Time Series Resolution of the Fish Necrobiome Reveals a Decomposer Succession Involving Toxigenic Bacterial Pathogens

The microbial decomposition of animal tissues is an important ecological process that impacts nutrient cycling in natural environments. We studied the microbial decomposition of a common North American fish (rainbow darters) over four time points, combining 16S rRNA gene and shotgun metagenomic sequ...

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Main Authors: Briallen Lobb, Rhiannon Hodgson, Michael D. J. Lynch, Michael J. Mansfield, Jiujun Cheng, Trevor C. Charles, Josh D. Neufeld, Paul M. Craig, Andrew C. Doxey
Format: Article
Language:English
Published: American Society for Microbiology 2020-04-01
Series:mSystems
Subjects:
Online Access:https://doi.org/10.1128/mSystems.00145-20
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spelling doaj-529601045f554c27a78d03ea93a7955f2020-11-25T03:17:43ZengAmerican Society for MicrobiologymSystems2379-50772020-04-0152e00145-2010.1128/mSystems.00145-20Time Series Resolution of the Fish Necrobiome Reveals a Decomposer Succession Involving Toxigenic Bacterial PathogensBriallen LobbRhiannon HodgsonMichael D. J. LynchMichael J. MansfieldJiujun ChengTrevor C. CharlesJosh D. NeufeldPaul M. CraigAndrew C. DoxeyThe microbial decomposition of animal tissues is an important ecological process that impacts nutrient cycling in natural environments. We studied the microbial decomposition of a common North American fish (rainbow darters) over four time points, combining 16S rRNA gene and shotgun metagenomic sequence data to obtain both taxonomic and functional perspectives. Our data revealed a strong community succession that was reproduced across different fish and environments. Decomposition time point was the main driver of community composition and functional potential; fish environmental origin (upstream or downstream of a wastewater treatment plant) had a secondary effect. We also identified strains related to the putative pathogen Aeromonas veronii as dominant members of the decomposition community. These bacteria peaked early in decomposition and coincided with the metagenomic abundance of hemolytic toxin genes. Our work reveals a strong decomposer succession in wild-caught fish, providing functional and taxonomic insights into the vertebrate necrobiome.Despite progress understanding microbial communities involved in terrestrial vertebrate decomposition, little is known about the microbial decomposition of aquatic vertebrates from a functional and environmental context. Here, we analyzed temporal changes in the “necrobiome” of rainbow darters, which are common North American fish that are sensitive indicators of water quality. By combining 16S rRNA gene and shotgun metagenomic sequence data from four time points, we studied the progression of decomposers from both taxonomic and functional perspectives. The 16S rRNA gene profiles revealed strong community succession, with early decomposition stages associated with Aeromonas and Clostridium taxa and later stages dominated by members of the Rikenellaceae (i.e., Alistipes/Acetobacteroides genera). These results were reproducible and independent of environmental perturbation, given that exposure to wastewater treatment plant effluent did not substantially influence the necrobiome composition of fish or the associated water sample microbiota. Metagenomic analysis revealed significant changes throughout decomposition in degradation pathways for amino acids, carbohydrates/glycans, and other compounds, in addition to putrefaction pathways for production of putrescine, cadaverine, and indole. Binning of contigs confirmed a predominance of Aeromonas genome assemblies, including those from novel strains related to the pathogen Aeromonas veronii. These bins of Aeromonas genes also encoded known hemolysin toxins (e.g., aerolysin) that were particularly abundant early in the process, potentially contributing to host cell lysis during decomposition. Overall, our results demonstrate that wild-caught fish have a reproducible decomposer succession and that the fish necrobiome serves as a potential source of putative pathogens and toxigenic bacteria.https://doi.org/10.1128/mSystems.00145-20necrobiomemicrobiomedecompositionwastewaterrainbow darteraeromonasaerolysincommunity profilingfishmetagenomicsthanatomicrobiometoxins
collection DOAJ
language English
format Article
sources DOAJ
author Briallen Lobb
Rhiannon Hodgson
Michael D. J. Lynch
Michael J. Mansfield
Jiujun Cheng
Trevor C. Charles
Josh D. Neufeld
Paul M. Craig
Andrew C. Doxey
spellingShingle Briallen Lobb
Rhiannon Hodgson
