Isolation and characterisation of dog uropathogenic Escherichia coli strains and their fimbriae

A number of Escherichia coli strains have been isolated from dogs with urinary tract infections. These strains have been characterised with respect to their O, K, H, and fimbrial antigens, colicin production, antibiotic resistance, plasmid content and their ability to haemagglutinate erythrocytes from various species. Crossed immunoelectrophoresis of fimbrial extracts, as well as the reaction of partly purified fimbriae of a number of these strains with monoclonal antibodies revealed homology or a strong crossereaction with an F12 fimbrial subunit protein of human uropathogenic E. coli strains. Unlike human F12 fimbriae producing strains, the dog isolates did agglutinate dog erythrocytes in the presence of D-mannose but not human erythrocytes, indicating that the adhesin carried by these strains is different from the adhesin on fimbriae of human uropathogenic E. coli. Similar indications were obtained from experiments with latex beads coated with the receptor for P-fimbriae. These beads were agglutinated by Escherichia coli strains from human urinary tract infections, but not by the dog isolates described here. Preliminary adhesion experiments of human and dog Escherichia coli to human bladder epithelial and canine kidney epithelial cells also showed differences in adhesion depending on the origin of the strain tested.     

Galactose-Specific Fimbrial Adhesin of Enteroaggregative <Emphasis Type="Italic">Escherichia coli</Emphasis>: A Possible Aggregative Factor

A galactose-specific adhesin was isolated from the fimbriae of an enteroaggregative Escherichia coli (EAEC) strain. The adhesin was found to be a high molecular weight aggregate of the 18-kDa monomer. The dimeric (36 kDa) and tetrameric (76 kDa) forms appeared in sodium dodecyl sulphate polyacrylamide gel electrophoresis when a higher concentration of the adhesin was used. The IgG_AD (IgG against adhesin) obtained from the immune sera raised in rabbits against purified adhesin could detect all three forms of the adhesin even from the crude fimbrial preparation. The IgG_AD failed to recognize the adhesin in the presence of galactose, thereby suggesting the antibody-binding site and the sugar-binding site on the adhesin might be same or overlapping. Furthermore, the IgG_AD could localize the adhesin exclusively on the fimbriae as observed in immunogold electron microscopy. The aggregative adherence of the bacteria to HEp-2 cells was reduced to 70% in the presence of the IgG_AD. A glycoprotein (34 kDa) present in the membrane fraction of HEp-2 cells interacted with the purified adhesin in a galactose-specific manner. The IgG_AD could recognize the adhesin from the crude fimbrial preparation of 9 out of 10 clinical isolates of EAEC strains but failed to identify any protein from the crude fimbrial preparation of Salmonella typhimurium (fim +ve as well as fim −ve strain), Vibrio cholerae (WO7) or Escherichia coli DH5α.     

Host-specificity of uropathogenic Escherichia coli depends on differences in binding specificity to Gal alpha 1-4Gal-containing isoreceptors.

Four G adhesins, cloned from uropathogenic Escherichia coli strains, were examined for binding to glycolipids and various eukaryotic cells. PapGAD110 and PapGIA2 showed virtually identical binding patterns to Gal alpha 1-4Gal-containing glycolipids, while PapGJ96 differed slightly and PrsGJ96 markedly with respect to the effect of neighbouring groups on the binding. Their hemagglutination patterns confirmed the existence of three receptor-binding specificities. While the PapG adhesins bound to uroepithelial cells from man (T24) but not to those from the dog (MDCK II), the reverse was true of PrsG. These binding patterns were largely explained by the absence or presence of appropriate glycolipid isoreceptors, although the inability of the PapG adhesins to bind MDCK II cells was attributed to an inappropriate presentation of their receptor epitopes. The high prevalence of PrsG-like specificities observed among wild-type dog uropathogenic E. coli isolates, together with the determined isoreceptor composition of human and dog kidney target tissues, suggest variation in receptor specificity as a mechanism for shifting host specificity, and that this variation has evolved in response to the topography of the host cellular receptors. The receptor-binding half proposed for the predicted amino acid sequences of the four G adhesins and the corresponding adhesin of one of the dog E. coli isolates varied considerably among the three receptor-binding groups of adhesins, but only little within each group.     

