Planktonic foraminifera regulate calcification according to ocean density

Stergios D. Zarkogiannis; James W. B. Rae; Benjamin R. Shipley; P. Graham Mortyn

doi:10.1038/s43247-025-02558-w

Planktonic foraminifera regulate calcification according to ocean density

Stergios D. Zarkogiannis^*, James W. B. Rae, Benjamin R. Shipley, P. Graham Mortyn

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Planktonic foraminifera are key contributors to the oceanic carbon cycle. In pelagic environments, carbonate production by planktonic biomineralizers regulates ocean-atmosphere carbon dioxide exchange and exports surface carbon to the deep ocean. Here we compare shell traits of three planktonic foraminifera species from the central Atlantic with a suite of environmental parameters to discern the factors underlying their variations. Our analysis revealed that calcification in foraminifera is associated with seawater density and depends on species habitat depth, whereas foraminifera bulk shell densities may serve as a seawater density proxy, regardless of species. We observe that their shell weights increased with habitat depth, enabling the living cells to adjust their overall density to match that of the surrounding liquid. This suggests that calcification in nonmotile organisms has a buoyancy regulatory function and will respond to the anthropogenically driven reductions in ocean density (oceanic rarefication), with potential consequences for the carbon cycle.

Original language	English
Article number	605
Pages (from-to)	1-12
Number of pages	12
Journal	Communications Earth & Environment
Volume	6
DOIs	https://doi.org/10.1038/s43247-025-02558-w
Publication status	Published - 31 Jul 2025

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title = "Planktonic foraminifera regulate calcification according to ocean density",

abstract = "Planktonic foraminifera are key contributors to the oceanic carbon cycle. In pelagic environments, carbonate production by planktonic biomineralizers regulates ocean-atmosphere carbon dioxide exchange and exports surface carbon to the deep ocean. Here we compare shell traits of three planktonic foraminifera species from the central Atlantic with a suite of environmental parameters to discern the factors underlying their variations. Our analysis revealed that calcification in foraminifera is associated with seawater density and depends on species habitat depth, whereas foraminifera bulk shell densities may serve as a seawater density proxy, regardless of species. We observe that their shell weights increased with habitat depth, enabling the living cells to adjust their overall density to match that of the surrounding liquid. This suggests that calcification in nonmotile organisms has a buoyancy regulatory function and will respond to the anthropogenically driven reductions in ocean density (oceanic rarefication), with potential consequences for the carbon cycle.",

author = "Zarkogiannis, \{Stergios D.\} and Rae, \{James W. B.\} and Shipley, \{Benjamin R.\} and Mortyn, \{P. Graham\}",

note = "Funding: S.D.Z. would like to acknowledge the UK Research and Innovation Grant (SODIOM) EP/Y004221/1. B.R.S. is funded by the NSF EAR Postdoc Fellowship 2305234. J.W.B.R. was supported by European Research Council Horizon 2020 research and innovation programme grant agreement No. 805246. ",

year = "2025",

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doi = "10.1038/s43247-025-02558-w",

language = "English",

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AU - Zarkogiannis, Stergios D.

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AU - Shipley, Benjamin R.

AU - Mortyn, P. Graham

N1 - Funding: S.D.Z. would like to acknowledge the UK Research and Innovation Grant (SODIOM) EP/Y004221/1. B.R.S. is funded by the NSF EAR Postdoc Fellowship 2305234. J.W.B.R. was supported by European Research Council Horizon 2020 research and innovation programme grant agreement No. 805246.

PY - 2025/7/31

Y1 - 2025/7/31

N2 - Planktonic foraminifera are key contributors to the oceanic carbon cycle. In pelagic environments, carbonate production by planktonic biomineralizers regulates ocean-atmosphere carbon dioxide exchange and exports surface carbon to the deep ocean. Here we compare shell traits of three planktonic foraminifera species from the central Atlantic with a suite of environmental parameters to discern the factors underlying their variations. Our analysis revealed that calcification in foraminifera is associated with seawater density and depends on species habitat depth, whereas foraminifera bulk shell densities may serve as a seawater density proxy, regardless of species. We observe that their shell weights increased with habitat depth, enabling the living cells to adjust their overall density to match that of the surrounding liquid. This suggests that calcification in nonmotile organisms has a buoyancy regulatory function and will respond to the anthropogenically driven reductions in ocean density (oceanic rarefication), with potential consequences for the carbon cycle.

AB - Planktonic foraminifera are key contributors to the oceanic carbon cycle. In pelagic environments, carbonate production by planktonic biomineralizers regulates ocean-atmosphere carbon dioxide exchange and exports surface carbon to the deep ocean. Here we compare shell traits of three planktonic foraminifera species from the central Atlantic with a suite of environmental parameters to discern the factors underlying their variations. Our analysis revealed that calcification in foraminifera is associated with seawater density and depends on species habitat depth, whereas foraminifera bulk shell densities may serve as a seawater density proxy, regardless of species. We observe that their shell weights increased with habitat depth, enabling the living cells to adjust their overall density to match that of the surrounding liquid. This suggests that calcification in nonmotile organisms has a buoyancy regulatory function and will respond to the anthropogenically driven reductions in ocean density (oceanic rarefication), with potential consequences for the carbon cycle.

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Planktonic foraminifera regulate calcification according to ocean density

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Planktonic foraminifera regulate calcification according to ocean density

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