Abstract
In Bacteria, a working consensus of species circumscription may have been reached and one of the most prominent criteria is high average nucleotide identity (ANI). ANI in effect groups strains that may recombine more or less frequently, depending on their biology, as opposed to rare interspecies gene transfer. For bacteriophages, which show various lifestyles, the nature of the fundamental natural unit, if it exists in a biological sense, is not well understood and defined. The approaches based on dot-plots are useful to group similar bacteriophages, yet are not quantitative and use arbitrarily set cut-offs. Here, we focus on lytic Myoviridae and test the ANI metric for group delineation. We show that ANI-based groups are in agreement with the International Committee on Taxonomy of Viruses (ICTV) classification and already established dot-plot groups, which are occasionally further refined owing to higher resolution of ANI analysis. Furthermore, these groups are separated among themselves by clear ANI discontinuities. Their members readily exchange core genes with each other while they do not with bacteriophages of other ANI groups, not even with the most similar. Thus, ANI-delineated groups may represent the natural units in lytic Myoviridae evolution with features that resemble those encountered in bacterial species.
Highlights
In bacterial taxonomy, a species is proposed based on the monophyly, and genetic and phenotypic coherence of its members [1]
We introduce the average nucleotide identity (ANI) metric, which is widely used in bacterial species circumscription, for fine-scale lytic Myoviridae classification
A comparison of all-versus-all 186 lytic Myoviridae bacteriophages using ANIb can be seen in Fig. 1(a) and Table S2
Summary
A species is proposed based on the monophyly, and genetic and phenotypic coherence of its members [1]. There is a discrepancy, between the breadth of bacterial species from a taxonomic and ecological point of view because the former emphasizes the common evolutionary history and the latter the current niche adaptation, which may often circumscribe a narrower collection of strains [3]. Metagenomics studies have shown that related bacteria from similar (interconnected) habitats and in similar living conditions form separated sequence clusters, possibly meaningful units of ecological diversity [4]. The genetic coherence of strains/sequence clusters is usually determined by the average nucleotide identity of the shared DNA (ANI), and for inclusion into species, ANI of the strains must be at least 96 % [1, 5]. A small (
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