Deciphering the roles of BamB and its interaction with BamA in outer membrane biogenesis, T3SS expression and virulence in Salmonella.

The folding and insertion of ß-barrel proteins in the outer membrane of Gram-negative bacteria is mediated by the BAM complex, which is composed of the outer membrane protein BamA and four lipoproteins BamB to BamE. In Escherichia coli and/or Salmonella, the BamB lipoprotein is involved in (i) ß-barrel protein assembly in the outer membrane, (ii) outer membrane permeability to antibiotics, (iii) the control of the expression of T3SS which are major virulence factors and (iv) the virulence of Salmonella. In E. coli, this protein has been shown to interact directly with BamA. In this study, we investigated the structure-function relationship of BamB in order to assess whether the roles of BamB in these phenotypes were inter-related and whether they require the interaction of BamB with BamA. For this purpose, recombinant plasmids harbouring point mutations in bamB were introduced in a ΔSalmonella bamB mutant. We demonstrated that the residues L173, L175 and R176 are crucial for all the roles of BamB and for the interaction of BamB with BamA. Moreover, the results obtained with a D229A BamB variant, which is unable to immunoprecipitate BamA, suggest that the interaction of BamB with BamA is not absolutely necessary for BamB function in outer-membrane protein assembly, T3SS expression and virulence. Finally, we showed that the virulence defect of the ΔbamB mutant is not related to its increased susceptibility to antimicrobials, as the D227A BamB variant fully restored the virulence of the mutant while having a similar antibiotic susceptibility to the ΔbamB strain. Overall, this study demonstrates that the different roles of BamB are not all inter-related and that L173, L175 and R176 amino-acids are privileged sites for the design of BamB inhibitors that could be used as alternative therapeutics to antibiotics, at least against Salmonella.

Genetic structure associated with blaOXA-18, encoding a clavulanic acid-inhibited extended-spectrum oxacillinase.

The genetic environment of the bla(OXA-18) gene encoding a peculiar clavulanic acid-inhibitable Ambler class D extended-spectrum beta-lactamase was determined from the prototype OXA-18-producing Pseudomonas aeruginosa MUS clinical isolate. An 8.2-kb genomic DNA fragment containing bla(OXA-18) was cloned from P. aeruginosa MUS. Although most oxacillinases are located in integrons, bla(OXA-18) lacked gene cassette-specific features. It was bracketed by two duplicated sequences containing ISCR19, a novel insertion sequence of the ISCR family of mobile elements; DeltaintI1, a truncated integrase gene; and a truncated Deltaaac6'-Ib gene cassette. It is likely that ISCR19 was at the origin of the bla(OXA-18) gene mobilization by a rolling-circle transposition event followed by homologous recombination. Furthermore, analysis of the cloned genomic DNA fragment revealed the presence of the integron-containing bla(OXA-20) gene. Concomitantly, three P. aeruginosa clinical isolates, displaying a synergy image as determined by double-disk diffusion tests on cloxacillin-containing plates, were isolated from three patients hospitalized in different wards over a 9-month period at the Saint-Luc University hospital (Brussels, Belgium). These isolates were positive by PCR for bla(OXA-18) and bla(OXA-20) genes, genetically related to P. aeruginosa MUS as determined by pulsed-field gel electrophoresis, and carried the same bla(OXA-18)/bla(OXA-20)-associated genetic structures. This report characterized the genetic elements likely at the origin of bla(OXA-18) gene mobilization in P. aeruginosa and suggests the spread of oxacillin-type extended-spectrum beta-lactamases in P. aeruginosa at the Saint-Luc University hospital of Brussels, Belgium.