The PapG adhesin of uropathogenic Escherichia coli contains separate regions for receptor binding and for the incorporation into the pilus

Escherichia coli periplasmic chaperone FaeE is a homodimer and the chaperone-K88 subunit complex is a heterotrimer

The interaction of FaeE, a periplasmic chaperone involved in K88 biosynthesis, and the major fimbrial subunit FaeG was investigated. The genes encoding the two proteins were subcloned together in the expression vector pINIIIA1. Cells expressing the subcloned genes accumulated in their periplasm a complex of FaeE and FaeG. This complex was purified by isoelectric focusing and anion-exchange fast-protein liquid chromatography. SDS-PAGE, native gel electrophoresis, immunoblotting and determination of the N-terminal amino acid sequences and the molar ratio of the N-terminal amino acid residues revealed that the complex is a heterotrimer consisting of two molecules of FaeE and one molecule of FaeG. The periplasmic chaperone FaeE was purified from the periplasm of cells expressing only the subcloned faeE gene. Gel filtration, protein cross-linking analysis and a biophysical approach in which the rotation diffusion coefficient of the purified FaeE was determined led to the conclusion that the native FaeE chaperone is a homodimer.

FimC is a periplasmic PapD-like chaperone that directs assembly of type 1 pili in bacteria

Biogenesis of the type 1 pilus fiber in Escherichia coli requires the product of the fimC locus. We have demonstrated that FimC is a member of the periplasmic chaperone family. The deduced primary sequence of FimC shows a high degree of homology to PapD and fits well with the derived consensus sequence for periplasmic chaperones, predicting that it has an immunoglobulin-like topology. The chaperone activity of FimC was demonstrated by purifying a complex that FimC forms with the FimH adhesion. A fimC1 null allele could be complemented by the prototype member of the chaperone superfamily, PapD, resulting in the production of adhesive type 1 pili. The general mechanism of action of members of the chaperone superfamily was demonstrated by showing that the ability of PapD to assemble both P and type 1 pili was dependent on an invariant arginine residue (Arg-8), which forms part of a conserved subunit binding site in the cleft of PapD. We suggest that the conserved cleft is a subunit binding feature of all members of this protein family. These studies point out the general strategies used by Gram-negative bacteria to assemble adhesins into pilus fibers, allowing them to promote attachment to eukaryotic receptors.

Characterization of recombinant and native forms of a cell surface antigen of Porphyromonas (Bacteroides) gingivalis

The cloning of genes encoding putative cell surface antigens of Porphyromonas gingivalis ATCC 33277 has been reported previously (B. C. McBride, A. Joe, and U. Singh, Arch. Oral Biol. 55:59S-68S, 1990). This study characterizes the recombinant protein rPgAg1, which is highly expressed in clone BA3, and the corresponding 51-kDa native antigen PgAg1. Cellular localization studies with monospecific antibodies to rPgAg1 in a Western immunoblot assay of a P. gingivalis membrane fraction and immunogold labeling of intact P. gingivalis cells confirmed the cell surface location of the native PgAg1 molecule. The pgag1 gene was found to be present in all four strains of P. gingivalis examined, and the gene product was expressed. Highly homologous DNA sequences and immunologically related proteins, however, were not detected in related species in the group formerly known as black-pigmented Bacteroides. This suggests that PgAg1 is specific to P. gingivalis and is highly conserved within this species. A protein data base search with the NH2-terminal amino acid sequence of rPgAg1 did not identify any significantly similar protein sequences. The high level of expression of rPgAg1 was not dependent on the insertional orientation of the cloned fragment. It therefore appears that a P. gingivalis promoter is present which is well recognized by the transcriptional apparatus of the Escherichia coli cloning host. The promoter element and structural gene for a specific cell surface antigen of P. gingivalis have been cloned.

