Primary structure and subcellular localization of two fimbrial subunit-like proteins involved in the biosynthesis of K99 fibrillae

Analysis of the nucleotide sequence of the distal part of the fan gene cluster encoding the proteins involved in the biosynthesis of the fibrillar adhesin, K99, revealed the presence of two structural genes, fanG and fanH. The amino acid sequence of the gene products (FanG and FanH) showed significant homology to the amino acid sequence of the fibrillar subunit protein (FanC). Introduction of a site-specific frameshift mutation in fanG or fanH resulted in a simultaneous decrease in fibrillae production and adhesive capacity. Analysis of subcellular fractions showed that, in contrast to the K99 fibrillar subunit (FanC), both the FanH and the FanG protein were loosely associated with the outer membrane, possibly on the periplasmic side, but were not components of the fimbriae themselves.     

Effect of chemical modifications on the K99 and K88ab fibrillar adhesins of Escherichia coli

The role of specific amino acid residues of the K88ab and K99 fibrillar adhesins in the binding to erythrocytes and antibodies has been studied by chemical modification. It appeared that: (1) The integrity of the single disulfide bridge in the K99 subunits is essential for the binding of the fibrillae to the glycolipid receptors, but not for the recognition and binding of specific anti-K99 antibodies. (2) Modification of one lysine residue per subunit with 4-chloro-3,5-dinitrobenzoate results in the loss of the adhesive capacity of K99 fibrillae. Lysine residue are not important for the adhesive activity of K88ab fibrillae. Three or five lysine residues per subunit, respectively, can be modified without an effect on the immunological properties of the K99 and K88ab fibrillae. (3) Limited reaction of K99 and K88ab fibrillae with 2,3-butanedione destroys the adhesive activity of both fibrillae. This inactivation corresponds with the loss of one (K99) or two (K88ab) arginine residues per subunit. Ultimately, in K99 three, and in K88ab four, arginine residues per subunit can be modified without affecting the binding of specific antibodies. (4) Modification of five out of the nine carboxyl groups contained in the K99 subunit suppresses the recognition of specific anti-K99 antibodies, but carboxylates are not important for the adhesive activity of K99 fibrillae. Modification of two additional carboxylates in K99 results in an insoluble product. (5) Tyrosine residues are most probably not present in the adhesive or antigenic sites of K99 fibrillae. Modification of six out of the ten tyrosine residues in the K88ab subunit results in a decrease in adhesive activity but has no effect on the reaction with anti-K88ab antibodies.     

The role of lysine-132 and arginine-136 in the receptor-binding domain of the K99 fibrillar subunit.

The gene encoding the K99 fibrillar adhesin of Escherichia coli has been modified by oligonucleotide-directed, site-specific, mutagenesis. The tryptophan-67, lysine-132, lysine-133 or arginine-136 were replaced by leucine, threonine, threonine and serine, respectively. The threonine-133 mutant fibrillae were indistinguishable from wild-type fibrillae. In contrast, replacement of lysine-132 or arginine-136 by threonine or serine, respectively, resulted in mutant fibrillae which had completely lost adhesive capacity, suggesting that the positive charges of these residues are essential for the interaction with the negatively charged sialic acid residue of the receptor molecules. After the replacement of tryptophan-67 with leucine neither fibrillae nor subunits were detectable, indicating that the mutant product is unstable and that tryptophan-67 has an essential structural role in the K99 subunit.     

Structure, localization and function of FanF, a minor component of K99 fibrillae of enterotoxigenic Escherichia coii

The DNA sequence of the K99 fanF gene, encoding FanF, was determined. An open reading frame of 999 bp was found. The primary structure of FanF was deduced and analysis revealed the presence of a signal sequence of 22 amino acid residues. The mature protein contains 311 amino acid residues (Mr 33,905 D). The amino acid sequence of FanF showed similarity with the K88ab major subunit FaeG. A specific mouse antiserum against FanF was prepared by constructing and purifying a hybrid Cro-LacZ-FanF protein. Minicell analysis, immunoblotting and immunoelectronmicroscopy revealed a pool of FanF in the periplasm of K99-producing cells and showed, furthermore, that FanF is a minor component of K99 fibrillae, present at the top and in or along the shaft of the K99 fibrillar structures. A fanF mutant plasmid was constructed. Cells harbouring this plasmid produced all K99-specific proteins, except FanF, but produced 0.1% of the K99 fibrillae relative to 'normal' K99-producing cells. Electron microscopic observations showed that cells defective in fanF produce only a few (apparently short) K99 fibrillae. FanF, therefore, was supposed to play a role in initiation and elongation of K99 fibrillae formation. Thin-layer chromatography experiments involving purified receptor material showed that FanF is not required for binding of K99 fibrillae to the ganglioside receptor. Fibrillae produced by an adhesion-negative strain carrying a mutation in the K99 major fibrillar subunit were shown to contain a normal amount of FanF.     

