Phenotypic variation in metabolism and morphology correlating with animal swimming activity in the wild: relevance for the OCLTT (oxygen- and capacity-limitation of thermal tolerance), allocation and performance models.

Henrik Baktoft,Jon C Svendsen,Lene Jacobsen,Niels Jepsen,Anders Koed,Christian Skov,Mikkel Boel,Kim Aarestrup,Søren Berg

doi:10.1093/conphys/cov055

Henrik Baktoft, Jon C Svendsen + Show 7 more

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https://doi.org/10.1093/conphys/cov055

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Abstract

Ongoing climate change is affecting animal physiology in many parts of the world. Using metabolism, the oxygen- and capacity-limitation of thermal tolerance (OCLTT) hypothesis provides a tool to predict the responses of ectothermic animals to variation in temperature, oxygen availability and pH in the aquatic environment. The hypothesis remains controversial, however, and has been questioned in several studies. A positive relationship between aerobic metabolic scope and animal activity would be consistent with the OCLTT but has rarely been tested. Moreover, the performance model and the allocation model predict positive and negative relationships, respectively, between standard metabolic rate and activity. Finally, animal activity could be affected by individual morphology because of covariation with cost of transport. Therefore, we hypothesized that individual variation in activity is correlated with variation in metabolism and morphology. To test this prediction, we captured 23 wild European perch (Perca fluviatilis) in a lake, tagged them with telemetry transmitters, measured standard and maximal metabolic rates, aerobic metabolic scope and fineness ratio and returned the fish to the lake to quantify individual in situ activity levels. Metabolic rates were measured using intermittent flow respirometry, whereas the activity assay involved high-resolution telemetry providing positions every 30 s over 12 days. We found no correlation between individual metabolic traits and activity, whereas individual fineness ratio correlated with activity. Independent of body length, and consistent with physics theory, slender fish maintained faster mean and maximal swimming speeds, but this variation did not result in a larger area (in square metres) explored per 24 h. Testing assumptions and predictions of recent conceptual models, our study indicates that individual metabolism is not a strong determinant of animal activity, in contrast to individual morphology, which is correlated with in situ activity patterns.

Highlights

Aerobic metabolism in animals is dependent on several abiotic factors, including ambient water temperature and CO2 and O2 levels
Aerobic metabolic scope is defined as the excess oxygen available above oxygen demand for maintenance and fuels the performance capacity of the animal (Pörtner and Lannig, 2009), which is limited by the maximal aerobic metabolic rate
Overall individual daily activity levels were partly repeatable over time, as indicated by the relatively high median intraclass correlation coefficients (ICCs) found for Aday and ARday

Summary

Introduction

Aerobic metabolism in animals is dependent on several abiotic factors, including ambient water temperature and CO2 and O2 levels. Metabolic performance, typically measured as oxygen consumption rate, has been identified as a key component in predicting the reaction of aquatic ectothermic animals to climate change and their conservation through the oxygenand capacity-limited thermal tolerance (OCLTT) hypothesis (Pörtner, 2010). Clark et al 2013; Ern et al 2014; Norin et al 2014; Wang et al 2014), it is conceivable that the link between AMS and performance, as suggested by the OCLTT hypothesis, should be revealed by positive correlations between individual AMS and activity levels. Correlations between individual AMS and activity levels have, rarely been tested in the wild

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