Outer-membrane PapC molecular usher discriminately recognizes periplasmic chaperone-pilus subunit complexes

P pili are highly ordered composite structures consisting of thin fibrillar tips joined end-to-end to rigid helical rods. The production of these virulence-associated structures requires a periplasmic chaperone (PapD) and an outer membrane protein (PapC) that is the prototype member of a newly recognized class of proteins that we have named "molecular ushers." Two in vitro assays showed that the preassembly complexes that PapD forms with the three most distal tip fibrillar proteins (PapG, PapF, and PapE) bound to PapC. The relative affinity of each complex for PapC was found to correlate with the final position of the subunit type in the tip fibrillum. In contrast, the complexes PapD forms with the major component of the pilus rod, PapA, or the pilus rod initiating protein, PapK, did not recognize PapC. The in vitro data argue that differential targeting of chaperone-subunit complexes to PapC may be part of a mechanism to ensure the correctly ordered assembly of adhesive composite pili.

Yersinia pestis pH 6 antigen forms fimbriae and is induced by intracellular association with macrophages

Ability to express pH 6 antigen (Ag) is necessary for full virulence of Yersinia pestis; however, the function of the Ag in pathogenesis remains unclear. We determined the nucleotide sequence of a 4232 bp region of Y. pestis DNA which encoded the pH 6 Ag structural gene (psaA) and accessory loci necessary for Ag synthesis. Protein sequences encoded by the Y. pestis DNA were similar to accessory proteins which function in the biosynthesis of Escherichia coli fimbriae Pap, K88, K99 and CS3 as well as the molecular chaperone for the Y. pestis capsule protein. Electron microscopy and immunogold labelling studies revealed that pH 6 Ag expressing E. coli or Yersinia produced flexible 'fibrillar' organelles composed of individual linear strands, multiple strand bundles or wiry aggregates of PsaA. Y. pestis associated with the murine macrophage-like cell line, RAW264.7, expressed pH 6 Ag in an intracellular acidification-dependent manner. Together with an earlier study showing that a Y. pestis psaA mutant was reduced in virulence, these results demonstrate that the expression of fimbriae which are induced in host macrophages is involved in plague pathogenesis.

The complete general secretory pathway in gram-negative bacteria

The unifying feature of all proteins that are transported out of the cytoplasm of gram-negative bacteria by the general secretory pathway (GSP) is the presence of a long stretch of predominantly hydrophobic amino acids, the signal sequence. The interaction between signal sequence-bearing proteins and the cytoplasmic membrane may be a spontaneous event driven by the electrochemical energy potential across the cytoplasmic membrane, leading to membrane integration. The translocation of large, hydrophilic polypeptide segments to the periplasmic side of this membrane almost always requires at least six different proteins encoded by the sec genes and is dependent on both ATP hydrolysis and the electrochemical energy potential. Signal peptidases process precursors with a single, amino-terminal signal sequence, allowing them to be released into the periplasm, where they may remain or whence they may be inserted into the outer membrane. Selected proteins may also be transported across this membrane for assembly into cell surface appendages or for release into the extracellular medium. Many bacteria secrete a variety of structurally different proteins by a common pathway, referred to here as the main terminal branch of the GSP. This recently discovered branch pathway comprises at least 14 gene products. Other, simpler terminal branches of the GSP are also used by gram-negative bacteria to secrete a more limited range of extracellular proteins.

Cloning and characterization of the bundle-forming pilin gene of enteropathogenic Escherichia coli and its distribution in Salmonella serotypes

