Tuomo Karjalainen

Role of FliC and FliD flagellar proteins of Clostridium difficile in adherence and gut colonization.

ABSTRACT In vitro and in vivo adhesive properties of flagella and recombinant flagellin FliC and flagellar cap FliD proteins ofClostridium difficile were analyzed. FliC, FliD, and crude flagella adhered in vitro to axenic mouse cecal mucus. Radiolabeled cultured cells bound to a high degree to FliD and weakly to flagella deposited on a membrane. The tissue association in the mouse cecum of a nonflagellated strain was 10-fold lower than that of a flagellated strain belonging to the same serogroup, confirming the role of flagella in adherence.

GroEL (Hsp60) of Clostridium difficile is involved in cell adherence

Previous results have demonstrated that adherence of Clostridium difficile to tissue culture cells is augmented by various stresses; this study focussed on whether the GroEL heat shock protein is implicated in this process. The 1940 bp groESL operon of C. difficile was isolated by PCR. The 1623 bp groEL gene is highly conserved between various C. difficile isolates as determined by RFLP-PCR and DNA sequencing, and the operon is present in one copy on the bacterial chromosome. The 58 kDa GroEL protein was expressed in Escherichia coli in fusion with glutathione S:-transferase and the fusion protein was purified from IPTG-induced bacterial lysates by affinity chromatography on glutathione-Sepharose. A polyclonal, monospecific antiserum was obtained for GroEL which established by immunoelectron microscopy, indirect immunofluorescence and immunoblot analysis that GroEL is released extracellularly after heat shock and can be surface associated. Cell fractionation experiments suggest that GroEL is predominantly cytoplasmic and membrane bound. GroEL-specific antibodies as well as the purified protein partially inhibited C. difficile cell attachment and expression of the protein was induced by cell contact, suggesting a role for GroEL in cell adherence.

Characterization of a cell surface protein of Clostridium difficile with adhesive properties.

ABSTRACT Our laboratory has previously shown that Clostridium difficile adherence to cultured cells is enhanced after heat shock at 60°C and that it is mediated by a proteinaceous surface component. The present study was undertaken to identify the surface molecules of this bacterium that could play a role in its adherence to the intestine. The cwp66 gene, encoding a cell surface-associated protein of C. difficile 79-685, was isolated by immunoscreening of a C. difficile gene library with polyclonal antibodies against C. difficile heated at 60°C. The Cwp66 protein (66 kDa) contains two domains, each carrying three imperfect repeats and one presenting homologies to the autolysin CwlB of Bacillus subtilis. A survey of 36 strains ofC. difficile representing 11 serogroups showed that the 3′ portion of the cwp66 gene is variable; this was confirmed by sequencing of cwp66 from another strain, C-253. Two recombinant protein fragments corresponding to the two domains of Cwp66 were expressed in fusion with glutathione S-transferase inEscherichia coli and purified by affinity chromatography using gluthatione-Sepharose 4B. Antibodies raised against the two domains recognized Cwp66 in bacterial surface extracts. By immunoelectron microscopy, the C-terminal domain was found to be cell surface exposed. When used as inhibitors in cell binding studies, the antibodies and protein fragments partially inhibited adherence ofC. difficile to cultured cells, confirming that Cwp66 is an adhesin, the first to be identified in clostridia.

Molecular and Genomic Analysis of Genes Encoding Surface-Anchored Proteins from Clostridium difficile

ABSTRACT The gene slpA, encoding the S-layer precursor protein in the virulent Clostridium difficile strains C253 and 79–685, was identified. The precursor protein carries a C-terminal highly conserved anchoring domain, similar to the one found in the Cwp66 adhesin (previously characterized in strain 79–685), an SLH domain, and a variable N-terminal domain mediating cell adherence. The genes encoding the S-layer precursor proteins and the Cwp66 adhesin are present in a genetic locus carrying 17 open reading frames, 11 of which encode a similar two-domain architecture, likely to include surface-anchored proteins.

