Ancestral genetic diversity associated with the rapid spread of stress-tolerant coral symbionts in response to holocene climate change

Benjamin C.C. Hume; Christian R. Voolstra; Chatchanit Arif; Cecilia D'Angelo; John A. Burt; Gal Eyal; Yossi Loya; Jörg Wiedenmann

doi:10.1073/pnas.1601910113

Ancestral genetic diversity associated with the rapid spread of stress-tolerant coral symbionts in response to holocene climate change

Benjamin C.C. Hume, Christian R. Voolstra, Chatchanit Arif, Cecilia D'Angelo, John A. Burt, Gal Eyal, Yossi Loya, Jörg Wiedenmann

Biology

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

Abstract

Coral communities in the Persian/Arabian Gulf (PAG) withstand unusually high salinity levels and regular summer temperature maxima of up to ∼35 °C that kill conspecifics elsewhere. Due to the recent formation of the PAG and its subsequent shift to a hot climate, these corals have had only <6, 000 y to adapt to these extreme conditions and can therefore inform on how coral reefs may respond to global warming. One key to coral survival in the world's warmest reefs are symbioses with a newly discovered alga, Symbiodinium thermophilum. Currently, it is unknown whether this symbiont originated elsewhere or emerged from unexpectedly fast evolution catalyzed by the extreme environment. Analyzing genetic diversity of symbiotic algae across >5, 000 km of the PAG, the Gulf of Oman, and the Red Sea coastline, we show that S. thermophilum is a member of a highly diverse, ancient group of symbionts cryptically distributed outside the PAG. We argue that the adjustment to temperature extremes by PAG corals was facilitated by the positive selection of preadapted symbionts. Our findings suggest that maintaining the largest possible pool of potentially stress-tolerant genotypes by protecting existing biodiversity is crucial to promote rapid adaptation to present-day climate change, not only for coral reefs, but for ecosystems in general.

Original language	English (US)
Pages (from-to)	4416-4421
Number of pages	6
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	113
Issue number	16
DOIs	https://doi.org/10.1073/pnas.1601910113
State	Published - Apr 19 2016

Keywords

Adaptation
Climate change
Coral
Persian/Arabian Gulf
Symbiodinium

ASJC Scopus subject areas

General

Access to Document

10.1073/pnas.1601910113

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Hume, B. C. C., Voolstra, C. R., Arif, C., D'Angelo, C., Burt, J. A., Eyal, G., Loya, Y., & Wiedenmann, J. (2016). Ancestral genetic diversity associated with the rapid spread of stress-tolerant coral symbionts in response to holocene climate change. Proceedings of the National Academy of Sciences of the United States of America, 113(16), 4416-4421. https://doi.org/10.1073/pnas.1601910113

Ancestral genetic diversity associated with the rapid spread of stress-tolerant coral symbionts in response to holocene climate change. / Hume, Benjamin C.C.; Voolstra, Christian R.; Arif, Chatchanit et al.
In: Proceedings of the National Academy of Sciences of the United States of America, Vol. 113, No. 16, 19.04.2016, p. 4416-4421.

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

Hume, BCC, Voolstra, CR, Arif, C, D'Angelo, C, Burt, JA, Eyal, G, Loya, Y & Wiedenmann, J 2016, 'Ancestral genetic diversity associated with the rapid spread of stress-tolerant coral symbionts in response to holocene climate change', Proceedings of the National Academy of Sciences of the United States of America, vol. 113, no. 16, pp. 4416-4421. https://doi.org/10.1073/pnas.1601910113

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title = "Ancestral genetic diversity associated with the rapid spread of stress-tolerant coral symbionts in response to holocene climate change",

abstract = "Coral communities in the Persian/Arabian Gulf (PAG) withstand unusually high salinity levels and regular summer temperature maxima of up to ∼35 °C that kill conspecifics elsewhere. Due to the recent formation of the PAG and its subsequent shift to a hot climate, these corals have had only <6, 000 y to adapt to these extreme conditions and can therefore inform on how coral reefs may respond to global warming. One key to coral survival in the world's warmest reefs are symbioses with a newly discovered alga, Symbiodinium thermophilum. Currently, it is unknown whether this symbiont originated elsewhere or emerged from unexpectedly fast evolution catalyzed by the extreme environment. Analyzing genetic diversity of symbiotic algae across >5, 000 km of the PAG, the Gulf of Oman, and the Red Sea coastline, we show that S. thermophilum is a member of a highly diverse, ancient group of symbionts cryptically distributed outside the PAG. We argue that the adjustment to temperature extremes by PAG corals was facilitated by the positive selection of preadapted symbionts. Our findings suggest that maintaining the largest possible pool of potentially stress-tolerant genotypes by protecting existing biodiversity is crucial to promote rapid adaptation to present-day climate change, not only for coral reefs, but for ecosystems in general.",

