Integrative analysis of coral plasticity and adaptations reveals key proteins driving resilience to changes in ocean carbonate chemistry

Xiangcheng YUAN; Ellias Y. FENG; Jingtian WANG; Lei JIANG; Tao YUAN; Hui HUANG; Weihua ZHOU; Jack Chi Ho IP; Wei Jun CAI; Senjie LIN

doi:10.1007/s42995-025-00321-w

Integrative analysis of coral plasticity and adaptations reveals key proteins driving resilience to changes in ocean carbonate chemistry

Xiangcheng YUAN
, Ellias Y. FENG^*
, Jingtian WANG
, Lei JIANG
, Tao YUAN
, Hui HUANG
, Weihua ZHOU
, Jack Chi Ho IP
, Wei Jun CAI
, Senjie LIN^*

^*Corresponding author for this work

Division of Science

Research output: Journal Publications › Journal Article (refereed) › peer-review

Abstract

Understanding how corals adapt to changes in seawater carbonate chemistry is crucial for developing effective coral conservation strategies. Research to date has mostly focused on short-term experiments, overlooking long-term evolutionary effects. Here, we investigated the link between short-term stress responses and long-term genetic adaptations in the coral species Porites pukoensis through experiments under varying CO2 and alkalinity conditions. Our results showed that alkalinity enrichment significantly increased coral calcification rates by 35%-45% compared to high CO2 treatment, highlighting the potential of alkalinity enrichment to mitigate acidification impacts. Corals modulated relative expression levels of basic and acidic proteins in response to changes in seawater carbonate chemistry in the stress experiments. Genomic data revealed that this mechanism has been evolutionarily fixed in various organisms adapting to seawater carbonate chemistry. Additionally, both experimental and genomic results showed that extracellular matrix proteins, like collagen with von Willebrand factor type A domain, were modified in response to distinct carbonate environments. Molecular dynamics simulations and in-vitro experiments demonstrated that the structural stability of these proteins contributes to coral resilience under acidified conditions. This study established an integrated framework combining stress experiments, multi-omics analyses, molecular simulations, and in-vitro validation to identify key proteins involved in coral adaptation to acidification.

Original language	English
Pages (from-to)	1008-1020
Number of pages	13
Journal	Marine Life Science & Technology
Volume	7
Issue number	4
DOIs	https://doi.org/10.1007/s42995-025-00321-w https://doi.org/10.1007/s42995-025-00321-w
Publication status	Published - 5 Nov 2025

Bibliographical note

We would like to express our gratitude to Zhenyue Lin for kindly permitting the use of proteomic data in his paper, Lin et al. (2022). We are also grateful to Yuxian Liang and Youfang Sun for their assistance and expertise in conducting the experiments.

Publisher Copyright:
© The Author(s) 2025.

Funding

Hainan Province Key R&D Program Project (ZDYF2023SHFZ131). National Key R&D Program Project (2021YFF0502800, 20223–6), and NSFC (42494882, U23A2036). The Key Special Project for Introduced Talents Team (GML2019ZD0404). NRSTS Natural Resources Science and Technology Strategy Research Project (2023-ZL-66). Lin was in part supported by the Gordon and Betty Moore Foundation grant #4980.01. Feng was supported by Tai Young Scholar Fund.

Keywords

Alkalinity enrichment
Coral
Translation efficiency
Ocean acidification
Protein isoelectric point (pI)

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

https://link.springer.com/10.1007/s42995-025-00321-w

Cite this

YUAN, X., FENG, E. Y., WANG, J., JIANG, L., YUAN, T., HUANG, H., ZHOU, W., IP, J. C. H., CAI, W. J., & LIN, S. (2025). Integrative analysis of coral plasticity and adaptations reveals key proteins driving resilience to changes in ocean carbonate chemistry. Marine Life Science & Technology, 7(4), 1008-1020. https://doi.org/10.1007/s42995-025-00321-w, https://doi.org/10.1007/s42995-025-00321-w

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title = "Integrative analysis of coral plasticity and adaptations reveals key proteins driving resilience to changes in ocean carbonate chemistry",

abstract = "Understanding how corals adapt to changes in seawater carbonate chemistry is crucial for developing effective coral conservation strategies. Research to date has mostly focused on short-term experiments, overlooking long-term evolutionary effects. Here, we investigated the link between short-term stress responses and long-term genetic adaptations in the coral species Porites pukoensis through experiments under varying CO2 and alkalinity conditions. Our results showed that alkalinity enrichment significantly increased coral calcification rates by 35\%-45\% compared to high CO2 treatment, highlighting the potential of alkalinity enrichment to mitigate acidification impacts. Corals modulated relative expression levels of basic and acidic proteins in response to changes in seawater carbonate chemistry in the stress experiments. Genomic data revealed that this mechanism has been evolutionarily fixed in various organisms adapting to seawater carbonate chemistry. Additionally, both experimental and genomic results showed that extracellular matrix proteins, like collagen with von Willebrand factor type A domain, were modified in response to distinct carbonate environments. Molecular dynamics simulations and in-vitro experiments demonstrated that the structural stability of these proteins contributes to coral resilience under acidified conditions. This study established an integrated framework combining stress experiments, multi-omics analyses, molecular simulations, and in-vitro validation to identify key proteins involved in coral adaptation to acidification.",

