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The role of aspartic acid in reducing coral calcification under ocean acidification conditions

The role of aspartic acid in reducing coral calcification under ocean acidification conditions
The role of aspartic acid in reducing coral calcification under ocean acidification conditions

Biomolecules play key roles in regulating the precipitation of CaCO3 biominerals but their response to ocean acidification is poorly understood. We analysed the skeletal intracrystalline amino acids of massive, tropical Porites spp. corals cultured over different seawater pCO2. We find that concentrations of total amino acids, aspartic acid/asparagine (Asx), glutamic acid/glutamine and alanine are positively correlated with seawater pCO2 and inversely correlated with seawater pH. Almost all variance in calcification rates between corals can be explained by changes in the skeletal total amino acid, Asx, serine and alanine concentrations combined with the calcification media pH (a likely indicator of the dissolved inorganic carbon available to support calcification). We show that aspartic acid inhibits aragonite precipitation from seawater in vitro, at the pH, saturation state and approximate aspartic acid concentrations inferred to occur at the coral calcification site. Reducing seawater saturation state and increasing [aspartic acid], as occurs in some corals at high pCO2, both serve to increase the degree of inhibition, indicating that biomolecules may contribute to reduced coral calcification rates under ocean acidification.

2045-2322
Kellock, Celeste
1ee0e375-537a-4998-8dc7-10dbde6abdcc
Cole, Catherine
67504de5-efc6-4e39-987d-ece6fb873f19
Penkman, Kirsty
f94c1369-265e-4ddb-8578-80d6d6cdc616
Evans, David
878c65c7-eab9-4362-896b-166e165eb94b
Kröger, Roland
81d45bb6-2855-46e5-8d8b-7436ca668238
Hintz, Chris
e75794bb-e8f9-4779-a827-5d4524a131f7
Hintz, Ken
9e257fb0-1c68-43de-821f-db8e7bb942bc
Finch, Adrian
9aa72138-899e-4a5d-a47d-14ac8d904f1f
Allison, Nicola
f62c8053-72de-4197-a094-722a39998e94
Kellock, Celeste
1ee0e375-537a-4998-8dc7-10dbde6abdcc
Cole, Catherine
67504de5-efc6-4e39-987d-ece6fb873f19
Penkman, Kirsty
f94c1369-265e-4ddb-8578-80d6d6cdc616
Evans, David
878c65c7-eab9-4362-896b-166e165eb94b
Kröger, Roland
81d45bb6-2855-46e5-8d8b-7436ca668238
Hintz, Chris
e75794bb-e8f9-4779-a827-5d4524a131f7
Hintz, Ken
9e257fb0-1c68-43de-821f-db8e7bb942bc
Finch, Adrian
9aa72138-899e-4a5d-a47d-14ac8d904f1f
Allison, Nicola
f62c8053-72de-4197-a094-722a39998e94

Kellock, Celeste, Cole, Catherine, Penkman, Kirsty, Evans, David, Kröger, Roland, Hintz, Chris, Hintz, Ken, Finch, Adrian and Allison, Nicola (2020) The role of aspartic acid in reducing coral calcification under ocean acidification conditions. Scientific Reports, 10 (1), [12797]. (doi:10.1038/s41598-020-69556-0).

Record type: Article

Abstract

Biomolecules play key roles in regulating the precipitation of CaCO3 biominerals but their response to ocean acidification is poorly understood. We analysed the skeletal intracrystalline amino acids of massive, tropical Porites spp. corals cultured over different seawater pCO2. We find that concentrations of total amino acids, aspartic acid/asparagine (Asx), glutamic acid/glutamine and alanine are positively correlated with seawater pCO2 and inversely correlated with seawater pH. Almost all variance in calcification rates between corals can be explained by changes in the skeletal total amino acid, Asx, serine and alanine concentrations combined with the calcification media pH (a likely indicator of the dissolved inorganic carbon available to support calcification). We show that aspartic acid inhibits aragonite precipitation from seawater in vitro, at the pH, saturation state and approximate aspartic acid concentrations inferred to occur at the coral calcification site. Reducing seawater saturation state and increasing [aspartic acid], as occurs in some corals at high pCO2, both serve to increase the degree of inhibition, indicating that biomolecules may contribute to reduced coral calcification rates under ocean acidification.

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Published date: 1 December 2020
Additional Information: Publisher Copyright: © 2020, The Author(s).

Identifiers

Local EPrints ID: 503001
URI: http://eprints.soton.ac.uk/id/eprint/503001
DOI: doi:10.1038/s41598-020-69556-0
ISSN: 2045-2322
PURE UUID: b314c2e4-4e59-46c5-b215-b0c50d710d11
ORCID for David Evans: ORCID iD orcid.org/0000-0002-8685-671X

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Date deposited: 15 Jul 2025 16:56
Last modified: 17 Jul 2025 02:23

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Contributors

Author: Celeste Kellock
Author: Catherine Cole
Author: Kirsty Penkman
Author: David Evans ORCID iD
Author: Roland Kröger
Author: Chris Hintz
Author: Ken Hintz
Author: Adrian Finch
Author: Nicola Allison

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