Role of phenylalanine 150 in the receptor-binding domain of the K88 fibrillar subunit.

Recently, we reported the isolation of three peptides, Ile-83-Ala-Phe-85, Ser-148-Leu-Phe-150, and Ala-156-Ile-Phe-158, derived from the K88 fibrillar subunit and found to inhibit the binding of K88 fibrillae to cavia erythrocytes or pig intestinal epithelial cells (A. A. C. Jacobs, J. Venema, R. Leeven, H. van Pelt-Heerschap, and F. K. de Graaf, J. Bacteriol. 169:735-741, 1987). The gene encoding the K88 fibrillar adhesin was modified by oligonucleotide-directed site-specific mutagenesis such that each of the phenylalanine residues at positions 85, 150, and 158 were replaced by serine. Replacement of phenylalanine 85 or 158 had no apparent effect on the biosynthesis of the fibrillae or on their adhesive capacity. In contrast, substitution of phenylalanine 150 with serine resulted in a dramatic decrease in adhesive capacity of the K88 fibrillae. Apparently, phenylalanine 150 plays an essential role in the interaction of the adhesin with receptor molecules present on eucaryotic cells.     

Epitope analysis of the FanC subunit protein of the K99 (F5) fimbriae of enterotoxigenic Escherichia coli using a recombinant fusion technique

We have used a recombinant approach to characterise the B- and T-cell epitopes of FanC, the major subunit polypeptide of K99 (F5) fimbriae of enterotoxigenic Escherichia coli strains. This involved the fusion of FanC and its carboxy-terminal truncated derivatives to a reporter, the E. coli alkaline phosphatase (PhoA), generating stable, recombinant fusions. The B-cell epitopes of FanC were characterised by Western blotting of FanC::PhoA fusion proteins with a polyclonal mouse antiserum directed against K99 fimbrial antigen, and with a panel of monoclonal antibodies generated to the K99 antigen. An attempt to characterise the T-cell epitopes of the fimbrial subunit was made by standard in vitro T-cell proliferation assay. Our results suggest that the B-cell epitopes of FanC are likely to be continuous, with a potentially immunodominant epitope at the carboxy-terminus. However, T-cell proliferation assays with the FanC::PhoA fusion proteins did not indicate any immunodominant T-cell epitope(s). We hypothesise that fusion of FanC peptides to PhoA had resulted in altered folding of the peptides for antibody and T-cell recognition, highlighting the potential problems and drawbacks of the recombinant fusion technique in defining the epitopes of certain proteins.     

Localization of lysine residues in the binding domain of the K99 fibrillar subunit of enterotoxigenic Escherichia coli

Modification of lysine residues with 4-chloro-3,5-dinitrobenzoate results in the loss of the binding capacity of K99 fibrillae to horse erythrocytes (Jacobs, A.A.C., van Mechelen, J.R. and de Graaf, F.K. (1985) Biochim. Biophys. Acta 832, 148-155). In the present study we used dinitrobenzoate as a spectral probe to map the modified residues. After the incorporation of 0.7 mol CDNB per mol subunit, 90% of the binding activity disappeared and the lysine residues at positions 87, 132 and 133 incorporated 20%, 27.5% and 52.2% of the totally incorporated label, respectively. In the presence of the glycolipid receptor, Lys-132 and Lys-133 were partially protected against modification, while Lys-87 was not protected. The results suggest that Lys-132 and Lys-133 are part of the receptor-binding domain of the K99 fibrillar subunit and that the positive charges on these residues are important for the interaction of the fibrillae with the negatively charged sialic acid residue of the glycolipid receptor. A striking homology was found between a six-amino-acid residue segment of K99, containing Lys-132 and Lys-133, and segments of three other sialic-acid-specific lectins; cholera toxin B subunit, heat-labile toxin B subunit of Escherichia coli and CFA1 fimbrial subunit, suggesting that these segments might also be part of the receptor-binding domain in these three proteins.     

