Toxic stress-specific cytoprotective responses regulate learned behavioral decisions in C. elegans

Abstract

AbstractBackgroundProtection of organismal integrity involve physiological stress responses and behavioral defenses. Recent studies in the roundworm Caenorhabditis elegans have shown that pathogen and toxin exposure simultaneously stimulate cellular stress and detoxification responses and aversive behavior. However, whether a coordinate regulation exists between cellular and neurobehavioral defenses remains unclear.ResultsHere we show that exposure of C. elegans to high concentrations of naturally attractive food-derived odors, benzaldehyde and diacetyl, induces toxicity and aversive behavior. Benzaldehyde preconditioning activates systemic cytoprotective stress responses involving DAF-16/FOXO, SKN-1/Nrf and Hsp90 in somatic cells, which confer behavioral tolerance to benzaldehyde and cross-tolerance to the structurally similar methyl-salicylate, but not to the structurally unrelated diacetyl. In contrast, diacetyl preconditioning augments diacetyl avoidance and does not induce apparent molecular defenses. Reinforcement of the experiences using massed training forms relevant associative memories. Memory retrieval by the odor olfactory cues leads to avoidance of food contaminated by diacetyl and context-dependent behavioral decision to avoid benzaldehyde only if there is an alternative, food-indicative odor.ConclusionsOur findings reveal a regulatory link between physiological stress responses and learned behavior which facilitates self-protection in real and anticipated stresses. The potential conservation of this somato-neuronal connection might have relevance in maladaptive avoidant human behaviors.