Abstract
The present study investigates the response of the hormone arginine vasotocin (AVT), the non-mammalian antidiuretic hormone, to the acclimation of fish to high hydrostatic pressure (5.1 MPa). Two fish species with different osmoregulatory strategies, the lesser spotted dogfish Scyliorhinus canicula, a marine osmoconforming chondrichthyan species adapted for migration to deep waters, and the rainbow trout Oncorhynchus mykiss, a pressure-sensitive freshwater species, were selected for study. Fish were exposed to hydrostatic pressures of either 0.1 (control) or 5.1 MPa in hydrostatic chambers for up to 2 wk at their appropriate salinities. Plasma cortisol was measured in trout, and plasma chloride, sodium and potassium were measured in both fish species. A transient high level of plasma AVT was found in dogfish and in trout after 1 and 3 d of exposure to high hydrostatic pressure, which returned to basal levels by 14 d of exposure. In contrast, pituitary AVT content was reduced after short-term exposure in dogfish, while in trout, lower expression was found in high pressure than in control conditions, independently of exposure time. In dogfish, pituitary AVT levels recovered by 14 d under high hydrostatic pressure. No changes in plasma cortisol (trout) or ions (both species) were observed. These initial increases of the AVT release from the pituitary during fish acclimation to high pressure suggest that it works as a physiological short-term response to reduce water loss and equilibrate ion osmotic balance.
Highlights
Deep waters in lakes, seas and oceans differ in several physical parameters from their respective shallow depths, affecting the physiology and evolutionary patterns of fish that live or migrate there (Gibbs1997, Gaither et al 2016, Priede 2017)
The effects of high hydrostatic pressure on circulating arginine vasotocin (AVT) levels were dependent on exposure time (2-way ANOVA: interaction p = 0.002)
Pituitary AVT levels were significantly lower in high hydrostatic pressure exposed trout than in control trout (2-way ANOVA: F1,22 = 13.528; p = 0.001) but with no effect of time (2way ANOVA: F1,22 = 1.177; p = 0.327)
Summary
Seas and oceans differ in several physical parameters from their respective shallow depths, affecting the physiology and evolutionary patterns of fish that live or migrate there (Gibbs1997, Gaither et al 2016, Priede 2017). Many fish species can tolerate hydrostatic pressures corresponding to depths greater than 6000 m (approximately 59 MPa) (Günther 1887), while others can migrate vertically from about 1000 m (approximately 9.8 MPa), as is the case of Osteichthyes, including the Atlantic bluefin tuna (Block et al 2001), and cyclostomes, including the European eel (Righton et al 2016), or from 600 m (approximately 5.9 MPa) in some chondrichthyan species, such as the blue shark (Kyne & Simpfendorfer 2010). These eurybathic species, such as the trout (Sébert & Theron 2001), are well suited to the study of the plasticity of fish physiological mechanisms, as it relates to their response to hydrostatic pressure changes
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