Soma to neuron communication links stress adaptation to stress avoidance behavior.

In multicellular organisms, signaling from the nervous system to the peripheral tissues can activate physiological responses to stress. Here, we show that inter-tissue stress communication can also function in reverse, i.e. from the peripheral tissue to the nervous system. mutants, which activate the osmotic stress response in the skin, also exhibit defective osmotic avoidance behavior, which is regulated by the ASH neuronal avoidance circuit. osmotic avoidance behavior is completely suppressed by mutation of the Patched/NPC1 homolog The function of and in the hypodermal epithelial cells is both necessary and sufficient for directing neuronal osmotic avoidance behavior. Endogenously tagged alleles of and co-localize exclusively in the hypodermal lysosomes. Unbiased lipidomic analysis shows that leads to a -dependent elevation of the lysosome specific lipid bis(monoacylglycero)phosphate (BMP) and expansion of the pool of hypodermal lysosomes. Just as genetic activation of the osmotic stress response by loss of in the hypodermis causes an Osm phenotype, acute physiological exposure to osmotic stress also confers a reversible Osm phenotype. Behavioral plasticity requires glycerol production, as mutations in the glycerol biosynthetic enzymes and are defective in acquired Osm behavior. While the induced Osm behavior requires physiologically induced Osm behavior does not. Instead, both genetic and physiologically induced Osm phenotypes require the unusual non-neuronal lysosomal V-ATPase subunit which is also critical for organismal osmotic stress survival. Together, these data reveal that genetic or physiological activation of stress signaling from the skin elicits lysosome-associated signals that modulate the function of a sensory neuron circuit. Such 'body-brain' interoceptive communication may allow organisms to better match neuronal decision-making with organismal physiological state.