keywords = "Adaptation, Climate change, Coral, Persian/Arabian Gulf, Symbiodinium",

author = "Hume, {Benjamin C.C.} and Voolstra, {Christian R.} and Chatchanit Arif and Cecilia D'Angelo and Burt, {John A.} and Gal Eyal and Yossi Loya and J{\"o}rg Wiedenmann",

note = "Funding Information: We appreciate the help of Cornelia Roder, Sergey Dobretsov, Julia Schnetzer, Todd LaJeunesse, and Drew Wham with sample collection. A. Al-Hemeri (UAE Federal Environment Agency), A. Al-Cibahy (Environment Agency of Abu Dhabi), and the Oman Ministry of Environment & Climate Affairs kindly provided Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) export permits (no. 09FEA555) and collection permits. We acknowledge Tropical Marine Centre (London) and Tropic Marin (Wartenberg) for sponsoring the Coral Reef Laboratory at the University of Southampton. We thank the NYU Abu Dhabi Institute for supporting the 2012/2013 field workshops during which samples for this study were collected and the Interuniversity Institute for Marine Sciences in Eilat for field work support. The study was funded by Natural Environment Research Council Grant NE/K00641X/1 (to J.W.), the European Research Council under the European Union's Seventh Framework Programme Grant FP7/2007-2013/ERC Grant Agreement 311179 (to J.W.), the King Abdullah University of Science and Technology (C.R.V.), and Israel Science Foundation Grant 341/12, United States Agency for International Development/Middle East Regional Cooperation (USAID/MERC) No. M32-037 (to Y.L.).",

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AU - Arif, Chatchanit

AU - D'Angelo, Cecilia

AU - Burt, John A.

AU - Eyal, Gal

AU - Loya, Yossi

AU - Wiedenmann, Jörg

N1 - Funding Information: We appreciate the help of Cornelia Roder, Sergey Dobretsov, Julia Schnetzer, Todd LaJeunesse, and Drew Wham with sample collection. A. Al-Hemeri (UAE Federal Environment Agency), A. Al-Cibahy (Environment Agency of Abu Dhabi), and the Oman Ministry of Environment & Climate Affairs kindly provided Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) export permits (no. 09FEA555) and collection permits. We acknowledge Tropical Marine Centre (London) and Tropic Marin (Wartenberg) for sponsoring the Coral Reef Laboratory at the University of Southampton. We thank the NYU Abu Dhabi Institute for supporting the 2012/2013 field workshops during which samples for this study were collected and the Interuniversity Institute for Marine Sciences in Eilat for field work support. The study was funded by Natural Environment Research Council Grant NE/K00641X/1 (to J.W.), the European Research Council under the European Union's Seventh Framework Programme Grant FP7/2007-2013/ERC Grant Agreement 311179 (to J.W.), the King Abdullah University of Science and Technology (C.R.V.), and Israel Science Foundation Grant 341/12, United States Agency for International Development/Middle East Regional Cooperation (USAID/MERC) No. M32-037 (to Y.L.).

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N2 - Coral communities in the Persian/Arabian Gulf (PAG) withstand unusually high salinity levels and regular summer temperature maxima of up to ∼35 °C that kill conspecifics elsewhere. Due to the recent formation of the PAG and its subsequent shift to a hot climate, these corals have had only <6, 000 y to adapt to these extreme conditions and can therefore inform on how coral reefs may respond to global warming. One key to coral survival in the world's warmest reefs are symbioses with a newly discovered alga, Symbiodinium thermophilum. Currently, it is unknown whether this symbiont originated elsewhere or emerged from unexpectedly fast evolution catalyzed by the extreme environment. Analyzing genetic diversity of symbiotic algae across >5, 000 km of the PAG, the Gulf of Oman, and the Red Sea coastline, we show that S. thermophilum is a member of a highly diverse, ancient group of symbionts cryptically distributed outside the PAG. We argue that the adjustment to temperature extremes by PAG corals was facilitated by the positive selection of preadapted symbionts. Our findings suggest that maintaining the largest possible pool of potentially stress-tolerant genotypes by protecting existing biodiversity is crucial to promote rapid adaptation to present-day climate change, not only for coral reefs, but for ecosystems in general.

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Ancestral genetic diversity associated with the rapid spread of stress-tolerant coral symbionts in response to holocene climate change

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