TY - JOUR
T1 - Viral tagging reveals discrete populations in Synechococcus viral genome sequence space
AU - Deng, Li
AU - Ignacio-Espinoza, J. Cesar
AU - Gregory, Ann C.
AU - Poulos, Bonnie T.
AU - Weitz, Joshua S.
AU - Hugenholtz, Philip
AU - Sullivan, Matthew B.
N1 - Funding Information:
Acknowledgements Funding was provided by the US Department of Energy (DOE) Joint Genome Institute (JGI) Community Sequencing Program, Biosphere 2, BIO5, US National Science Foundation (NSF) OCE0940390, and Gordon and Betty Moore Foundation grants to M.B.S., as well as NSF OCE1233760 and Burroughs Wellcome Fund grants to J.S.W. We thank J. Fuhrman for suggesting stable-isotope-labelled host DNA; A. Z. Worden and the CANON Initiative for the cruise opportunity; Worden laboratory members; the captain and crew of the R/V Western Flyer for operational/ sampling support; J. B. Waterbury, S. W. Chisholm and A. Wichels for strains; the Tucson Marine Phage laboratory; Institute of Groundwater Ecology of Helmholtz Munich; and N. Pace, M. Young, S. W. Chisholm and S. Yilmaz for technical/analytical support and manuscript comments. We acknowledge the University of Arizona Genetics Core for viral-tagging metagenomic sequencing; iCyt and the Arizona Cancer Center and Arizona Research Laboratories (ARL) Division of Biotechnology Cytometry Core Facility for cytometry support; the University Information Technology Services Research Computing Group and the ARL Biotechnology Computing for high-performance computing clusters (HPCC) access and support. Community metagenomic sequencing was provided by the DOE JGI Community Sequencing Program underthe Officeof Scienceof the US DOE contractno. DE-AC02-05CH11231.
Publisher Copyright:
©2014 Macmillan Publishers Limited. All rights reserved.
PY - 2014/9/11
Y1 - 2014/9/11
N2 - Microbes and their viruses drive myriad processes across ecosystems ranging from oceans and soils to bioreactors and humans. Despite this importance, microbial diversity is only now being mapped at scales relevant to nature, while the viral diversity associated with any particular host remains little researched. Here we quantify host-associated viral diversity using viral-tagged metagenomics, which links viruses to specific host cells for high-throughput screening and sequencing. In a single experiment, we screened 10 Pacific Ocean viruses against a single strain of Synechococcus and found that naturally occurring cyanophage genome sequence space is statistically clustered into discrete populations. These population-based, host-linked viral ecological data suggest that, for this single host and seawater sample alone, there are at least 26 double-stranded DNA viral populations with estimated relative abundances ranging from 0.06 to 18.2%. These populations include previously cultivated cyanophage and new viral types missed by decades of isolate-based studies. Nucleotide identities of homologous genes mostly varied by less than 1% within populations, even in hypervariable genome regions, and by 42-71% between populations, which provides benchmarks for viral metagenomics and genome-based viral species definitions. Together these findings showcase a new approach to viral ecology that quantitatively links objectively defined environmental viral populations, and their genomes, to their hosts.
AB - Microbes and their viruses drive myriad processes across ecosystems ranging from oceans and soils to bioreactors and humans. Despite this importance, microbial diversity is only now being mapped at scales relevant to nature, while the viral diversity associated with any particular host remains little researched. Here we quantify host-associated viral diversity using viral-tagged metagenomics, which links viruses to specific host cells for high-throughput screening and sequencing. In a single experiment, we screened 10 Pacific Ocean viruses against a single strain of Synechococcus and found that naturally occurring cyanophage genome sequence space is statistically clustered into discrete populations. These population-based, host-linked viral ecological data suggest that, for this single host and seawater sample alone, there are at least 26 double-stranded DNA viral populations with estimated relative abundances ranging from 0.06 to 18.2%. These populations include previously cultivated cyanophage and new viral types missed by decades of isolate-based studies. Nucleotide identities of homologous genes mostly varied by less than 1% within populations, even in hypervariable genome regions, and by 42-71% between populations, which provides benchmarks for viral metagenomics and genome-based viral species definitions. Together these findings showcase a new approach to viral ecology that quantitatively links objectively defined environmental viral populations, and their genomes, to their hosts.
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U2 - 10.1038/nature13459
DO - 10.1038/nature13459
M3 - Article
C2 - 25043051
AN - SCOPUS:84906254581
SN - 0028-0836
VL - 513
SP - 242
EP - 245
JO - Nature
JF - Nature
IS - 7517
ER -