM-SEC, TEM-LoDorm, BN-13645-64, Alamo, BN-10860-61, BN-12323-69, TEM-SLC, T-2086, T-2100, T-2101, Caddo, and Blackwell-1 had relatively higher ranking values, indicating that they are more tolerant to drought. In contrast, the genotypes Grif Nebraska 28, Grenville-2, Central Iowa Germplasm, Cave-in-Rock, Dacotah, and Nebraska 28 were found to be relatively sensitive to drought stress. By analyzing physiological response parameters and different metabolic profiles, the methods utilized in this study identified drought-tolerant and

Published
2015
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36. Physiological Evaluation of Alkali-Salt Tolerance of Thirty Switchgrass (Panicum virgatum) Lines

Author

School of Plant and Environmental Sciences, Hu, Guofu, Liu, Yiming, Zhang, Xunzhong, Yao, Fengjiao, Huang, Yan, Ervin, Erik H., Zhao, Bingyu Y., School of Plant and Environmental Sciences, Hu, Guofu, Liu, Yiming, Zhang, Xunzhong, Yao, Fengjiao, Huang, Yan, Ervin, Erik H., and Zhao, Bingyu Y.

Abstract

Soil salt-alkalization is a major limiting factor for crop production in many regions. Switchgrass (Panicum virgatum L.) is a warm-season C4 perennial rhizomatous bunchgrass and a target lignocellulosic biofuel species. The objective of this study was to evaluate relative alkali-salt tolerance among 30 switchgrass lines. Tillers of each switchgrass line were transplanted into pots filled with fine sand. Two months after transplanting, plants at E5 developmental stage were grown in either half strength Hoagland’s nutrient solution with 0 mM Na+ (control) or half strength Hoagland’s nutrient solution with 150 mM Na+ and pH of 9.5 (alkali-salt stress treatment) for 20 d. Alkali-salt stress damaged cell membranes [higher electrolyte leakage (EL) ], reduced leaf relative water content (RWC), net photosynthetic rate (Pn), stomatal conductance (gs), and transpiration rate (Tr). An alkali-salt stress tolerance trait index (ASTTI) for each parameter was calculated based on the ratio of the value under alkali-salt stress and the value under non-stress conditions for each parameter of each line. Relative alkali-salt tolerance was determined based on principal components analysis and cluster analysis of the physiological parameters and their ASTTI values. Significant differences in alkali-salt stress tolerance were found among the 30 lines. Lowland lines TEM-SEC, Alamo, TEM-SLC and Kanlow were classified as alkali-salt tolerant. In contrast, three lowland lines (AM-314/MS-155, BN-13645-64) and two upland lines (Caddo and Blackwell-1) were classified as alkali-salt sensitive. The results suggest wide variations exist in alkali-salt stress tolerance among the 30 switchgrass lines. The approach of using a combination of principal components and cluster analysis of the physiological parameters and related ASTTI is feasible for evaluating alkali-salt tolerance in switchgrass.

Published
2015

37. Assessment of drought tolerance of 49 switchgrass (Panicum virgatum) genotypes using physiological and morphological parameters

Author

School of Plant and Environmental Sciences, Liu, Yiming, Zhang, Xunzhong, Tran, Hong T., Shan, Liang, Kim, Jeongwoon, Childs, Kevin L., Ervin, Erik H., Frazier, Taylor P., Zhao, Bingyu Y., School of Plant and Environmental Sciences, Liu, Yiming, Zhang, Xunzhong, Tran, Hong T., Shan, Liang, Kim, Jeongwoon, Childs, Kevin L., Ervin, Erik H., Frazier, Taylor P., and Zhao, Bingyu Y.

Abstract

Background Switchgrass (Panicum virgatum L.) is a warm-season C4 grass that is a target lignocellulosic biofuel species. In many regions, drought stress is one of the major limiting factors for switchgrass growth. The objective of this study was to evaluate the drought tolerance of 49 switchgrass genotypes. The relative drought stress tolerance was determined based on a set of parameters including plant height, leaf length, leaf width, leaf sheath length, leaf relative water content (RWC), electrolyte leakage (EL), photosynthetic rate (Pn), stomatal conductance (g s), transpiration rate (Tr), intercellular CO2 concentration (Ci), and water use efficiency (WUE). Results SRAP marker analysis determined that the selected 49 switchgrass genotypes represent a diverse genetic pool of switchgrass germplasm. Principal component analysis (PCA) and drought stress indexes (DSI) of each physiological parameter showed significant differences in the drought stress tolerance among the 49 genotypes. Heatmap and PCA data revealed that physiological parameters are more sensitive than morphological parameters in distinguishing the control and drought treatments. Metabolite profiling data found that under drought stress, the five best drought-tolerant genotypes tended to have higher levels of abscisic acid (ABA), spermine, trehalose, and fructose in comparison to the five most drought-sensitive genotypes. Conclusion Based on PCA ranking value, the genotypes TEM-SEC, TEM-LoDorm, BN-13645-64, Alamo, BN-10860-61, BN-12323-69, TEM-SLC, T-2086, T-2100, T-2101, Caddo, and Blackwell-1 had relatively higher ranking values, indicating that they are more tolerant to drought. In contrast, the genotypes Grif Nebraska 28, Grenville-2, Central Iowa Germplasm, Cave-in-Rock, Dacotah, and Nebraska 28 were found to be relatively sensitive to drought stress. By analyzing physiological response parameters and different metabolic profiles, the methods utilized in this study identified drought-tolerant and

