The nucleotide sequence of the gene encoding the K99 subunit of enterotoxigenic Escherichia coli

Abstract The nucleotide sequence of the gene encoding the K99 fimbrial subunit of enterotoxigenic Escherichia coli was determined. It appeared that the subunit is composed of 159 amino acid residues preceded by a N-terminal signal sequence of 22 amino acid residues. The secondary structure of the mature K99 polypeptide and the location of potential antigenic determinants were predicted. A comparison was made between the amino acid sequence of the K99 subunit and the subunits of other fimbrial adhesins.     

Engineering upstream transcriptional and translational signals of Bordetella pertussis serotype 2 fimbrial subunit protein for efficient expression in Escherichia coli: in vitro autoassembly of the expressed product into filamentous structures

Escherichia coli containing a cloned gene encoding the Bordetella pertussis serotype 2 fimbrial subunit failed to produce detectable levels of the gene product in whole-cell extracts. To engineer plasmids capable of directing the expression in E. coli of high levels of this product, both as a pre-protein and as a methionylated mature form the upstream signals of the fimbrial subunit gene were replaced by the lambda P(L) and P(R) promoters and the E. coli atpE translational initiation region. These constructs did not result in the expression of fimbrial subunit at detectable levels in several E. coli strains including DH5. However, they did in E. coli CAG629, which is lon protease and heat shock protein deficient. Both pre-protein and methionylated mature protein had molecular weights of 25.0 kD, which indicated that correct processing of the leader sequence had occurred and thus that it was transposed across the inner membrane. Electron microscopic investigation of the cell surface of E. coli cells expressing either form of the fimbrial gene failed to detect the presence of filamentous structures. The methionylated mature form of the recombinant fimbrial subunit was purified to apparent homogeneity. After dialysis in appropriate conditions it was seen to autoassemble into protein polymers. Antibodies raised against polymerized recombinant subunit reacted weakly with whole B. pertussis serotype 2 fimbriae in immunodot blot assays. However, such antibodies reacted in Western blots equally well with the recombinant and wild-type form of the fimbrial subunit.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cloning and expression in Escherichia coli of Haemophilus influenzae fimbrial genes establishes adherence to oropharyngeal epithelial cells.

In this report the first example of functional expression of a fimbrial gene cluster of a non-enteric human pathogen in Escherichia coli is described. This is shown for Haemophilus influenzae fimbriae which mediate adherence to oropharyngeal epithelial cells. A genomic library of H.influenzae type b, strain 770235f+bo, was constructed using a cosmid vector and screened with a synthetic oligonucleotide probe derived from the N-terminal sequence of the fimbrial subunit of H.influenzae. Four cosmid clones were found which hybridized to this oligonucleotide probe. Escherichia coli strains harbouring these clones expressed the H.influenzae fimbriae at their cell surface, as was demonstrated in a whole-cell ELISA and by immunogold electron microscopy using a monoclonal antibody specific for the H.influenzae fimbriae. Surface expression could be maintained during subcloning until a minimal H.influenzae DNA insert of approximately 8.1 kb was obtained. Escherichia coli strains harbouring the 8.1 kb H. influenzae DNA were able to cause a mannose-resistant adherence to oropharyngeal epithelial cells and a mannose-resistant haemagglutination of human AnWj-positive erythrocytes. The nucleotide sequence of hifA, the gene encoding the major fimbrial subunit, was determined. The predicted amino acid sequence shows a significant homology with a number of E.coli fimbrial subunits.     

