AbstractIncreasing evidence in animal species ranging from mammals to insects has revealed phenotypes that are caused by ancestral life experiences including stress and diet. The descendent phenotypes themselves are wide ranging, and include changes to behaviour, disease risk, metabolism, and growth. Ancestral dietary macronutrient composition, and quantity (over- and under-nutrition) have been shown to alter descendent growth, metabolism and behaviour. Several studies have identified inherited molecules in gametes which are altered by ancestral diet and are required for the transgenerational effect. However, there is less understanding of the developmental pathways in the period between fertilisation and adulthood that are altered by the inherited molecules. Here we identify a key role of the MAPK signalling pathway in mediating changes to Drosophila larval developmental timing due to variation in ancestral diet. We exposed grand-parental and great grand-parental generations to defined protein to carbohydrate (P:C) dietary ratios and measured developmental timing. Descendent developmental timing was consistently faster in the period between the embryonic and pupal stages when the ancestor had a higher P:C ratio diet. Transcriptional analysis of embryos, larvae and adults revealed extensive and long-lasting changes to the MAPK signalling pathway which controlled growth rate through regulation of ribosomal RNA transcription. The importance of these processes was supported by pharmacological inhibition of MAPK and rRNA proteins which reproduced the ancestral diet-induced developmental changes. This work provides insight into the role of developmental growth signalling networks in mediating non-genetic inheritance in the period between fertilisation and adult.Summary statementAncestral, diet-induced descendent developmental timing changes are caused by alteration of MAPK signalling pathways in the period between the embryo and pupal stages in Drosophila.
Regulation of pancreatic -cell insulin secretion by actin cytoskeleton remodelling: role of gelsolin and cooperation with the MAPK signalling pathway