Published
2015

41. Salt Stress-induced Injury is Associated with Hormonal Alteration in Kentucky Bluegrass.

Author

Xunzhong Zhang, Ervin, Erik H., Chao Shang, Wenli Wu, and Harich, Kim

Subjects
*BLUEGRASSES (Plants), *PLANT hormones, *ABIOTIC stress, *PHOTOSYNTHETIC rates, *CHLOROPHYLL
Abstract

Plant hormones play an important role in plant adaptation to abiotic stress, but hormonal responses of cool-season turfgrass species to salt stress are not well documented. This study was carried out to investigate the responses of hormones to salt stress and examine if salt stress-induced injury was associated with hormonal alteration in kentucky bluegrass (KBG, Poa pratensis L.). The grass was grown in a growth chamber for 6 weeks and then subjected to salt stress (170 mM NaCl) for 28 days. Salt stress caused cell membrane damage, resulting in photosynthetic rate (Pn), chlorophyll (Chl), and turf quality decline in KBG. Salt stress increased leaf abscisic acid (ABA) and ABA/cytokinin (CK) ratio; reduced trans-zeatin riboside (ZR), isopentenyl adenosine (iPA), and indole-3-acetic acid (IAA), but did not affect gibberellin A4 (GA4). On average, salt stress reduced ZR by 67.4% and IAA by 58.6%, whereas it increased ABA by 398.5%. At the end of the experiment (day 28), turf quality, Pn, and stomatal conductance (gs) were negatively correlated with ABA and ABA/CK ratio, but positively correlated with ZR, iPA, and IAA. Electrolyte leakage (EL) was positively correlated with ABA and ABA/CK and negatively correlated with ZR, iPA, IAA, and GA4. GA4 was also positively correlated with turf quality and gs. The results of this study suggest that salt stressinduced injury of the cell membrane and photosynthetic function may be associated with hormonal alteration and imbalance in KBG. [ABSTRACT FROM AUTHOR]

Published
2018
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42. Auxin and Trinexapac-Ethyl Impact on Root Viability and Hormone Metabolism in Creeping Bentgrass under Water Deficit.

Author

Xunzhong Zhang, Ervin, Erik H., Wenli Wu, Sharma, Naina, and Hamill, Alyssa

Subjects
*PLANT regulators, *TURFGRASS quality, *DROUGHT tolerance
Abstract

Plant growth regulators have been used to improve turfgrass quality and drought tolerance. This study was designed to investigate if foliar application of auxin (indole-3-butyric acid [IBA] at 2 mM) and trinexapac-ethyl (TE, 45 g ha-1), alone or in a combination, improves creeping bentgrass (Agrostis stolonifera L.) root growth and hormone metabolism under water-deficit conditions. The plants were subjected to well-watered or water-deficit stress (40-50% evapotranspiration replacement) conditions for up to 42 d in growth chambers. Water deficit reduced turf quality and net photosynthetic rate (Pn), leaf indole-3-acetic acid (IAA), isopentenyl adenosine (iPA) content, and root viability. Exogenous application of TE or IBA, alone or in a combination, improved turf quality, Pn, and stomatal conductance under water-deficit conditions. Under water deficit, TE, IBA, and TE + IBA treatments also increased leaf IAA, iPA, and abscisic acid content relative to the control. The combination treatment (TE + IBA) increased root biomass relative to the control under waterdeficit and well-watered conditions. Under water deficit, TE, IBA, TE + IBA increased root viability by 16.7, 32.2, and 56.2%, respectively, relative to the control. Under well-watered conditions, IBA, with or without TE, also increased leaf IAA and iPA, as well as root viability. Results suggest that foliar application of auxin and TE at proper rates may promote root viability and hormonally mediated adjustments to drought, resulting in improved turf quality under waterdeficit conditions. [ABSTRACT FROM AUTHOR]

Published
2017
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43. Physiological Mechanism of Enhancing Salt Stress Tolerance of Perennial Ryegrass by 24-Epibrassinolide.

