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Title: Thermotolerant coral symbionts modulate heat stress‐responsive genes in their hosts
Abstract

Some corals may become more resistant to bleaching by shuffling their Symbiodiniaceae communities toward thermally tolerant species, and manipulations to boost the abundance of these symbionts in corals may increase resilience in warming oceans. However, the thermotolerant symbiontDurusdinium trenchiimay reduce growth and fecundity in Caribbean corals, and these tradeoffs need to be better understood as this symbiont spreads through the region. We sought to understand howD. trenchiimodulates coral gene expression by manipulating symbiont communities inMontastraea cavernosato produce replicate ramets containingD. trenchiitogether with paired ramets of these same genets (n = 3) containingCladocopiumC3 symbionts. We then examined differences in global gene expression between corals hostingDurusdiniumandCladocopiumunder control temperatures, and in response to short‐term heat stress. We identified numerous transcriptional differences associated with symbiont identity, which explained 2%–14% of the transcriptional variance. Corals withD. trenchiiupregulated genes related to translation, ribosomal structure and biogenesis, and downregulated genes related to extracellular structures, and carbohydrate and lipid transport and metabolism, relative to corals withCladocopium. Unexpectedly, these changes were similar to those observed inCladocopium‐dominated corals in response to heat stress, suggesting that thermotolerantD. trenchiimay cause corals to increase expression of heat stress‐responsive genes, explaining both the increased heat tolerance and the associated energetic tradeoffs in corals containingD. trenchii. These findings provide insight into the ecological changes occurring on contemporary coral reefs in response to climate change, and the diverse ways in which different symbionts modulate emergent phenotypes of their hosts.

 
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NSF-PAR ID:
10456473
Author(s) / Creator(s):
 ;  
Publisher / Repository:
Wiley-Blackwell
Date Published:
Journal Name:
Molecular Ecology
Volume:
29
Issue:
15
ISSN:
0962-1083
Page Range / eLocation ID:
p. 2940-2950
Format(s):
Medium: X
Sponsoring Org:
National Science Foundation
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