Oxidative stress, DNA damage, and histological alterations in Bombyx mori exposed orally to pesticide dimethoate

Pesticides are an essential part of agricultural practices that ward off pathogens and diseases from the agricultural crop. However, apart from target organisms, these chemicals also have adverse effects on non‐target organisms. Dimethoate is an insecticide used extensively in agriculture and hortic...

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Bibliographic Details
Published in:Physiological entomology 2023-03, Vol.48 (1), p.1-13
Main Authors: Qadri, Hashim Ashraf, Qamar, Ayesha, Maheshwari, Nikhil
Format: Article
Language:English
Subjects:
Agricultural practices
Agrochemicals
Analytical methods
Body weight loss
Bombyx mori
comet assay
Damage
Deoxyribonucleic acid
Dimethoate
DNA
DNA damage
Electrophoresis
Fat body
Free radicals
Gel electrophoresis
Gels
histological alteration
Horticulture
Insecticides
Lethal limits
Lipid peroxidation
Lipids
Mortality causes
Organisms
organophosphate
Oxidative stress
Pathogens
Peroxidation
Pesticides
Silk
Silk gland
Silkworms
Tissues
Toxicity tests
Weight loss
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Summary:Pesticides are an essential part of agricultural practices that ward off pathogens and diseases from the agricultural crop. However, apart from target organisms, these chemicals also have adverse effects on non‐target organisms. Dimethoate is an insecticide used extensively in agriculture and horticulture practices worldwide. We used the silkworm Bombyx mori as a model organism to study the effect of commercial formulation of dimethoate (Dimethoate‐30% EC) on the gut, silk gland, and fat body tissues. LD50 of dimethoate‐30% EC on silkworm (B. mori) was 997 ppm, as reported in a previous study. We used concentrations of 25, 50, and 100 ppm in our experiments. Our results showed that sub‐lethal doses of dimethoate caused weight loss and induced damage at the histological level to the mid‐gut, silk gland, and fat body of B. mori. It also caused a decrease in the level of antioxidants like CAT, SOD, GPx, GSH, and GST, indicating that dimethoate has produced a shift of ROS balance towards free radical generation and therefore resulted in overall damage to this organism. Sub‐lethal doses of this pesticide also caused lipid peroxidation in the silk gland, gut, and fat body of B. mori, damaging these tissues. The disruption was also seen in the mid‐gut and middle silk gland at the DNA level, where it caused single‐strand breaks, as was revealed by single cell gel electrophoresis studies. Damage at histological, biochemical, and molecular levels was most extreme at a concentration of 100 ppm, the highest sub‐lethal concentration given to B. mori. General overview of the study
ISSN:0307-6962
1365-3032
DOI:10.1111/phen.12397