Detection and identification of FaeC as a minor component of K88 fibriilae of Escherichia coli

A tribrid gene containing ompF, faeC, and lacZ sequences was constructed by subcloning a large central segment of the K88ab gene encoding the fibrillar subunit-like protein FaeC into the open reading frame expression vector pORF2. The resulting tribrid protein was isolated and used to raise antibodies against the FaeC protein. These antibodies were then used for the detection and subcellular localization of the FaeC protein in Escherichia coli harbouring the K88ab-encoding plasmid pFM205 or mutant derivatives. Immunoblotting of subcellular fractions and of purified fibrillae, and agglutination experiments using whole cells revealed that the FaeC protein is present in the periplasm and as a minor component in the K88ab fibrillae. FaeC was also detected in purified K88ac and K88ad fibrillae. Immunoelectron microscopy confirmed the presence of FaeC in K88ab fibrillae, particularly at the tips of the longer fibrillae.     

Expression and immunogenicity of an <Emphasis Type="Italic">Escherichia coli</Emphasis> K99 fimbriae subunit antigen in soybean

Enterotoxigenic Escherichia coli (ETEC) cause acute diarrhea in humans and farm animals, and can be fatal if the host is left untreated. As a potential alternative to traditional needle vaccination of cattle, we investigated the feasibility of expressing the major K99 fimbrial subunit, FanC, in soybean (Glycine max) for use as an edible subunit vaccine. As a first step in this developmental process, a synthetic version of fanC was optimized for expression in the cytosol and transferred to soybean via Agrobacterium-mediated transformation. Western analysis of T₀ events revealed the presence of a peptide with the expected mobility for FanC in transgenic protein extracts, and immunofluorescense confirmed localization to the cytosol. Two T₀ lines, which accumulated FanC to levels near 0.5% of total soluble protein, were chosen for further molecular characterization in the T₁ and T₂ generations. Mice immunized intraperitoneally with protein extract derived from transgenic leaves expressing synthetic FanC developed significant antibody titers against bacterially derived FanC and produced antigen-specific CD4⁺ T lymphocytes, demonstrating the ability of transgenic FanC to function as an immunogen. These experiments are the first to demonstrate the expression and immunogenicity of a model subunit antigen in the soybean system, and mark the first steps toward the development of a K99 edible vaccine to protect against ETEC.     

Chloroplast targeting of FanC,the major antigenic subunit of <Emphasis Type="Italic">Escherichia coli</Emphasis> K99 fimbriae,in transgenic soybean

Enterotoxigenic Escherichia coli (ETEC) strains are a major cause of enteric diseases affecting livestock and humans. Edible transgenic plants producing E. coli fimbrial subunit proteins have the potential to vaccinate against these diseases, but have not reached their full potential as a renewable source of oral vaccines due in part to insufficient levels of recombinant protein accumulation. Previously, we reported that cytosol targeting of the E. coli K99 fimbrial subunit antigen resulted in FanC accumulation to ∼0.4% of total soluble protein in soybean leaves (Piller et al. in Planta 222:6–18, 2005). In this study, we report on the subcellular targeting of FanC to chloroplasts. Twenty-two transgenic T₁ progeny derived from seven individual T₀ transformation events were characterized, and 17 accumulated transgenic FanC. All of the characterized events displayed relatively low T-DNA complexity, and all exhibited proper targeting of FanC to the chloroplast. Accumulation of chloroplast-targeted FanC was ∼0.08% of total soluble leaf protein, or ∼5-fold less than cytosol-targeted FanC. Protein analysis of leaves at various stages of maturity suggested stability of chloroplast-targeted FanC throughout leaf maturation. Furthermore, mice immunized intraperitoneally with protein extract derived from transgenic leaves expressing chloroplast-targeted FanC developed significant antibody titers against FanC. This is the first report of subcellular targeting of a vaccine subunit antigen in soybean.     

Synthesis of a precursor to the B subunit of heat-labile enterotoxin in Escherichia coli.

Escherichia coli K-12 minicells were employed to investigate the biosynthesis of plasmid-encoded, heat-labile enterotoxin of E. coli. Two polypeptide species related to the B subunit of the toxin were expressed in the minicells. One of these polypeptides (molecular weight, 11,500) was immunoprecipitated by antiserum to cholera toxin. Because the B subunits of heat-labile enterotoxin and cholera toxin have common antigenic sites, we concluded that this species was the mature B subunit. The larger polypeptide (molecular weight, 13,000) is likely to be a precursor of the B subunit because it could be chased into the mature form. This conversion was inhibited by compounds which dissipate proton motive force, suggesting that processing requires energy.     