bfp, the structural gene of the major repeating bundle-forming pilus (BFP) subunit, was cloned from the enteroadherent factor (EAF) plasmid of enteropathogenic Escherichia coli (EPEC) strain B171 (O111:NM). The bfp open reading frame encoded a 193-amino-acid protein; comparison of this sequence with the biochemically determined N-terminal amino acid sequence showed that the mature pilin protein is comprised of 180 amino acids, that this sequence is similar to other members of the type IV pilin family, and that it is preceded by a 13-amino-acid signal peptide. Expression of the cloned bfp structural gene in an EPEC strain that had been cured of the EAF plasmid yielded a 21,000 dalton protein that co-migrated with the BFP precursor protein. Thus, other genes, probably carried by the EAF plasmid, are required for the maturation of the bfp product and for the production of extracellular pilus filaments. Use of bfp as a hybridization probe showed that homologous sequences are present in all tested EPEC strains and in 13 of 16 tested Salmonella serotypes. Fifty per cent of these bfp probe-sensitive salmonellae exhibited the localized-adherence (LA) phenotype when incubated with tissue culture cell monolayers, a trait previously associated with EAF plasmid-containing EPEC strains. Scanning electron micrographs of a bfp probe-sensitive, LA-positive Salmonella dublin strain showed that it grows as adherent colonies on infected monolayers and that within these colonies, BFP-like fibres form inter-bacterial linkages. For EAF plasmid-containing EPEC strains and for several Salmonella serotypes, BFP expression may lead to the development of adherent colonies on epithelial surfaces early in the infective process.

PapD and superfamily of periplasmic immunoglobulin-like pilus chaperones

The formation of a P pilus requires a molecular chaperone in the periplasm and a molecular usher in the outer membrane. Each pilus is composed of six different types of proteins that are assembled into a composite fiber in a defined order. The correct folding of subunits into domains that can serve as assembly modules requires an association with the periplasmic chaperone. PapD is the prototype member of the family of bacterial pilus chaperones that have a three-dimensional structure consistent with an immunoglobulin fold. In general, proteins with an immunoglobulin fold structure have molecular recognition functions in eukaryotic cells that are often integrated with effector functions. PapD has also a recognition function, binding nascently translocated pilus subunits and maintaining them in assembly-competent conformations. The association of the chaperone with the subunit triggers the targeting of the latter to an outer membrane usher. The usher serves as a molecular gatekeeper, allowing the ordered incorporation of the pilus subunits into the pilus structure from the periplasmic chaperone complexes. The two immunoglobulin-like domains of PapD are oriented to form a cleft that contains the subunit binding site. This is a different binding paradigm from that used by either antibodies or the growth hormone receptor. The blend of genetics, biochemistry, X-ray crystallography, and carbohydrate chemistry in the study of pili biogenesis will continue to give insight into some of the most basic intellectual challenges in molecular biology concerning how proteins fold into domains that serve as modules for the formation of larger assemblies, and relating these processes to microbial pathogenesis.

The molecular study of bacterial virulence: a review of current approaches, illustrated by the study of adhesion in uropathogenic Escherichia coli

Pathogenic bacteria coexist with their hosts in a relationship which most frequently allows persistence of the bacteria without causing disease. In a small proportion of colonised individuals the complex mutual interaction between microbe and host is upset, leading to disease in the host. The investigation of bacterial virulence determinants and their genetic control at the molecular level is an important facet of the development of strategies to combat disease. This review focuses on the investigation of a single pathogenic organism as a means of illustrating modern approaches to the investigation of bacterial virulence. The importance of uropathogenic Escherichia coli in causing acute and recurrent pyelonephritis with the consequent morbidity of chronic renal failure is well established. Pyelonephritis-associated (Pap) pili are likely to be critical virulence factors in uropathogenic E. coli. The evidence for their role in pathogenicity and the control of their expression at the molecular genetic level is discussed.

Horizontal gene transfer of the Escherichia coli pap and prs pili operons as a mechanism for the development of tissue-specific adhesive properties

Escherichia coli strains bind to Gal alpha 1-4Gal-containing glycolipids via P pili-associated G-adhesins. Three functional classes of adhesins with different binding specificities are encoded by conserved G-alleles. We suggest that the Class I papG-allele of strain J96 is a novel acquisition possibly introduced via horizontal gene transfer into one of the two P pili gene clusters carried by this strain. Closely related strains in the ECOR collection of natural E. coli isolates carry either a Class II or a Class III G-adhesin. Data indicate that genetic exchanges involving either entire pap or prs gene clusters or individual pap/prs genes have occurred. We propose that the retention and spread of pap/prs DNA among E. coli is the result of selection pressure exerted by mammalian intestinal isoreceptors.

