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Main Authors: Maritan, Andrew J, Clements, Cody S, Pratte, Zoe A, Hay, Mark E, Stewart, Frank J
Format: Artículo científico
Language:en
Published: The ISME journal 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/40318224/
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author Maritan, Andrew J
Clements, Cody S
Pratte, Zoe A
Hay, Mark E
Stewart, Frank J
author_facet Maritan, Andrew J
Clements, Cody S
Pratte, Zoe A
Hay, Mark E
Stewart, Frank J
Maritan, Andrew J
Clements, Cody S
Pratte, Zoe A
Hay, Mark E
Stewart, Frank J
collection PubMed - marine biology
contents Sea cucumber grazing linked to enrichment of anaerobic microbial metabolisms in coral reef sediments. Maritan, Andrew J Clements, Cody S Pratte, Zoe A Hay, Mark E Stewart, Frank J Animals Geologic Sediments RNA, Ribosomal, 16S Anaerobiosis Sea Cucumbers Coral Reefs Anthozoa Microbiota Polynesia Metagenomics Metagenome Bacteria Sea cucumbers have been overharvested world-wide, making assessments of their ecological effects challenging, but recent research demonstrated that sea cucumbers increased coral survival via disease suppression and were therefore important for facilitating reef health. The mechanisms underpinning the sea cucumber-coral interaction are not well understood but are likely mediated through sea cucumber grazing of microbes from reef sediments. We explored how sea cucumber grazing alters the sediment microbiome by leveraging a healthy sea cucumber population on a reef in French Polynesia. We used quantitative PCR, 16S rRNA gene sequencing, and shotgun metagenomics to compare the sediment microbiome in cages placed in situ with or without sea cucumbers. We hypothesized that grazing would lower microbial biomass, change sediment microbiome composition, and deplete sediment metagenomes of anaerobic metabolisms, likely due to aeration of the sediments. Sea cucumber grazing resulted in a 75% reduction in 16S rRNA gene abundances and reshaped microbiome composition, causing a significant decrease of cyanobacteria and other phototrophs relative to ungrazed sediments. Grazing also resulted in a depletion of genes associated with cyanotoxin synthesis, suggesting a potential link to coral health. In contrast to expectations, grazed sediment metagenomes were enriched with marker genes of diverse anaerobic or microaerophilic metabolisms, including those encoding high oxygen affinity cytochrome oxidases. This enrichment differs from patterns linked to other bioturbating invertebrates. We hypothesize that grazing enriches anaerobic processes in sediment microbiomes through removal of oxygen-producing autotrophs, fecal deposition of sea cucumber gut-associated anaerobes, or modification of sediment diffusibility. These results suggest that sea cucumber harvesting influences biogeochemical processes in reef sediments, potentially mediating coral survival by altering the sediment microbiome and its production of coral-influencing metabolites.
format Artículo científico
id pubmed_40318224
institution PubMed
language en
publishDate 2025
publisher The ISME journal
record_format pubmed
spellingShingle Sea cucumber grazing linked to enrichment of anaerobic microbial metabolisms in coral reef sediments.
Maritan, Andrew J
Clements, Cody S
Pratte, Zoe A
Hay, Mark E
Stewart, Frank J
Animals
Geologic Sediments
RNA, Ribosomal, 16S
Anaerobiosis
Sea Cucumbers
Coral Reefs
Anthozoa
Microbiota
Polynesia
Metagenomics
Metagenome
Bacteria
Sea cucumber grazing linked to enrichment of anaerobic microbial metabolisms in coral reef sediments. Maritan, Andrew J Clements, Cody S Pratte, Zoe A Hay, Mark E Stewart, Frank J Animals Geologic Sediments RNA, Ribosomal, 16S Anaerobiosis Sea Cucumbers Coral Reefs Anthozoa Microbiota Polynesia Metagenomics Metagenome Bacteria Sea cucumbers have been overharvested world-wide, making assessments of their ecological effects challenging, but recent research demonstrated that sea cucumbers increased coral survival via disease suppression and were therefore important for facilitating reef health. The mechanisms underpinning the sea cucumber-coral interaction are not well understood but are likely mediated through sea cucumber grazing of microbes from reef sediments. We explored how sea cucumber grazing alters the sediment microbiome by leveraging a healthy sea cucumber population on a reef in French Polynesia. We used quantitative PCR, 16S rRNA gene sequencing, and shotgun metagenomics to compare the sediment microbiome in cages placed in situ with or without sea cucumbers. We hypothesized that grazing would lower microbial biomass, change sediment microbiome composition, and deplete sediment metagenomes of anaerobic metabolisms, likely due to aeration of the sediments. Sea cucumber grazing resulted in a 75% reduction in 16S rRNA gene abundances and reshaped microbiome composition, causing a significant decrease of cyanobacteria and other phototrophs relative to ungrazed sediments. Grazing also resulted in a depletion of genes associated with cyanotoxin synthesis, suggesting a potential link to coral health. In contrast to expectations, grazed sediment metagenomes were enriched with marker genes of diverse anaerobic or microaerophilic metabolisms, including those encoding high oxygen affinity cytochrome oxidases. This enrichment differs from patterns linked to other bioturbating invertebrates. We hypothesize that grazing enriches anaerobic processes in sediment microbiomes through removal of oxygen-producing autotrophs, fecal deposition of sea cucumber gut-associated anaerobes, or modification of sediment diffusibility. These results suggest that sea cucumber harvesting influences biogeochemical processes in reef sediments, potentially mediating coral survival by altering the sediment microbiome and its production of coral-influencing metabolites.
title Sea cucumber grazing linked to enrichment of anaerobic microbial metabolisms in coral reef sediments.
topic Animals
Geologic Sediments
RNA, Ribosomal, 16S
Anaerobiosis
Sea Cucumbers
Coral Reefs
Anthozoa
Microbiota
Polynesia
Metagenomics
Metagenome
Bacteria
url https://pubmed.ncbi.nlm.nih.gov/40318224/