Viral Community Structure and Potential Functions in the Dried-Out Aral Sea Basin Change along a Desiccation Gradient

Viral Community Structure and Potential Functions in the Dried-Out Aral Sea Basin Change along a Desiccation Gradient

The dried-out Aral Sea basin represents an extreme environment due to a man-made ecological disaster. Studies conducted in this unique environment revealed high levels of pollution and a specifically adapted microbiota; however, viral populations remained entirely unexplored. By employing an in-dept...

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Bibliographic Details
Published in:mSystems Vol. 8; no. 1; p. e0099422
Main Authors: Wicaksono, Wisnu Adi, Egamberdieva, Dilfuza, Cernava, Tomislav, Berg, Gabriele
Format: Journal Article
Language:English
Published: United States American Society for Microbiology 23-02-2023
Subjects:
Bacteria - genetics
Bacteriophages
Biofilms
Biogeochemical cycles
Community structure
Competitiveness
CRISPR
Desiccation
DNA sequencing
Ecosystems
extreme environments
Genomes
Humans
Kruskal-Wallis test
Metagenome
Metagenomics
Microbiota
Microbiota - genetics
Microorganisms
Nutrient cycles
pioneer plants
Research Article
Revegetation
Rhizosphere
Salinity
Suaeda acuminata
Taxonomy
Terrestrial ecosystems
viral communities
Viruses
Aral Sea
pioneer plants
extreme environments
viral communities
Suaeda acuminata
metagenomics
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Summary:The dried-out Aral Sea basin represents an extreme environment due to a man-made ecological disaster. Studies conducted in this unique environment revealed high levels of pollution and a specifically adapted microbiota; however, viral populations remained entirely unexplored. By employing an in-depth analysis based on the sequencing of metagenomic DNA recovered from rhizosphere samples of Suaeda acuminata (C. A. Mey.) Moq. along a desiccation gradient of 5, 10, and 40 years, we detected a diverse viral community comprising 674 viral populations (viral operational taxonomic units [vOTUs]) dominated by . Targeted analyses highlighted that viral populations in this habitat are subjected to certain dynamics that are driven mainly by the gradient of desiccation, the corresponding salinity, and the rhizosphere bacterial populations. predictions linked the viruses to dominant prokaryotic taxa in the Aral Sea basin, such as , , and . The lysogenic lifestyle was predicted to be predominant in areas that dried out 5 years ago, representing the early revegetation phase. Metabolic prediction of viral auxiliary metabolic genes (AMGs) suggests that viruses may play a role in the biogeochemical cycles, stress resilience, and competitiveness of their hosts due to the presence of genes that are involved in biofilm formation. Overall, our study provides important insights into viral ecology in an extreme environment and expands our knowledge related to virus occurrence in terrestrial systems. Environmental viruses have added a wealth of knowledge to ecological studies with the emergence of metagenomic technology and approaches. They are also becoming recognized as important genetic repositories that underpin the functioning of terrestrial ecosystems but have remain moslty unexplored. Using shotgun metagenome sequencing and bioinformatic tools, we found that the viral community structure was affected during natural revegetation in the dried-up Aral Sea area, a model habitat for investigating natural ecological restoration but still understudied. In this study, we highlight the importance of viruses, elements that are overlooked, for their potential contribution to terrestrial ecosystems, i.e., nutrient cycles, stress resilience, and host competitiveness, during natural revegetation.
Bibliography:The authors declare no conflict of interest.
ISSN:2379-5077
2379-5077
DOI:10.1128/msystems.00994-22