Stylasterid corals build aragonite skeletons in undersaturated water despite low pH at the site of calcification

Joseph A. Stewart; Ivo Strawson; James Kershaw; Laura F. Robinson

doi:10.1038/s41598-022-16787-y

Stylasterid corals build aragonite skeletons in undersaturated water despite low pH at the site of calcification

Joseph A. Stewart^*, Ivo Strawson, James Kershaw, Laura F. Robinson

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

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Abstract

Anthropogenic carbon emissions are causing seawater pH to decline, yet the impact on marine calcifiers is uncertain. Scleractinian corals and coralline algae strongly elevate the pH of their calcifying fluid (CF) to promote calcification. Other organisms adopt less energetically demanding calcification approaches but restrict their habitat. Stylasterid corals occur widely (extending well below the carbonate saturation horizon) and precipitate both aragonite and high-Mg calcite, however, their mode of biocalcification and resilience to ocean acidification are unknown. Here we measure skeletal boron isotopes (δ11B), B/Ca, and U/Ca to provide the first assessment of pH and rate of seawater flushing of stylasterid CF. Remarkably, both aragonitic and high-Mg calcitic stylasterids have low δ11B values implying little modification of internal pH. Collectively, our results suggest stylasterids have low seawater exchange rates into the calcifying space or rely on organic molecule templating to facilitate calcification. Thus, despite occupying similar niches to Scleractinia, Stylasteridae exhibit highly contrasting biocalcification, calling into question their resilience to ocean acidification.

Original language	English
Article number	13105
Number of pages	11
Journal	Scientific Reports
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41598-022-16787-y
Publication status	Published - 30 Jul 2022

Bibliographical note

Funding Information:
We acknowledge the crew and researchers on board the research vessels that obtained the samples for this study. Cruise AL1508 was supported by The Dalio Explore Fund. We also acknowledge the Galápagos National Park directorate for permission to map and collect submarine rock and biological samples (PC-44-15), and the Charles Darwin Foundation for facilitating scientific collaboration in the Galápagos. We thank C. Coath, and C. Taylor for their help with laboratory work and A. Gagnon for helpful discussion while preparing this manuscript. Funding was provided by an Antarctic Bursary awarded to J.A.S., ERC and NERC grants awarded to L.F.R. (NE/S001743/1; NE/R005117/1; NE/N003861/1).

Funding Information:
We acknowledge the crew and researchers on board the research vessels that obtained the samples for this study. Cruise AL1508 was supported by The Dalio Explore Fund. We also acknowledge the Galápagos National Park directorate for permission to map and collect submarine rock and biological samples (PC-44-15), and the Charles Darwin Foundation for facilitating scientific collaboration in the Galápagos. We thank C. Coath, and C. Taylor for their help with laboratory work and A. Gagnon for helpful discussion while preparing this manuscript. Funding was provided by an Antarctic Bursary awarded to J.A.S., ERC and NERC grants awarded to L.F.R. (NE/S001743/1; NE/R005117/1; NE/N003861/1).

Publisher Copyright:
© 2022, The Author(s).

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SDG 14 Life Below Water

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title = "Stylasterid corals build aragonite skeletons in undersaturated water despite low pH at the site of calcification",

abstract = "Anthropogenic carbon emissions are causing seawater pH to decline, yet the impact on marine calcifiers is uncertain. Scleractinian corals and coralline algae strongly elevate the pH of their calcifying fluid (CF) to promote calcification. Other organisms adopt less energetically demanding calcification approaches but restrict their habitat. Stylasterid corals occur widely (extending well below the carbonate saturation horizon) and precipitate both aragonite and high-Mg calcite, however, their mode of biocalcification and resilience to ocean acidification are unknown. Here we measure skeletal boron isotopes (δ11B), B/Ca, and U/Ca to provide the first assessment of pH and rate of seawater flushing of stylasterid CF. Remarkably, both aragonitic and high-Mg calcitic stylasterids have low δ11B values implying little modification of internal pH. Collectively, our results suggest stylasterids have low seawater exchange rates into the calcifying space or rely on organic molecule templating to facilitate calcification. Thus, despite occupying similar niches to Scleractinia, Stylasteridae exhibit highly contrasting biocalcification, calling into question their resilience to ocean acidification.",

author = "Stewart, \{Joseph A.\} and Ivo Strawson and James Kershaw and Robinson, \{Laura F.\}",

