A novel two-component system controls vancomycin resistance in epidemic Clostridioides difficile

The glycopeptide antibiotic vancomycin is the frontline treatment for C. difficile infection in the UK. There have been only sporadic reports of resistance in the clinic but testing is rare so the true resistance landscape is unclear. We have previously shown that resistance can emerge rapidly in vitro via distinct but complementary pathways. Strain Bc2, characterised here, is an experimentally evolved derivative of C. difficile strain R20291 that displays a 16-fold increase in vancomycin MIC over its parent. Bc2 has point mutations in dacS, bclA3, CDR20291_0794, CDR20291_1871 and CDR20291_3124 (vnrS). By genetically engineering a wild-type vancomycin susceptible strain, we demonstrated that a combination of just two mutations, dacSc.798A>T and vnrSc.692G>T, both of which encode two-component system histidine kinases, was sufficient to recapitulate Bc2 resistance. We have previously shown that mutations in dacS can confer low level resistance via increases in the expression of a D,D-carboxypeptidase DacJ. dacSc.798A>T also led to increased transcription of dacJ and led to a modest increase in vancomycin MIC. Surprisingly vnrSc.692G>T led to overexpression of the vanG cluster, which encodes all of the enzymes needed for resistance via substitution of the terminal D-Ala on peptidoglycan lipid II precursors with D-Ser. Genomic analysis of a large collection of European C. difficile strains showed that a three gene cluster, which includes vnrS, vnrR (encoding the cognate response regulator) and an adjacent gene CDR20291_3123, is unique to the phylogenetic branch that contains strains belonging to epidemic ribotypes 027 and 176. Transcriptomic analysis of the wider VnrS regulon also revealed an additional previously unknown role in regulating the expression of the flagellum, an important virulence factor in C. difficile. Analysis of the response to vancomycin exposure also revealed that dacJ is one of a small set of genes that are upregulated shortly after antibiotic stress, even in the absence of mutations that typically lead to its overexpression. Together these data reveal a new synergistic route, needing only two point mutations, by which epidemic lineages of C. difficile can attain vancomycin resistance.