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Main Authors: Hung, Julia Y, Cooke, Ira, Sato, Yui, Miller, David J, Bourne, David G
Format: Artículo científico
Language:en
Published: Environmental microbiology 2026
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/41644119/
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author Hung, Julia Y
Cooke, Ira
Sato, Yui
Miller, David J
Bourne, David G
author_facet Hung, Julia Y
Cooke, Ira
Sato, Yui
Miller, David J
Bourne, David G
Hung, Julia Y
Cooke, Ira
Sato, Yui
Miller, David J
Bourne, David G
collection PubMed - marine biology
contents Microbial Metabolism and Disease Virulence Changes Across Day and Night in Coral Black Band Disease Lesions. Hung, Julia Y Cooke, Ira Sato, Yui Miller, David J Bourne, David G Animals Anthozoa Virulence Bacteria Cyanobacteria Metagenome Photosynthesis Light Coral black band disease (BBD) is characterised as a cyanobacteria-dominated microbial mat that rapidly kills underlying coral tissue. Solar radiation promotes lesion progression by fuelling the cyanobacterial photosynthesis, while sulphate-reducing bacteria and sulphide-oxidising bacteria are implicated in sulphide dynamics within the mat. How the metabolism of the key microbial communities in the mat varies under light and dark conditions and impacts lesion virulence is poorly characterised, however. To compare microbial gene expression under different light regimes, we recovered 28 near-complete BBD-derived metagenome-assembled genomes (MAGs) using Oxford Nanopore Technologies long-read sequencing and profiled Illumina metatranscriptomic reads from BBD lesions collected at day and night by mapping to these MAGs. Genes from the cyanobacterium Roseofilum reptotaenium dominated the differentially expressed genes, with photosynthesis highly represented during the daytime. Relative expression of sulphur and nitrogen metabolism, cofactor biosynthesis, chemotaxis and motility increased among the non-cyanobacterial members at night. Enhanced sulphur reduction by Campylobacteriales and Desulfovibrionaceae at night likely supports a sulphide-rich and low oxygen micro-environment in the lesion, while increased chemotaxis and motility by Campylobacteriales and other heterotrophic bacteria drive lesion progression towards healthy coral tissue. This study provides insights into how diurnal light dynamics drive microbial metabolic pathways changes, thereby promoting BBD virulence.
format Artículo científico
id pubmed_41644119
institution PubMed
language en
publishDate 2026
publisher Environmental microbiology
record_format pubmed
spellingShingle Microbial Metabolism and Disease Virulence Changes Across Day and Night in Coral Black Band Disease Lesions.
Hung, Julia Y
Cooke, Ira
Sato, Yui
Miller, David J
Bourne, David G
Animals
Anthozoa
Virulence
Bacteria
Cyanobacteria
Metagenome
Photosynthesis
Light
Microbial Metabolism and Disease Virulence Changes Across Day and Night in Coral Black Band Disease Lesions. Hung, Julia Y Cooke, Ira Sato, Yui Miller, David J Bourne, David G Animals Anthozoa Virulence Bacteria Cyanobacteria Metagenome Photosynthesis Light Coral black band disease (BBD) is characterised as a cyanobacteria-dominated microbial mat that rapidly kills underlying coral tissue. Solar radiation promotes lesion progression by fuelling the cyanobacterial photosynthesis, while sulphate-reducing bacteria and sulphide-oxidising bacteria are implicated in sulphide dynamics within the mat. How the metabolism of the key microbial communities in the mat varies under light and dark conditions and impacts lesion virulence is poorly characterised, however. To compare microbial gene expression under different light regimes, we recovered 28 near-complete BBD-derived metagenome-assembled genomes (MAGs) using Oxford Nanopore Technologies long-read sequencing and profiled Illumina metatranscriptomic reads from BBD lesions collected at day and night by mapping to these MAGs. Genes from the cyanobacterium Roseofilum reptotaenium dominated the differentially expressed genes, with photosynthesis highly represented during the daytime. Relative expression of sulphur and nitrogen metabolism, cofactor biosynthesis, chemotaxis and motility increased among the non-cyanobacterial members at night. Enhanced sulphur reduction by Campylobacteriales and Desulfovibrionaceae at night likely supports a sulphide-rich and low oxygen micro-environment in the lesion, while increased chemotaxis and motility by Campylobacteriales and other heterotrophic bacteria drive lesion progression towards healthy coral tissue. This study provides insights into how diurnal light dynamics drive microbial metabolic pathways changes, thereby promoting BBD virulence.
title Microbial Metabolism and Disease Virulence Changes Across Day and Night in Coral Black Band Disease Lesions.
topic Animals
Anthozoa
Virulence
Bacteria
Cyanobacteria
Metagenome
Photosynthesis
Light
url https://pubmed.ncbi.nlm.nih.gov/41644119/