Abstract
Tetracyclines are broad-spectrum antibiotics widely used in agriculture, medicine, and research. However, they are associated with harmful side effects. In arthropods, parental exposure to tetracyclines has been linked to reduced health and fitness in untreated offspring. These transgenerational effects of tetracyclines could jeopardize the success of pest control programs that use tetracyclines to control gene expression. In this study, we investigated the transgenerational effects of 2 tetracyclines, doxycycline (DOX) and anhydrotetracycline (ATC), in the blowfly Lucilia cuprina, a significant pest of sheep. To simulate the rearing conditions of a transgenic male-only release program, blowflies were reared on standard diet alone, or standard diet plus DOX or ATC, for 3 generations, and then reared for an additional fourth generation on standard diet alone. We used behavioral assays, 16S amplicon sequencing, and mRNA sequencing to determine how DOX and ATC influenced male sexual competitiveness, microbiome composition, and gene expression in the third and fourth generations. We found that 3 generations of DOX treatment led to lower sexual competitiveness in both third- and fourth-generation males. In addition, DOX and ATC shifted the composition of the blowfly microbiome and altered the expression of numerous mitochondria- and immunity-related genes in both generations. Our study supports an emerging body of evidence that tetracyclines exert not only direct but also transgenerational effects, and sheds light on the transcriptional and microbial responses to antibiotic exposure and removal. Our findings emphasize the need for pest control programs that use tetracyclines to evaluate the long-term effects of these antibiotics.