Abundance of Macrophomina phaseolina (Tassi) Goid from soybean fields in the Departament of Itapúa-Paraguay

Authors

  • Marco Maidana-Ojeda Centro de Desarrollo e Innovación Tecnológica (CEDIT). Hohenau, Itapúa, Paraguay. https://orcid.org/0000-0002-1578-7454
  • Julio César Sosa-Gerke Universidad Católica “Nuestra Señora De La Asunción” Campus Universitario De Itapúa, Unidad Pedagógica María Auxiliadora, Tomás Romero Pereira. Itapúa, Paraguay
  • Claudia Elizabeth Bogado-González Universidad Católica “Nuestra Señora De La Asunción” Campus Universitario de Itapúa. Unidad Pedagógica María Auxiliadora, Tomás Romero Pereira. Itapúa, Paraguay
  • Marta Alicia Fernández-Gamarra Centro de Investigación Capitán Miranda. Instituto Paraguayo de Tecnología Agraria. Itapúa, Paraguay
  • Andrés Dejesús Sanabria-Velázquez Centro de Desarrollo e Innovación Tecnológica (CEDIT). Hohenau, Itapúa, Paraguay. https://orcid.org/0000-0002-8694-3725
  • Horacio Daniel López-Nicora Universidad San Carlos. Departamento de Producción Agrícola. Asunción, C.P. 1884, Paraguay. https://orcid.org/0000-0002-9672-9589
  • Guillermo Andrés Enciso-Maldonado Centro de Desarrollo e Innovación Tecnológica (CEDIT). Hohenau, Itapúa, Paraguay. https://orcid.org/0000-0002-9528-7627

DOI:

https://doi.org/10.47133/IEUNA2027

Keywords:

charcoal rot, Glycine max, soilborne pathogen, crop rotation

Abstract

The density of viable microsclerotia of the plant pathogen Macrophomina phaseolina in the soil is related to the intensity of the charcoal rot, which causes significant reductions in soybean yield in Paraguay. During January 2017 and again in May 2019, soil samplings were carried out in soybean plots in 5 districts of the Department of Itapúa (Edelira, Tomás Romero Pereira, Capitán Meza, Natalio and San Rafael), during the reproductive phenological stages (R1-R7) with the objective of quantifying the amount of M. phaseolina inoculum in soils with soybean crops. At the time of sampling, a questionnaire was carried out to the owners about the previous crop rotation in their fields. The presence of M. phaseolina was detected in 100 % of the sampled points. The inoculum density varied from 7 to 147 CFU/g of soil, with an average of 51 CFU/g of soil and a median of 48 CFU/g of soil in 2017, while in 2019 the inoculum density varied from 6 to 49 CFU/g of soil, with an average of 25 CFU/g of soil and a median of 23 CFU/g of soil. Lower inoculum density was observed in plots with canola-soybean-soybean crop rotation with averages of 30 and 12 CFU/g of soil. Our results will make it possible to identify areas with high initial populations of M. phaseolina to inform producers in these areas and create a pool of farms where future experiments can be established in commercial fields.

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References

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Published

2020-12-22

How to Cite

Maidana-Ojeda, M., Sosa-Gerke, J. C., Bogado-González, C. E., Fernández-Gamarra, M. A., Sanabria-Velázquez, A. D., López-Nicora, H. D., & Enciso-Maldonado, G. A. (2020). Abundance of Macrophomina phaseolina (Tassi) Goid from soybean fields in the Departament of Itapúa-Paraguay. Journal Investigaciones Y Estudios - UNA , 11(2), 69–77. https://doi.org/10.47133/IEUNA2027

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