Author

Wenli Wu, Qiang Zhang, Ervin, Erik. H., Zhiping Yang, and Xunzhong Zhang

Subjects
BRASSINOSTEROIDS, RYEGRASSES, BIOCOMPATIBILITY, PHYSIOLOGY
Abstract

Brassinosteroids (BR) regulate plant tolerance to salt stress but the mechanisms underlying are not fully understood. This study was to investigate physiological mechanisms of 24-epibrassinolide (EBR)'s impact on salt stress tolerance in perennial ryegrass (Lolium perenne L.) The grass seedlings were treated with EBR at 0, 10, and 100 nM, and subjected to salt stress (250 mM NaCl). The grass irrigated with regular water without EBR served as the control. Salt stress increased leaf electrolyte leakage (EL), malondialdehyde (MDA), and reduced photosynthetic rate (Pn). Exogenous EBR reduced EL and MDA, increased Pn, chlorophyll content, and stomatal conductance (gs). The EBR applications also alleviated decline of superoxide dismutase (SOD) and catalase (CAT) and ascorbate peroxidase (APX) activity when compared to salt treatment alone. Salt stress increased leaf abscisic acid (ABA) and gibberellin A4 (GA4) content but reduced indole-3-acetic acid (IAA), zeatin riboside (ZR), isopentenyl adenosine (iPA), and salicylic acid (SA). Exogenous EBR at 10 nm and 100 nM increased ABA, and iPA content under salt stress. The EBR treatment at 100 nM also increased leaf IAA, ZR, JA, and SA. In addition, EBR treatments increased leaf proline and ions (K+, Mg2+, and Ca2+) content, and reduced Na+/K+ in leaf tissues. The results of this study suggest that EBR treatment may improve salt stress tolerance by increasing the level of selected hormones and antioxidant enzyme (SOD and CAT) activity, promoting accumulation of proline and ions (K+, Ca2+, and Mg2+) in perennial ryegrass. [ABSTRACT FROM AUTHOR]

Published
2017
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44. Influence of Ferrous Sulfate and Its Elemental Components on Dollar Spot Suppression.

Author

McCall, David S., Ervin, Erik H., Shelton, Camden D., Reams, Nathaniel, and Askew, Shawn D.

Subjects
*EFFECT of ferrous sulfate on plants, *CREEPING bentgrass, *GRASS disease & pest prevention
Abstract

Dollar spot (caused by Sclerotinia homoeocarpa F.T. Bennett) is a common disease of Agrostis stolonifera L. and is especially devastating on putting greens. Sequential fungicide applications are often required throughout the growing season for adequate control. This research was conducted to determine if ferrous sulfate (FeSO4) and its elemental components are capable of reducing dollar spot development. Trials were established in situ and in vitro to address this objective. Putting green trials were conducted in Blacksburg, VA, during the summers of 2012 and 2015. Biweekly (May to September) foliar treatments were applied in four randomized complete blocks as: control, FeSO4 (48.8 kg ha-1), sulfur (10.3 kg ha-1), and iron chelate (11.2 kg Fe ha-1). Dollar spot infection centers and visual turf quality were recorded throughout the summer. When disease exceeded a threshold of 75 infection centers per plot, chlorothalonil (2,4,5,6-tetrachloroisophthalonitrile, 12.5 kg ha-1 a.i.) and nitrogen fertility (12.2 kg ha-1) were applied to encourage recovery. After recovery, inputs were minimized to encourage dollar spot development. Ferrous sulfate reduced dollar spot pressure each year. Turf quality was improved with FeSO4 in 2012, but not in 2015. Iron chelate suppressed dollar spot in 2012, but not in 2015. Sulfur had no impact on dollar spot or turf quality in either year. Direct fungitoxic activity of FeSO4 against the dollar spot pathogen was evaluated in vitro across a range of pH. Pure cultures of S. homoeocarpa obtained from the field test site were plated on 0.25× potato dextrose agar amended with 0, 10, 100, and 1000 mg kg-1 FeSO4. Mycelial growth was enhanced at 10 mg kg-1, was not affected at 100 mg kg-1, and was completely inhibited at 1000 mg kg-1. These data suggest FeSO4 suppresses dollar spot by acting as a fungistat against the pathogen. [ABSTRACT FROM AUTHOR]

Published
2017
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45. An Integrated Nutritional and Chemical Approach to Poa AnnuaSuppression in Creeping Bentgrass Greens