Type 1C fimbriae of a uropathogenic Escherichia coli strain: cloning and characterization of the genes involved in the expression of the 1C antigen and nucleotide sequence of the subunit gene

The genes responsible for expression of type 1C fimbriae have been cloned from the uropathogenic Escherichia coli strain AD110 in the plasmid vector pACYC184. Analysis of deletion mutants from these plasmids showed that a 7-kb DNA fragment was required for biosynthesis of 1C fimbriae. Further analysis of this DNA fragment showed that four genes are present encoding proteins of 16, 18.5, 21 and 89 kDal. A DNA fragment encoding the 16-kDal fimbrial subunit has been cloned. The nucleotide sequence of the structural gene and of the C- and N-terminal flanking regions was determined. The structural gene codes for a polypeptide of 181 amino acids, including a 24-residue N-terminal signal sequence. The nucleotide sequence and the deduced amino acid sequence of the 1C subunit gene were compared with the sequences of the fimA gene, encoding the type 1 fimbrial subunit of E. coli K-12. The data show absolute homology at the N- and C-termini; there is less, but significant homology in the region between the N- and C-termini. Comparison of the amino acid compositions of the 1C and FimA subunit proteins with those of the F72 and PapA proteins (subunits for P-fimbriae) revealed that homology between these two sets of fimbrial subunits is also maximal at the N- and C-termini.     

Sequence homology between the subunits of two immunologically and functionally distinct types of fimbriae of Actinomyces spp.

Nucleotide sequencing of the type 1 fimbrial subunit gene of Actinomyces viscosus T14V revealed a consensus ribosome-binding site followed by an open reading frame of 1,599 nucleotides. The encoded protein of 533 amino acids (Mr = 56,899) was predominantly hydrophilic except for an amino-terminal signal peptide and a carboxy-terminal region identified as a potential membrane-spanning segment. Edman degradation of the cloned protein expressed in Escherichia coli and the type 1 fimbriae of A. viscosus T14V showed that both began with alanine at position 31 of the deduced amino acid sequence. The amino acid compositions of the cloned protein and fimbriae also were comparable and in close agreement with the composition of the deduced protein. The amino acid sequence of the A. viscosus T14V type 1 fimbrial subunit showed no significant global homology with various other proteins, including the pilins of gram-negative bacteria. However, 34% amino acid sequence identity was noted between the type 1 fimbrial subunit of strain T14V and the type 2 fimbrial subunit of Actinomyces naeslundii WVU45 (M. K. Yeung and J. O. Cisar, J. Bacteriol. 170:3803-3809, 1988). This homology included several different conserved sequences of up to eight identical amino acids that were distributed in both the amino- and carboxy-terminal thirds of each Actinomyces fimbrial subunit. These findings indicate that the different types of fimbriae on these gram-positive bacteria share a common ancestry.     

K88ab gene of Escherichia coli encodes a fimbria-like protein distinct from the K88ab fimbrial adhesin.

The K88ab adhesin operon of Escherichia coli encodes for a fimbrial protein (the K88ab adhesin) which is involved in colonization of the porcine intestine. We characterized a structural gene (gene A) which is part of the K88ab adhesin operon and codes for an as yet unidentified polypeptide (pA). A mutation in gene A resulted in accumulation of K88ab adhesin subunits inside the cell. The nucleotide sequence of gene A was determined, and the deduced amino acid sequence suggested that pA is synthesized as a precursor containing a typical N-terminal signal peptide. The molecular weight of pA was calculated to be ca. 17,600. Gene A is preceded by a sequence showing homology with the consensus promoter. Fimbrial subunits from a number of E. coli strains have significant homology at their N- and C-termini. pA also contained some of these conserved sequences and showed a number of other similarities with fimbrial subunits. Therefore, it seems likely that the K88ab adhesin operon codes for a fimbrial subunit (pA) distinct from the K88ab adhesin subunit.     

Analysis of genes coding for the sialic acid-binding adhesin and two other minor fimbrial subunits of the S-fimbrial adhesin determinant of Escherichia coli

The S fimbrial adhesin (Sfa) enables Escherichia coli to attach to sialic acid-containing receptor molecules of eukaryotic cells. As previously reported, the genetic determinant coding for the Sfa of an E. coli O6 strain was cloned, the gene coding for the major fimbrial subunit was identified and sequenced and the S specific adhesin was detected. Here we present evidence that in addition to the major subunit protein SfaA three other minor subunit proteins, SfaG (17 kD), SfaS (14 kD) and SfaH (31 kD) can be isolated from the S-specific fimbrial adhesin complex. The genes coding for these minor subunits were identified, mutagenized separately and sequenced. Using haemagglutination tests, electron-microscopy and quantitative ELISA assays with monoclonal anti-SfaA and anti-SfaS antibodies the functions of the minor subunits were determined. It was determined that SfaS is identical to the S-specific adhesin, which also plays a role in determination of the degree of fimbriation of the cell. The minor subunit SfaH also had some influence on the level of fimbriation of the cell, while SfaG is necessary for full expression of S-specific binding. It was further shown that the amino-terminal protein sequence of the isolated SfaS protein was identical to the protein sequence calculated from the DNA sequence of the sfaS gene locus.     

