Abstract
During aging, etiologies of senescence cause multiple pathologies, leading to morbidity and death. To understand aging requires identification of these etiologies. For example, Caenorhabditis elegans hermaphrodites consume their own intestinal biomass to support yolk production, which in later life drives intestinal atrophy and ectopic yolk deposition. Yolk proteins (YPs; vitellogenins) exist as three abundant species: YP170, derived from vit-1–vit-5; and YP115 and YP88, derived from vit-6. Here, we show that inhibiting YP170 synthesis leads to a reciprocal increase in YP115/YP88 levels and vice versa, an effect involving posttranscriptional mechanisms. Inhibiting YP170 production alone, despite increasing YP115/YP88 synthesis, reduces intestinal atrophy as much as inhibition of all YP synthesis, which increases life span. By contrast, inhibiting YP115/YP88 production alone accelerates intestinal atrophy and reduces life span, an effect that is dependent on increased YP170 production. Thus, despite copious abundance of both YP170 and YP115/YP88, only YP170 production is coupled to intestinal atrophy and shortened life span. In addition, increasing levels of YP115/YP88 but not of YP170 increases resistance to oxidative stress; thus, longevity resulting from reduced vitellogenin synthesis is not attributable to oxidative stress resistance.
Highlights
C. elegans hermaphrodites initially produce sperm but switch to production of oocytes, which are fertilized by self-sperm
We recently identified a mechanism causing intestinal atrophy, demonstrating that yolk u synthesis is coupled to intestinal atrophy, as gut biomass is apparently consumed in order to sustain yolk n synthesis [10]
M In this study we verify the vitellogenic open faucet model, showing that yolk accumulation results from a d relatively steady flow of continued synthesis of yolk during adulthood combined with cessation of egg laying. te We describe how blocking YP115/YP88 synthesis increases YP170 levels, which accelerates gut atrophy p and shortens lifespan; it is YP170 production that is a major driver of C. elegans senescence. e In addition, increased YP115/YP88 level protects against oxidative stress, but does not increase lifespan, c suggesting that lifespan is not limited by oxidative stress
Summary
Thanet and Ezcurra, Marina and Kern, Carina and Galimov, Evgeniy R and Au, Catherine and de la Guardia, Yila and Gems, David (2019) Production of YP170 vitellogenins promotes intestinal senescence in C. elegans.
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