Author

Ervin, Erik. H., Reams, Nathaniel, Zhang, Xunzhong, Boyd, Adam, and Askew, Shawn

Abstract

Creeping bentgrass (Agrostis stoloniferaL.) provides an ideal putting surface for golf courses located in temperate climates but is invaded by annual bluegrass (Poa annuaL.) and silvery‐thread moss (Bryum argenteumHedw.). There are no currently registered herbicides for annual bluegrass control in bentgrass greens. Paclobutrazol and FeSO4will suppress one or both of these pests, but research on the effectiveness of the two together has not been reported. Our objectives were to determine the effects of repeated high rates of FeSO4and paclobutrazol on transitioning annual bluegrass out of a creeping bentgrass green and determine if seaweed extract (SWE) aids the transition. An unanticipated objective was to assess treatment effects on moss incidence. The effects of all combinations of FeSO4(0.0, 12.2, 24.4, or 48.8 kg ha−1), paclobutrazol (0.18–0.36 kg a.i. ha−1), and SWE (12.8 L ha−1) on control of these pests were investigated over 2 yr on a ‘Penneagle’ green. All FeSO4rates decreased annual bluegrass to 21% when averaged over 2 yr. The paclobutrazol program reduced annual bluegrass to 5% regardless of FeSO4rate. Repeated use of SWE had no effect on annual bluegrass or moss populations. An 8% decline in annual bluegrass occurred in untreated plots, possibly due to creeping bentgrass competition being favored by biweekly application of ammonium sulfate and exclusion of phosphorus and potassium fertilizers. Treatment with FeSO4decreased moss, regardless of paclobutrazol or SWE. Paclobutrazol increased moss when FeSO4was not applied. Season‐long applications of FeSO4(24.4 kg ha−1) plus high rates of paclobutrazol controlled annual bluegrass and silvery‐thread moss while providing a putting surface of acceptable quality.

Published
2017
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46. Differential Responses of Antioxidants, Abscisic Acid, and Auxin to Deficit Irrigation in Two Perennial Ryegrass Cultivars Contrasting in Drought Tolerance.

Author

Xunzhong Zhang, Ervin, Erik H., Yiming Liu, Guofu Hu, Chao Shang, Takeshi Fukao, and Jasper Alpuerto

Subjects
*GRASS research, *PLANT growing media, *ANTIOXIDANTS, *PLANT water requirements, *INDOLEACETIC acid, *SUPEROXIDE dismutase
Abstract

Water deficit is a major limiting factor for grass culture in many regions with physiological mechanisms of tolerance not yet well understood. Antioxidant isozymes and hormones may play important roles in plant tolerance to water deficit. This study was designed to investigate antioxidant enzymes, isozymes, abscisic acid (ABA), and indole-3-acetic acid (IAA) responses to deficit irrigation in two perennial ryegrass (Lolium perenne L.) cultivars contrasting in drought tolerance. The plants were subjected to well-watered {100% container capacity, 34.4% ± 0.21% volumetric moisture content (VWC), or deficit irrigation [30% evapotranspiration (ET) replacement; 28.6% ± 0.15% to 7.5% ± 0.12% VWC]} conditions for up to 8 days and rewatering for 4 days for recovery in growth chambers. Deficit irrigation increased leaf malondialdehyde (MDA) content in both cultivars, but drought-tolerant Manhattan-5 exhibited lower levels relative to drought-sensitive Silver Dollar. Superoxide dismutase (SOD) activity declined and then increased during water-deficit treatment. 'Manhattan-5' had higher SOD activity and greater abundance of SOD1 isozyme than 'Silver Dollar' under water deficit. Deficit irrigation increased catalase (CAT) and ascorbate peroxidase (APX) activity in 'Manhattan-5', but not in 'Silver Dollar'. 'Manhattan-5' had higher CAT, APX, and peroxidase (POD) activity than 'Silver Dollar' during water limitation. Deficit irrigation increased mRNA accumulation of cytosolic cupper/zinc SOD (Cyt Cu/Zn SOD), whereas gene expression of manganese SOD (Mn SOD) and peroxisome APX (pAPX) were not significantly altered in response to deficit irrigation. No differences in Cyt Cu/Zn SOD, Mn SOD, and pAPX gene expression were found between the two cultivars under deficit irrigation. Water limitation increased leaf ABA and IAA contents in both cultivars, with Silver Dollar having a higher ABA content than Manhattan-5. Change in ABA level may regulate stomatal opening and oxidative stress, which may trigger antioxidant defense responses. These results indicate that accumulation of antioxidant enzymes and ABA are associated with perennial ryegrass drought tolerance. Activity and isozyme assays of key antioxidant enzymes under soil moisture limitation can be a practical screening approach to improve perennial ryegrass drought tolerance and quality. [ABSTRACT FROM AUTHOR]

Published
2015
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47. Factors governing zoysiagrass response to herbicides applied during spring green-up

Author

Craft, Jordan Michael, Plant Pathology, Physiology and Weed Science, Askew, Shawn D., Ervin, Erik H., Goatley, James Michael, Zhang, Xunzhong, and McCall, David S.