Michael D. J. Lynch
Michael J. Mansfield
Jiujun Cheng
Trevor C. Charles
Josh D. Neufeld
Paul M. Craig
Andrew C. Doxey
Time Series Resolution of the Fish Necrobiome Reveals a Decomposer Succession Involving Toxigenic Bacterial Pathogens
mSystems
necrobiome
microbiome
decomposition
wastewater
rainbow darter
aeromonas
aerolysin
community profiling
fish
metagenomics
thanatomicrobiome
toxins
author_facet Briallen Lobb
Rhiannon Hodgson
Michael D. J. Lynch
Michael J. Mansfield
Jiujun Cheng
Trevor C. Charles
Josh D. Neufeld
Paul M. Craig
Andrew C. Doxey
author_sort Briallen Lobb
title Time Series Resolution of the Fish Necrobiome Reveals a Decomposer Succession Involving Toxigenic Bacterial Pathogens
title_short Time Series Resolution of the Fish Necrobiome Reveals a Decomposer Succession Involving Toxigenic Bacterial Pathogens
title_full Time Series Resolution of the Fish Necrobiome Reveals a Decomposer Succession Involving Toxigenic Bacterial Pathogens
title_fullStr Time Series Resolution of the Fish Necrobiome Reveals a Decomposer Succession Involving Toxigenic Bacterial Pathogens
title_full_unstemmed Time Series Resolution of the Fish Necrobiome Reveals a Decomposer Succession Involving Toxigenic Bacterial Pathogens
title_sort time series resolution of the fish necrobiome reveals a decomposer succession involving toxigenic bacterial pathogens
publisher American Society for Microbiology
series mSystems
issn 2379-5077
publishDate 2020-04-01
description The microbial decomposition of animal tissues is an important ecological process that impacts nutrient cycling in natural environments. We studied the microbial decomposition of a common North American fish (rainbow darters) over four time points, combining 16S rRNA gene and shotgun metagenomic sequence data to obtain both taxonomic and functional perspectives. Our data revealed a strong community succession that was reproduced across different fish and environments. Decomposition time point was the main driver of community composition and functional potential; fish environmental origin (upstream or downstream of a wastewater treatment plant) had a secondary effect. We also identified strains related to the putative pathogen Aeromonas veronii as dominant members of the decomposition community. These bacteria peaked early in decomposition and coincided with the metagenomic abundance of hemolytic toxin genes. Our work reveals a strong decomposer succession in wild-caught fish, providing functional and taxonomic insights into the vertebrate necrobiome.Despite progress understanding microbial communities involved in terrestrial vertebrate decomposition, little is known about the microbial decomposition of aquatic vertebrates from a functional and environmental context. Here, we analyzed temporal changes in the “necrobiome” of rainbow darters, which are common North American fish that are sensitive indicators of water quality. By combining 16S rRNA gene and shotgun metagenomic sequence data from four time points, we studied the progression of decomposers from both taxonomic and functional perspectives. The 16S rRNA gene profiles revealed strong community succession, with early decomposition stages associated with Aeromonas and Clostridium taxa and later stages dominated by members of the Rikenellaceae (i.e., Alistipes/Acetobacteroides genera). These results were reproducible and independent of environmental perturbation, given that exposure to wastewater treatment plant effluent did not substantially influence the necrobiome composition of fish or the associated water sample microbiota. Metagenomic analysis revealed significant changes throughout decomposition in degradation pathways for amino acids, carbohydrates/glycans, and other compounds, in addition to putrefaction pathways for production of putrescine, cadaverine, and indole. Binning of contigs confirmed a predominance of Aeromonas genome assemblies, including those from novel strains related to the pathogen Aeromonas veronii. These bins of Aeromonas genes also encoded known hemolysin toxins (e.g., aerolysin) that were particularly abundant early in the process, potentially contributing to host cell lysis during decomposition. Overall, our results demonstrate that wild-caught fish have a reproducible decomposer succession and that the fish necrobiome serves as a potential source of putative pathogens and toxigenic bacteria.
topic necrobiome
microbiome
decomposition
wastewater
rainbow darter
aeromonas
aerolysin
community profiling
fish
metagenomics
thanatomicrobiome
toxins
url https://doi.org/10.1128/mSystems.00145-20
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