Neuronal SKN-1B modulates nutritional signalling pathways and mitochondrial networks to control satiety.

The feeling of hunger or satiety results from integration of the sensory nervous system with other physiological and metabolic cues. This regulates food intake, maintains homeostasis and prevents disease. In C. elegans, chemosensory neurons sense food and relay information to the rest of the animal via hormones to control food-related behaviour and physiology. Here we identify a new component of this system, SKN-1B which acts as a central food-responsive node, ultimately controlling satiety and metabolic homeostasis. SKN-1B, an ortholog of mammalian NF-E2 related transcription factors (Nrfs), has previously been implicated with metabolism, respiration and the increased lifespan incurred by dietary restriction. Here we show that SKN-1B acts in two hypothalamus-like ASI neurons to sense food, communicate nutritional status to the organism, and control satiety and exploratory behaviours. This is achieved by SKN-1B modulating endocrine signalling pathways (IIS and TGF-ß), and by promoting a robust mitochondrial network. Our data suggest a food-sensing and satiety role for mammalian Nrf proteins.

Mitochondrial clearance and increased HSF-1 activity are coupled to promote longevity in fasted Caenorhabditis elegans.

Fasting has emerged as a potent means of preserving tissue function with age in multiple model organisms. However, our understanding of the relationship between food removal and long-term health is incomplete. Here, we demonstrate that in the nematode worm Caenorhabditis elegans, a single period of early-life fasting is sufficient to selectively enhance HSF-1 activity, maintain proteostasis capacity and promote longevity without compromising fecundity. These effects persist even when food is returned, and are dependent on the mitochondrial sirtuin, SIR-2.2 and the H3K27me3 demethylase, JMJD-3.1. We find that increased HSF-1 activity upon fasting is associated with elevated SIR-2.2 levels, decreased mitochondrial copy number and reduced H3K27me3 levels at the promoters of HSF-1 target genes. Furthermore, consistent with our findings in worms, HSF-1 activity is also enhanced in muscle tissue from fasted mice, suggesting that the potentiation of HSF-1 is a conserved response to food withdrawal.

Loss of MTCH-1 suppresses age-related proteostasis collapse through the inhibition of programmed cell death factors.

The age-related loss of protein homeostasis (proteostasis) is at the heart of numerous neurodegenerative diseases. Therefore, finding ways to preserve proteome integrity in aged cells may be a powerful way to promote long-term health. Here, we show that reducing the activity of a highly conserved mitochondrial outer membrane protein, MTCH-1/MTCH2, suppresses age-related proteostasis collapse in Caenorhabditis elegans without disrupting development, growth, or reproduction. Loss of MTCH-1 does not influence proteostasis capacity in aged tissues through previously described pathways but instead operates by reducing CED-4 levels. This results in the sequestration of HSP-90 by inactive CED-3, which in turn leads to an increase in HSF-1 activity, transcriptional remodeling of the proteostasis network, and maintenance of proteostasis capacity with age. Together, our findings reveal a role for programmed cell death factors in determining proteome health and suggest that inhibiting MTCH-1 activity in adulthood may safeguard the aging proteome and suppress age-related diseases.