Subjects
weed control, spray deposition, glyphosate, Zoysia japonica Steud, heat unit, Zoyisagrass, spring green-up, glufosinate, Zoysia matrella (L) Merr, dormant zoysiagrass, growing-degree-days, herbicide absorption and translocation
Abstract

Zoysiagrass (Zoysia spp.) is utilized as a warm-season turfgrass because of its density, visual quality, stress tolerance, and reduced input requirements. Turf managers often exploit winter dormancy in warm-season turfgrass to apply nonselective herbicides such as glyphosate and glufosinate to control winter annual weeds. Although this weed control strategy is common in bermudagrass (Cynodon spp.), it has been less adopted in zoysiagrass due to unexplainable turf injury. Many university extension publications recommend against applying nonselective herbicides to dormant zoysiagrass despite promotional language found in a few peer-reviewed publications and product labels. Previous researchers have used vague terminology such as "applied to dormant zoysiagrass" or "applied prior to zoysiagrass green-up" to describe herbicide application timings. These ambiguous terms have led to confusion since zoysiagrass typically has subcanopy green leaves and stems throughout the winter dormancy period. No research has sought to explain why some turfgrass managers are observing zoysiagrass injury when the literature only offers evidence that these herbicides do not injure dormant zoysiagrass. We sought to explore various herbicides, prevailing temperatures surrounding application, heat unit based application timings, and spray penetration into zoysiagrass canopies as possible contributors to zoysiagrass injury. The results indicated that a wide range of herbicides may be safely used in dormant zoysiagrass. However, as zoysiagrass begins to produce more green leaves, herbicides such as metsulfuron, glyphosate, glufosinate, flumioxazin, and diquat become too injurious. Glufosinate was consistently more injurious regardless of application timing than glyphosate and other herbicides. When temperatures were 10 °C for 7 d following treatment, a delayed effect of glyphosate and glufosinate effect on digitally-assessed green cover loss was noted on zoysiagrass sprigs. In subsequent studies on turf plugs, a 14-d incubation period at 10 °C reduced glyphosate but not glufosinate effects on turf green color reduction. Glyphosate applied at 125, and 200 GDD5C can safely be applied to zoysiagrass while glufosinate applied at the same timings caused inconsistent and often unacceptable zoysiagrass injury in field studies conducted at Blacksburg, VA, Starkville, MS, and Virginia Beach, VA. Zoysiagrass green leaf density was described as a function of accumulated heat units consistently across years and locations but variably by turf mowing height. Turf normalized difference vegetative index was primarily governed by green turf cover but reduced by herbicide treatments, especially when applied at greater than 200 GDD5C. Substantial spray deposition occurred to subcanopy tissue regardless of nozzle type, pressure and height above the zoysiagrass canopy based on spectrophotometric assessment of a colorant admixture. However, increasing nozzle height above the turf canopy and avoiding air induction type nozzles significantly reduced the percentage of green tissue exposed at lower canopy levels. Absorption of radio-labeled glyphosate and glufosinate was up to four times greater when exposed to zoysiagrass stems compared to leaves. Glyphosate translocated more than glufosinate and both herbicides moved more readily from stem to leaf than from leaf to stem Doctor of Philosophy Zoysiagrass (Zoysia spp.) is utilized as a warm-season turfgrass because of its density, visual quality, stress tolerance, and reduced input requirements. Being that zoysiagrass is a warm-season turfgrass, it enters a dormancy period during the winter months. During this period, zoysiagrasses' active growth is halted, and leaves lose their green color and turn a golden-brown color. The winter dormancy period presents turfgrass managers with a unique opportunity to apply nonselective herbicides such as glyphosate and glufosinate to control a broad spectrum of winter annual weeds. Although this weed control strategy is common in bermudagrass (Cynodon spp.), it has been less adopted in zoysiagrass due to turfgrass managers observing unexplainable turfgrass injury. Many university extension publications recommend against applying nonselective herbicides to dormant zoysiagrass despite language found in peer-reviewed publications and product labels suggesting they could be safely applied. Previous researchers have used vague terminology such as "applied to dormant zoysiagrass" or "applied prior to zoysiagrass green-up" to describe herbicide application timings. These terms have led to confusion about when to make these applications since zoysiagrass typically has subcanopy green leaves and stems throughout the winter dormancy period. No research has sought to explain why some turfgrass managers observe zoysiagrass injury when the literature only offers evidence that these herbicides do not injure dormant zoysiagrass. Research projects were designed to explore various herbicides, temperatures surrounding herbicide applications, application timings, and spray penetration into zoysiagrass canopies as possible contributors to zoysiagrass injury. The results indicated that a wide range of herbicides may be safely used in dormant and semidormant zoysiagrass. However, as zoysiagrass begins to produce more green leaves and stems, herbicides such as metsulfuron, glyphosate, glufosinate, flumioxazin, and diquat become too injurious and should be avoided. Across multiple research studies, glufosinate was consistently more injurious regardless of application timing than glyphosate and other herbicides. When temperatures were 10 °C for 7-d following treatment, it delayed zoysaigrass response to glyphosate and glufosinate. In a subsequent study, when temperatures were at 10 °C for a 14-d period, glyphosate and the nontreated reached 50% green cover at the same time, which suggests cold temperatures could mitigate glyphosate injury on zoysiagrass over a 14-d period. The 10 ° temperature only delayed glufosinate injury on zoysiagrass, and no safening was observed. The results also indicated that as temperatures increased, glyphosate and glufosinate rate in which injury was observed increased on the zoysiagrass. Glyphosate applied at 125, and 200 GDD5C can safely be applied to zoysiagrass while glufosinate applied at the same timings caused inconsistent and often unacceptable zoysiagrass injury in field studies conducted at Blacksburg, VA, Starkville, MS, and Virginia Beach, VA. Zoysiagrass injury increased when glyphosate and glufosinate were applied later into the spring when more green leaves were present regardless of location. Accumulated heat units and zoysiagrass green leaf density were closely related, indicating that accumulated heat units could be a useful tool for turfgrass managers to track zoysiagrass spring green-up. Substantial spray deposition was found on subcanopy zoysiagrass leaves and stems regardless of nozzle type, pressure, and height above the zoysiagrass canopy based on recovered colorant at the upper, middle and lower levels of the zoysiagrass canopy. However, avoiding air induction-type nozzles and raising spray height may slightly decrease penetration of spray droplets into a zoysiagrass subcanopy, but a large percentage of droplets still reached the middle and lower canopy layers in this research. Absorption of radio-labeled glyphosate and glufosinate was up to four times greater when applied directly to zoysiagrass stolen compared to leaves. Glyphosate translocated more than glufosinate, and both herbicides moved more readily from stem to leaf than from leaf to stem. These data suggest limiting the number of green zoysiagrass leaves at application would be an effective method to avoid injury zoysiagrass when applying nonselective herbicides

