PhiD12-Like Livestock-Associated Prophages Are Associated With Novel Subpopulations of Streptococcus agalactiae Infecting Neonates.

Sandra Dos Santos,Roland Quentin,Luka Courtier-Martinez,Adélaïde Renard,Nathalie L Van Der Mee-Marquet,Laurent Mereghetti,Laurie Barbera,Anne-Sophie Valentin

doi:10.3389/fcimb.2019.00166

Sandra Dos Santos, Roland Quentin + Show 6 more

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https://doi.org/10.3389/fcimb.2019.00166

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Abstract

Group B Streptococcus (GBS) is a major cause of invasive disease in neonates worldwide. Monitoring data have revealed a continuing trend toward an increase in neonatal GBS infections, despite the introduction of preventive measures. We investigated this trend, by performing the first ever characterization of the prophage content for 106 GBS strains causing neonatal infections between 2002 and 2018. We determined whether the genome of each strain harbored prophages, and identified the insertion site of each of the prophages identified. We found that 71.7% of the strains carried at least one prophage, and that prophages genetically similar to livestock-associated phiD12, carrying genes potentially involved in GBS pathogenesis (e.g., genes encoding putative virulence factors and factors involved in biofilm formation, bacterial persistence, or adaptation to challenging environments) predominated. The phiD12-like prophages were (1) associated with CC17 and 1 strains (p = 0.002), (2) more frequent among strains recovered during the 2011–2018 period than among those from 2002–2010 (p < 0.001), and (3) located at two major insertion sites close to bacterial genes involved in host adaptation and colonization. Our data provide evidence for a recent increase in lysogeny in GBS, characterized by the acquisition, within the genome, of genetic features typical of animal-associated mobile genetic elements by GBS strains causing neonatal infection. We suggest that lysogeny and phiD12-like prophage genetic elements may have conferred an advantage on GBS strains for adaptation to or colonization of the maternal vaginal tract, or for pathogenicity, and that these factors are currently playing a key role in the increasing ability of GBS strains to infect neonates.

Highlights

Bacterial pathogens frequently harbor prophages or phage remnants within their DNA
The carriage of prophages differed between Group B Streptococcus (GBS) lineages: prophages A were more frequent in the strains of CC1 and 17 (80 and 52.0%, respectively) than in the strains of other CCs (p = 0.002); prophages B were significantly associated with CC17 strains (p = 0.004) and prophages E were significantly associated with CC23 strains (p = 0.001)
We showed that lysogeny is frequently observed in GBS strains responsible for neonatal infections (71.7%), mostly associated with prophages A, which are genetically similar to the phiD12 prophages recently described in livestock-associated S. suis (Tang et al, 2013)

Summary

Introduction

Prophage-encoded virulence factors have been identified in many bacterial species, including Staphylococcus aureus and Streptococcus pyogenes (Banks et al, 2002; Brüssow et al, 2004; Denou et al, 2008; Boyd, 2012; Harrison and Brockhurst, 2017). Prophages A harbor genes that have been shown to protect bacteria against horizontal gene transfer and to mediate adaptation to stress and colonization They contain, in particular, a gene encoding a hypothetical protein with an LPXTG motif consistent with adhesin function (van der Mee-Marquet et al, 2017), the four genes clpP, metK, relB, and yafQ, which have been implicated in biofilm formation and resistance to both oxidative and acid stresses (Yadav et al, 2012; Hou et al, 2014; Wen et al, 2014; Chan et al, 2018)

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