Sequence type 1 group B Streptococcus, an emerging cause of invasive disease in adults, evolves by small genetic changes

Significance Serotype V group B Streptococcus (GBS) infection rates in humans have steadily increased during the past several decades. We determined that 92% of bloodstream infections caused by serotype V GBS in Houston and Toronto are caused by genetically related strains called sequence type (ST) 1. Whole-genome analysis of 202 serotype V ST-1 strains revealed the molecular relationship among these strains and that they are closely related to a bovine strain. Moreover, we found that a subset of GBS genes is under selective evolutionary pressure, indicating that proteins produced by these genes likely contribute to GBS host–pathogen interaction. These data will assist in understanding how bacteria adapt to cause disease in humans, thereby potentially informing new preventive and therapeutic strategies. The molecular mechanisms underlying pathogen emergence in humans is a critical but poorly understood area of microbiologic investigation. Serotype V group B Streptococcus (GBS) was first isolated from humans in 1975, and rates of invasive serotype V GBS disease significantly increased starting in the early 1990s. We found that 210 of 229 serotype V GBS strains (92%) isolated from the bloodstream of nonpregnant adults in the United States and Canada between 1992 and 2013 were multilocus sequence type (ST) 1. Elucidation of the complete genome of a 1992 ST-1 strain revealed that this strain had the highest homology with a GBS strain causing cow mastitis and that the 1992 ST-1 strain differed from serotype V strains isolated in the late 1970s by acquisition of cell surface proteins and antimicrobial resistance determinants. Whole-genome comparison of 202 invasive ST-1 strains detected significant recombination in only eight strains. The remaining 194 strains differed by an average of 97 SNPs. Phylogenetic analysis revealed a temporally dependent mode of genetic diversification consistent with the emergence in the 1990s of ST-1 GBS as major agents of human disease. Thirty-one loci were identified as being under positive selective pressure, and mutations at loci encoding polysaccharide capsule production proteins, regulators of pilus expression, and two-component gene regulatory systems were shown to affect the bacterial phenotype. These data reveal that phenotypic diversity among ST-1 GBS is mainly driven by small genetic changes rather than extensive recombination, thereby extending knowledge into how pathogens adapt to humans.

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