Neisseria gonorrhoeae PilC expression provides a selective mechanism for structural diversity of pili

Pili of Neisseria gonorrhoeae undergo both phase and structural variation. Phase variation of gonococcal pili can be caused by a RecA-independent on/off switch in PilC, a protein involved in pilus biogenesis. We show here that spontaneous nonpiliated PilC- derivatives as well as PilC- insertional mutants have also acquired sequence alterations in pilE relative to the pilE gene of the piliated MS11mk(P+)-u parent, so that the pilin produced is processed to soluble S-pilin and can be released into the medium. It is proposed that pilin alterations are selected for in PilC- bacteria if the parental nonassembled pilin is toxic to the cells--i.e., is not degradable to S-pilin at rates sufficient to allow viability of the cells. Toxicity is indicated by the extreme instability of certain unassembled pilin sequences and by the low frequency of nonpiliated, pilin+, PilC- variants that emerge from piliated recA- cells. The presence of a point mutation changing leucine-39 to phenylalanine at the cleavage site for S-pilin in one nonpiliated, PilC-, recA- variant relative to its piliated parent is a further argument for a selective mechanism of structural diversity of the gonococcal pilin.

P pili in uropathogenic E. coli are composite fibres with distinct fibrillar adhesive tips

Escherichia coli is a frequent cause of several common bacterial infections in humans and animals, including urinary tract infections, bacteraemia and bacteria-related diarrhoea and is also the main cause of neonatal meningitis. Microbial attachment to surfaces is a key event in colonization and infection and results mainly from a stereochemical fit between microbial adhesins and complementary receptors on host cells. Bacterial adhesins required for extracellular colonization by Gram-negative bacteria are often minor components of heteropolymeric fibres called pili which must be oriented in an accessible manner in these structures to be able to bind to specific receptor architectures. P pili mediate the binding of uropathogenic E. coli to a digalactoside receptor determinant present in the urinary tract epithelium. We report here that the adhesin is a component of distinct fibrillar structures present at the tips of the pili. These virulence-associated tip fibrillae are thin, flexible polymers composed mostly of repeating subunits of PapE that frequently terminate with the alpha-D-galactopyranosyl-(1-4)-beta-D-galactopyranose or Gal alpha (1-4)Gal binding PapG adhesin.

Analysis of a Caulobacter crescentus gene cluster involved in attachment of the holdfast to the cell

Caulobacter crescentus firmly adheres to surfaces with a structure known as the holdfast, which is located at the flagellar pole of swarmer cells and at the stalk tip in stalked cells. A three-gene cluster (hfaAB and hfaC) is involved in attachment of the holdfast to the cell. Deletion and complementation analysis of the hfaAB locus revealed two genes in a single operon; both were required for holdfast attachment to the cell. Sequence analysis of the hfaAB locus showed two open reading frames with the potential to encode proteins of 15,000 and 26,000 Da, respectively. A protein migrating with an apparent size of 21 kDa in gel electrophoresis was encoded by the hfaA region when expressed in Escherichia coli under the control of the lac promoter, but no protein synthesis could be detected from the hfaB region. S1 nuclease analysis indicated that transcription of the hfaAB locus was initiated from a region containing a sequence nearly identical to the consensus for C. crescentus sigma 54-dependent promoters. In addition, a sequence with some similarity to ftr sequences (a consensus sequence associated with other Caulobacter sigma 54-dependent genes) was identified upstream of the hypothesized sigma 54 promoter. At least one of the hfaAB gene products was required for maximal transcription of hfaC. The sequence of hfaB showed some similarity to that of transcriptional activators of other bacteria. The C-terminal region of the putative gene product HfaA was found to be homologous to PapG and SmfG, which are adhesin molecules of enteropathogenic E. coli and Serratia marcescens, respectively. This information suggests that the protein encoded by the hfaA locus may have a direct role in the attachment of the holdfast to the cell, whereas hfaB may be involved in the positive regulation of hfaC.