Fermentative degradation of acetone by an enrichment culture in membrane-separated culture devices and in cell suspensions

Abstract We have recently demonstrated that cultured human intestinal HT-29 and Caco-2 cell lines express receptors for the F1845 fimbrial adhesin harbored by the diarrheagenic C1845 Escherichia coli (Kernéis et al., Infect. Immun. 59 (1991) 4013–4018). This adhesinn belongs to a family of adhesins including the Dr hemagglutinin and the afimbrial adhesin AFA-1 harbored by uropathogenic E. coli . Here we investigated the cell association of laboratory E. coli strains expressing the Dr hemagglutinin and the afimbrial adhesin AFA-I with human cultured enterocyte-like or mucosecreting cells. We observed that the E. coli strains bearing these adhesins adhere both to human intestinal undifferentiated and differentiated fluid-transporting cells, and to mucus-secreting cells. This result strongly suggests a high capacity of intestinal colonization for the uropathogenic E. coli harboring adhesive factors belonging to the Dr adhesin family. These results further corroborate the intestinal colonization by uropathogenic E. coli of the Dr family related to the fecal-perineal-urethral hypothesis of urinary tract infection pathogenesis.     

Characterization of fimbriae produced by enteropathogenic Escherichia coli.

Enteropathogenic Escherichia coli (EPEC) express rope-like bundles of filaments, termed bundle-forming pili (BFP) (J. A. Girón, A. S. Y. Ho, and G. K. Schoolnik, Science 254:710-713, 1991). Expression of BFP is associated with localized adherence to HEp-2 cells and the presence of the EPEC adherence factor plasmid. In this study, we describe the identification of rod-like fimbriae and fibrillae expressed simultaneously on the bacterial surface of three prototype EPEC strains. Upon fimbrial extraction from EPEC B171 (O111:NM), three fimbrial subunits with masses of 16.5, 15.5, and 14.7 kDa were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Their N-terminal amino acid sequence showed homology with F9 and F7(2) fimbriae of uropathogenic E. coli and F1845 of diffuse-adhering E. coli, respectively. The mixture of fimbrial subunits (called FB171) exhibited mannose-resistant agglutination of human erythrocytes only, and this activity was not inhibited by alpha-D-Gal(1-4)-beta-Gal disaccharide or any other described receptor analogs for P, S, F, M, G, and Dr hemagglutinins of uropathogenic E. coli, which suggests a different receptor specificity. Hemagglutination was inhibited by extracellular matrix glycoproteins, i.e., collagen type IV, laminin, and fibronectin, and to a lesser extent by gangliosides, fetuin, and asialofetuin. Scanning electron microscopic studies performed on clusters of bacteria adhering to HEp-2 cells revealed the presence of structures resembling BFP and rod-like fimbriae linking bacteria to bacteria and bacteria to the eukaryotic cell membrane. We suggest a role of these surface appendages in the interaction of EPEC with eukaryotic cells as well as in the overall pathogenesis of intestinal disease caused by EPEC.     

Presentation of the functional receptor-binding domain of the bacterial adhesin F17a-G on bacteriophage M13

Bovine enterotoxigenic Escherichia coli (ETEC) carrying F17a fimbriae attach to the intestinal epithelium by means of the F17a-G adhesin. Since filamentous bacteriophages can be employed for the display of foreign peptides, we tested the applicability of this system to F17a-G. The receptor-binding domain of the F17a-G adhesin was expressed on bacteriophage M13, as an amino-terminal fusion with the phage protein pIII. This domain retained its N-acetyl-beta-d-glucosamine binding activity. The phage presenting the fimbrial receptor-binding domain elicited an IgG response against F17a-G after intraperitoneal immunisation of mice.     

