Hypoxic acclimation leads to metabolic compensation after reoxygenation in Atlantic salmon yolk-sac alevins

Hypoxia is common in aquatic environments and has substantial effects on development, metabolism and survival of aquatic organisms. To understand the physiological effects of hypoxia and its dependence on temperature, metabolic rate (ṀO 2 ) and cardiorespiratory function were studied in response to...

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Bibliographic Details
Published in:Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology
Main Authors: Polymeropoulos, ET, Elliott, NG, Frappell, PB
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier Science Inc 2017
Subjects:
Agricultural and Veterinary Sciences
Fisheries Sciences
Aquaculture
Atlantic salmon
Salmo salar
Online Access:https://doi.org/10.1016/j.cbpa.2017.08.011
http://www.ncbi.nlm.nih.gov/pubmed/28864081
http://ecite.utas.edu.au/122378
Description
Summary:Hypoxia is common in aquatic environments and has substantial effects on development, metabolism and survival of aquatic organisms. To understand the physiological effects of hypoxia and its dependence on temperature, metabolic rate (ṀO 2 ) and cardiorespiratory function were studied in response to acute hypoxia (21 → 5 kPa) at different measurement temperatures (Ta; 4, 8 and 12 C) in Salmo salar alevins that were incubated under normoxic conditions (PO 2 = 21 kPa) or following hypoxic acclimation (PO 2 = 10 kPa) as well as two different temperatures (4 C or 8 C). Hypoxic acclimation lead to a developmental delay manifested through slower yolk absorption. The general response to acute hypoxia was metabolic depression (~ 60%). Hypoxia acclimated alevins had higher ṀO 2 s when measured in normoxia than alevins acclimated to normoxia. ṀO 2 s were elevated to the same degree (~ 30% per 4 C change) irrespective of Ta. Under severe, acute hypoxia (~ 5 kPa) and irrespective of Ta or acclimation, ṀO 2 s were similar between most groups. This suggests that despite different acclimation regimes, O 2 transport was limited to the same degree. While cardiorespiratory function (heart-, ventilation rate) was unchanged in response to acute hypoxia after normoxic acclimation, hypoxic acclimation led to cardiorespiratory changes predominantly in severe hypoxia, indicating earlier onset and plasticity of cardiorespiratory control mechanisms. Although ṀO 2 in normoxia was higher after hypoxic acclimation, at the respective acclimation PO 2 , ṀO 2 was similar in normoxia and hypoxia acclimated alevins. This is indicative of metabolic compensation to an intrinsic ṀO2 at the acclimation condition in hypoxia-acclimated alevins after re-exposure to normoxia.

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