DecAI: Decoding Aging Initiative

Abstract

A number of pathways have been shown to regulate animal lifespan and organismal aging. The Antebi lab has recently discovered the nucleolus as a crucial focal point for these pathways. The nucleolus is a subnuclear organelle dedicated to rRNA production and ribogenesis, which also controls other key processes in the RNA metabolism of the cell, including small RNA processing and assembly of ribonucleoproteins. miRNAs are a class of small non-coding RNAs which regulate gene expression at the post-transcriptional level and have been implicated in development, disease, and aging. We and others have shown that miRNAs can influence lifespan, and that they can exert their effects in a cell-non-autonomous fashion. Our investigation of miRNA regulation in aging and cell-non-autonomy gave rise to the initiation of the DecAl cooperation in 2018, a project funded by CAPES and DAAD to allow human resource exchange. Early results from this collaboration have revealed that loss-of-function mutations in a miRNA/siRNA processing enzyme, DICER, affect nucleolar size, thereby potentially also placing the nucleolus as a link between small RNAs and aging. In addition, we found that incubation of human Jurkat cells with serum of exercised mice reduces nucleolus size and that this effect is dependent on the presence of DICER in adipocytes, suggesting that nucleolus size is cell non-autonomously controlled by adipose tissue small RNAs in response to exercise training. Despite the mounting evidence, the extent and mechanism of this regulation remains unclear. The focus of this proposal is therefore to (1) identify genes and circulating factors that affect miRNA and siRNA processing and RNA metabolism in aging, and (2) map the processes through which this regulation occurs, with a particular focus on the nucleolus. (AU)