Multiple carbonate system parameters independently govern shell formation in a marine mussel

Abstract Calcification is vital to marine organisms that produce calcium carbonate shells and skeletons. However, how calcification is impacted by ongoing environmental changes, including ocean acidification, remains incompletely understood due to complex relationships among the carbonate system var...

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Bibliographic Details
Published inCommunications earth & environment Vol. 5; no. 1; pp. 273 - 13
Main Authors Ninokawa, Aaron T., Saley, Alisha M., Shalchi, Roya, Gaylord, Brian
Format Journal Article
LanguageEnglish
Published London Nature Publishing Group 01.12.2024
Nature Portfolio
Subjects
Acidification
Alkalinity
Bicarbonates
Calcification
Calcium carbonate
Environmental changes
Hydrogen ion concentration
Hydrogen ions
Ion concentration
Marine organisms
Mollusks
Mussels
Mytilus californianus
Ocean acidification
Parameters
pH effects
Seawater
Substrate inhibition
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Summary:Abstract Calcification is vital to marine organisms that produce calcium carbonate shells and skeletons. However, how calcification is impacted by ongoing environmental changes, including ocean acidification, remains incompletely understood due to complex relationships among the carbonate system variables hypothesized to drive calcification. Here, we experimentally decouple these drivers in an exploration of shell formation in adult marine mussels, Mytilus californianus . In contrast to models that focus on single parameters like calcium carbonate saturation state, our results implicate two independent factors, bicarbonate concentration and seawater pH, in governing calcification. While qualitatively similar to ideas embodied in the related substrate-inhibitor ratio (bicarbonate divided by hydrogen ion concentration), our data highlight that merging bicarbonate ion and hydrogen ion concentrations into a simple quotient obscures important features of calcification. Considering a dual-parameter framework improves mechanistic understanding of how calcifiers interact with complex and changing chemical conditions.
ISSN:2662-4435
2662-4435
DOI:10.1038/s43247-024-01440-5