Calcite-aragonite seas as a driver of echinoderm evolution? Experimental insight and deep-time decoupling
Calcite-aragonite seas as a driver of echinoderm evolution? Experimental insight and deep-time decoupling
Seawater magnesium (Mg) and calcium (Ca) have undergone secular fluctuations throughout the Phanerozoic, controlling whether the dominant calcium carbonate precipitant is calcite or aragonite + high-Mg calcite. Although these oscillations in seawater Mg/Ca ratios have been implicated as an important control on Phanerozoic diversification of calcifying marine organisms, determining the degree to which Mg/Ca ratios affected different clades requires integration of experimental data with historical patterns of biodiversity from the fossil record. We explore short-term and long-term responses of echinoderms to shifting calcite-aragonite seas by combining experimental and deep-time biodiversity investigations. While experimental results support a strong relationship between Mg/Ca ratios and short-term echinoderm regeneration rates, patterns of Phanerozoic echinoderm diversification dynamics show no correspondence with Mg/Ca ratios or calcite-aragonite sea transitions. This decoupling between short- and long-term responses of echinoderms to seawater Mg/Ca ratios suggests echinoderms were relatively unaffected by seawater chemistry throughout their evolutionary history, possibly due to their ability to alter skeletal Mg fractionation and/or adapt to gradual shifts in seawater chemistry. Notably, our results indicate a strict uniformitarian extrapolation of experimental results over geological time scales may not be appropriate for many calcifying marine invertebrates. Instead, the effect of seawater Mg/Ca ratios should be evaluated for individual clades using both experimental and deep-time biodiversity data in a time series.
1091-1095
Cole, Selina R.
caaef4fe-97d3-48d0-a1bc-60f219288042
Wright, David F.
75d0701e-c96c-4e60-9f4a-ec795fd6265d
Thompson, Jeffrey R.
d2c9b7bb-3e33-4918-97c8-0c36e7af30a4
2023
Cole, Selina R.
caaef4fe-97d3-48d0-a1bc-60f219288042
Wright, David F.
75d0701e-c96c-4e60-9f4a-ec795fd6265d
Thompson, Jeffrey R.
d2c9b7bb-3e33-4918-97c8-0c36e7af30a4
Cole, Selina R., Wright, David F. and Thompson, Jeffrey R.
(2023)
Calcite-aragonite seas as a driver of echinoderm evolution? Experimental insight and deep-time decoupling.
Geology, 51 (12), .
(doi:10.1130/G51444.1).
Abstract
Seawater magnesium (Mg) and calcium (Ca) have undergone secular fluctuations throughout the Phanerozoic, controlling whether the dominant calcium carbonate precipitant is calcite or aragonite + high-Mg calcite. Although these oscillations in seawater Mg/Ca ratios have been implicated as an important control on Phanerozoic diversification of calcifying marine organisms, determining the degree to which Mg/Ca ratios affected different clades requires integration of experimental data with historical patterns of biodiversity from the fossil record. We explore short-term and long-term responses of echinoderms to shifting calcite-aragonite seas by combining experimental and deep-time biodiversity investigations. While experimental results support a strong relationship between Mg/Ca ratios and short-term echinoderm regeneration rates, patterns of Phanerozoic echinoderm diversification dynamics show no correspondence with Mg/Ca ratios or calcite-aragonite sea transitions. This decoupling between short- and long-term responses of echinoderms to seawater Mg/Ca ratios suggests echinoderms were relatively unaffected by seawater chemistry throughout their evolutionary history, possibly due to their ability to alter skeletal Mg fractionation and/or adapt to gradual shifts in seawater chemistry. Notably, our results indicate a strict uniformitarian extrapolation of experimental results over geological time scales may not be appropriate for many calcifying marine invertebrates. Instead, the effect of seawater Mg/Ca ratios should be evaluated for individual clades using both experimental and deep-time biodiversity data in a time series.
Text
Cole et al. 2023
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Accepted/In Press date: 24 August 2023
e-pub ahead of print date: 12 September 2023
Published date: 2023
Additional Information:
Funding Information:
We thank J.B. Ries for providing artificial seawater formulas and W.I. Ausich, W.B. Lyons, and M.E. Peter for helpful discussions. We thank P. Gorzelak and two anonymous reviewers for helpful comments. This work was supported by funding from Sigma Xi (J. Thompson), The Geological Society of America (S. Cole), and The Ohio State University Friends of Orton Hall (S. Cole).
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© (2023), (Geological Society of America). All Rights Reserved.
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Local EPrints ID: 483302
URI: http://eprints.soton.ac.uk/id/eprint/483302
ISSN: 0091-7613
PURE UUID: b99c78d3-0a07-43d9-bacc-49d07225a1a8
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Date deposited: 27 Oct 2023 16:45
Last modified: 18 Mar 2024 04:07
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Author:
Selina R. Cole
Author:
David F. Wright
Author:
Jeffrey R. Thompson
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