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Journal of Applied & Environmental Microbiology
ISSN (Print): 2373-6747 ISSN (Online): 2373-6712 Website: https://www.sciepub.com/journal/jaem Editor-in-chief: Sankar Narayan Sinha
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Issue 1, Volume 13
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Journal of Applied & Environmental Microbiology. 2025, 13(1), 1-6
DOI: 10.12691/jaem-13-1-1
Open AccessArticle

Unregulated Use of Glyphosate Herbicide Has Effect on the Abundance of the Microbiota and Nutrient in the Soil

Kilaza Samson Mwaikono1, and Hamis Mkinga James2

1Department of Science and Laboratory Technology, Dar es salaam Institute of Technology, P. O Box 2958, Dar es salaam, Tanzania

2School of Aquatic Science and Fisheries Technology, University of Dar es salaam, P. O BOX 60091, Dar es salaam. Tanzania

Pub. Date: December 30, 2024
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Cite this paper:
Kilaza Samson Mwaikono and Hamis Mkinga James. Unregulated Use of Glyphosate Herbicide Has Effect on the Abundance of the Microbiota and Nutrient in the Soil. Journal of Applied & Environmental Microbiology. 2025; 13(1):1-6. doi: 10.12691/jaem-13-1-1

Abstract

There is a growing usage of herbicides in agriculture to improve productivity, however, there is limited studies on the effect of herbicides to the soil microbiota and nutrients. This study assessed the effect of glyphosate herbicide on the abundance and activity of soil microbiota on the agricultural soil at Kauzeni village, Morogoro, Tanzania. Two groups of soil samples; 15 from soil with herbicides, and another 15 without herbicide application were assessed. Abundance of bacteria and fungi were determined using culture-based method, while soil organic matter and Nitrogen were determined using muffle furnace and Kjeldahl methods, respectively. Bacterial load in soil with glyphosate was found to be (1.5±0.4) ×105 CFU/mL and without herbicide (2.2±0.4) x105 CFU/mL. The fungi load in soil with herbicides was (1.2±0.5) ×105 CFU/mL and without (1.8 ± 0.5) ×105 CFU/ml. The organic matter in soil with herbicide was (12±7) % and without herbicide (28.3 ± 17) %, while Nitrogen in soil with herbicide was (7.0±3.8) % and without (17±6.6) %. ANOVA revealed significant difference in soil microbiota of soil with and without herbicides, P-value = 0.0002 and P-value = 0.0064 for bacterial and fungi, respectively. Soil organic matter and nitrogen contents were also different, p-value = 0.0023 and p-value = 0.00002 for the organic matter and nitrogen content, respectively. Glyphosate affects the abundance of soil microbiota and hence nutrient levels in the soil. There is a need to study the effect of herbicides to different types of soil and provide guideline of its use for a comprehensive management of the soil.

Keywords:
Glyphosate Soil Bacteria Fungi Organic matter Nitrogen Herbicide Microbiota

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

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