Abstract
Antibiotic resistance is an indispensable threat facing in the present era. However, the studies on long term and trans-generational effects of using drugs or antibiotics on living organisms are scarce. Emphasizing the necessity to address such problems, this study investigated the potential effects of antibiotic, ampicillin (AMP) stress on the physiology of Drosophila melanogaster across multiple generations with mechanistic details. We evaluated the larval feeding behavior, fertility, cell viability in ovary and testis, longevity, expression of methylation-related genes (dDnmt2 and dMBD2/3), and antimicrobial peptide production. Larvae exposed to AMP exhibited increased mouth hook movement, indicating altered behaviour. AMP stress significantly reduced fertility across generations, with eclosion counts decreasing notably in F3 and F4 generations compared to controls. Moreover, AMP-treated flies showed decreased cell viability in ovary and testis, leading to impaired reproductive function. AMP exposure shortened the mean lifespan of flies and upregulated the expression of apoptosis-related gene p53 in females. However, there was no significant difference in p53 expression in males. Additionally, AMP stress caused a significant decrease in Drosomycin expression in treated males, while no significant changes were observed in Drosocin and Metchnikowin. In treated females, Drosocin and Drosomycin expression increased significantly, whereas the increase in Metchnikowin was not significant. The study also revealed downregulation of methylation-related genes (dDnmt2 and dMBD2/3) in AMP-treated female flies which was normalised in the rescue flies suggesting disrupted epigenetic mechanisms. Overall, the findings highlighted the importance of evaluating the trans-generational impacts of AMP stress on Drosophila physiology and gene expression, particularly in reproductive function and epigenetic regulation. The study of the impact of widely used antibiotic, AMP on model organism, Drosophila (model organism known for its genetic similarity to human), will help in predicting potential impacts on higher organisms and human. The finding would ultimately promote proper use of antibiotics and use of alternative medicine.
