Behavioral Thermoregulation in Captive Fish: Molecular, Physiological, and Welfare Implications

Abstract

AbstractEnvironmental Enrichment (EE) serves as a cornerstone in the attempt to emulate natural habitats for captive organisms. While substantial strides have been made in this field, current methodologies still grapple with discrepancies between recreated habitats and the innate conditions vital for maintaining biological homeostasis in captive species. Our study highlights the pivotal role of behavioral thermoregulation in modulating molecular and physiological outcomes in captive fish. Collective evidence suggests that enabling fish to autonomously regulate temperature confers numerous beneficial cellular and systemic effects. Specifically, introducing a thermal gradient within the EE paradigm correlated with increased survival metrics, enhanced physiological parameters, and improved welfare indices, establishing the criticality of thermoregulation in captivity. In contrast, the lack of a thermoregulatory framework resulted in the emergence of transient free radicals, a clear marker of temperature-induced oxidative stress. Persistent disruptions in free radical equilibrium, especially in uniform temperature settings, were linked to DNA damage, heightened cellular apoptosis, tissue anomalies, and metabolic deviations. In conclusion, this research underscores the significance of behavioral thermoregulation as an integral feature of EE, especially related to fish in controlled environments. Our data present key biomarkers valuable for optimizing fish welfare and highlight the necessity for sustained research into their adaptability and survival benchmarks. Such insights aim to enhance EE protocols, fortifying their efficacy in mirroring natural habitats and, in turn, advancing the welfare benchmarks of captive organisms.