Abstract
Behavioural flexibility allows ectotherms to exploit the environment to govern their metabolic physiology, including in response to environmental stress. Hydrogen sulfide (H2S) is a widespread environmental toxin that can lethally inhibit metabolism. However, H2S can also alter behaviour and physiology, including a hypothesized induction of hibernation-like states characterized by downward shifts of the innate thermal set point (anapyrexia). Support for this hypothesis has proved controversial because it is difficult to isolate active and passive components of thermoregulation, especially in animals with high resting metabolic heat production. Here, we directly test this hypothesis by leveraging the natural behavioural thermoregulatory drive of fish to move between environments of different temperatures in accordance with their current physiological state and thermal preference. We observed a decrease in adult zebrafish (Danio rerio) preferred body temperature with exposure to 0.02% H2S, which we interpret as a shift in the thermal set point. Individuals exhibited consistent differences in shuttling behaviour and preferred temperatures, which were reduced by a constant temperature magnitude during H2S exposure. Seeking lower temperatures alleviated H2S-induced metabolic stress, as measured by reduced rates of aquatic surface respiration. Our findings highlight the interactions between individual variation and sublethal impacts of environmental toxins on behaviour.
Highlights
Environmental toxicants may act through myriad pathways, including hijacking the body’s own signalling pathways
In 0% H2S, a constant preferred temperature is indicated by a regression slope overlapping unity and moderate repeatability (R = 0.54, confidence intervals (CI): 0.13–0.78, p = 0.006)
A central question in thermoregulatory physiology is the nature of the thermal set point and how it is adjusted [16,18]
Summary
Environmental toxicants may act through myriad pathways, including hijacking the body’s own signalling pathways. It has been proposed that application of exogenous H2S in combination with low temperatures induces a drop in body temperature through entry into a hypometabolic hibernation-like state in mice [8] It is unclear if this is an effect of H2S alone or aggravation of a conserved environmental hypoxia response [9,10]. Whereas in most terrestrial animals exogenous H2S is applied to study the gasotransmitter’s endogenous functions [8,9], exogenous H2S is ecologically relevant in aquatic habitats [11,12,13,14] We exploit this physiology as a direct test of the hypothesis that H2S drives changes in thermal preferences, which is significant for the ecology and behaviour of this major taxon
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