Identification and characterization of adhesive factors of Clostridium difficile involved in adhesion to human colonic enterocyte-like Caco-2 and mucus-secreting HT29 cells in culture

Experiments reported in this communication showed that the highly toxinogenic Cd 79685, Cd 4784, and Wilkins Clostridium difficile strains and the moderately toxinogenic FD strain grown in the presence of blood adhere to polarized monolayers of two cultured human intestinal cell lines: the human colonic epithelial Caco‐2 cells and the human mucus‐secreting HT29‐MTX cells. Scanning electron microscopy revealed that the bacteria interacted with well‐defined apical microvilli of differentiated Caco‐2 cells and that the bacteria strongly bind to the mucus layer that entirely covers the surface of the HT29‐MTX cells. The binding of C. difficile to Caco‐2 cells developed in parallel with the differentiation features of the Caco‐2 cells, suggesting that the protein(s) which constitute C. difficile‐binding sites are differentiation‐related brush border protein(s). To better define this interaction, we tentatively characterized the mechanism(s) of adhesion of C. difficile with adherence assays. It was shown that heating of C. difficile grown in the presence of blood enhanced the bacterial interaction with the brush border of the enterocyte‐like Caco‐2 cells and the human mucus‐secreting HT29‐MTX cells. A labile surface‐associated component was involved in C. difficile adhesion since washes of C. difficile grown in the presence of blood without heat shock decreased adhesion. After heating, washes of C. difficile grown in the presence of blood did not modify adhesion. Analysis of surface‐associated proteins of C. difficile subjected to different culture conditions was con‐ducted. After growth of C. difficile Cd 79685, Cd 4784, FD and Wilkins strains in the presence of blood and heating, two predominant SDS‐extractable proteins with molecular masses of 12 and 27 kDa were observed and two other proteins with masses of 48 and 31 kDa disappeared. Direct involvement of the 12 and 27 kDa surface‐associated proteins in the adhe‐sion of C. difficile strains was demonstrated by using rat polycolonal antibodies pAb 12 and pAb 27 directed against the 12 and 27kDa proteins. Indeed, adhesion to Caco‐2 cell monoiayers of C. difficiie strains grown in the presence of blood, without or with heat‐shock, was blocked. Taken together, our results suggest that C. difficiie may utilize blood components as adhesins to adhere to human intestinal cultured cells.

Clostridium difficile genotyping based on slpA variable region in S-layer gene sequence: an alternative to serotyping.

ABSTRACT Recent investigations of Clostridium difficile cell wall components have revealed the presence of an S-layer encoded by the slpA gene. The aim of this study was to determine whether slpA genotyping can be used as an alternative to serotyping. The variable regions of slpA were amplified by PCR from serogroup reference strains and various clinical isolates chosen randomly. Amplified products were analyzed after restriction enzyme digestion and DNA sequencing. The sequences of the variable region of the SlpA protein were found to be strictly identical within a given serogroup but divergent between serogroups. These preliminary results suggest that PCR-restriction fragment length polymorphism, in conjunction with DNA sequencing of the slpA variable region, could constitute an alternative typing method for determining C. difficile serotypes.

A Clostridium difficile gene encoding flagellin

Six strains of Clostridium difficile examined by electron microscopy were found to carry flagella. The flagella of these strains were extracted and the N-terminal sequences of the flagellin proteins were determined. Four of the strains carried the N-terminal sequence MRVNTNVSAL exhibiting up to 90% identity to numerous flagellins. Using degenerate primers based on the N-terminal sequence and the conserved C-terminal sequence of several flagellins, the gene encoding the flagellum subunit (fliC) was isolated and sequenced from two virulent strains. The two gene sequences exhibited 91% inter-strain identity. The gene consists of 870 nt encoding a protein of 290 amino acids with an estimated molecular mass of 31 kDa, while the extracted flagellin has an apparent molecular mass of 39 kDa on SDS-PAGE. The FliC protein displays a high degree of identity in the N- and C-terminal amino acids whereas the central region is variable. A second ORF is present downstream of fliC displaying homology to glycosyltransferases. The fliC gene was expressed in fusion with glutathione S-transferase, purified and a polyclonal monospecific antiserum was obtained. Flagella of C. difficile do not play a role in adherence, since the antiserum raised against the purified protein did not inhibit adherence to cultured cells. PCR-RFLP analysis of amplified flagellin gene products and Southern analysis revealed inter-strain heterogeneity; this could be useful for epidemiological and phylogenetic studies of this organism.