Role of fimbrial adhesins in the pathogenesis of Escherichia coli infections.

Escherichia coli strains are able to cause intestinal (enteritis, diarrhoeal diseases) and extraintestinal (urinary tract infections, sepsis, meningitis) infections. Most pathogenic E. coli strains produce specific fimbrial adhesins, which represent essential colonization factors: intestinal E. coli strains very often carry transferable plasmids with gene clusters specific for fimbrial adhesins, like K88 and K99, or colonization factor antigens (CFA) I and II. In contrast, the fimbrial gene clusters of extraintestinal E. coli strains, such as P, S, or F1C fimbriae, are located on the chromosomes. The fimbrial adhesin complexes consist of major and minor subunit proteins. Their binding specificity can generally be assayed in hemagglutination tests. In the case of fimbrial adhesins of intestinal E. coli strains, the major subunit proteins preferentially represent the hemagglutinating adhesins, whereas minor subunit proteins are the hemagglutinins of extraintestinal E. coli strains. Recently "alternative" adhesin proteins were identified, which have the capacity to bind to eukaryotic structures different from the receptors of the erythrocytes. Fimbrial adhesins are not constitutively expressed but are stringently regulated on the molecular level. Extraintestinal E. coli wild-type strains normally carry three or more fimbrial adhesin determinants, which have the capacity to influence the expression of one another (cross talk). Furthermore the fimbrial gene clusters undergo phase variation, which seems to be important for their contribution to pathogenesis of E. coli.     

Ordered translocation of 987P fimbrial subunits through the outer membrane of Escherichia coli.

The 987P fimbria of enterotoxigenic Escherichia coli is a heteropolymeric structure which consists essentially of a major FasA subunit and a minor subunit, the FasG adhesin. The latter harbors the binding moiety for receptor molecules on piglet intestinal epithelial cells. In this study, anti-FasF antibody probes were developed and used to demonstrate that the FasF protein represents a new minor fimbrial component. FasF was identified in highly purified fimbriae, and its sequence demonstrated significant levels of similarity with that of FasA. Immune electron microscopy localized both the FasG and FasF proteins at the fimbrial tip as well as at broken ends and at various intervals along the fimbrial length. The presence of these minor proteins in purified 987P fimbriae was corroborated by enzyme-linked immunosorbent assay inhibitions. Finally, the use of nonfimbriated fasG, fasF, and fasA mutants indicated that subunit translocation through the outer membrane follows a specific order, FasG being the first, FasF being the second, and FasA being the third type of exported subunit. Since fimbriae are thought to grow from the base, FasG is proposed to be a tip adhesin and FasF is proposed to be a linker molecule between the adhesin and the fimbrial shaft. Moreover, export of FasG (or FasF) in the absence of FasF (or FasA) indicates that during the process of fimbrial biogenesis in the outer membrane, translocating events precede the initiation of subunit heteropolymerization.     