Immunoglobulin-like PapD chaperone caps and uncaps interactive surfaces of nascently translocated pilus subunits

Molecular chaperones are found in the cytoplasm of bacteria and in various cellular compartments in eukaryotes to maintain proteins in nonnative conformations that permit their secretion across membranes or assembly into oligomeric structures. Virtually nothing, however, has been reported about a similar requirement for molecular chaperones in the periplasm of Gram-negative bacteria. We used the well-characterized P pilus biogenesis system in Escherichia coli as a model to elucidate the mechanism of action of a periplasmic chaperone, PapD, which is specifically required for P pilus biogenesis. PapD probably associates with at least six P pilus subunits after their secretion across the cytoplasmic membrane, but PapD is not incorporated into the pilus. We used purified periplasmic complex that PapD forms with the PapG adhesin to investigate the function of interactions between the chaperone and its targets. We demonstrated that PapD binds to PapG to form a stable, discrete bimolecular complex and that, unlike cytoplasmic chaperones, the periplasmic PapD chaperone maintained PapG in a native-like conformation. Bound PapD in the complex was displaced by free PapD in vitro; however, the in vivo release of subunits to the nascent pilus is probably driven by an ATP-independent mechanism involving the outer membrane protein PapC. In addition, the binding of PapD to PapG in vitro prevented aggregation of PapG. We propose that the function of PapD and other periplasmic pilus chaperones is to partition newly translocated pilus subunits into assembly-competent complexes and thereby prevent nonproductive aggregation of the subunits in the periplasm. These data provide important information for understanding the mechanism of action of this general class of chaperones that function in the periplasmic space.

DNA sequences of three papA genes from uropathogenic Escherichia coli strains: evidence of structural and serological conservation

Pyelonephritis-associated pili (Pap) are important in the pathogenesis of ascending, unobstructive Escherichia coli-caused renal infections because these surface bacterial organelles mediate digalactoside-specific binding to host uroepithelial cells. Pap are composed of many different polypeptides, of which only the tip proteins mediate specific binding. The PapA moiety polymerizes to form the bulk of the pilus structure and has been employed in vaccines despite its lack of Gal alpha(1-4)Gal receptor specificity. Animal recipients of PapA pilus-based vaccines are protected against experimental pyelonephritis caused by homologous and heterologous Gal-Gal-binding uropathogenic E. coli strains. Specific PapA immunoglobulin G antibodies in urine are correlated with protection in these infection models. The nucleotide sequences of the gene encoding PapA were determined for three E. coli clones expressing F7(1), F7(2), and F9 pili and were compared with corresponding sequences for other F serotypes. Specific rabbit antisera were employed in enzyme-linked immunosorbent assays to study the cross-reactivity between Gal-Gal pili purified from recombinant strains expressing F7(1), F7(2), F9, or F13 pili and among 60 Gal-Gal-binding wild-type strains. We present data which corroborate the concept that papA genes are highly homologous and encode proteins which exhibit greater than 70% homology among pili of different serotypes. The differences primarily occur in the cysteine-cysteine loop and variable regions and constitute the basis for serological diversity of these pili. Although there are differences in primary structures among these pili, antisera raised against pili of one serotype cross-reacted frequently with many other Gal-Gal pili of different serotypes. Furthermore, antisera raised against pili of the F13 serotype cross-reacted strongly or moderately with 52 (86%) of 60 wild-type Gal-Gal-binding E. coli strains. These data suggest that there are common immunogenic domains among these proteins. These additional data further support the hypothesis that broadly cross-protective PapA pilus vaccines for the immunoprophylaxis of pyelonephritis might be developed.

Expression of the envelope antigen F1 of Yersinia pestis is mediated by the product of caf1M gene having homology with the chaperone protein PapD of Escherichia coli

The effective synthesis of the envelope antigen F1 of Y. pestis in E. coli HB101 is mediated by the expression of the caf1M gene. This gene was sequenced, and the protein encoded was found to have a significant homology with the chaperone protein PapD of uropathogenic E. coli. The data presented allow one to suppose Caf1M and PapD proteins perform similar functions in the biogenesis of the Y. pestis capsule and E. coli P-pili, respectively.

