Impact of Viral Lysis on the Composition of Bacterial Communities and Dissolved Organic Matter in Deep-Sea Sediments

Viral lysis is a main mortality factor for bacteria in deep-sea sediments, leading to changing microbial community structures and the release of cellular components to the environment. Nature and fate of these compounds and the role of viruses for microbial diversity is largely unknown. We investiga...

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Veröffentlicht in:	Viruses 2020-08, Vol.12 (9), p.922, Article 922
Hauptverfasser:	Heinrichs, Mara E., Tebbe, Dennis A., Wemheuer, Bernd, Niggemann, Jutta, Engelen, Bert
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Sprache:	eng
Schlagworte:	Bacteria Bacteria - chemistry Bacteria - classification Bacteria - isolation & purification Bacteria - virology Bacteriolysis Bacteriophages - physiology Bering Sea Biodiversity Biogeochemistry Carbon Cell division Community Dissolved organic matter Experiments Geologic Sediments - chemistry Geologic Sediments - microbiology killing the winner Life Sciences & Biomedicine Lysis Mass spectroscopy Microbiota Mitomycin - pharmacology Mitomycin C Next-generation sequencing Ocean floor Oceans and Seas Organic Chemicals - analysis Prokaryotes prophages Prophages - physiology Science & Technology Seawater - chemistry Seawater - microbiology Sediments Virology Virus Activation - drug effects virus-induction Viruses
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description	Viral lysis is a main mortality factor for bacteria in deep-sea sediments, leading to changing microbial community structures and the release of cellular components to the environment. Nature and fate of these compounds and the role of viruses for microbial diversity is largely unknown. We investigated the effect of viruses on the composition of bacterial communities and the pool of dissolved organic matter (DOM) by setting up virus-induction experiments using mitomycin C with sediments from the seafloor of the Bering Sea. At the sediment surface, no substantial prophage induction was detected, while incubations from 20 cm below seafloor showed a doubling of the virus-to-cell ratio. Ultra-high resolution mass spectrometry revealed an imprint of cell lysis on the molecular composition of DOM, showing an increase of molecular formulas typical for common biomolecules. More than 50% of these compounds were removed or transformed during incubation. The remaining material potentially contributed to the pool of refractory DOM. Next generation sequencing of the bacterial communities from the induction experiment showed a stable composition over time. In contrast, in the non-treated controls the abundance of dominant taxa (e.g., Gammaproteobacteria) increased at the expense of less abundant phyla. Thus, we conclude that viral lysis was an important driver in sustaining bacterial diversity, consistent with the "killing the winner" model.
doi_str_mv	10.3390/v12090922
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Nature and fate of these compounds and the role of viruses for microbial diversity is largely unknown. We investigated the effect of viruses on the composition of bacterial communities and the pool of dissolved organic matter (DOM) by setting up virus-induction experiments using mitomycin C with sediments from the seafloor of the Bering Sea. At the sediment surface, no substantial prophage induction was detected, while incubations from 20 cm below seafloor showed a doubling of the virus-to-cell ratio. Ultra-high resolution mass spectrometry revealed an imprint of cell lysis on the molecular composition of DOM, showing an increase of molecular formulas typical for common biomolecules. More than 50% of these compounds were removed or transformed during incubation. The remaining material potentially contributed to the pool of refractory DOM. Next generation sequencing of the bacterial communities from the induction experiment showed a stable composition over time. 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subjects	Bacteria Bacteria - chemistry Bacteria - classification Bacteria - isolation & purification Bacteria - virology Bacteriolysis Bacteriophages - physiology Bering Sea Biodiversity Biogeochemistry Carbon Cell division Community Dissolved organic matter Experiments Geologic Sediments - chemistry Geologic Sediments - microbiology killing the winner Life Sciences & Biomedicine Lysis Mass spectroscopy Microbiota Mitomycin - pharmacology Mitomycin C Next-generation sequencing Ocean floor Oceans and Seas Organic Chemicals - analysis Prokaryotes prophages Prophages - physiology Science & Technology Seawater - chemistry Seawater - microbiology Sediments Virology Virus Activation - drug effects virus-induction Viruses
title	Impact of Viral Lysis on the Composition of Bacterial Communities and Dissolved Organic Matter in Deep-Sea Sediments
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