Stress response to genotoxic agents and to infection

Abstract

Insects have evolved various physiological responses to cope with stressors such as pathogens, toxins and environmental factors. It is known that the responses resulting from infection or DNA damage share some of the same pathways. Exposure of Drosophila melanogaster and the dung beetle Euoniticellus intermedius to stress led to changes in the expression of proteins involved in metabolism, development, protein degradation, mRNA processing and stress responses. Stress responses in D. melanogaster are well characterised. However, the role played by Drosophila p53 (Dmp53) and a member of the retinoblastoma binding protein 6 (RBBP6) family, Snama, are unknown. Snama has been proposed to play a role in Dmp53 regulation. Following DNA damage we investigated the role of Dmp53 and Snama. Flies recovering from camptothecin treatment display a glycolytic flux, involving a metabolic shift, different to that observed in cancer cells. Camptothecin treatment leads to an increase in the mortality of both sexes. Furthermore, females show a specific decrease in fecundity which is due to an increase in Dmp53 dependent apoptosis in the ovaries and is accompanied by a depletion of Snama and an increase in Dmp53 transcripts. Expression data indicated that Dmp53 activity may be largely regulated at the protein level. Bypassing glycolysis through methyl pyruvate supplementation led to differential expression of Dmp53 and Snama and improved reproduction and embryonic development. These results highlight differences between the metabolic strategies used by cancerous and non-cancerous cells which may be exploited in future chemotherapies. While immune responses amongst insect orders are evolutionarily conserved, many remain uncharacterised. To investigate the immune system of an organism that lives in a microbe rich environment, E. intermedius was infected with the fungal pathogen Beauveria bassiana. This resulted in decreased lifespan and fecundity. Homologs of proteins involved in the immune response of insects were identified in E. intermedius, including a member of the Toll family of proteins, an insect defensin (present in the hemolymph) as well as a homolog of the serine protease Persephone. These results show that immune signalling pathways are conserved in this dung beetle.