note = "Funding Information: We acknowledge the crew and researchers on board the research vessels that obtained the samples for this study. Cruise AL1508 was supported by The Dalio Explore Fund. We also acknowledge the Gal{\'a}pagos National Park directorate for permission to map and collect submarine rock and biological samples (PC-44-15), and the Charles Darwin Foundation for facilitating scientific collaboration in the Gal{\'a}pagos. We thank C. Coath, and C. Taylor for their help with laboratory work and A. Gagnon for helpful discussion while preparing this manuscript. Funding was provided by an Antarctic Bursary awarded to J.A.S., ERC and NERC grants awarded to L.F.R. (NE/S001743/1; NE/R005117/1; NE/N003861/1). Funding Information: We acknowledge the crew and researchers on board the research vessels that obtained the samples for this study. Cruise AL1508 was supported by The Dalio Explore Fund. We also acknowledge the Gal{\'a}pagos National Park directorate for permission to map and collect submarine rock and biological samples (PC-44-15), and the Charles Darwin Foundation for facilitating scientific collaboration in the Gal{\'a}pagos. We thank C. Coath, and C. Taylor for their help with laboratory work and A. Gagnon for helpful discussion while preparing this manuscript. Funding was provided by an Antarctic Bursary awarded to J.A.S., ERC and NERC grants awarded to L.F.R. (NE/S001743/1; NE/R005117/1; NE/N003861/1). Publisher Copyright: {\textcopyright} 2022, The Author(s).",

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AU - Stewart, Joseph A.

AU - Strawson, Ivo

AU - Kershaw, James

AU - Robinson, Laura F.

N1 - Funding Information: We acknowledge the crew and researchers on board the research vessels that obtained the samples for this study. Cruise AL1508 was supported by The Dalio Explore Fund. We also acknowledge the Galápagos National Park directorate for permission to map and collect submarine rock and biological samples (PC-44-15), and the Charles Darwin Foundation for facilitating scientific collaboration in the Galápagos. We thank C. Coath, and C. Taylor for their help with laboratory work and A. Gagnon for helpful discussion while preparing this manuscript. Funding was provided by an Antarctic Bursary awarded to J.A.S., ERC and NERC grants awarded to L.F.R. (NE/S001743/1; NE/R005117/1; NE/N003861/1). Funding Information: We acknowledge the crew and researchers on board the research vessels that obtained the samples for this study. Cruise AL1508 was supported by The Dalio Explore Fund. We also acknowledge the Galápagos National Park directorate for permission to map and collect submarine rock and biological samples (PC-44-15), and the Charles Darwin Foundation for facilitating scientific collaboration in the Galápagos. We thank C. Coath, and C. Taylor for their help with laboratory work and A. Gagnon for helpful discussion while preparing this manuscript. Funding was provided by an Antarctic Bursary awarded to J.A.S., ERC and NERC grants awarded to L.F.R. (NE/S001743/1; NE/R005117/1; NE/N003861/1). Publisher Copyright: © 2022, The Author(s).

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N2 - Anthropogenic carbon emissions are causing seawater pH to decline, yet the impact on marine calcifiers is uncertain. Scleractinian corals and coralline algae strongly elevate the pH of their calcifying fluid (CF) to promote calcification. Other organisms adopt less energetically demanding calcification approaches but restrict their habitat. Stylasterid corals occur widely (extending well below the carbonate saturation horizon) and precipitate both aragonite and high-Mg calcite, however, their mode of biocalcification and resilience to ocean acidification are unknown. Here we measure skeletal boron isotopes (δ11B), B/Ca, and U/Ca to provide the first assessment of pH and rate of seawater flushing of stylasterid CF. Remarkably, both aragonitic and high-Mg calcitic stylasterids have low δ11B values implying little modification of internal pH. Collectively, our results suggest stylasterids have low seawater exchange rates into the calcifying space or rely on organic molecule templating to facilitate calcification. Thus, despite occupying similar niches to Scleractinia, Stylasteridae exhibit highly contrasting biocalcification, calling into question their resilience to ocean acidification.

AB - Anthropogenic carbon emissions are causing seawater pH to decline, yet the impact on marine calcifiers is uncertain. Scleractinian corals and coralline algae strongly elevate the pH of their calcifying fluid (CF) to promote calcification. Other organisms adopt less energetically demanding calcification approaches but restrict their habitat. Stylasterid corals occur widely (extending well below the carbonate saturation horizon) and precipitate both aragonite and high-Mg calcite, however, their mode of biocalcification and resilience to ocean acidification are unknown. Here we measure skeletal boron isotopes (δ11B), B/Ca, and U/Ca to provide the first assessment of pH and rate of seawater flushing of stylasterid CF. Remarkably, both aragonitic and high-Mg calcitic stylasterids have low δ11B values implying little modification of internal pH. Collectively, our results suggest stylasterids have low seawater exchange rates into the calcifying space or rely on organic molecule templating to facilitate calcification. Thus, despite occupying similar niches to Scleractinia, Stylasteridae exhibit highly contrasting biocalcification, calling into question their resilience to ocean acidification.

U2 - 10.1038/s41598-022-16787-y

DO - 10.1038/s41598-022-16787-y

M3 - Article (Academic Journal)

C2 - 35907926

SN - 2045-2322

VL - 12

JO - Scientific Reports

JF - Scientific Reports

IS - 1

M1 - 13105

ER -

Stylasterid corals build aragonite skeletons in undersaturated water despite low pH at the site of calcification

Abstract

Bibliographical note

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