The N-terminal -barrel domain of the Escherichia coli K88 periplasmic chaperone FaeE determines fimbrial subunit recognition and dimerization

The K88 periplasmic chaperone FaeE is a homodimer, whereas the K99 chaperone FanE is a monomer. The structural requirements for dimerization of the K88 fimbrial periplasmic chaperone and for fimbrial subunit-binding specificity were investigated by analysis of mutant chaperones. FaeE contains a C-terminal extension of 19 amino acid residues when compared to FanE and most other fimbrial chaperones. A C-terminal truncate of the K88 chaperone FaeE was constructed that lacked 19 C-terminal amino acid residues. Expression and complementation experiments revealed that this C-terminal shortened chaperone was still functional in binding the K88 major subunit FaeG and K88 biosynthesis. Two hybrid chaperones were constructed. Each hybrid protein contained one -barrel domain of FaeE and the other -barrel domain of FanE (Fae/FanE or Fan/FaeE, respectively). Expression and complementation experiments revealed that the Fae/FanE but not the Fan/FaeE hybrid chaperone was functional in the formation of K88 fimbriae. The Fan/FaeE hybrid chaperone was active in the biosynthesis of K99 fimbriae. The truncated FaeE mutant chaperone and the hybrid Fae/FanE chaperone were able to form stable periplasmic protein complexes with the K88 major fimbrial subunit FaeG. Cross-linking experiments suggested that the C-terminal shortened chaperone and the Fae/FanE hybrid chaperone were homodimers, as is the wild-type K88 chaperone. Altogether, the data suggested that the N-terminal -barrel domain of a fimbrial chaperone determines subunit specificity. In the case of the K88 periplasmic chaperone, this N-terminal domain also determines dimerization of the protein.     

Characterization of two new point mutations in the low density lipoprotein receptor genes of an English patient with homozygous familial hypercholesterolemia.

Two new point mutations have been detected in the low density lipoprotein (LDL) receptor gene of a patient with a clinical diagnosis of homozygous familial hypercholesterolemia (FH). The patient is a compound heterozygote, in whom the mutant allele inherited from his English father has a single base substitution of A for G in exon 3, changing the codon for residue 80 in the mature protein from glutamic acid to lysine. The mutant allele inherited from his mother, who is of Irish origin, has a single base pair deletion in the codon for residue 743 in exon 15 that causes a frameshift and introduces a new stop codon in the adjacent position. The glu80 to lys mutation results in a transport-defective phenotype and a mature protein that migrates abnormally slowly on nonreduced SDS-PAGE, but normally under reducing conditions; this was confirmed by site-directed mutagenesis and expression in vitro. The deletion in exon 15 results in a null phenotype in which the putative truncated receptor protein cannot be detected in cultured skin fibroblasts and the amount of mRNA derived from the allele is reduced. The glu80 to lys mutation was found in a further five unrelated individuals in a sample of 200 FH patients from the London area and in 11 from a sample of 77 FH patients from Manchester. Haplotype analysis suggested that all the patients had inherited this allele from a common ancestor. The deletion in exon 15 was not found in the London sample, nor in any unrelated individuals in the Manchester sample.     

The localization of FGFR3 mutations causing thanatophoric dysplasia type I differentially affects phosphorylation, processing and ubiquitylation of the receptor

Recurrent missense fibroblast growth factor receptor 3 (FGFR3) mutations have been ascribed to skeletal dysplasias of variable severity including the lethal neonatal thanatophoric dysplasia types I (TDI) and II (TDII). To elucidate the role of activating mutations causing TDI on receptor trafficking and endocytosis, a series of four mutants located in different domains of the receptor were generated and transiently expressed. The putatively elongated X807R receptor was identified as three isoforms. The fully glycosylated mature isoform was constitutively but mildly phosphorylated. Similarly, mutations affecting the extracellular domain (R248C and Y373C) induced moderate constitutive receptor phosphorylation. By contrast, the K650M mutation affecting the tyrosine kinase 2 (TK2) domain produced heavy phosphorylation of the nonglycosylated and mannose-rich isoforms that impaired receptor trafficking through the Golgi network. This resulted in defective expression of the mature isoform at the cell surface. Normal processing was rescued by tyrosine kinase inhibitor treatment. Internalization of the R248C and Y373C mutant receptors, which form stable disulfide-bonded dimers at the cell surface was less efficient than the wild-type, whereas ubiquitylation was markedly increased but apparently independent of the E3 ubiquitin-ligase casitas B-lineage lymphoma (c-Cbl). Constitutive phosphorylation of c-Cbl by the K650M mutant appeared to be related to the intracellular retention of the receptor. Therefore, although mutation K650M affecting the TK2 domain induces defective targeting of the overphosphorylated receptor, a different mechanism characterized by receptor retention at the plasma membrane, excessive ubiquitylation and reduced degradation results from mutations that affect the extracellular domain and the stop codon.     