Immunocytochemical analysis of P-fimbrial structure: localization of minor subunits and the influence of the minor subunit FsoE on the biogenesis of the adhesin

Antibodies recognizing the non-adhesive minor P-fimbral subunit protein E and the P-fimbrial adhesin were used in an immunocytochemical analysis of P-fimbrial structure. It was demonstrated that P-fimbriae of the serotypes F71, F72 and F11 carry their adhesin in a complex with protein E. These complexes are commonly found at the tip of the fimbrial structure. In P-fimbriae of serotype F9, expressed by the uropathogenic Escherichia coli strain 21086, adhesin-protein E complexes are localized at the tips as well as along the shafts of the fimbriae. Protein E of F71 fimbriae (FsoE) plays a catalysing role in the biogenesis of the adhesin, but has no effect on the eventual localization of the adhesin.     

Gene clusters for S fimbrial adhesin (sfa) and F1C fimbriae (foc) of Escherichia coli: comparative aspects of structure and function.

Fimbrial adhesins enable bacteria to attach to eucaryotic cells. The genetic determinants for S fimbrial adhesins (sfa) and for F1C ("pseudotype I") fimbriae (foc) were compared. Sfa and F1C represent functionally distinct adhesins in their receptor specificities. Nevertheless, a high degree of homology between both determinants was found on the basis of DNA-DNA hybridizations. Characteristic differences in the restriction maps of the corresponding gene clusters, however, were visible in regions coding for the fimbrial subunits and for the S-specific adhesin. While a plasmid carrying the genetic determinant for F1C fimbriae was able to complement transposon-induced sfa mutants, a plasmid carrying the genetic determinant for a third adhesin type, termed P fimbriae, was unable to do so. Proximal sfa-specific sequences carrying the S fimbrial structural gene were fused to sequences representing the distal part of the foc gene cluster to form a hybrid cluster, and the foc proximal region coding for the structural protein was ligated to sfa distal sequences to form a second hybrid. Both hybrid clones produced intact fimbriae. Anti-F1C monoclonal antibodies (MAbs) only recognized clones which produced F1C fimbriae, and an anti-S adhesin MAb marked clones which expressed the S adhesin. However, one of four other anti-S fimbriae-specific MAbs reacted with both fimbrial structures, S and F1C, indicating a common epitope on both antigens. The results presented here support the view that sfa and foc determinants code for fimbriae that are similar in several aspects, while the P fimbriae are members of a more distantly related group.     

The DraC usher in Dr fimbriae biogenesis of uropathogenic E. coli Dr+ strains

Biogenesis of Dr fimbriae encoded by the dra gene cluster of uropathogenic Escherichia coli strains requires the chaperone-usher pathway. This secretion system is based on two non-structural assembly components, the DraB periplasmic chaperone and DraC outer-membrane usher. The DraB controls the folding of DraE subunits, and DraC forms the assembly and secretion platform for polymerization of subunits in linear fibers. In this study, mutagenesis of the DraC N-terminus was undertaken to select residues critical for Dr fimbriae bioassembly. The DraC-F4A, DraC-C64, DraC-C100A and DraC-W142A significantly reduced the adhesive ability of E. coli strains. The biological activity of the DraC mutants as a assembly platform for Dr fimbriae polymerization was verified by agglutination of human erythrocytes and adhesion to DAF localized at the surface of CHO-DAF⁺ and HeLa cells. The residue F4 of the DraC usher conserved among FGL and FGS chaperone-assembled adhesive organelles can be used to design pillicides blocking the biogenesis of Dr fimbriae. Because the draC and afaC-III genes share 100% identity the range of the virulence determinant inhibitors could also be extended to E. coli strains encoding afa-3 gene cluster. The investigations performed showed that the usher N-terminus plays an important role in biogenesis of complete fiber.     