Fimbriae of Bacteroides nodosus: protein engineering of the structural subunit for the production of an exogenous peptide

The pattern of sequence variation between Bacteroides nodosus fimbrial subunits of different serotypes suggests a degree of flexibility, which might be exploited for protein engineering approaches for the expression of other peptides. We have tested this using the well-characterized peptide epitope from VP1 of foot-and-mouth disease virus (FMDV), residues 144-159: LRGDLQVLAQKVARTL (strain 01-BFS). Using bacterial codon usage, several oligonucleotides were designed for the substitution of this sequence internally at hypervariable regions of the fimbrial subunit (aligned for maximum homology), and for its addition at the carboxyterminus with a diglycine spacer as a flexible hinge. Following site-directed mutagenesis in phage M13, the modified genes were placed under PL promoter control and placed in a broad host range vector. Analysis of the variant proteins expressed in E. coli showed that these substitutions affected, to varying extents, recognition by both anti-fimbrial and anti-FMDV antibodies, indicating that hypervariable region 2 is a major antigenic determinant of the fimbrial subunit and that local stereochemical effects can influence antibody binding to the FMDV peptide antigenic determinant. In Pseudomonas aeruginosa, viable transformants could only be obtained with the mutant gene encoding the carboxy-terminal graft. These cells provided fimbrial preparations comprised of the modified subunit. This then constitutes the prototype for the development of a general expression system for the production of vaccine epitopes and other bioactive peptides. Furthermore, there is considerable scope for further modification of the system, for example by engineering specific chemical or protease cleavage sites for release of the grafted peptide. Alternatively, the fimbriae themselves may serve as a useful supramolecular carrier or adjuvant for immune provocation.     

Molecular basis for the enterocyte tropism exhibited by Salmonella typhimurium type 1 fimbriae

Salmonella typhimurium exhibits a distinct tropism for mouse enterocytes that is linked to their expression of type 1 fimbriae. The distinct binding traits of Salmonella type 1 fimbriae is also reflected in their binding to selected mannosylated proteins and in their ability to promote secondary bacterial aggregation on enterocyte surfaces. The determinant of binding in Salmonella type 1 fimbriae is a 35-kDa structurally distinct fimbrial subunit, FimHS, because inactivation of fimHS abolished binding activity in the resulting mutant without any apparent effect on fimbrial expression. Surprisingly, when expressed in the absence of other fimbrial components and as a translational fusion protein with MalE, FimHS failed to demonstrate any specific binding tropism and bound equally to all cells and mannosylated proteins tested. To determine if the binding specificity of Salmonella type 1 fimbriae was determined by the fimbrial shaft that is intimately associated with FimHS, we replaced the amino-terminal half of FimHS with the corresponding sequence from Escherichia coli FimH (FimHE) that contains the receptor binding domain of FimHE. The resulting hybrid fimbriae bearing FimHES on a Salmonella fimbrial shaft exhibited binding traits that resembled that of Salmonella rather than E. coli fimbriae. Apparently, the quaternary constraints imposed by the fimbrial shaft on the adhesin determine the distinct binding traits of S. typhimurium type 1 fimbriae.     

Characterization and molecular cloning of the PCF8775 CS5 antigen from an enterotoxigenic Escherichia coli 0115:H40 isolated in Central Australia

The genes determining the biosynthesis of the colonization factor CS5 have been cloned from Escherichia coli 0115:H40:PCF8775 isolated during an outbreak of diarrhoea among aboriginal children in Central Australia. Electron microscopy has shown purified CS5 to be of semi-rigid fimbrial type. NH2-terminal analysis has shown the CS5 determinant to be distinct from other fimbriae, although there is some conservation of certain residues. Expression in minicells of the cloned fimbrial genes encoded on pPM1312 has shown that proteins of 70 and 46.5 kD which co-purity with the 23 kD major fimbrial subunit protein are also co-expressed along with proteins of 45, 31, 17 and 14 kD. The major CS5 subunit is synthesized in precursor form (approximately 26 kD). A synthetic oligonucleotide to the NH2-terminal amino acid coding sequence of the purified protein has been used in Southern hybridization analyses to define the region on pPM1312 encoding the structural gene for the major pilin subunit.     

Three fim genes required for the regulation of length and mediation of adhesion of Escherichia coli type 1 fimbriae

Summary Three novel fim genes of Escherichia coli, fimF, fimG and fimH, were characterized. These genes were not necessary for the production of fimbriae but were shown to be involved in the adhesive property and longitudinal regulation of these structures. Complementation experiments indicated that both the major fimbrial subunit gene, fimA, and the fimH gene in combination with either the fimF or the fimG gene were required for mannose-specific adhesion. The fimF, fimG and fimH gene products were likewise shown to play a major role in the fimbrial morphology as longitudinal modulators. The amount of FimF, FimG and FimH proteins appeared to control the length and number of the fimbriae. The DNA sequence of a 2050 bp region containing the three genes was determined. The corresponding protein sequences all exhibited homology with the fimbrial subunit protein, FimA.     

