Translational regulation of non-autonomous mitochondrial stress response promotes longevity

Abstract

SummaryInhibition of mRNA translation delays aging, but the underlying mechanisms remain underexplored. Mutations in both DAF-2 (IGF-1 receptor) and RSKS-1 (ribosomal S6 kinase/S6K) cause synergistic lifespan extension in C. elegans. To understand the roles of S6K-mediated translational regulation in this process, we performed genome-wide translational profiling and genetic screens to identify genes that are not only regulated at the translational level in the daf-2 rsks-1 mutant, but also affect lifespan. Inhibition of CYC-2.1 (cytochrome c) in the germline significantly extends lifespan through non-autonomous activation of the mitochondrial unfolded protein response (UPRmt) and AMP-activated kinase (AMPK) in the metabolic tissue. Furthermore, the RNA-binding protein GLD-1-mediated translational repression of cytochrome c in the germline is important for the non-autonomous activation of UPRmt and synergistic longevity of the daf-2 rsks-1 mutant. Together, these results illustrate a translationally regulated non-autonomous mitochondrial stress response mechanism in the modulation of lifespan by insulin-like signaling and S6K.HighlightsLongevity of the daf-2 rsks-1 mutant is mediated by translational repression of ribosomal proteins and CYC-2.1/cytochrome c.Germline inhibition of cyc-2.1 non-autonomously activates UPRmt and AMPK to extend lifespan.GLD-1 represses germline cyc-2.1 translation in the daf-2 rsks-1 mutant.Translational regulation of cyc-2.1 and UPRmt contribute to the synergistic longevity of the daf-2 rsks-1 mutant.