Type I fimbriae mediate in vitro adherence of porcine F18ac+ enterotoxigenic <Emphasis Type="Italic">Escherichia coli</Emphasis> (ETEC)

Type I fimbriae commonly expressed by Escherichia coli mediate initial attachment of bacteria to host epithelial cells. However, the role of type I fimbriae in the adherence of porcine enterotoxigenic E. coli (ETEC) to host receptors is unclear. In this study, we examined the role of type I fimbriae in the adherence and biofilm formation of F18ac+ ETEC by constructing mutant strains with deletion of type I fimbrial major subunit (fimA) or minor subunit (fimH). The data indicated that the isogenic ΔfimA and ΔfimH mutants showed significantly lower adherence to porcine epithelial IPEC-1 and IPEC-J2 cells as compared to the F18ac+ ETEC parent strain. In addition, the adherence of F18ac+ ETEC to both cell lines was blocked by the presence of 0.5% D-mannose in the cell culture medium. In addition, both mutant strains impaired their ability to form biofilm in vitro. Interestingly, the deletion of fimA or fimH genes resulted in remarkable up-regulation of the expression of adhesin involved in diffuse adherence (AIDA-I). These results indicated that type I fimbriae may be required for efficient adherence of F18ac+ ETEC to pig epithelial cells and, perhaps, biofilm formation.     

Shiga Toxin 2e-Producing Escherichia coli Isolates from Humans and Pigs Differ in Their Virulence Profiles and Interactions with Intestinal Epithelial Cells

Thirteen Escherichia coli strains harboring stx_2e were isolated from 11,056 human stools. This frequency corresponded to the presence of the stx_2e allele in 1.7% of all Shiga toxin-producing E. coli (STEC) strains. The strains harboring stx_2e were associated with mild diarrhea (n = 9) or asymptomatic infections (n = 4). Because STEC isolates possessing stx_2e are porcine pathogens, we compared the human STEC isolates with stx_2e-harboring E. coli isolated from piglets with edema disease and postweaning diarrhea. All pig isolates possessed the gene encoding the F18 adhesin, and the majority possessed adhesin involved in diffuse adherence; these adhesins were absent from all the human STEC isolates. In contrast, the high-pathogenicity island encoding an iron uptake system was found only in human isolates. Host-specific patterns of interaction with intestinal epithelial cells were observed. All human isolates adhered to human intestinal epithelial cell lines T84 and HCT-8 but not to pig intestinal epithelial cell line IPEC-J2. In contrast, the pig isolates completely lysed human epithelial cells but not IPEC-J2 cells, to which most of them adhered. Our data demonstrate that E. coli isolates producing Shiga toxin 2e have imported specific virulence and fitness determinants which allow them to adapt to the specific hosts in which they cause various forms of disease.     

Purification and Characterization of Type 1 Fimbriae of Salmonella typhi

Type 1 fimbriae have been purified from a Salmonella typhi strain of clinical origin. Purified fimbriae retained their ability to bind to erythrocytes in a mannose-inhibitable fashion and, in doing so, behaved preferentially as a monovalent adhesin. SDS-PAGE analysis of the fimbrial preparation showed the presence of a 20-kDa major polypeptide component (fimbrillin) and of additional larger polypeptides present in smaller amounts. The amino-terminal sequence of fimbrillin was determined and turned out to be very similar but not identical to that of type 1 fimbrillins of other Salmonella serovars. A Western blot analysis of the purified fimbrial preparation using an antiserum raised against native fimbriae suggested that fimbrial proteins did not carry any major sequential epitope and that, in native fimbriae, conformational epitopes, possibly generated between different subunits, might provide for the major immunogenic epitopes. Analysis of different S. typhi clinical isolates using the anti-fimbrial antiserum showed an overall immunological similarity of these structures within this serovar.     

