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Heat stress decreases the diversity, abundance and functional potential of coral gas emissions
Journal article   Peer reviewed

Heat stress decreases the diversity, abundance and functional potential of coral gas emissions

Caitlin A Lawson, Jean‐Baptiste Raina, Elisabeth Deschaseaux, Victoria Hrebien, Malcolm Possell, Justin R Seymour and David J Suggett
Global Change Biology, Vol.27(4), pp.879-891
02/2021
DOI: https://doi.org/10.1111/gcb.15446
PMID: 33253484
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Heat stress decreases the diversityView
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Abstract

volatilome heat stress biogenic volatile organic compounds BVOC emissions DMS biogeochemical cycling Pocillopora damicornis Acropora intermedia coral bleaching
Terrestrial ecosystems emit large quantities of biogenic volatile organic compounds (BVOCs), many of which play important roles in abiotic stress responses, pathogen and grazing defences, inter- and intra-species communications, and climate regulation. Conversely, comparatively little is known about the diversity and functional potential of BVOCs produced in the marine environment, especially in highly productive coral reefs. Here we describe the first ‘volatilomes’ of two common reef-building corals, Acropora intermedia and Pocillopora damicornis, and how the functional potential of their gaseous emissions is altered by heat stress events that are driving rapid deterioration of coral reef ecosystems worldwide. A total of 87 BVOCs were detected from the two species and the chemical richness of both coral volatilomes—particularly the chemical classes of alkanes and carboxylic acids—decreased during heat stress by 41% and 62% in A. intermedia and P. damicornis, respectively. Across both coral species, the abundance of individual compounds changed significantly during heat stress, with the majority (>86%) significantly decreasing compared to control conditions. Additionally, almost 60% of the coral volatilome (or 52 BVOCs) could be assigned to four key functional groups based on their activities in other species or systems, including stress response, chemical signalling, climate regulation and antimicrobial activity. The total number of compounds assigned to these functions decreased significantly under heat stress for both A. intermedia (by 35%) and P. damicornis (by 64%), with most dramatic losses found for climatically active BVOCs in P. damicornis and antimicrobial BVOCs in A. intermedia. Together, our observations suggest that future heat stress events predicted for coral reefs will reduce the diversity, quantity and functional potential of BVOCs emitted by reef-building corals, potentially further compromising the healthy functioning of these ecosystems.

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