Using naturally occurring climate resilient corals to construct bleaching-resistant nurseries

Using naturally occurring climate resilient corals to construct bleaching-resistant nurseries

Ecological restoration of forests, meadows, reefs, or other foundational ecosystems during climate change depends on the discovery and use of individuals able to withstand future conditions. For coral reefs, climate-tolerant corals might not remain tolerant in different environments because of wides...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 116; no. 21; pp. 10586 - 10591
Main Authors: Morikawa, Megan K., Palumbi, Stephen R.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 21-05-2019
Subjects:
Animals
Anthozoa - microbiology
Anthozoa - physiology
Aquaculture - methods
Biological Sciences
Biomarkers
Bleaching
Climate Change
Colonies
Coral Reefs
Corals
Environmental changes
Environmental restoration
Environmental Restoration and Remediation - methods
Forest ecosystems
Genetic diversity
Genotypes
Heat stress
Heat tolerance
Heat-Shock Response
Meadows
Microclimate
Parents
Restoration
Species
Symbionts
Symbiosis
Temperature tolerance
Thermal stress
Thermotolerance
American Samoa
coral resilience
restoration
bleaching
climate change
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Summary:Ecological restoration of forests, meadows, reefs, or other foundational ecosystems during climate change depends on the discovery and use of individuals able to withstand future conditions. For coral reefs, climate-tolerant corals might not remain tolerant in different environments because of widespread environmental adjustment of coral physiology and symbionts. Here, we test if parent corals retain their heat tolerance in nursery settings, if simple proxies predict successful colonies, and if heat-tolerant corals suffer lower growth or survival in normal settings. Before the 2015 natural bleaching event in American Samoa, we set out 800 coral fragments from 80 colonies of four species selected by prior tests to have a range of intraspecific natural heat tolerance. After the event, nursery stock from heat-tolerant parents showed two to three times less bleaching across species than nursery stock from less tolerant parents. They also retained higher individual genetic diversity through the bleaching event than did less heat-tolerant corals. The three best proxies for thermal tolerance were response to experimental heat stress, location on the reef, and thermal microclimate. Molecular biomarkers were also predictive but were highly species specific. Colony geno-type and symbiont genus played a similarly strong role in predicting bleaching. Combined, our results show that selecting for host and symbiont resilience produced a multispecies coral nursery that withstood multiple bleaching events, that proxies for thermal tolerance in restoration can work across species and be inexpensive, and that different coral clones within species reacted very differently to bleaching.
Bibliography:Contributed by Stephen R. Palumbi, February 27, 2019 (sent for review December 11, 2017; reviewed by Andrew C. Baker, Les Kaufman, and Nancy Knowlton)
Author contributions: M.K.M. and S.R.P. designed research; M.K.M. performed research; M.K.M. and S.R.P. analyzed data; and M.K.M. and S.R.P. wrote the paper.
Reviewers: A.C.B., University of Miami; L.K., Boston University; and N.K., Smithsonian Institution.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1721415116