Structure-function analysis of the K88ab fimbrial subunit protein from porcine enterotoxigenic Escherichia coli

Several in-frame linker insertions have been made in various positions in the faeG gene encoding the K88ab fimbrial subunit protein from porcine enterotoxigenic Escherichia coli. The effects of the linker insertions have been investigated with regard to the ability of the mutated fimbrial subunits to be exported to the surface of the bacterial cell and assembled into a fimbrial structure. The structure/function relationship of the subunit protein is discussed in the light of the phenotypes of the mutations constructed, secondary structure predictions, and hydrophilicity plots.     

Cloning and nucleotide sequence analysis of the serotype 2 fimbrial subunit gene of Bordetella pertussis

An oligonucleotide probe complementary to the beginning of the gene encoding the serotype 2(ST2) fimbrial subunit of Bordetella pertussis was synthesized and a cloned DNA fragment hybridizing with the probe identified and sequenced. Several lines of evidence indicate that an open reading frame with coding information for a polypeptide of 207 amino acids, including a 26-amino-acid signal sequence, is the ST2 gene. The protein deduced from the nucleotide sequence shows good agreement with the NH2-terminal amino acid sequence, amino acid composition and molecular weight of the purified fimbrial subunit. In addition, the proposed ST2 subunit is shown to have homology with other fimbrial subunits.     

Immunogenicity of a Cholera Toxin B Subunit <Emphasis Type="Italic">Porphyromonas gingivalis</Emphasis> Fimbrial Antigen Fusion Protein Expressed in <Emphasis Type="Italic">E. coli</Emphasis>

The gram-negative anaerobic oral bacterium Porphyromonas gingivalis initiates periodontal disease through fimbrial attachment to saliva-coated oral surfaces. To study the effects of immunomodulation on enhancement of subunit vaccination, the expression in E. coli and immunogenicity of P. gingivalis fimbrial protein (FimA) linked to the C-terminus of the cholera toxin B subunit (CTB) were investigated. Complementary DNAs encoding the P. gingivalis 381 fimbrillin protein sequence FimA1 (amino acid residues 1-200) and FimA2 (amino acid residues 201-337) were cloned into an E. coli expression vector downstream of a cDNA fragment encoding the immunostimulatory CTB. CTB-FimA1 and CTB-FimA2 fusion proteins synthesized in E. coli BL21 (DE3) cells were purified under denaturing conditions by Ni2+-NTA affinity column chromatography. Renaturation of the CTB-FimA1 and CTB-FimA2 fusion proteins, permitted identification of CTB-FimA pentamers and restored CTB binding activity to GM1-ganglioside to provide a biologically active CTB-FimA fusion protein. Mice orally inoculated with purified CTB-FimA1 or CTB-FimA2 fusion proteins generated measurable FimA1 and FimA2 IgG antibody titers, while no serum fimbrial IgG antibodies were detected when mice were inoculated with FimA1 or FimA2 proteins alone. Immunoblot analysis confirmed that sera from mice immunized with CTB linked to FimA1 or FimA2 contained antibodies specific for P. gingivalis fimbrial proteins. In addition, mice immunized with FimA2 or CTB-FimA2 generated measurable intestinal IgA titers indicating the presence of fimbrial antibody class switching. Further, mice orally immunized with CTB-FimA1 generated higher IgA antibody titers than mice inoculated with FimA1 alone. The experimental data show that the immunostimulatory molecule CTB enhances B cell-mediated immunity against linked P. gingivalis FimA fusion proteins, in comparison to immunization with FimA protein alone. Thus, linkage of CTB to P. gingivalis fimbrial antigens can increase subunit vaccine immunogenicity to provide enhanced protection against periodontal disease.