In this study, intact flagellin proteins were purified from strains of Clostridium difficile and analyzed using quadrupole time of flight and linear ion trap mass spectrometers. Top-down studies showed the flagellin proteins to have a mass greater than that predicted from the corresponding gene sequence. These top-down studies revealed marker ions characteristic of glycan modifications. Additionally, diversity in the observed masses of glycan modifications was seen between strains. Electron transfer dissociation mass spectrometry was used to demonstrate that the glycan was attached to the flagellin protein backbone in O linkage via a HexNAc residue in all strains examined. Bioinformatic analysis of C. difficile genomes revealed diversity with respect to glycan biosynthesis gene content within the flagellar biosynthesis locus, likely reflected by the observed flagellar glycan diversity. In C. difficile strain 630, insertional inactivation of a glycosyltransferase gene (CD0240) present in all sequenced genomes resulted in an inability to produce flagellar filaments at the cell surface and only minor amounts of unmodified flagellin protein.
We show in this study that toxin production in Clostridium difficile is altered in cells which can no longer form flagellar filaments. The impact of inactivation of fliC, CD0240, fliF, fliG, fliM, and flhB-fliR flagellar genes upon toxin levels in culture supernatants was assessed using cell-based cytotoxicity assay, proteomics, immunoassay, and immunoblotting approaches. Each of these showed that toxin levels in supernatants were significantly increased in a fliC mutant compared to that in the C. difficile 630 parent strain. In contrast, the toxin levels in supernatants secreted from other flagellar mutants were significantly reduced compared with that in the parental C. difficile 630 strain. Transcriptional analysis of the pathogenicity locus genes (tcdR, tcdB, tcdE, and tcdA) revealed a significant increase of all four genes in the fliC mutant strain, while transcription of all four genes was significantly reduced in fliM, fliF, fliG, and flhB-fliR mutants. These results demonstrate that toxin transcription in C. difficile is modulated by the flagellar regulon. More significantly, mutant strains showed a corresponding change in virulence compared to the 630 parent strain when tested in a hamster model of C. difficile infection. This is the first demonstration of differential flagellum-related transcriptional regulation of toxin production in C. difficile and provides evidence for elaborate regulatory networks for virulence genes in C. difficile. Clostridium difficile is a Gram-positive spore-forming bacillus which is recognized to be the major cause of nosocomial diarrhea associated with antibiotic therapy (35). The incidence of C. difficile infection has been rapidly increasing in both Europe and North America, and this increase in infections has been associated with a significantly high mortality rate (2, 35). The broad spectrum of diseases caused by C. difficile, which range from antibiotic-associated diarrhea to the potentially lethal, pseudomembranous colitis, has been shown to depend on the level of toxin produced (1), and this production is recognized as a critical determinant of pathogenicity. Following antibiotic therapy when the microbiota of the gastrointestinal tract is disrupted, infection by C. difficile is mediated by spores which germinate in the gut, followed by vegetative cell proliferation and the subsequent secretion of the two major virulence factors, the Rho glucosylating toxins TcdA and TcdB.The toxin-encoding genes (tcdA and tcdB) are localized to a 19.6-kb pathogenicity locus (PaLoc) which includes three other accessory genes, tcdR, tcdE and tcdC (43). TcdR is an alternative sigma factor required for transcription of the two toxin genes; TcdE has been described to be a putative holin-like protein involved in toxin secretion, although this role has recently been a source of debate (17, 32); and TcdC is an anti-sigma factor that negatively regulates tcdR-dependent transcription (28, 29). In addition, four other regulators of toxin synthesis have recently been identified: CepA (3), CodY ...
In Francisella tularensis subsp. tularensis, DsbA has been shown to be an essential virulence factor and has been observed to migrate to multiple protein spots on two-dimensional electrophoresis gels. In this work, we show that the protein is modified with a 1,156-Da glycan moiety in O-linkage. The results of mass spectrometry studies suggest that the glycan is a hexasaccharide, comprised of N-acetylhexosamines, hexoses, and an unknown monosaccharide. Disruption of two genes within the FTT0789-FTT0800 putative polysaccharide locus, including a galE homologue (FTT0791) and a putative glycosyltransferase (FTT0798), resulted in loss of glycan modification of DsbA. The F. tularensis subsp. tularensis ⌬FTT0798 and ⌬FTT0791::Cm mutants remained virulent in the murine model of subcutaneous tularemia. This indicates that glycosylation of DsbA does not play a major role in virulence under these conditions. This is the first report of the detailed characterization of the DsbA glycan and putative role of the FTT0789-FTT0800 gene cluster in glycan biosynthesis.
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