Genetic transfer in Staphylococcus: a case study of 13 genomes

TL;DR

This study systematically investigates lateral genetic transfer in 13 Staphylococcus genomes, revealing significant gene transfer events that contribute to genetic diversity and functional innovation in these bacteria.

Contribution

First comprehensive phylogenetic analysis of genetic transfer units in Staphylococcus genomes, highlighting the roles of within-gene and whole-gene transfer.

Findings

26.1% of gene families show evidence of LGT

Higher LGT frequency in multi-copy gene families

Both within-gene and whole-gene transfer contribute equally

Abstract

The widespread presence of antibiotic resistance and virulence among Staphylococcus isolates has been attributed to lateral genetic transfer (LGT) between different strains or species. However, there has been very little study of the extent of LGT in Staphylococcus species using a phylogenetic approach, particularly of the units of such genetic transfer. Here we report the first systematic study of the units of genetic transfer in 13 Staphylococcus genomes, using a rigorous phylogenetic approach. We found clear evidence of LGT in 26.1% of the 1354 homologous gene families examined, and possibly more in another 17.9% of the total families. Within-gene and whole-gene transfer contribute almost equally to the discordance of these gene families against a reference phylogeny. Comparing genetic transfer in single-copy and in multi-copy gene families, we found little functional bias in cases of within-gene (fragmentary) genetic transfer but substantial functional bias in cases of whole-gene (non-fragmentary) genetic transfer, and we observed a higher frequency of LGT in multi-copy gene families. Our results demonstrate that LGT and gene duplication play an important part among the factors that contribute to functional innovation in staphylococcal genomes.