Frequency and organization of papA homologous DNA sequences among uropathogenic digalactoside-binding Escherichia coli strains

The frequency of selected papA DNA sequences among 89 digalactoside-binding, uropathogenic Escherichia coli strains was evaluated with 12 different synthetic 15-base probes corresponding to papA genes from four digalactoside-binding piliated recombinant strains (HU849, 201B, and 200A). The papA probes encode amino acids which are common at the carboxy terminus of all strains, adjacent to the proximal portion of the intramolecular disulfide loop of strain 210B, or predicted to constitute the type-specific epitope for each of the four recombinant strains or other epitopes of strain HU849. The presence among the strains of DNA sequence homology to the papA probes was determined by in situ colony hybridization. Hybridization data suggest that there is a high frequency of homologous papA DNA sequences corresponding to selected regions of the papA gene from strain HU849 among the clinical strains. The following nucleotide locations which encode portions of the mature HU849 PapA are detected in a high percentage (42 to 70%) of clinical isolates: 208 to 222, 310 to 324, 478 to 492, 517 to 531, 553 to 567, and 679 to 693. These sequences encode portions of the predicted protective, immunogenic, and/or antigenic epitopes of this PapA. The data also indicate considerable heterogeneity of papA sequences among the strains, especially in the region of nucleotide bases corresponding to positions 391 to 418. These oligonucleotides encode the predicted PapA type-specific immunogenic dominant epitope. Determination of the extent of genetic variability in the papA gene among digalactoside-binding strains will require more extensive DNA sequencing of prototypic papA genes, additional hybridization studies employing other papA gene oligonucleotide probes, and assessment of the different pap operons and their copy number in each strain.

Identification and nucleotide sequence of the gene determining the adhesion capacity of Serratia marcescens

Three open reading frames, designated smfE, smfF, and smfG, within the mannose-resistant fimbria gene cluster of Serratia marcescens were identified. smfG, which is responsible for determining the receptor binding of S. marcescens, encodes a 280-amino-acid polypeptide with a typical prokaryotic signal sequence.

Structure and function of periplasmic chaperone-like proteins involved in the biosynthesis of K88 and K99 fimbriae in enterotoxigenic Escherichia coli

The nucleotide sequence of faeE and fanE, two genes involved in the biosynthesis of K88 and K99 fimbriae, respectively, was determined and the amino acid sequence of the FaeE and FanE proteins was deduced. Immunoblotting of subcellular fractions with an antiserum raised against purified FaeE confirmed that FaeE is located in the periplasm. Indications were obtained that FaeE functions as a chaperone-like protein. Its interaction with the fimbrial subunit (FaeG) in the periplasm stabilized this polypeptide and prevents its degradation by the cell-envelope protease DegP. Furthermore, FaeE prevents the formation of FaeG multimers which cannot be incorporated into fimbriae. The reactions of the FaeE/FaeG dimers with a set of monoclonal antibodies directed against the various epitopes present on K88 fimbriae revealed that the fimbrial subunits associated with FaeE were present in a conformation resembling their native configuration. Indications about the domains in FaeG involved in the interaction with FaeE are discussed.

Phase variation of gonococcal pili by frameshift mutation in pilC, a novel gene for pilus assembly

Pili prepared from Neisseria gonorrhoeae contain minor amounts of a 110 kd outer membrane protein denoted PilC. The corresponding gene exists in two copies, pilC1 and pilC2, in most strains of N.gonorrhoeae. In the piliated strain MS11(P+), only one of the genes, pilC2, was expressed. Inactivation of pilC2 by a mTnCm insertion resulted in a nonpiliated phenotype, while a mTnCm insertion in pilC1 had no effect on piliation. Expression of pilC was found to be controlled at the translational level by frameshift mutations in a run of G residues positioned in the region encoding the signal peptide. Nonpilated (P-), pilin expressing colony variants that did not express detectable levels of PilC were selected; all P+ backswitchers from these P-, PilC- clones were found to be PilC+. The structural gene for pilin, pilE, was sequenced and found to be identical in one P-, PilC- and P+, PilC+ pair. Most PilC- cells were completely bald whereas the PilC+ backswitcher had 10-40 pili per cell. Thus, a turn ON and turn OFF in the expression of PilC results in gonococcal pili phase variation. These results suggest that PilC is required for pilus assembly and/or translocation across the gonococcal outer membrane.

