Naturally occurring single amino acid replacements in a regulatory protein alter streptococcal gene expression and virulence in mice
Ronan K. Carroll, … , Anthony R. Flores, James M. Musser
Ronan K. Carroll, … , Anthony R. Flores, James M. Musser
Published April 1, 2011
Citation Information: J Clin Invest. 2011;121(5):1956-1968. https://doi.org/10.1172/JCI45169.
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Naturally occurring single amino acid replacements in a regulatory protein alter streptococcal gene expression and virulence in mice

Abstract

Infection with different strains of the same species of bacteria often results in vastly different clinical outcomes. Despite extensive investigation, the genetic basis of microbial strain-specific virulence remains poorly understood. Recent whole-genome sequencing has revealed that SNPs are the most prevalent form of genetic diversity among different strains of the same species of bacteria. For invasive serotype M3 group A streptococci (GAS) strains, the gene encoding regulator of proteinase B (RopB) has the highest frequency of SNPs. Here, we have determined that ropB polymorphisms alter RopB function and modulate GAS host-pathogen interactions. Sequencing of ropB in 171 invasive serotype M3 GAS strains identified 19 distinct ropB alleles. Inactivation of the ropB gene in strains producing distinct RopB variants had dramatically divergent effects on GAS global gene expression. Additionally, generation of isoallelic GAS strains differing only by a single amino acid in RopB confirmed that variant proteins affected transcript levels of the gene encoding streptococcal proteinase B, a major RopB-regulated virulence factor. Comparison of parental, RopB-inactivated, and RopB isoallelic strains in mouse infection models demonstrated that ropB polymorphisms influence GAS virulence and disease manifestations. These data detail a paradigm in which unbiased, whole-genome sequence analysis of populations of clinical bacterial isolates creates new avenues of productive investigation into the pathogenesis of common human infections.

Authors

Ronan K. Carroll, Samuel A. Shelburne III, Randall J. Olsen, Bryce Suber, Pranoti Sahasrabhojane, Muthiah Kumaraswami, Stephen B. Beres, Patrick R. Shea, Anthony R. Flores, James M. Musser

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Figure 3

Relationship of growth phase to ropB and speB transcript level and SpeB production.

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Relationship of growth phase to ropB and speB transcript level and SpeB ...
(A) Growth curve of strain MGAS10870 in THY broth. Growth was done in triplicate on 3 separate occasions. Arrows indicate the points at which RNA and culture supernatants were harvested for analysis. EE, early exponential; ME, mid-exponential; LE, late exponential; S, stationary. (B) Transcript level of ropB and speB in strain MGAS10870 measured by TaqMan QRT-PCR and graphed relative to endogenous control gene tufA (71). Biologic replicates were performed in duplicate on 2 separate occasions and analyzed in duplicate. For A and B, the data shown are mean ± SD. (C) Western immunoblot using anti-SpeB polyclonal rabbit antibody and culture supernatants taken at the indicated time points. The zymogen form of SpeB is approximately 40 kDa. The multiple bands observed in the stationary-phase supernatant represent various SpeB maturation isoforms, with the majority of immunoreactive material being mature SpeB (~28 kDa) (72).