Published
2021

48. Biosolids as a source of soil conditioning and fertility for turfgrass

Author

Badzmierowski, Mike J., Crop and Soil Environmental Sciences, Evanylo, Gregory K., Ervin, Erik H., Xia, Kang, and Strahm, Brian D.

Subjects
anthropogenically disturbed urban soils, Nitrogen, carbon, biosolids, Phosphorus
Abstract

Wastewater treatment plants are shifting towards producing exceptional quality (EQ) biosolids to increase recycling rates to land, especially urban areas. Other methods of improving the environmental impact of wastewater treatment includes additions of iron (Fe) to reduce phosphorus (P) concentrations in outgoing treated water and precipitate the P into the biosolids. Proper management of biosolids to rehabilitate anthropogenically disturbed urban soils for improved plant growth and effects on the cycling of nutrients requires further study. Our objectives were: 1) to determine whether various EQ biosolids could be managed to improve degraded soil properties and turfgrass quality while minimizing risk of P loss in a field study; and 2) to use spectral reflectance data to compare relationships of vegetation indices to soil and turfgrass parameters. We found that after an initial lag-time of one year, biosolids amendments increased turfgrass clipping biomass and aesthetic quality greater than did synthetic fertilizer. Repeated topdressing applications of biosolids reduced soil bulk density and increased soil organic carbon (OC) and nitrogen (N) stocks. Biosolids applied at the agronomic N rate did not increase water-soluble P (15 and 18 mg P kg-1 of soil) compared to biosolids applied at the agronomic P rate (9.6 mg P kg-1 of soil) and synthetic fertilizer (13 mg P kg-1 of soil) after five years. We further demonstrated at this field site that collecting continuous data improves spectral reflectance vegetation indices relationships to turfgrass quality, clipping biomass, and tissue N accumulation. Soil volumetric water content was best correlated to the water band index (r = 0.60) and the green-to-red ratio index (r = 0.54) vegetation indices. Differences in soil and turfgrass measured parameters were best detected when there was drought-stressed versus irrigated turfgrass. Doctor of Philosophy Biosolids are the sanitized and nutrient-rich organic solids and semi-solids resulting from treatment of wastewater. The nutrient-rich organic solids provide plant-essential elements (e.g., nitrogen) and can improve soil physical parameters such as soil compaction. Wastewater treatment plants are adopting processes that produce cleaner, exceptional quality (EQ) biosolids to increase biosolids recycling rates to land, especially to urban areas to improve urban soil quality. Adding iron to treated wastewater further improves the quality of biosolids and effluent released to surface water by removing phosphorus from wastewater and concentrating this essential plant nutrient within biosolids. Our research objectives were to quantify the potential benefits of EQ biosolids for improving degraded urban soils, providing sufficient plant available nitrogen to improve turfgrass quality, avoiding increasing soil phosphorus to levels that could result in pollution, and increasing the long-term storage of soil carbon to mitigate climate change. We learned that biosolids were the best long-term solution for providing a high quality turfgrass stand and improve soil properties. Repeated applications of EQ biosolids reduced soil bulk density and increased soil organic carbon and nitrogen stocks. The increased iron in the biosolids reduced water-soluble phosphorus and may reduce phosphorus loss to surface waters.

