Low global sensitivity of metabolic rate to temperature in calcified marine invertebrates
Low global sensitivity of metabolic rate to temperature in calcified marine invertebrates
Metabolic rate is a key component of energy budgets that scales with body size and varies with large-scale environmental geographical patterns. Here we conduct an analysis of standard metabolic rates (SMR) of marine ectotherms across a 70° latitudinal gradient in both hemispheres that spanned collection temperatures of 0–30 °C. To account for latitudinal differences in the size and skeletal composition between species, SMR was mass normalized to that of a standard-sized (223 mg) ash-free dry mass individual. SMR was measured for 17 species of calcified invertebrates (bivalves, gastropods, urchins and brachiopods), using a single consistent methodology, including 11 species whose SMR was described for the first time. SMR of 15 out of 17 species had a mass-scaling exponent between 2/3 and 1, with no greater support for a 3/4 rather than a 2/3 scaling exponent. After accounting for taxonomy and variability in parameter estimates among species using variance-weighted linear mixed effects modelling, temperature sensitivity of SMR had an activation energy (Ea) of 0.16 for both Northern and Southern Hemisphere species which was lower than predicted under the metabolic theory of ecology (Ea 0.2–1.2 eV). Northern Hemisphere species, however, had a higher SMR at each habitat temperature, but a lower mass-scaling exponent relative to SMR. Evolutionary trade-offs that may be driving differences in metabolic rate (such as metabolic cold adaptation of Northern Hemisphere species) will have important impacts on species abilities to respond to changing environments.
Oxygen, Latitude, Activation energy, Energetics, Climate change
45-54
Watson, Sue-Ann
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Morley, Simon A.
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Bates, Amanda E.
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Clark, Melody S.
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Day, Robert W.
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Lamare, Miles
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Martin, Stephanie M.
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Southgate, Paul C.
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Tan, Koh Siang
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Tyler, Paul A.
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Peck, Lloyd S.
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2014
Watson, Sue-Ann
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Morley, Simon A.
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Bates, Amanda E.
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Clark, Melody S.
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Day, Robert W.
fc276889-b081-4230-9e97-ae5eba8389df
Lamare, Miles
90ed0aca-043a-4e54-888f-952bcc2f3c1c
Martin, Stephanie M.
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Southgate, Paul C.
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Tan, Koh Siang
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Tyler, Paul A.
d1965388-38cc-4c1d-9217-d59dba4dd7f8
Peck, Lloyd S.
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Watson, Sue-Ann, Morley, Simon A., Bates, Amanda E., Clark, Melody S., Day, Robert W., Lamare, Miles, Martin, Stephanie M., Southgate, Paul C., Tan, Koh Siang, Tyler, Paul A. and Peck, Lloyd S.
(2014)
Low global sensitivity of metabolic rate to temperature in calcified marine invertebrates.
Oecologia, 174, .
(doi:10.1007/s00442-013-2767-8).
Abstract
Metabolic rate is a key component of energy budgets that scales with body size and varies with large-scale environmental geographical patterns. Here we conduct an analysis of standard metabolic rates (SMR) of marine ectotherms across a 70° latitudinal gradient in both hemispheres that spanned collection temperatures of 0–30 °C. To account for latitudinal differences in the size and skeletal composition between species, SMR was mass normalized to that of a standard-sized (223 mg) ash-free dry mass individual. SMR was measured for 17 species of calcified invertebrates (bivalves, gastropods, urchins and brachiopods), using a single consistent methodology, including 11 species whose SMR was described for the first time. SMR of 15 out of 17 species had a mass-scaling exponent between 2/3 and 1, with no greater support for a 3/4 rather than a 2/3 scaling exponent. After accounting for taxonomy and variability in parameter estimates among species using variance-weighted linear mixed effects modelling, temperature sensitivity of SMR had an activation energy (Ea) of 0.16 for both Northern and Southern Hemisphere species which was lower than predicted under the metabolic theory of ecology (Ea 0.2–1.2 eV). Northern Hemisphere species, however, had a higher SMR at each habitat temperature, but a lower mass-scaling exponent relative to SMR. Evolutionary trade-offs that may be driving differences in metabolic rate (such as metabolic cold adaptation of Northern Hemisphere species) will have important impacts on species abilities to respond to changing environments.
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e-pub ahead of print date: September 2013
Published date: 2014
Keywords:
Oxygen, Latitude, Activation energy, Energetics, Climate change
Organisations:
Ocean Biochemistry & Ecosystems
Identifiers
Local EPrints ID: 358211
URI: http://eprints.soton.ac.uk/id/eprint/358211
ISSN: 0029-8549
PURE UUID: 7e75e08b-ca47-4a25-92b9-93f6a2127593
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Date deposited: 01 Oct 2013 12:57
Last modified: 14 Mar 2024 15:01
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Contributors
Author:
Sue-Ann Watson
Author:
Simon A. Morley
Author:
Amanda E. Bates
Author:
Melody S. Clark
Author:
Robert W. Day
Author:
Miles Lamare
Author:
Stephanie M. Martin
Author:
Paul C. Southgate
Author:
Koh Siang Tan
Author:
Lloyd S. Peck
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