Evidence for the importance of litter as a co-substrate for MCPA dissipation in an agricultural soil

Saleh, Omar; Pagel, Holger; Enowashu, Esther; Devers, Marion; Martin-Laurent, Fabrice; Streck, Thilo; Kandeler, Ellen; Poll, Christian

doi:10.1007/s11356-015-4633-1

Cited by 11 publications

(3 citation statements)

References 65 publications

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“…Therefore, we used experimental data from previous studies to evaluate models’ performance. Short-term experiments showed that both 2,4-D and MCPA are readily degradable compounds which do not persist in soil. − Some experiments have reported no 2,4-D and MCPA residues or residues below detection limit after 1 to 5 weeks. ,− …”

Section: Resultsmentioning

confidence: 99%

Gene-Centric Model Approaches for Accurate Prediction of Pesticide Biodegradation in Soils

Rodriguez

Ingalls

Schwarz

et al. 2020

Environ. Sci. Technol.

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Pesticides are widely used in agriculture despite their negative impact on ecosystems and human health. Biogeochemical modeling facilitates the mechanistic understanding of microbial controls on pesticide turnover in soils. We propose to inform models of coupled microbial dynamics and pesticide turnover with measurements of the abundance and expression of functional genes. To assess the advantages of informing models with genetic data, we developed a novel “gene-centric” model and compared model variants of differing structural complexity against a standard biomass-based model. The models were calibrated and validated using data from two batch experiments in which the degradation of the pesticides dichlorophenoxyacetic acid (2,4-D) and 2-methyl-4-chlorophenoxyacetic acid (MCPA) were observed in soil. When calibrating against data on pesticide mineralization, the gene-centric and biomass-based models performed equally well. However, accounting for pesticide-triggered gene regulation allows improved performance in capturing microbial dynamics and in predicting pesticide mineralization. This novel modeling approach also reveals a hysteretic relationship between pesticide degradation rates and gene expression, implying that the biodegradation performance in soils cannot be directly assessed by measuring the expression of functional genes. Our gene-centric model provides an effective approach for exploiting molecular biology data to simulate pesticide degradation in soils.

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Section: Resultsmentioning

confidence: 99%

Gene-Centric Model Approaches for Accurate Prediction of Pesticide Biodegradation in Soils

Rodriguez

Ingalls

Schwarz

et al. 2020

Environ. Sci. Technol.

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“…Little is known about the effects these herbicides and organic residues have on the various groups of soil microorganisms when they are applied jointly. Most of the studies on soil microbial response to pesticides and organic residues have been assessed at laboratory or greenhouse scale [6,14,[22][23][24][25], but only a few assays have been performed at field scale [13,19]. Moreover, only one study has been found in the literature that refers to the impact on soil microbial activity of the combined application of the herbicide chlorotoluron with organic residues under field conditions [11].…”

Section: Introductionmentioning

confidence: 99%

Soil Microbial Community Changes in a Field Treatment with Chlorotoluron, Flufenacet and Diflufenican and Two Organic Amendments

et al. 2020

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The soil microbial activity, biomass and structure were evaluated in an unamended (S) and organically amended soil treated with two commercial formulations of the herbicides chlorotoluron (Erturon®) and flufenacet plus diflufenican (Herold®) under field conditions. Soils were amended with spent mushroom substrate (SMS) or green compost (GC). Soil microbial dehydrogenase activity (DHA), biomass and structure determined by the phospholipid fatty acid (PLFA) profiles were recorded at 0, 45, 145, 229 and 339 days after herbicide treatment. The soil DHA values steadily decreased over time in the unamended soil treated with the herbicides, while microbial activity was constant in the amended soils. The amended soils recorded higher values of concentrations of PLFAs. Total soil microbial biomass decreased over time regardless of the organic amendment or the herbicide. Herbicide application sharply decreased the microbial population, with a significant modification of the microbial structure in the unamended soil. In contrast, no significant differences in microbial biomass and structure were detected in S + SMS and S + GC, untreated or treated with herbicides. The application of SMS and GC led to a significant shift in the soil microbial community regardless of the herbicides. The use of SMS and GC as organic amendments had a certain buffer effect on soil DHA and microbial biomass and structure after herbicide application due to the higher adsorption capacity of herbicides by the amended soils.

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“…Also, it has been indicated a significant early impact and a relevant late impact on the bacterial community when the application of pethoxamid and glyphosate to soil was carried out (Valverde et al, 2014). Saleh et al (2016) have reported signs of toxic effects on soil bacteria at high herbicide (MCPA) concentrations. Karpouzas et al (2014) have reported the inhibitory effects of nicosulfuron on Actinobacteria at rates 20 times higher than the recommended ones.…”

Section: Phospholipid Fatty Acid Profile Analysismentioning

confidence: 99%

Pethoxamid dissipation and microbial activity and structure in an agricultural soil: Effect of herbicide rate and organic residues

Rodríguez‐Cruz

Pose-Juan

Marín-Benito

et al. 2019

Applied Soil Ecology

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Highlights The effect of pethoxamid doses and amendments on soil microbial community was evaluated. The dissipation rate of pethoxamid decreased with the dose applied. Organic amendments accelerated the dissipation of higher doses of pethoxamid.  Higher soil dehydrogenase activity values are close to the half-life of herbicide. Effects of pethoxamid dose on soil microbial structure were recorded in amended soils.

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Evidence for the importance of litter as a co-substrate for MCPA dissipation in an agricultural soil

Cited by 11 publications

References 65 publications

Gene-Centric Model Approaches for Accurate Prediction of Pesticide Biodegradation in Soils

Gene-Centric Model Approaches for Accurate Prediction of Pesticide Biodegradation in Soils

Soil Microbial Community Changes in a Field Treatment with Chlorotoluron, Flufenacet and Diflufenican and Two Organic Amendments

Pethoxamid dissipation and microbial activity and structure in an agricultural soil: Effect of herbicide rate and organic residues

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