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Main Authors: Brown, Anya L, McGovern, Meriel J, Schickle, Alicia, Sharp, Koty H, Apprill, Amy
Format: Artículo científico
Language:en
Published: Frontiers in microbiology 2026
Online Access:https://pubmed.ncbi.nlm.nih.gov/42182007/
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author Brown, Anya L
McGovern, Meriel J
Schickle, Alicia
Sharp, Koty H
Apprill, Amy
author_facet Brown, Anya L
McGovern, Meriel J
Schickle, Alicia
Sharp, Koty H
Apprill, Amy
Brown, Anya L
McGovern, Meriel J
Schickle, Alicia
Sharp, Koty H
Apprill, Amy
collection PubMed - marine biology
contents Controlled temperature-induced dormancy leads to predictable microbial recovery in the temperate coral microbiome. Brown, Anya L McGovern, Meriel J Schickle, Alicia Sharp, Koty H Apprill, Amy Dormancy is a common response to harsh conditions across the tree of life. Increasingly, the animal microbiome is suggested to mediate dormancy, including onset, maintenance and exit or recovery periods. However, it is unclear what triggers dormancy and the consistency of microbial patterns across populations. Because it regularly undergoes dormancy during winter in the northernmost part of its range, the temperate coral can serve as a model for studying coral-microbiome dynamics during environmental stress and recovery. Here, we experimentally manipulated temperature to induce dormancy and measured the microbial community shifts associated with dormancy and during the days that the corals were exiting dormancy in two populations. Our treatments successfully induced dormancy, which was maintained through low temperatures. We found consistent and predictable shifts in the microbiome during dormancy and during the recovery period while corals exited dormancy. We suggest , a key genus in tropical corals, may be involved in early recovery in the assembly of the microbiome. Broadly, our results highlight that the inducible, consistent, and persistent microbial restructuring associated with dormancy can be applied more generally to tropical coral recovery from stress.
format Artículo científico
id pubmed_42182007
institution PubMed
language en
publishDate 2026
publisher Frontiers in microbiology
record_format pubmed
spellingShingle Controlled temperature-induced dormancy leads to predictable microbial recovery in the temperate coral microbiome.
Brown, Anya L
McGovern, Meriel J
Schickle, Alicia
Sharp, Koty H
Apprill, Amy
Controlled temperature-induced dormancy leads to predictable microbial recovery in the temperate coral microbiome. Brown, Anya L McGovern, Meriel J Schickle, Alicia Sharp, Koty H Apprill, Amy Dormancy is a common response to harsh conditions across the tree of life. Increasingly, the animal microbiome is suggested to mediate dormancy, including onset, maintenance and exit or recovery periods. However, it is unclear what triggers dormancy and the consistency of microbial patterns across populations. Because it regularly undergoes dormancy during winter in the northernmost part of its range, the temperate coral can serve as a model for studying coral-microbiome dynamics during environmental stress and recovery. Here, we experimentally manipulated temperature to induce dormancy and measured the microbial community shifts associated with dormancy and during the days that the corals were exiting dormancy in two populations. Our treatments successfully induced dormancy, which was maintained through low temperatures. We found consistent and predictable shifts in the microbiome during dormancy and during the recovery period while corals exited dormancy. We suggest , a key genus in tropical corals, may be involved in early recovery in the assembly of the microbiome. Broadly, our results highlight that the inducible, consistent, and persistent microbial restructuring associated with dormancy can be applied more generally to tropical coral recovery from stress.
title Controlled temperature-induced dormancy leads to predictable microbial recovery in the temperate coral microbiome.
url https://pubmed.ncbi.nlm.nih.gov/42182007/