Published
2019

49. Improved Strategies for Dollar Spot Suppression Using Ferrous Sulfate

Author

Shelton, Camden Drake, Plant Pathology, Physiology, and Weed Science, McCall, David S., Askew, Shawn D., and Ervin, Erik H.

Subjects
dollar spot, ferrous sulfate, turfgrass pathology
Abstract

Dollar spot is one of the most common diseases of warm- and cool-season turfgrass stands and is especially devastating on creeping bentgrass (Agrostis stolonifera L.). The fungus Sclerotinia homoeocarpa degrades the foliage by creating silver, dollar-sized depressions of dead and bleached turf. Frequent fungicide applications and cultural management strategies are required throughout the growing season to prevent or reduce severity of this disease. Previous research has demonstrated that ferrous sulfate applied at 48.8 kg ha-1 suppresses dollar spot epidemics without traditional fungicides. In vitro studies showed 100 to 1,000 mg kg-1 of ferrous sulfate directly suppressed S. homoeocarpa growth of an isolate collected from an established, intensively-maintained creeping bentgrass putting green. Genetic diversity of S. homoeocarpa segregates isolates into two groups; strains generally associated with warm-season and cool-season grasses. It is unknown whether isolates of each group react similarly in the presence of ferrous sulfate. Our research explored use rates of ferrous sulfate required to suppress 50% of dollar spot in the field and in vitro. Ferrous sulfate (heptahydrate 20% Fe, Valudor Products Inc) rates in field trials included 0, 4.88, 24.4, 48.8, and 97.6 kg ha-1. Our results indicate a hyperbolic relationship between ferrous sulfate rate and dollar spot reduction. Using this model, 26.4 kg ha-1 reduced dollar spot incidence by 50%. We concluded that ferrous sulfate suppresses 50% of S. homoeocarpa mycelial growth at between 480 and 720 mg L-1 concentration in 0.25 strength potato dextrose agar in vitro, and fungitoxic activity of ferrous sulfate was dependent primarily on historical fungicide inputs at isolate collection sites. The use of ferrous sulfate may supplement traditional fungicide use. Chlorothalonil is the most common fungicide used to suppress dollar spot in turfgrass. Annual site-use limitations of chlorothalonil often prevent turf managers from achieving acceptable dollar spot control throughout the season. It is not known how ferrous sulfate may contribute to a successful chlorothalonil fungicide program. Therefore, we examined whether ferrous sulfate can be used to minimize chlorothalonil requirements through reducing active ingredient concentrations and extending the longevity, while still maintaining acceptable disease control. Chlorothalonil treatments were applied at 0, 2.28, 4.57, 6.86, and 9.16 kg ai ha-1 (Daconil WeatherStik) across plots treated with and without 48.8 kg ha-1 ferrous sulfate applied bi-weekly. Ferrous sulfate reduced the chlorothalonil rates necessary for 80% disease reduction by 36 to 51% across all trials. Additional studies showed that ferrous sulfate applied with chlorothalonil increased duration of disease control by five days and eliminated two seasonal treatments. Our research expands the guidelines for practical ferrous sulfate usage for dollar spot suppression by elucidating the rate-to-disease relationship and providing best management practices involving admixtures with chlorothalonil. Master of Science Turfgrass systems offer many environmental and recreational benefits. Managing turfgrass stands that are free of damaging turf pests is essential to providing aesthetically pleasing lawns, golf courses, and sports fields. Creeping bentgrass is one of the most common turfgrass types found on golf course putting greens but is also used on golf course fairways and tee boxes. There are many diseases that can be found on creeping bentgrass when environmental conditions are favorable. Of these diseases, dollar spot is the most common. When dollar spot is present, half-dollar sized spots of bleached turf can be seen. In order to prevent these easily noticeable spots from appearing, fungicide applications are required in a given growing season to prevent the pathogen from infecting. Available fungicides are very effective at providing control but can be very costly. Beyond fungicide use, other research has shown various cultural practices to reduce disease incidence. Previous research has shown that iron sulfate applied to creeping bentgrass can reduce dollar spot epidemics without the use of fungicides. Laboratory studies have shown a similar trend as ferrous sulfate at varying concentrations directly suppressed dollar spot pathogen growth. In both cases, a limited range of ferrous sulfate rates was tested. To obtain more information we explored use rates of ferrous sulfate required to suppress 50% of dollar spot in the field and in vitro. Ferrous sulfate rates in field trials ranged from 0 to 97.6 kg ha⁻¹ . Results from these trials were used to create a hyperbolic regression. Using this model, we were then able to determine that 26.4 kg ha⁻¹ iron sulfate was required to suppress 50% of the dollar spot in the field. For the laboratory studies we concluded that ferrous sulfate suppresses 50% of the dollar spot pathogen mycelial growth between 480 and 720 mg L ⁻¹ iron sulfate concentrated potato dextrose agar. Although there are many different fungicides available for dollar spot control, the active ingredient chlorothalonil is the most common used. Due to the mode of action which chlorothalonil exhibits, it is much less likely that the pathogen causing dollar spot can become resistant. Although resistance is not an issue, governmental annual site-use limitations restrict turf managers from achieving desirable control. The use of iron sulfate in conjunction with chlorothalonil has not been previously studied. Chlorothalonil treatments were applied at a range of labeled use rates across plots treated with and without 48.8 kg ha⁻¹ ferrous sulfate applied bi-weekly. Ferrous sulfate reduced the chlorothalonil rates necessary for disease reduction. If a threshold of 80% is used, up to 50% reduction in chlorothalonil use was observed. Supplemental studies investigating the duration of control achieved by the combination showed an increase of up to 5 days and eliminated the need for two applications across one season. This research fills a huge gap in our knowledge base on the practical use of iron sulfate for dollar spot control.

