Encoding of hunger by the neuronal epigenome slows aging in Drosophila

AbstractHunger is, by necessity, an ancient motivational drive, yet the molecular nature of homeostatic pressures of this sort and how they modulate health and physiology are largely unknown. Here we show that the molecular encoding of hunger slows aging in Drosophila. We identify the branched-chain amino acids (BCAAs) as dietary hunger signals that extend lifespan despite increasing food intake when reduced, and in parallel show that optogenetic activation of a subset of hunger-promoting neurons is sufficient to recapitulate these effects. We find that remodeling of the neuronal histone acetylome is associated with dietary BCAA reduction, and that this requires BCAA metabolism in specific subsets of neurons. Preventing the histone acetylome from being molded by dietary BCAAs abrogates both increased feeding and extended lifespan. However, the mechanisms that promote feeding and modulate aging downstream of alterations in histone acetylation occur through spatially and temporally distinct responses; differential usage of the histone variant H3.3A in the brain is an acute response to hunger that promotes increased feeding without modulating lifespan, while a prolonged experience of hunger may slow aging by promoting a beneficial decrease of a set-point around which hunger levels are regulated. Identification of a molecular basis for the encoding of hunger and demonstration of its sufficiency in extending lifespan reveals that motivational states alone are deterministic drivers of aging and behavior.