Abstract
Aberrant mitochondrial function contributes to the pathogenesis of various metabolic and chronic disorders. Inhibition of insulin/IGF‐1 signaling (IIS) represents a promising avenue for the treatment of mitochondrial diseases, although many of the molecular mechanisms underlying this beneficial effect remain elusive. Using an unbiased multi‐omics approach, we report here that IIS inhibition reduces protein synthesis and favors catabolism in mitochondrial deficient Caenorhabditis elegans. We unveil that the lifespan extension does not occur through the restoration of mitochondrial respiration, but as a consequence of an ATP‐saving metabolic rewiring that is associated with an evolutionarily conserved phosphoproteome landscape. Furthermore, we identify xanthine accumulation as a prominent downstream metabolic output of IIS inhibition. We provide evidence that supplementation of FDA‐approved xanthine derivatives is sufficient to promote fitness and survival of nematodes carrying mitochondrial lesions. Together, our data describe previously unknown molecular components of a metabolic network that can extend the lifespan of short‐lived mitochondrial mutant animals.
Highlights
Mitochondria take part in key biological processes, supporting energy production as well as biosynthesis of various metabolic intermediates needed for cell growth and homeostasis
We found that the lifespan of age-1; gas-1 double mutant nematodes was significantly longer compared to gas1 mutants, as well as of wild-type and even age-1(hx546) single mutant animals (Fig 1B and Dataset EV1)
The lifespan-extending effect of insulin/ IGF-1 signaling (IIS) inhibition was not limited to complex I-deficient nematodes, since age-1(hx546); mev-1(kn1) double mutants lived significantly longer compared to complex II-deficient mev-1(kn1) animals (Fig 1F and Dataset EV1)
Summary
Mitochondria take part in key biological processes, supporting energy production as well as biosynthesis of various metabolic intermediates needed for cell growth and homeostasis. Aberrant mitochondrial bioenergetics is associated with a wide spectrum of age-related chronic diseases (Schon & Przedborski, 2011; Exner et al, 2012; Vafai & Mootha, 2012; Camandola & Mattson, 2017). It causally underlies several debilitating human pathologies commonly known as mitochondrial diseases (Koopman et al, 2012, 2016; DiMauro et al, 2013; Chinnery, 2015; Viscomi et al, 2015; Gorman et al, 2016). Due to the genetic and structural complexity of the OXPHOS system (Koopman et al, 2012; Area-Gomez & Schon, 2014), the loose genotype–phenotype correlation complicates diagnostics as well as the development of effective treatments
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