Molecular Characterization of fliD Gene Encoding Flagellar Cap and Its Expression among Clostridium difficile Isolates from Different Serogroups

ABSTRACT The fliD gene encoding the flagellar cap protein (FliD) of Clostridium difficile was studied in 46 isolates belonging to serogroups A, B, C, D, F, G, H, I, K, X, and S3, including 30 flagellated strains and 16 nonflagellated strains. In all but three isolates, amplification by PCR and reverse transcription-PCR demonstrated that the fliD gene is present and transcribed in both flagellated and nonflagellated strains. PCR-restriction fragment length polymorphism (RFLP) analysis of amplifiedfliD gene products revealed interstrain homogeneity, with one of two major patterns (a and b) found in all but one of the strains, which had pattern c. A polyclonal monospecific antiserum raised to the recombinant FliD protein reacted in immunoblots with crude flagellar preparations from 28 of 30 flagellated strains but did not recognize FliD from nonflagellated strains. The fliDgenes from five strains representative of the three different RFLP groups were sequenced, and sequencing revealed 100% identity between the strains with the same pattern and 88% identity among strains with different patterns. Our results show that even though FliD is a structure exposed to the outer environment, the flagellar cap protein is very well conserved, and this high degree of conservation suggests that it has a very specific function in attachment to cell or mucus receptors.

Transcription and Analysis of Polymorphism in a Cluster of Genes Encoding Surface-Associated Proteins of Clostridium difficile

Recent investigations of the Clostridium difficile genome have revealed the presence of a cluster of 17 genes, 11 of which encode proteins with similar two-domain structures, likely to be surface-anchored proteins. Two of these genes have been proven to encode proteins involved in cell adherence: slpA encodes the precursor of the two proteins of the S-layer, P36 and P47, whereas cwp66 encodes the Cwp66 adhesin. To gain further insight into the function of this cluster, we further focused on slpA, cwp66, and cwp84, the latter of which encodes a putative surface-associated protein with homology to numerous cysteine proteases. It displayed nonspecific proteolytic activity when expressed as a recombinant protein in Escherichia coli. Polymorphism of cwp66 and cwp84 genes was analyzed in 28 strains, and transcriptional organization of the three genes was explored by Northern blots. The slpA gene is strongly transcribed during the entire growth phase as a bicistronic transcript; cwp66 is transcribed only in the early exponential growth phase as a polycistronic transcript encompassing the two contiguous genes upstream. The putative proteins encoded by the cotranscribed genes have no significant homology with known proteins but may have a role in adherence. No correlation could be established between sequence patterns of Cwp66 and Cwp84 and virulence of the strains. The cwp84 gene is strongly transcribed as a monocistronic message. This feature, together with the highly conserved sequence pattern of cwp84, suggests a significant role in the physiopathology of C. difficile for the Cwp84 protease, potentially in the maturation of surface-associated adhesins encoded by the gene cluster.

Development of an integrative vector for the expression of antisense RNA in Clostridium difficile

A method was developed to use the conjugative transposon Tn916 as a vector for introducing recombinant DNA into Clostridium difficile. This was used to introduce antisense RNA for the adhesin encoding gene cwp66 into C. difficile 79-685. RT-PCR demonstrated that cwp66 specific antisense RNA was produced. However, there was no statistically significant difference in the protein expression or in the adherence of recombinant C. difficile strains. This may be due to the amount of transcripts of the wild-type (sense) cwp66 outnumbering the antisense transcripts or secondary structures present within the cwp66 mRNA. Unlike in other strains of C. difficile, where Tn916 inserts into the genome at highly preferred sites, in C. difficile 79-685, it integrates into multiple sites opening up the possibility of using Tn916 as a mutagen in this strain.