Individual variation in aerobic scope affects modeled vertical foraging migration in Atlantic cod Gadhus morhua, but only in moderate hypoxia

Vertical migration is the most widespread migration in the aquatic world, yet the mechanisms limiting the extent of this behavior are largely unknown. In the Baltic Sea, some Atlantic cod Gadus morhua perform vertical foraging migrations into severely hypoxic demersal zones where aerobic metabolism...

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Bibliographic Details
Published in:Marine Ecology Progress Series
Main Authors: Behrens, Jane W., Svendsen, Jon Christian, Neuenfeldt, Stefan, Andersen, Niels Gerner, van Deurs, Mikael
Format: Article in Journal/Newspaper
Language:English
Published: 2018
Subjects:
ECOLOGY
MARINE
OCEANOGRAPHY
POSTHYPOXIC OXYGEN-CONSUMPTION
GADUS-MORHUA
SWIMMING PERFORMANCE
MARINE TELEOSTS
METABOLIC SCOPE
RAINBOW-TROUT
BALTIC SEA
TEMPERATURE
BEHAVIOR
ONCORHYNCHUS
Physiology
Bioenergetics
Aerobic scope
Hypoxia
Gadus morhua
Individual-based model
/dk/atira/pure/sustainabledevelopmentgoals/life_below_water
SDG 14 - Life Below Water
atlantic cod
Online Access:https://orbit.dtu.dk/en/publications/fb018e6a-7c60-4ba9-9918-38839b1f68c3
https://doi.org/10.3354/meps12629
https://backend.orbit.dtu.dk/ws/files/152225589/Publishers_version.pdf
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Summary:Vertical migration is the most widespread migration in the aquatic world, yet the mechanisms limiting the extent of this behavior are largely unknown. In the Baltic Sea, some Atlantic cod Gadus morhua perform vertical foraging migrations into severely hypoxic demersal zones where aerobic metabolism is insufficient to cover energy requirements. After foraging, the fish return to better oxygenated waters for physiological recovery and digestion. To test the influence of phenotypic variation in aerobic scope (AS; the difference between the maximum and the minimum metabolic rate) on the capacity to migrate into severely hypoxic zones, we incorporated AS into a state-dependent individual-based model simulating vertical foraging migrations of G. morhua. We found little effect of individual variation in AS on the capacity for vertical migration when the zone used for physiological recovery was normoxic. In contrast, when there was moderate hypoxia (30% air saturation, O-2sat) in the zone used for physiological recovery, the high AS phenotype had a clear advantage because it could forage 3-4 times longer in the severely hypoxic (16% O-2sat, i.e. below the threshold for aerobic metabolism of the species) demersal zone compared to the low AS phenotype. Thus, phenotypic variation in AS is only important when there is moderate hypoxia in the zone used for physiological recovery, suggesting that the influence of AS variation on the capacity for vertical migration is context dependent. We propose that elevated AS may be evolutionarily favorable when hypoxia prevails in the water column.

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