{"id":36415,"date":"2024-09-17T00:01:26","date_gmt":"2024-09-17T04:01:26","guid":{"rendered":"https:\/\/beyondpesticides.org\/dailynewsblog\/?p=36415"},"modified":"2024-09-13T10:54:11","modified_gmt":"2024-09-13T14:54:11","slug":"pesticide-residue-impacts-microbial-health","status":"publish","type":"post","link":"https:\/\/beyondpesticides.org\/dailynewsblog\/2024\/09\/pesticide-residue-impacts-microbial-health\/","title":{"rendered":"Pesticide Residue Impacts Microbial Health"},"content":{"rendered":"

(Beyond Pesticides, September 17, 2024) Today, International Microorganism Day<\/a>, is a prime moment to focus on the complexity of billions of living beings that establish the foundation of land management and food production. Organic advocates, community members, and farmers identify the protection and enhancement of biological diversity in the soil as a key goal, especially in light of mounting concerns over rising microbial resistance to chemical-intensive practices.<\/p>\n

A recent article in British Journal of Environmental Sciences<\/em><\/a> points to several microbial populations adversely affected by pesticide-contaminated soil on various farmland plots in Nigeria. There are significant variations in bacteria presence between pesticide-treated and control plots, with a lab analysis finding \u201c[s]eventy-five percent (75%) of pesticide residue was detected in the soil samples,\u201d which includes paraquat dichloride<\/a>, endosulfan<\/a>, diazinon<\/a>, and N-(phosponomethyl)glycine [glyphosate<\/a>]. This report builds on years of research from higher education institutions worldwide, including participatory research centering applied experiments on farmland, demonstrating the consequences of relying on pesticide-intensive agriculture and land management.<\/p>\n

The main goal of this report is to \u201cdetermine the influence of pesticide contamination on the microbial population, physiochemical parameters and pesticide residue of soil of selected farmlands in Otuoke, Bayelsa State, Nigeria.\u201d Researchers document the presence of eleven different bacteria isolates and sixteen different fungi across four different farmland sites (with one site serving as the control in which no pesticides were sprayed during the course of the experiment), since researchers identified in previous research that several selected bacteria \u201cthrive as a response to environmental stress, possibly induced by pesticide contamination.\u201d [The sites are identified as Bakery 1, Bakery 2, Dorcas, PGS, and Control.]<\/p>\n

Researchers found high variability between levels of different bacteria and fungi across the experimental and control sites, indicating that pesticide contamination influences microbial activity. Across all five sites, there was relatively higher microbial activity at the control site corresponding with limited pesticide residue (except a small presence of paraquat across all sites). For example, the highest occurrence of beneficial fungi including Trichoderma <\/em>species (14.3%), Lichtheimia hyalospora <\/em>(28.6%), Penicillium camemberti<\/em> (14.3%), as well as beneficial bacteria including Streptomyces coelicolor<\/em> (29.4%), were found at the control site.<\/p>\n

Some additional main takeaways include:<\/p>\n