Etiology and pathophysiology of pyelonephritis

Escherichia coli is the most frequent cause of pyelonephritis. Its possible virulence factors include the ability to adhere and colonize the urinary tract, an important initiating factor in all urinary tract infections (UTIs). The importance of P fimbriae in this adhesion is stressed and the evidence for its importance in pyelonephritis is presented in epidemiologic studies of patients, as well as in animal studies. It appears that both host receptor density and the nonsecretor state is responsible for susceptibility to urinary tract infection. Vesicoureteral reflux can be responsible for ascending upper tract infection, but infection with P-fimbriated E coli may lead to ascending pyelonephritis without reflux because of the paralytic effect of lipid A on ureteral peristaltic activity. Renal ischemia leads to renal damage following infection by reperfusion damage due to the release of superoxide. Experimentally, this ischemic damage can be prevented by allopurinol, a xanthine oxidase inhibitor. The acute inflammatory response can produce renal damage because of the respiratory burst of phagocytosis, which while killing phagocytosed bacteria also damages renal tubules. An amelioration of the inflammatory response by treatment with superoxide dismutase or corticosteroids has been shown to modulate renal damage. Vaccination with P fimbriae has been shown experimentally to prevent the initiation of the disease. However, since vaccines are not clinically available, the clinical and animal studies on therapy of acute disease are stressed. Acute pyelonephritis during the first 3 years of life more often produced the renal damage that could lead to end-stage renal disease.(ABSTRACT TRUNCATED AT 250 WORDS)

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

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.

Mannose-sensitive haemagglutination in the absence of piliation in Escherichia coli

The relationship between type 1 pilus structure and the mannose-sensitive adhesin was investigated by analysing the properties of an 11.2 kb fragment of DNA derived from the chromosomal pil region of a type 1 piliated uropathogenic strain of Escherichia coli. The recombinant plasmids pHA9 and pSJH9, containing the cloned fragment, conferred a mannose-sensitive haemagglutination (MSHA)-positive but non-piliated phenotype on recipient cells of ORN104. Most of the DNA sequences homologous to the pilA and hyp genes were not present in the 11.2 kb insert, and the genetic information necessary for MSHA in the absence of piliation spanned a 6.5 kb region of the cloned fragment. The polypeptides expressed by pSJH9 were examined in minicells and Tn1000 insertions in three genes encoding proteins of molecular weights 90 kD, 29 kD and 17 kD abolished the MSHA phenotype.

Functional analysis of the sialic acid-binding adhesin SfaS of pathogenic Escherichia coli by site-specific mutagenesis

The gene coding for the sialic acid-specific adhesin SfaS produced by the S fimbrial adhesin (sfa) determinant of Escherichia coli has been modified by oligonucleotide-directed, site-specific mutagenesis. Lysine 116, arginine 118, and lysine 122 were replaced by threonine, serine, and threonine, respectively. The mutagenized gene clusters were able to produce S fimbrial adhesin complexes consisting of the S-specific subunit proteins including the adhesin SfaS. The mutant clones were further characterized by hemagglutination and by enzyme-linked immunoassay tests with antifimbria- and anti-adhesin-specific monoclonal antibodies, one of which is able to block S-specific binding (Moch et al., Proc. Natl. Acad. Sci. USA 84:3462-3466, 1987). The lysine-122 mutant clone was indistinguishable from the wild-type clone in these assays. Replacement of lysine 116 and arginine 118, however, abolished hemagglutination and resulted in clones which showed a weak (lysine 116) or a negative (arginine 118) reaction with the antiadhesin-specific antibody A1. We therefore suggest that lysine 116 and arginine 118 have an influence on binding of SfaS to the sialic acid residue of the receptor molecule. Substitution of arginine 118 by serine also had a negative effect on the amount of SfaS adhesin proteins isolated from the S fimbrial adhesin complex.

