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Biological species in the viral world
Edited by Edward F. DeLong, University of Hawaii at Manoa, Honolulu, HI, and approved May 2, 2018 (received for review October 6, 2017)

Significance
The biological species concept (BSC) has served as the basis for defining species for over 75 years. Members of a biological species are defined by their ability to exchange genetic material, and it was originally thought that asexual lineages were not amenable to species-level classification based on the BSC since clonal individuals are reproductively isolated from one another. In this study, we demonstrate that the rates and patterns of gene exchange in acellular organisms (viruses and bacteriophages) allow the assignment of true biological species, an essential step to organizing the tree of life. Our results show that a universal species definition, based on the BSC, can be used to define biological species in all major lifeforms.
Abstract
Due to their dependence on cellular organisms for metabolism and replication, viruses are typically named and assigned to species according to their genome structure and the original host that they infect. But because viruses often infect multiple hosts and the numbers of distinct lineages within a host can be vast, their delineation into species is often dictated by arbitrary sequence thresholds, which are highly inconsistent across lineages. Here we apply an approach to determine the boundaries of viral species based on the detection of gene flow within populations, thereby defining viral species according to the biological species concept (BSC). Despite the potential for gene transfer between highly divergent genomes, viruses, like the cellular organisms they infect, assort into reproductively isolated groups and can be organized into biological species. This approach revealed that BSC-defined viral species are often congruent with the taxonomic partitioning based on shared gene contents and host tropism, and that bacteriophages can similarly be classified in biological species. These results open the possibility to use a single, universal definition of species that is applicable across cellular and acellular lifeforms.
Footnotes
- ↵1To whom correspondence should be addressed. Email: ljbobay{at}uncg.edu.
Author contributions: L.-M.B. and H.O. designed research; L.-M.B. performed research; L.-M.B. analyzed data; and L.-M.B. and H.O. wrote the paper.
The authors declare no conflict of interest.
This article is a PNAS Direct Submission.
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1717593115/-/DCSupplemental.
Published under the PNAS license.
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