Defining natural species of bacteria: clear-cut genomic boundaries revealed by a turning point in nucleotide sequence divergence
Open Access
- 18 July 2013
- journal article
- research article
- Published by Springer Science and Business Media LLC in BMC Genomics
- Vol. 14 (1), 489-10
- https://doi.org/10.1186/1471-2164-14-489
Abstract
Background Bacteria are currently classified into arbitrary species, but whether they actually exist as discrete natural species was unclear. To reveal genomic features that may unambiguously group bacteria into discrete genetic clusters, we carried out systematic genomic comparisons among representative bacteria. Results We found that bacteria of Salmonella formed tight phylogenetic clusters separated by various genetic distances: whereas over 90% of the approximately four thousand shared genes had completely identical sequences among strains of the same lineage, the percentages dropped sharply to below 50% across the lineages, demonstrating the existence of clear-cut genetic boundaries by a steep turning point in nucleotide sequence divergence. Recombination assays supported the genetic boundary hypothesis, suggesting that genetic barriers had been formed between bacteria of even very closely related lineages. We found similar situations in bacteria of Yersinia and Staphylococcus. Conclusions Bacteria are genetically isolated into discrete clusters equivalent to natural species.Keywords
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