Necessity of conserved asparagine residues in the leucine-rich repeats of platelet glycoprotein Ib alpha for the proper conformation and function of the ligand-binding region

The polypeptides of the platelet von Willebrand factor (vWf) receptor, the GP Ib-IX-V complex, each contain tandem repeats of a sequence that assigns them to the leucine-rich repeat protein family. Here, we studied the role of conserved Asn residues in the leucine-rich repeats of GP Ib alpha, the ligand-binding subunit of the complex. We replaced the Asn residue in the sixth position of the first or sixth leucine-rich repeat (of seven) either with a bulky, charged Lys residue or with a Ser residue (sometimes found in the same position of other leucine-rich repeats) and studied the effect of the mutations on complex expression, modulator-dependent vWf binding, and interactions with immobilized vWf under fluid shear stress. As predicted, the Lys substitutions yielded more severe phenotypes, producing proteins that either were rapidly degraded within the cell (mutant N158K) or failed to bind vWf in the presence of ristocetin or roll on immobilized vWf under fluid shear stress (mutant N41K). The binding of function-blocking GP Ib alpha antibodies to the N41K mutant was either significantly reduced (AK2 and SZ2) or abolished (AN51 and CLB-MB45). Ser mutations were tolerated much better, although both mutants demonstrated subtle defects in vWf binding. These results suggest a vital role for the conserved asparagine residues in the leucine-rich repeats of GP Ib alpha for the structure and functions of this polypeptide. The finding that mutations in the first leucine-rich repeat had a much more profound effect on vWf binding indicates that the more N-terminal repeats may be directly involved in this interaction.     

Temperature-sensitive lethal mutant of era, a G protein in Escherichia coli.

The era gene of Escherichia coli encodes a GTP-binding protein which has similarities to elongation factor Tu and the Saccharomyces cerevisiae RAS protein. To investigate its function, mutations affecting era were isolated. A mini-Tn10 insertion, which truncated 22 amino acids from the COOH end of Era, did not affect cell growth. By using this mini-Tn10 insert as a coselectable marker, a temperature-sensitive lethal era mutant was isolated by localized mutagenesis using P1 phage transduction. A single-base G to A change was found at position 23, causing a tyrosine residue to be substituted for the cysteine residue at position 8 (era-770), in addition to the COOH-terminal mini-Tn10 disruption. Both alterations were necessary for the temperature-sensitive phenotype. Purified Era-770 mutant protein exhibited reduced binding to GTP compared with that of the wild-type Era protein.     

A missense mutation in the oxi-3 gene of the [mi-3] extranuclear mutant of Neurospora crassa

We have determined the DNA sequence of the oxi-3 gene and its 5' flanking region in the extranuclear [mi-3] mutant of Neurospora crassa. The oxi-3 gene encodes subunit 1 of cytochrome c oxidase, a protein known to be altered in the [mi-3] mutant (Bertrand, H., and Werner, S. (1979) Eur. J. Biochem. 98, 9-18). When the sequence from [mi-3] was compared to previously published sequences of the same region of mtDNA from wild-type N. crassa, a total of five differences was found. Four of these differences can be accounted for as either genetic polymorphisms or previous errors in DNA sequence determination. The remaining difference is a G/C to T/A transversion that changes a codon specifying an aspartic acid residue (GAC) to one that would specify tyrosine (TAC) at amino acid 448 of the 555 amino acid mature subunit 1 protein. This alteration was also found in the mtDNA of two separate heterokaryotic strains that had acquired the [mi-3] phenotype after repeated subculturing of heterokaryons forced between an [mi-3] strain and a strain containing a wild-type cytoplasm. The particular aspartic acid residue that would be affected by the mutation observed in [mi-3] is conserved in a diversity of species as either aspartic acid or glutamic acid, suggesting that an acidic residue at this position is important for the correct function of the subunit 1 protein. For these reasons, we consider it likely that the observed missense mutation is responsible for the [mi-3] phenotype.