大肠杆菌F18菌毛及其亚型的PCR鉴定

F18菌毛是产肠毒素大肠杆菌 (ETEC)与产vero细胞毒素大肠杆菌 (VTEC)的重要致病因子 ,可介导细菌对小肠细胞的黏附 ,并具有F18ab和F18ac 2个抗原亚型。根据已发表的F18ab菌毛A亚单位 (FedA ab)的基因 (fedA ab)设计 3条引物 ,建立了 2种聚合酶链式反应 (PCR)扩增方法。通过对F18ab 大肠杆菌、F18ac 大肠杆菌、K88 大肠杆菌、K99 大肠杆菌、987P 大肠杆菌、F4 1 大肠杆菌的试验 ,结果表明所建立的PCR方法可特异性鉴定F18 大肠杆菌并区别其亚型F18ab与F18ac     

Two kinds of P-fimbrial variants of uropathogenic Escherichia coli recognizing forssman glycosphingolipid.

Various types of fimbriae on pathogenic Escherichia coli strains have been classified by their antigenicities and recognition specificities for receptors. However, the antigenicity of fimbrial proteins does not always correlate with the fimbrial recognition specificity. In this communication, the exact carbohydrate structures recognized by the fimbriae of two human uropathogenic E. coli strains, KS71 (O4) and IH11024 (O6), that have P-fimbrial antigen, were examined. Strain KS71 showed mannose-resistant (MR) hemagglutination (HA) of human blood group OP1 phenotype erythrocytes, and its HA was inhibited by blood group Pk antigen, Gal(alpha,1-4)Gal(beta,1-4)Glc-ceramide and P antigen, GalNAc(beta,1-3)Gal (alpha,1-4)Gal(beta,1-4)Glc-ceramide but not by Forssman antigen, GalNAc(alpha,1-3)GalNAc(beta,1-3)Gal(alpha,1-4)Gal (beta,1-4)Glc-ceramide, as previously described in many papers. The cells also showed MR HA of sheep erythrocytes, which was potently inhibited by Forssman, and weakly by P and Pk antigens. These phenomena could not be explained by the above P adhesin specificity. This adhesin was called Forssman-like adhesin. Strain IH11024 also caused MR HA of sheep erythrocytes but not of human erythrocytes. The HA was inhibited specifically by Forssman but neither by Pk nor P antigen. This adhesin was completely different from P adhesin and Forssman-like adhesin in recognition of the carbohydrate epitope. This adhesin, until now called a pseudotype of P fimbriae, was renamed Forssman adhesin.     

Structural and Population Characterization of MrkD,the Adhesive Subunit of Type 3 Fimbriae

Type 3 fimbriae are adhesive organelles found in enterobacterial pathogens. The fimbriae promote biofilm formation on biotic and abiotic surfaces; however, the exact identity of the receptor for the type 3 fimbriae adhesin, MrkD, remains elusive. We analyzed naturally occurring structural and functional variabilities of the MrkD adhesin from Klebsiella pneumoniae and Escherichia coli isolates of diverse origins. We identified a total of 33 allelic variants of mrkD among 90 K. pneumoniae isolates and 10 allelic variants among 608 E. coli isolates, encoding 11 and 9 protein variants, respectively. Based on the level of accumulated silent variability between the alleles, mrkD was acquired a relatively long time ago in K. pneumoniae but recently in E. coli. However, unlike K. pneumoniae, mrkD in E. coli is actively evolving under a strong positive selection by accumulation of mutations, often targeting the same positions in the protein. Several naturally occurring MrkD protein variants from E. coli were found to be significantly less adherent when tested in a mannan-binding assay and showed reduced biofilm-forming capacity. Functional examination of the MrkD adhesin in flow chamber experiments determined that it interacts with Saccharomyces cerevisiae cells in a shear-dependent manner, i.e., the binding is catch-bond-like and enhanced under increasing shear conditions. Homology modeling strongly suggested that MrkD has a two-domain structure, comprising a pilin domain anchoring the adhesin to the fimbrial shaft and a lectin domain containing the binding pocket; this is similar to structures found in other catch-bond-forming fimbrial adhesins in enterobacteria.     

