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Seawater carbon chemistry and calcification,carbonic anhydrase activity of cold-water coral Lophelia pertusa

Ocean acidification, the decrease in seawater pH due to the absorption of atmospheric CO2, profoundly threatens the survival of a large number of marine species. Cold-water corals are considered to be among the most vulnerable organisms to ocean acidification because they are already exposed to relatively low pH and corresponding low calcium carbonate saturation states (Omega). Lophelia pertusa is a globally distributed cold-water scleractinian coral that provides critical three-dimensional habitat for many ecologically and economically significant species. In this study, four different genotypes of L. pertusa were exposed to three pH treatments (pH=7.60, 7.75, and 7.90) over a short (two-week) experimental period, and six genotypes were exposed to two pH treatments (pH=7.60, and 7.90) over a long (six-month) experimental period. Their physiological response was measured as net calcification rate and the activity of carbonic anhydrase, a key enzyme in the calcification pathway. In the short-term experiment, net calcification rates did not significantly change with pH, although they were highly variable in the low pH treatment, including some genotypes that maintained positive net calcification in undersaturated conditions. In the six-month experiment, average net calcification was significantly reduced at low pH, with corals exhibiting net dissolution of skeleton. However, one of the same genotypes that maintained positive net calcification (+0.04% day-1) under the low pH treatment in the short-term experiment also maintained positive net calcification longer than the other genotypes in the long-term experiment, although none of the corals maintained positive calcification for the entire 6 months. Average carbonic anhydrase activity was not affected by pH, although some genotypes exhibited small, insignificant, increases in activity after the sixth month. Our results suggest that while net calcification in L. pertusa is adversely affected by ocean acidification in the long term, it is possible that some genotypes may prove to be more resilient than others, particularly to short perturbations of the carbonate system. These results provide evidence that populations of L. pertusa in the Gulf of Mexico may contain the genetic variability necessary to support an adaptive response to future ocean acidification.

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Kurman, Melissa, Gómez, C E, Georgian, Samuel E, Lunden, Jay J, Cordes, Erik E (2017). Dataset: Seawater carbon chemistry and calcification,carbonic anhydrase activity of cold-water coral Lophelia pertusa. https://doi.org/10.1594/PANGAEA.877984

DOI retrieved: 2017

Additional Info

Field Value
Imported on November 30, 2024
Last update November 30, 2024
License CC-BY-3.0
Source https://doi.org/10.1594/PANGAEA.877984
Author Kurman, Melissa
Given Name Melissa
Family Name Kurman
More Authors
Gómez, C E
Georgian, Samuel E
Lunden, Jay J
Cordes, Erik E
Source Creation 2017
Publication Year 2017
Resource Type text/tab-separated-values - filename: Kurman-etal_2017
Subject Areas
Name: BiologicalClassification

Name: Chemistry

Name: Ecology

Related Identifiers
Title: Intra-Specific Variation Reveals Potential for Adaptation to Ocean Acidification in a Cold-Water Coral from the Gulf of Mexico
Identifier: https://doi.org/10.3389/fmars.2017.00111
Type: DOI
Relation: IsSupplementTo
Year: 2017
Source: Frontiers in Marine Science
Authors: Kurman Melissa , Gómez C E , Georgian Samuel E , Lunden Jay J , Cordes Erik E .

Title: seacarb: seawater carbonate chemistry with R. R package version 3.1
Identifier: https://cran.r-project.org/package=seacarb
Type: DOI
Relation: References
Year: 2016
Authors: Gattuso Jean-Pierre , Epitalon Jean-Marie , Lavigne Héloïse , Orr James C , Gentili Bernard , Proye Aurélien , Soetaert Karline , Rae James .