Induction of proteostasis pathways in a C. elegans model of exercise

Exercise is one of the most potent interventions known that is able to prevent and even treat dozens of age-related dysfunctions and diseases however much remains unknown about how its benefits are derived. Because exercise exerts such wide-ranging effects, and because a decline in protein homeostasis (proteostasis) with age has been connected to numerous age-related diseases, we hypothesized that exercise could increase the activity of proteostasis pathways like the proteasome and autophagy and that this could ameliorate age-related declines in function. We investigated the effects of exercise has on proteostasis in Caenorhabditis elegans . We utilized a involuntary movement exercise paradigm to investigate acute exercise and the effects of multiple days of exercise on aging and proteostasis, including the autophagy-lysosome system, the proteasome, and neurotoxic peptides. We found that exercise is able to increase proteasomal activity and autophagic flux in vivo , improved resistance to toxic peptides, and increased lifespan. One of the primary rationales for studying the mechanisms of exercise is to uncover potential mediators that can be repurposed to deliver the benefits of exercise to those unable to engage in physical activity. We hypothesized that exercise-elevated metabolite α-ketoglutarate, already demonstrated to improve age-related declines in flies and mice, would mimic the effects of exercise on proteostasis. Treatment with α-ketoglutarate showed resulted in complex proteostatic outcomes, indicative of the challenges in recapitulating a multi-functional domain phenomenon like exercise.