Genetic analysis of complex gene clusters inEscherichia coli: the genetic analysis of F72 fimbrial genes

Cloning techniques make it possible to accommodate bacterial genes on vector DNA molecules. On that basis the investigation of bacterial structures and functions got new impetus. The potentials of molecular genetics for detailed analysis of bacterial structures are illustrated in this paper for the gene cluster involved in the expression of F7₂ fimbriae associated with a uropathogenicEscherichia coli O6:K2:H1:F7 strain.     

Comparison between Enterotoxigenic Escherichia coli Strains Expressing “F42,” F41 and K99 Colonization Factors

Two enterotoxigenic Escherichia coli (ETEC) strains (coded 567/7 and 103) isolated from piglets with neonatal diarrhea were described as producers of a new adhesin (F42). With the use of molecular biology and immunology techniques such as DNA hybridization with probes for F41 and K99 genes and Western-blotting of the superficial proteins of these strains and standard E. coli strains carrying genes for F41 and K99 adhesins, it was demonstrated that this new adhesin either shares extensive genetic and immunological determinants with F41 adhesin or they are the same fimbriae.     

Synergy between type 1 fimbriae expression and C3 opsonisation increases internalisation of E. coli by human tubular epithelial cells

Background  

Bacterial infection of the urinary tract is a common clinical problem with E. coli being the most common urinary pathogen. Bacterial uptake into epithelial cells is increasingly recognised as an important feature of infection. Bacterial virulence factors, especially fimbrial adhesins, have been conclusively shown to promote host cell invasion. Our recent study reported that C3 opsonisation markedly increases the ability of E. coli strain J96 to internalise into human proximal tubular epithelial cells via CD46, a complement regulatory protein expressed on host cell membrane. In this study, we further assessed whether C3-dependent internalisation by human tubular epithelial cells is a general feature of uropathogenic E. coli and investigated features of the bacterial phenotype that may account for any heterogeneity.     

Fimbrial adhesins: similarities and variations in structure and biogenesis

Abstract Fimbriae are wiry (2 to 4 nm diam.) or rod-shaped (6 to 8 nm diam.), fibre-like structures on the surfaces of bacteria which mediate attachment to host cells. Much has been learned in recent years about the biogenesis, structure and regulation of expression of these adhesive organelles in Gram-negative bacteria. Analyses of the genetic determinants encoding the biogenesis of fimbriae has revealed that the adhesive interaction of fimbriae can be mediated by major subunits (CFA/I and CS1 fimbriae) or minor subunits (P, S, and type 1 fimbriae), with the adhesin being located either at the tip of the fimbria or along the length of the fimbrial shaft. Minor subunits can also act as adapters, anchors, initiators or elongators. Post-translational glycosylation of the type 4 pilins of Neisseria gonorrhoeae, Neisseria meningitidis and Pseudomonas aeruginosa has been demonstrated. The structures of the PapD chaperone of Escherichia coli and of N. gonorrhoeae type 4 fimbrin have been resolved at 2.0–2.6 Å. Rod-shaped fimbriae should not be thought of as being rigid inflexible structures but rather as dynamic structures which can undergo transition from a helicoidal to a fibrillar conformation to provide a degree of elasticity and plasticity to the fimbriae so that they can resist shear forces, rather like a bungee cord. At least four mechanisms have been identified in the assembly of fimbriae from fimbrin subunits, namely the chaperone-usher pathway (e.g., P-fimbriae of uropathogenic E. coli ), the general secretion assembly pathway (e.g., type 4 fimbriae or N -methylphenylalanine fimbriae of P. aeruginosa , the extracellular nucleation-precipitation pathway (e.g., curli of E. coli ) and the CFA/I, CS1 and CS2 fimbrial pathway.