A novel fimbrial type in Escherichia coli was identified and characterized. The expression of the fimbria was associated with the O18acK1H7 clonal group of E. coli, which cause newborn meningitis and septicemia when grown at low temperature; hence, it was named the Mat (meningitis associated and temperature regulated) fimbria. The fimbriae were purified from a fimA::cat sfaA::Gm fliC::St derivative of the O18K1H7 isolate E. coli IHE 3034. The purified Mat fimbrillin had an apparent molecular mass of 18 kDa and did not serologically cross-react with the type 1 or S fimbria of the same strain. The matB gene encoding the major fimbrillin was cloned from the genomic DNA of the fimA::cat sfaA::Gm fliC::St derivative of IHE 3034. The predicted MatB sequence was of 195 amino acids, contained a signal sequence of 22 residues, and did not show significant homology to any of the previously characterized fimbrial proteins. The DNA sequence of matB was 97.8% identical to a region from nucleotides 17882 to 18469 in the 6-to 8-min region of the E. coli K-12 chromosome, reported to encode a hypothetical protein. The 7-kb DNA fragment containing matB of IHE 3034 was found by restriction mapping and partial DNA sequencing to be highly similar to the corresponding region in the K-12 chromosome. Trans complementation of the matB::cat mutation in the IHE 3034 chromosome showed that matB in combination with matA or matC restored surface expression of the Mat fimbria. A total of 27 isolates representing K-12 strains and the major pathogroups of E. coli were analyzed for the presence of a matB homolog as well as for expression of the Mat fimbria. A conserved matB homolog was found in 25 isolates; however, expression of the Mat fimbriae was detected only in the O18acK1H7 isolates. Expression of the Mat fimbria was temperature regulated, with no or a very small amount of fimbriae or intracellular MatB fimbrillin being detected in cells cultivated at 37 o C. Reverse transcriptase PCR and complementation assays with mat genes controlled by the inducible trc promoter indicated that regulation of Mat fimbria expression involved both transcriptional and posttranscriptional events. Numerous proteinaceous adhesins have been detected inEscherichia coli (for recent reviews, see references 20 and 27). These adhesins occur in the form of fimbrial filaments or are nonfimbrial proteins of the outer membrane. The adhesins recognize different receptor molecules on the mammalian epithelia or extracellular matrices and function to enable colonization of E. coli at specific ecological niches. Many of the adhesins are associated with E. coli isolates from specific disease manifestations and contribute to the establishment of the infections. Examples of such disease-associated adhesins include the P fimbria of uropathogenic E. coli (UPEC) (55) and the various adhesin types detected in E. coli pathogroups causing diarrheal diseases (reviewed in references 13 and 36). Some adhesin genes, such as those encoding the mannosidebinding type 1 fimbriae (26) and th...
Interaction of the basement-membrane binding O75X adhesin of uropathogenic Escherichia coli with various extracellular matrix proteins was studied. The adhesin showed strong binding to type IV collagen immobilized on microtitre plates, whereas other collagens, laminin and fibronectin, were only weakly recognized. Similarly, specific binding of [125I]-labelled type IV collagen to O75X-positive bacteria was shown. Interaction of the two proteins was also demonstrated by affinity chromatography of the O75X adhesin on immobilized type IV collagen. The adhesin bound strongly to the immobilized N-terminal 7S domain of type IV collagen, and the binding of [125I]-labelled type IV collagen to O75X-positive bacteria was inhibited by the soluble 7S domain. Binding of O75X to type IV collagen and to its 7S domain was specifically inhibited by chloramphenicol but was not affected by periodate or endoglycosidase-H treatment of the glycoproteins. Our results show that the 7S domain of type IV collagen is the basement membrane receptor for the O75X adhesin and suggest an interaction based on protein-protein recognition. Inhibition of the interaction by chloramphenicol favours the supposition that a modified tyrosine is involved in the binding site.
Adherence of type-1-fimbriate Salmonella enterica and Escherichia coli to immobilized proteins of the extracellular matrix and reconstituted basement membranes was studied. The type-1-fimbriate strain SH401 of S. enterica serovar Enteritidis showed good adherence to laminin, whereas the adherence to fibronectin, type I, type III, type IV or type V collagens was poor. Only minimal adherence to the matrix proteins was seen with a non-fimbriate strain of S. enterica serovar Typhimurium. A specific and mannoside-inhibitable adhesion to laminin was exhibited by the recombinant E. coli strain HB101(pISF101) possessing fim genes of Typhimurium. Adherence to laminin of strain SH401 was inhibited by Fab fragments against purified SH401 fimbriae, and a specific binding to laminin, of the purified fimbriae, was demonstrated using fimbriae-coated fluorescent microparticles. Periodate treatment of laminin abolished the bacterial adhesion as well as the fimbrial binding. Specific adhesion to immobilized laminin was also shown by the type-1-fimbriate E. coli strain 2131 and the recombinant strain E. coli HB101(pPKL4) expressing the cloned type-1-fimbriae genes of E. coli. Adhesion to laminin of strain HB101(pPKL4) was inhibited by mannoside, and no adherence was seen with the fimH mutant E. coli HB101(pPKL5/pPKL53) lacking the fimbrial lectin subunit. The type-1 fimbriate strains also adhered to reconstituted basement membranes from mouse sarcoma cells and human placenta. Adhesion of strains HB101(pISF101) and HB101(pPKL4) to both basement membrane preparations was inhibited by mannoside. We conclude that type-1 fimbriae of S. enterica and E. coli bind to oligomannoside chains of the laminin network in basement membranes.
SummaryAdhesion of meningitis-associated Escherichia coli O18acK1H7 to collagens was characterized. The E. coli strain IHE 3034 adhered to type IV and type I collagens but not to type III collagen immobilized on glass. Collagens lack terminal mannosyl units, yet the bacterial adhesion was completely abolished in the presence of ␣-methyl-D-mannoside. A cat cassette was introduced into the fimA gene of IHE 3034, and the resulting mutant strain IHE 3034-2 failed to adhere to collagens. In contrast, insertion of a Gm cassette into the sfaA gene of IHE 3034, encoding the S-fimbrillin, had no significant effect on the adhesiveness. The fim cluster from IHE 3034 was cloned and expressed in trans in the fimA::cat mutant strain IHE 3034-2. The complemented strain IHE 3034-2(pRPO-1) exhibited adhesiveness to type IV and type I collagens, confirming the function of the type 1 fimbria in the adhesion. We have previously shown that the type 1 fimbria from E. coli K-12 strain PC31 does not confer bacterial adhesiveness to collagens. The fimH genes from E. coli IHE 3034 as well as from PC31 were expressed in the fimH-null strain MS4. The FimH from IHE 3034 potentiated collagen adherence, whereas the FimH from PC31 was inactive. Sequence comparison of fimH from IHE 3034 and PC31 revealed five amino-acid differences in the predicted mature FimH proteins: at residues 27, 62, 70, 78 and 201. Each of these residues in the IHE 3034-FimH were individually substituted to the corresponding amino acid in the PC31-FimH. The substitution S62→A completely abolished collagen adhesiveness. The reverse substitution A62→S in the PC31-FimH as well as in the FimH from another E. coli strain induced collagen adhesiveness to the level seen with IHE 3034-FimH. Out of nine fimH genes analysed from isolates of E. coli, collagen adhesiveness as well as alanine at position 62 in FimH were found only in two O18acK1H7 isolates with the isoenzyme profile ET type 1. Our results demonstrate that the amino-acid residue Ala-62 in the FimH lectin is critical for the adhesion to collagens by a highly virulent clonal group of E. coli.
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