Published January 13, 2021
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Nematicide effects on arthropods in bermudagrass
Authors/Creators
- 1. University of Florida, Department of Entomology and Nematology, Gainesville, Florida 32611-0620, USA; E-mail: bwaldo@ufl.edu (B. W.), wtcr@ufl.edu (W. C.)
- 2. with 0.6 m untreated borders between adjacent plots. Data were collected from 1.5 m & subplots located in the center of the treatment plots. Nematicides were applied at labeled rates every 4 wk as a summer treatment program from 7 Jun to 30 Aug 2016 and from 24 Apr to 18 Jul 2017 at the University of Florida Plant Science Research and Education Unit in Citra, Florida, USA. Samples were collected before treatment and at 2 d, 14 d, 56 d, and 238 d afer the final treatment. Data from each nematicide treatment were compared to the untreated data at each sample date using analysis of covariance with initial population counts serving as the covariate. Abamectin treatments significantly increased fungivore mite abundance relative to the untreated control at 2 sampling dates in 2016 and 3 sampling dates in 2017. Abamectin also decreased collembolan abundance significantly at 2 sampling dates in 2017. Fluopyram increased predatory mite abundance significantly at 3 sampling dates in 2016; decreased collembolan abundance significantly at 4 sampling dates in 2017; and significantly increased phytophagous insect abundance at 2 dates in 2017. Furfural and fluensulfone had low impacts on arthropod abundance. The results of this study suggest nematicides can impact arthropods in bermudagrass, which could affect organic matter decomposition and nutrient cycling processes. & con 0,6 m de bordes sin tratar entre parcelas adyacentes. Los datos se recolectaron de subparcelas de 1,5 m & ubicadas en el centro de las parcelas de tratamiento. Los nematicidas se aplicaron a las dosis indicadas cada 4 semanas como un programa de tratamiento de verano desde el 7 de junio al 30 de agosto del 2016 y desde el 24 de abril al 18 de julio del 2017 en el Unidad de Educación e Investigación en Ciencias Vegetales de la Universidad de Florida en Citra, Florida, EE. UU. Las muestras se recolectaron antes del tratamiento y a los 2 días, 14 días, 56 días, y 238 días después del tratamiento final. Los datos de cada tratamiento con nematicida se compararon con los datos no tratados en cada fecha de muestra utilizando un análisis de covarianza con los recuentos de población iniciales que sirven como covariables. Los tratamientos con abamectina aumentaron significativamente la abundancia de ácaros fungívoros en relación con el control no tratado en 2 fechas de muestreo en el 2016 y 3 fechas de muestreo en el 2017. La abamectina también disminuyó significativamente la abundancia de colémbolas en 2 fechas de muestreo en el 2017. Fluopiram aumentó significativamente la abundancia de ácaros depredadores en 3 fechas de muestreo en el 2016; disminuyó significativamente la abundancia de colémbolos en 4 fechas de muestreo en el 2017; y aumentó significativamente la abundancia de insectos fitófagos en 2 fechas en el 2017. El furfural y la fluensulfona tuvieron un bajo impacto en la abundancia de artrópodos. Los resultados de este estudio sugieren que los nematicidas pueden afectar a los artrópodos en el pasto bermuda, lo que podría afectar la descomposición de la materia orgánica y los procesos de ciclo de nutrientes. & Florida Department of Agriculture and Consumer Services, Department of Plant Industry, Gainesville, Florida 32608, USA;
Description
Waldo, Benjamin, Soto-Adames, Felipe, Crow, William (2021): Nematicide effects on arthropods in bermudagrass. Florida Entomologist 103 (4): 458-464, DOI: 10.1653/024.103.00407, URL: http://dx.doi.org/10.1653/024.103.00407
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