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author = "Xiangcheng YUAN and FENG, \{Ellias Y.\} and Jingtian WANG and Lei JIANG and Tao YUAN and Hui HUANG and Weihua ZHOU and IP, \{Jack Chi Ho\} and CAI, \{Wei Jun\} and Senjie LIN",

note = "We would like to express our gratitude to Zhenyue Lin for kindly permitting the use of proteomic data in his paper, Lin et al. (2022). We are also grateful to Yuxian Liang and Youfang Sun for their assistance and expertise in conducting the experiments. Publisher Copyright: {\textcopyright} The Author(s) 2025.",

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doi = "10.1007/s42995-025-00321-w",

language = "English",

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YUAN, X, FENG, EY, WANG, J, JIANG, L, YUAN, T, HUANG, H, ZHOU, W, IP, JCH, CAI, WJ & LIN, S 2025, 'Integrative analysis of coral plasticity and adaptations reveals key proteins driving resilience to changes in ocean carbonate chemistry', Marine Life Science & Technology, vol. 7, no. 4, pp. 1008-1020. https://doi.org/10.1007/s42995-025-00321-w, https://doi.org/10.1007/s42995-025-00321-w

TY - JOUR

T1 - Integrative analysis of coral plasticity and adaptations reveals key proteins driving resilience to changes in ocean carbonate chemistry

AU - YUAN, Xiangcheng

AU - FENG, Ellias Y.

AU - WANG, Jingtian

AU - JIANG, Lei

AU - YUAN, Tao

AU - HUANG, Hui

AU - ZHOU, Weihua

AU - IP, Jack Chi Ho

AU - CAI, Wei Jun

AU - LIN, Senjie

N1 - We would like to express our gratitude to Zhenyue Lin for kindly permitting the use of proteomic data in his paper, Lin et al. (2022). We are also grateful to Yuxian Liang and Youfang Sun for their assistance and expertise in conducting the experiments. Publisher Copyright: © The Author(s) 2025.

PY - 2025/11/5

Y1 - 2025/11/5

N2 - Understanding how corals adapt to changes in seawater carbonate chemistry is crucial for developing effective coral conservation strategies. Research to date has mostly focused on short-term experiments, overlooking long-term evolutionary effects. Here, we investigated the link between short-term stress responses and long-term genetic adaptations in the coral species Porites pukoensis through experiments under varying CO2 and alkalinity conditions. Our results showed that alkalinity enrichment significantly increased coral calcification rates by 35%-45% compared to high CO2 treatment, highlighting the potential of alkalinity enrichment to mitigate acidification impacts. Corals modulated relative expression levels of basic and acidic proteins in response to changes in seawater carbonate chemistry in the stress experiments. Genomic data revealed that this mechanism has been evolutionarily fixed in various organisms adapting to seawater carbonate chemistry. Additionally, both experimental and genomic results showed that extracellular matrix proteins, like collagen with von Willebrand factor type A domain, were modified in response to distinct carbonate environments. Molecular dynamics simulations and in-vitro experiments demonstrated that the structural stability of these proteins contributes to coral resilience under acidified conditions. This study established an integrated framework combining stress experiments, multi-omics analyses, molecular simulations, and in-vitro validation to identify key proteins involved in coral adaptation to acidification.

AB - Understanding how corals adapt to changes in seawater carbonate chemistry is crucial for developing effective coral conservation strategies. Research to date has mostly focused on short-term experiments, overlooking long-term evolutionary effects. Here, we investigated the link between short-term stress responses and long-term genetic adaptations in the coral species Porites pukoensis through experiments under varying CO2 and alkalinity conditions. Our results showed that alkalinity enrichment significantly increased coral calcification rates by 35%-45% compared to high CO2 treatment, highlighting the potential of alkalinity enrichment to mitigate acidification impacts. Corals modulated relative expression levels of basic and acidic proteins in response to changes in seawater carbonate chemistry in the stress experiments. Genomic data revealed that this mechanism has been evolutionarily fixed in various organisms adapting to seawater carbonate chemistry. Additionally, both experimental and genomic results showed that extracellular matrix proteins, like collagen with von Willebrand factor type A domain, were modified in response to distinct carbonate environments. Molecular dynamics simulations and in-vitro experiments demonstrated that the structural stability of these proteins contributes to coral resilience under acidified conditions. This study established an integrated framework combining stress experiments, multi-omics analyses, molecular simulations, and in-vitro validation to identify key proteins involved in coral adaptation to acidification.

KW - Alkalinity enrichment

KW - Coral

KW - Translation efficiency

KW - Ocean acidification

KW - Protein isoelectric point (pI)

UR - https://www.scopus.com/pages/publications/105021119927

U2 - 10.1007/s42995-025-00321-w

DO - 10.1007/s42995-025-00321-w

M3 - Journal Article (refereed)

SN - 2662-1746

VL - 7

SP - 1008

EP - 1020

JO - Marine Life Science & Technology

JF - Marine Life Science & Technology

IS - 4

ER -

Integrative analysis of coral plasticity and adaptations reveals key proteins driving resilience to changes in ocean carbonate chemistry

Abstract

Bibliographical note

Funding

Keywords

UN SDGs

Access to Document

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Cite this