Early life stage mechanisms of an active fish species to cope with ocean warming and hypoxia as interacting stressors

Early life stage mechanisms of an active fish species to cope with ocean warming and hypoxia as interacting stressors

Ocean's characteristics are rapidly changing, modifying environmental suitability for early life stages of fish. We assessed whether the chronic effects of warming (24 °C) and hypoxia (<2-2.5 mg L ) will be amplified by the combination of these stressors on mortality, growth, behaviour, meta...

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Bibliographic Details
Published in:Environmental pollution (1987) Vol. 341; p. 122989
Main Authors: Lima, André R A, Booms, Emily M, Lopes, Ana Rita, Martins-Cardoso, Sara, Novais, Sara C, Lemos, Marco F L, Ribeiro, Laura, Castanho, Sara, Candeias-Mendes, Ana, Pousão-Ferreira, Pedro, Faria, Ana M
Format: Journal Article
Language:English
Published: England 15-01-2024
Subjects:
Animals
Hypoxia
Larva
Oceans and Seas
Sea Bream - metabolism
Temperature
Growth strategies
Climate change
Fish larvae
Oxygen depletion
Fish behaviour
Fish physiology
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Summary:Ocean's characteristics are rapidly changing, modifying environmental suitability for early life stages of fish. We assessed whether the chronic effects of warming (24 °C) and hypoxia (<2-2.5 mg L ) will be amplified by the combination of these stressors on mortality, growth, behaviour, metabolism and oxidative stress of early stages of the white seabream Diplodus sargus. Combined warming and hypoxia synergistically increased larval mortality by >51%. Warming induced faster growth in length and slower gains in weight when compared to other treatments. Boldness and exploration were not directly affected, but swimming activity increased under all test treatments. Under the combination of warming and hypoxia, routine metabolic rate (RMR) significantly decreases when compared to other treatments and shows a negative thermal dependence. Superoxide dismutase and catalase activities increased under warming and were maintained similar to control levels under hypoxia or under combined stressors. Under hypoxia, the enzymatic activities were not enough to prevent oxidative damages as lipid peroxidation and DNA damage increased above control levels. Hypoxia reduced electron transport system activity (cellular respiration) and isocitrate dehydrogenase activity (aerobic metabolism) below control levels. However, lactate dehydrogenase activity (anaerobic metabolism) did not differ among treatments. A Redundancy Analysis showed that ∼99% of the variability in mortality, growth, behaviour and RMR among treatments can be explained by molecular responses. Mortality and growth are highly influenced by oxidative stress and energy metabolism, exhibiting a positive relationship with reactive oxygen species and a negative relationship with aerobic metabolism, regardless of treatment. Under hypoxic condition, RMR, boldness and swimming activity have a positive relationship with anaerobic metabolism regardless of temperature. Thus, seabreams may use anaerobic reliance to counterbalance the effects of the stressors on RMR, activity and growth. The outcomes suggests that early life stages of white seabream overcame the single and combined effects of hypoxia and warming.
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ISSN:0269-7491
1873-6424
DOI:10.1016/j.envpol.2023.122989