Integrity of Escherichia coli P pili during biogenesis: properties and role of PapJ

The papJ gene of uropathogenic Escherichia coli is required to maintain the integrity of Gal alpha (1-4)Gal-binding P pili. Electron microscopy and ELISA have established that strains carrying the papJ1 mutant allele have a large amount of pilus antigen free of the cells. In contrast to the whole pili released by strains unable to produce the PapH pilus anchor, the free papJ1 pili consist of variably sized segments that appear to result from internal breakages to the pilus. The DNA sequence of papJ is presented and its gene product identified as an 18kD periplasmic protein that possesses homology with nucleotide-binding proteins. PapJ may function as a 'molecular chaperone' directly or indirectly establishing the correct assembly of PapA subunits in the P pilus.

Cloning of the genes for AF/R1 pili from rabbit enteroadherent Escherichia coli RDEC-1 and DNA sequence of the major structural subunit

AF/R1 pili on the surface of Escherichia coli RDEC-1 promote attachment of the bacteria to rabbit intestinal brush borders. In order to characterize AF/R1 pili and manipulate their expression, we cloned the genes necessary for AF/R1 expression; determined the size of proteins produced in minicells; located the gene encoding the major structural subunit, named AfrA; and determined the DNA sequence of afrA as well as the sequence of 700 additional nucleotides upstream of afrA. Two contiguous EcoRI fragments spanning 7.9 kilobases were cloned from the 86-megadalton plasmid of RDEC-1 into vector pUC19 to make plasmid pW1. Bacteria carrying pW1 produced AF/R1 pili that were recognized by AF/R1-specific antiserum and promoted adherence of bacteria to brush borders prepared from rabbit intestine. Proteins with a molecular weight of 17,000 (17K proteins), which was the size of AfrA, as well as 15K, 15.5K, 26K, 28K, and 80K proteins were detected in minicells carrying pW1. The gene afrA was located by using an oligonucleotide probe, and its DNA sequence was determined. The DNA sequence of 700 additional nucleotides upstream was determined because this sequence may be important in the regulation of AF/R1 expression.

Crystal structure of chaperone protein PapD reveals an immunoglobulin fold

The chaperone protein PapD mediates assembly of pili in Escherichia coli. Its polypeptide chain folds into two immunoglobulin-type domains that are homologous in sequence to the human lymphocyte differentiation antigen Leu-1/CD5.

PapD, a periplasmic transport protein in P-pilus biogenesis

The product of the papD gene of uropathogenic Escherichia coli is required for the biogenesis of digalactoside-binding P pili. Mutations within papD result in complete degradation of the major pilus subunit, PapA, and of the pilinlike proteins PapE and PapF and also cause partial breakdown of the PapG adhesin. The papD gene was sequenced, and the gene product was purified from the periplasm. The deduced amino acid sequence and the N-terminal sequence obtained from the purified protein revealed that PapD is a basic and hydrophilic peripheral protein. A periplasmic complex between PapD and PapE was purified from cells that overproduced and accumulated these proteins in the periplasm. Antibodies raised against this complex reacted with purified wild-type P pili but not with pili purified from a papE mutant. In contrast, anti-PapD serum did not react with purified pili or with the culture fluid of piliated cells. However, this serum was able to specifically precipitate the PapE protein from periplasmic extracts, confirming that PapD and PapE were associated as a complex. It is suggested that PapD functions in P-pilus biogenesis as a periplasmic transport protein. Probably PapD forms complexes with pilus subunits at the outer surface of the inner membrane and transports them in a stable configuration across the periplasmic space before delivering them to the site(s) of pilus polymerization.