Published
2018

50. Influence of Annual Bluegrass on Putting Green Trueness and Control of Weedy Poa Species in Kentucky Bluegrass and Creeping Bentgrass Turf

Author

Rana, Sandeep Singh, Plant Pathology, Physiology, and Weed Science, Askew, Shawn D., Barney, Jacob, Goatley, James Michael, and Ervin, Erik H.

Subjects
methiozolin, Poa pratensis L, Annual bluegrass, ball roll, creeping bentgrass, putting green uniformity and smoothness, putting green trueness, Kentucky bluegrass, roughstalk bluegrass, Poa annua L, Agrostis stolonifera L, Poa trivialis L
Abstract

Annual bluegrass (Poa annua L.) and roughstalk bluegrass (Poa trivialis L.) are among the most troublesome grass weeds on golf courses throughout the United States. Herbicides for selective control of these weeds in cool-season fairways are limited and ineffective. Methiozolin is a new isoxazoline herbicide that controls annual bluegrass on putting greens and shows promise for possible weed control in fairways. Kentucky bluegrass (Poa pratensis L.) is among the most common turfgrass species used for golf fairways in the Northern United States and its response to methiozolin has scarcely been tested. A 2.5-yr field study was conducted at four Virginia locations to evaluate methiozolin efficacy for selective annual bluegrass and roughstalk bluegrass control in creeping bentgrass (Agrostis stolonifera L.) or Kentucky bluegrass fairways. Another study evaluated the response of 110 Kentucky bluegrass varieties to three rates of methiozolin. Annual bluegrass has long been presumed to impact putting green trueness, or the ability of the greens canopy to provide a smooth and directionally-consistent ball roll. Although much research has evaluated the impact of greens management on ball roll distance, no peer-reviewed research has evaluated how canopy surface factors, such as weedy annual bluegrass, will influence ball roll direction. Laboratory and field research was conducted to elucidate and overcome experimental errors that may be limiting assessment of ball directional imprecision caused by greens canopy anomalies. Techniques to minimize experimental error were employed in field studies at two Virginia golf courses to determine the influence of annual bluegrass on ball directional imprecision, bounce, and acceleration. Study results suggest that annual bluegrass patches in a creeping bentgrass putting surface can cause subtle increases in ball directional imprecision and bounce but several sources of error must be controlled before these effects can be measured. By using a mechanical putter to avoid directional errors associated with simulated-putt devices, selecting golf balls with balanced centers of gravity, eliminating legacy or "tracking" effects of repeated ball rolls via canopy brushing, and scoring ball direction 30 cm prior to terminal acceleration, we were able to detect an increase in ball directional imprecision of 8 mm m⁻¹ when balls rolled over a single patch of annual bluegrass compared to adjacent rolls on visually-pure creeping bentgrass. In herbicide efficacy studies, methiozolin-only treatments did not significantly injure creeping bentgrass or Kentucky bluegrass, reduce quality, or reduce normalized difference vegetative index regardless of application timings and rates. In general, fall applications of methiozolin reduced roughstalk bluegrass and annual bluegrass cover more than the spring-only treatments. At 1 year after the last treatment, methiozolin at 1500 g ha⁻¹ applied four times in fall at 2-wk intervals for two consecutive years controlled roughstalk bluegrass and annual bluegrass ≥85% and more consistently than other herbicides or treatment regimes. Spanning 110 Kentucky bluegrass varieties, a commercially-acceptable threshold of 30% Kentucky bluegrass injury required between 3.4 to more than 10 times the methiozolin rate needed for annual bluegrass control. Results indicate that annual bluegrass increases directional imprecision and bounce of golf balls rolling across a greens canopy. Methiozolin could be a viable herbicide for managing annual and roughstalk bluegrass in Kentucky bluegrass and creeping bentgrass fairways but weed control efficacy may be dependent on application timing. By measuring small differences in ball directional imprecision as influenced by greens canopy factors, future research efforts will aim to help turf managers choose appropriate greens management techniques. Ph. D.

Published
2016

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