Abstract
In common with other bacterial taxa, members of the genus Neisseria are classified using a range of phenotypic and biochemical approaches, which are not entirely satisfactory in assigning isolates to species groups. Recently, there has been increasing interest in using nucleotide sequences for bacterial typing and taxonomy, but to date, no broadly accepted alternative to conventional methods is available. Here, the taxonomic relationships of 55 representative members of the genus Neisseria have been analysed using whole-genome sequence data. As genetic material belonging to the accessory genome is widely shared among different taxa but not present in all isolates, this analysis indexed nucleotide sequence variation within sets of genes, specifically protein-coding genes that were present and directly comparable in all isolates. Variation in these genes identified seven species groups, which were robust to the choice of genes and phylogenetic clustering methods used. The groupings were largely, but not completely, congruent with current species designations, with some minor changes in nomenclature and the reassignment of a few isolates necessary. In particular, these data showed that isolates classified as Neisseria polysaccharea are polyphyletic and probably include more than one taxonomically distinct organism. The seven groups could be reliably and rapidly generated with sequence variation within the 53 ribosomal protein subunit (rps) genes, further demonstrating that ribosomal multilocus sequence typing (rMLST) is a practicable and powerful means of characterizing bacteria at all levels, from domain to strain.
Highlights
The genus Neisseria comprises Gram-negative oxidasepositive diplococci, many of which are harmless commensal inhabitants of the mucosal and dental surfaces of humans (Zaura et al, 2009)
The genome data discussed in this paper have been uploaded to a Bacterial Isolate Genome Sequence Database (BIGSDB), along with available taxonomic and provenance data and links to the appropriate PubMed record; these data are accessible through the PubMLST database
The availability of whole-genome sequences has greatly increased the number of possible comparative studies, but it is essential that the isolates used in such investigations are well characterized to realize the opportunities presented by association studies of diverse phenotypes with particular genotypes
Summary
The genus Neisseria comprises Gram-negative oxidasepositive diplococci, many of which are harmless commensal inhabitants of the mucosal and dental surfaces of humans (Zaura et al, 2009). The genus contains two human pathogens that cause very different diseases, both of global significance: Neisseria meningitidis, the meningococcus, which causes meningitis and septicaemia; and Neisseria gonorrhoeae, the gonococcus, which causes gonorrhoea and, occasionally, disseminated infections. Phenotypic properties, using assays such as carbohydrate utilization and enzyme substrate tests. While these techniques are generally satisfactory for the identification of the meningococcus, gonococcus and the lactose-fermenting organism Neisseria lactamica, misclassification is not uncommon using these methods and can have important medical consequences (Dossett et al, 1985)
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