Abstract
Understanding genomic variation and detecting selection signatures in a genome under selection have been great challenges for a century. Activation, development/exhaustion of primordial follicles in mammalian ovary determines reproductive success, menopause/end of female reproductive life. However, molecular mechanisms underlying oogenesis, particularly under artificial selection, are largely unknown. We report that a proteome-wide scan for selection signatures in the genome over 9,000 years of artificial pressure on the ovary revealed a general picture of selection signatures in the genome, especially genomic variations through artificial selection were detected in promoter and intron regions. Crossbreeding between domestic and wild species results in more than half of the protein spots exhibiting heterosis. Translationally controlled tumor protein (TCTP) is upregulated by artificial selection and positively regulates autophagy through the AMP-activated protein kinase pathway. Notably, TCTP interacts with ATG16 complex. In addition to cytoplasmic autophagy, nucleophagy occurs in the nuclei of granulosa and cumulus cells in ovaries, indicating an importance of the nuclear material for degradation by nucleophagy. Our findings provide insight into cellular and molecular mechanisms relevant for improvement of ovary functions, and identify selection signatures in the genome for ovary function over long-term artificial selection pressure.