Abstract
Anadromy is a distinctive life-history strategy in fishes that has evolved independently many times. In an evolutionary context, the benefits of anadromy for a species or population must outweigh the costs and risks associated with the habitat switch. The migration of fish across the freshwater-ocean boundary coincides with potentially energetically costly osmoregulatory modifications occurring at numerous levels of biological organization. By integrating whole animal and sub-cellular metabolic measurements, this study presents significant findings demonstrating how an anadromous salmonid (i.e. rainbow trout, Oncorhynchus mykiss) is able to transform from a hyper- to hypo-osmoregulatory state without incurring significant increases in whole animal oxygen consumption rate. Instead, underlying metabolic mechanisms that fuel the osmoregulatory machinery at the organ level (i.e. intestine) are modulated, as mitochondrial coupling and anaerobic metabolism are increased to satisfy the elevated energetic demands. This may have positive implications for the relative fitness of the migrating individual, as aerobic capacity may be maintained for locomotion (i.e. foraging and predator avoidance) and growth. Furthermore, the ability to modulate mitochondrial metabolism in order to maintain osmotic balance suggests that mitochondria of anadromous fish may have been a key target for natural selection, driving species adaptations to different aquatic environments.
Highlights
After 4 days of seawater acclimation, intestinal NKA activity was higher than that observed in freshwater-acclimated rainbow trout (p = 0.012), and at day 7 it reached a maximum value of 0.35 ± 0.10 U mg−1 protein before gradually returning to, and stabilizing at, an activity level of ~0.2 U mg−1 protein
Intestinal LDH activity was positively correlated with intestinal NKA activity (r(64) = 0.46, p < 0.001). Anadromous salmonids such as rainbow trout are able to tolerate short-term osmotic and ionic perturbations that accompany a transition to seawater, hypo-osmoregulatory mechanisms must be initiated relatively quickly as prolonged disruption of osmotic homeostasis results in death[4]
Rainbow trout experienced significantly increased plasma osmolality and ion concentrations for four days following a transfer to seawater, after which osmotic homeostasis was regained
Summary
Energetically costly than in freshwater habitats (as might be expected from the NaCl gradient between milieu intérieur and external medium[18]). The underlying mechanisms for adjusting mitochondrial respiration in the intestine of an anadromous salmonid have to our knowledge never been investigated, nor have the relative contributions of aerobic and/or anaerobic metabolism in this organ been studied. The elevated ATP demand by intestinal NKA would result in an elevated intestinal and whole animal metabolism To test this hypothesis, we investigated the temporal dynamics of osmotic balance (i.e. plasma osmolality and ion concentrations), intestinal NKA activity, M O2, intestinal mitochondrial respiration rates, as well as enzymatic activities of citrate synthase (CS, an enzyme of the tricarboxylic acid cycle and a marker of aerobic capacity) and lactate dehydrogenase (LDH, a marker of anaerobic capacity) during a 35-day seawater acclimation period
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