Re-examination of the relationship between marine virus and microbial cell abundances

To understand the activity of marine viruses, experiments on viral production, viral decay and the percentage of lytic and lysogenic bacterial cells among the total number of bacterial cells were carried out seasonally at two stations in the Adriatic Sea with different trophic conditions. Additionally, we are providing an insight on the enrichment with dissolved and particulate organic matter by viral lysis in the studied area. Viral production was higher at the coastal station than at the open-sea station. Viral decay rates were also higher at the coastal sea station than at the open-sea station, and accounted for approximately 40% of viral production at both investigated stations. The percentage of lysogenic infection was lower than that of lytical infection, which indicates the prevalence of the lytic cycle at both stations. Viruses had a significant influence on bacterial mortality through high daily removal of the bacterial standing stock at the coastal and open-sea station. The viruses contributed to the restoration of dissolved organic carbon, nitrogen and phosphorus in the microbial loop by lysing the bacterial cells at the studied stations. All the above suggest that viruses are important in the microbial food web and an important factor in the control of bacterial populations within the study area.

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“…However, new findings suggest that lysogeny could also be favoured in environments with increased host density [18,19].…”

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Viral dynamics in two trophically different areas in the Central Adriatic Sea

et al. 2017

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“…Although virologists have traditionally focused on viruses that cause disease in humans, domestic animals and crops, the recent advances in metagenomic sequencing, in particular high-throughput sequencing of environmental samples, have revealed a staggeringly large virome everywhere in the biosphere. At least 10 31 virus particles exist globally at any given time in most environments, including marine and freshwater habitats and metazoan gastrointestinal tracts, in which the number of detectable virus particles exceeds the number of cells by 10-100-fold [1][2][3][4][5] . To help conceptualize the sheer number of viruses in existence, their current biomass has been estimated to equal that of 75 million blue whales (approximately 200 million tonnes) and, if placed end to end, the collective length of their virions would span 65 galaxies 6 .…”

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Virus taxonomy in the age of metagenomics

et al. 2017

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| The number and diversity of viral sequences that are identified in metagenomic data far exceeds that of experimentally characterized virus isolates. In a recent workshop, a panel of experts discussed the proposal that, with appropriate quality control, viruses that are known only from metagenomic data can, and should be, incorporated into the official classification scheme of the International Committee on Taxonomy of Viruses (ICTV). Although a taxonomy that is based on metagenomic sequence data alone represents a substantial departure from the traditional reliance on phenotypic properties, the development of a robust framework for sequence-based virus taxonomy is indispensable for the comprehensive characterization of the global virome. In this Consensus Statement article, we consider the rationale for why metagenomic sequence data should, and how it can, be incorporated into the ICTV taxonomy, and present proposals that have been endorsed by the Executive Committee of the ICTV. NATURE REVIEWS | MICROBIOLOGY VOLUME 15 | MARCH 2017 | 161 CONSENSUS STATEMENT © 2 0 1 7 M a c m i l l a n P u b l i s h e r s L i m i t e d , p a r t o f S p r i n g e r N a t u r e . A l l r i g h t s r e s e r v e d .

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“…For example, in the lab experiments 11 E. coli population suffered a dramatic collapse by a factor ~10 4 -10 5 caused by a T7 phage infection. Collapse-driven dynamics is common in both natural 12 and man-made 13-16 ecosystems in which bacteria are engaged in the continuous arms race with phages [17][18][19][20][21] . Here we propose and explore a particularly simplified dynamical interpretation of Kill-the Winner principle, in which bacterial populations are characterized by periods of competitive exponential growth punctuated by rapid and severe collapses.…”

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confidence: 99%

Population cycles and species diversity in dynamic Kill-the-Winner model of microbial ecosystems

Maslov

snepppen²

2016

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Determinants of species diversity in microbial ecosystems remain poorly understood. Bacteriophages are believed to increase the diversity by the virtue of Kill-the-Winner infection bias preventing the fastest growing organism from taking over the community. Phage-bacterial ecosystems are traditionally described in terms of the static equilibrium state of Lotka-Volterra equations in which bacterial growth is exactly balanced by losses due to phage predation. Here we consider a more dynamic scenario in which phage infections give rise to abrupt and severe collapses of bacterial populations whenever they become sufficiently large. As a consequence, each bacterial population in our model follows cyclic dynamics of exponential growth interrupted by sudden declines. The total population of all species fluctuates around the carrying capacity of the environment, making these cycles cryptic. While a subset of the slowest growing species in our model is always driven towards extinction, in general the overall ecosystem diversity remains high. The number of surviving species is inversely proportional to the variation in their growth rates but increases with the frequency and severity of phage-induced collapses. Thus counter-intuitively we predict that microbial communities exposed to more violent perturbations should have higher diversity.An important and largely unsolved question in microbial ecology is what determines the diversity of microbial ecosystems. Indeed, unbridled competition between microbes sharing common resources would eventually limit species diversity not to exceed the number of different nutrient types 1 . Predation by bacteriophages introduces the negative frequency-dependent selection 2-5 which offers the possibility for a dramatically larger species diversity 5 . In the classical Kill-the-Winner (KtW) model of Thingstad 5 virulent phages reduce populations of their susceptible hosts to a low steady state level, which is independent of hosts' growth rate thus allowing multiple species per nutrient type. The number of co-existing bacterial species in the resulting ecosystem is determined exclusively by the parameters of phage predation 5 , the topology of the phage-bacterial infection network [6][7][8] , and the carrying capacity of the environment 4,[7][8][9] . Microbial populations are routinely exposed to more dynamics than assumed in the traditional steady state KtW model and its variants. Extended Lotka-Volterra equations for two layer ecosystems of phages and bacteria could predict persistently varying populations 10 , even without considering mutations. In addition, microbial systems are typically exposed to changes in interaction rules and new invading species. For example, in the lab experiments 11 E. coli population suffered a dramatic collapse by a factor ~10 4 -10 5 caused by a T7 phage infection. Collapse-driven dynamics is common in both natural 12 and man-made 13-16 ecosystems in which bacteria are engaged in the continuous arms race with phages [17][18][19][20][21] . Here we propose and ...

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Re-examination of the relationship between marine virus and microbial cell abundances

Cited by 270 publications

References 53 publications

Viral dynamics in two trophically different areas in the Central Adriatic Sea

Viral dynamics in two trophically different areas in the Central Adriatic Sea

Virus taxonomy in the age of metagenomics

Population cycles and species diversity in dynamic Kill-the-Winner model of microbial ecosystems

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