Sequence of pilin from Bacteroides nodosus 351 (Serogroup H) and implications for serogroup classification

The nucleotide sequence of the pilin gene from Bacteroides nodosus strain 351, currently classified as serogroup H, subgroup 2 (H2) has been determined. The gene encodes a single polypeptide (prepilin) of 160 amino acids and Mr 17,150. However, pilin isolated from B. nodosus 351 migrates as two distinct bands in sodium dodecyl sulphate-polyacrylamide gel electrophoresis, due to an internal peptide bond cleavage. Amino acid sequence studies of pilin from B. nodosus 351 have established that the cleavage occurs between 72Ala and 73Ser of the mature protein sequence. Comparisons of gene and amino acid sequences of pilin from B. nodosus 351 with the corresponding sequences from strains of serogroups D and H1 indicate that these sequences share a close relationship. However, the level of sequence identity between B. nodosus 351 pilin and pilin from strain 265 of serogroup H1 is lower than anticipated for strains within a serogroup and suggests that B. nodosus 265 and B. nodosus 351 should not be classified within the same serogroup.     

Nucleotide sequence of the pilin gene of Bacteroides nodosus 340 (serogroup D) and implications for the relatedness of serogroups

The gene encoding pilin of Bacteroides nodosus 340 has been isolated and the nucleotide sequence determined. The gene is present as a single copy within the B. nodosus genome and a protein of Mr 16683 can be predicted from the proposed coding region. A comparison of the predicted amino acid sequence with pilin from other strains of B. nodosus indicated that the protein of strain 340 (serogroup D) has a high degree of similarity with pilin of strain 265 (serogroup H). The degree of similarity between pilins from these strains and from other B. nodosus serogroups is no greater than that between B. nodosus pilins and the homologous proteins of several different bacterial species. These findings suggest that serogroups D and H may form a subset of B. nodosus serogroups.     

Cleavage, methylation, and localization of the Pseudomonas aeruginosa export proteins XcpT, -U, -V, and -W.

Four components of the apparatus of extracellular protein secretion of Pseudomonas aeruginosa, Xcpt, -U, -V, and -W (XcpT-W), are synthesized as precursors with short N-terminal leader peptides that share sequence similarity with the pilin subunit of this organism. A specialized leader peptidase/methylase, product of the pilD gene, has been shown to cleave the leader peptide from prepilin and to methylate the N-terminal phenylalanine of the mature pilin. Antibodies were prepared against XcpT-W and used to purify each of these proteins. Sequence analysis of XcpT-W has shown that these proteins, like mature pilin, contain N-methylphenylalanine as the N-terminal amino acid. Analysis of cellular fractions from wild-type and pilD mutant strains of P. aeruginosa showed that the precursor forms of XcpT-W are located predominantly in the bacterial inner membrane, and their localization is not altered after PilD-mediated removal of the leader sequence. These studies demonstrate that the biogenesis of the apparatus of extracellular protein secretion and that of type IV pili share a requirement for PilD. This bifunctional enzyme, acting in the inner membrane, cleaves the leader peptides from precursors of pilins and XcpT-W and subsequently methylates the amino group of the N-terminal phenylalanine of each of its substrates.     

The gene encoding the prepilin peptidase involved in biosynthesis of pilus colonization factor antigen III (CFA/III) of human enterotoxigenic Escherichia coli.

The assembly of pilus colonization factor antigen III (CFA/III) of human enterotoxigenic Escherichia coli requires the processing of CFA/III major pilin (CofA) by a peptidase, likely another type IV pilus formation system. Western blot analysis of CofA reveals that CofA is produced initially as a 26.5-kDa preform pilin (prepilin) and then processed to 20.5-kDa mature pilin by a prepilin peptidase. This processing is essential for exportation of the CofA from the cytoplasm to the periplasm. In this experiment, the structural gene, cofP, encoding CFA/III prepilin peptidase which cleavages at the Gly-30-Met-31 junction of CofA was identified, and the nucleotide sequence of the gene was determined. CofP consists of 819 bp encoding a 273-amino acid protein with a relative molecular mass of 30,533 Da. CofP is predicted to be localized in the inner membrane based on its hydropathy index. The amino acid sequence of CofP shows a high degree of homology with other prepilin peptidases which play a role in the assembly of type IV pili in several gram-negative bacteria.     

Comparative studies of the amino acid and nucleotide sequences of pilin derived from Pseudomonas aeruginosa PAK and PAO.

The entire amino acid sequence for Pseudomonas aeruginosa PAO pilin was determined through peptide sequencing and from the complete nucleotide sequence encoding the pilin gene. The precursor PAO pilin is 149 amino acids in length which includes a 6-amino-acid positively charged leader sequence. Comparison of the amino acid sequences of pilin produced by P. aeruginosa PAO and PAK reveals a region of high homology corresponding to the leader peptide and residues 1 to 54 of the mature pilin. The amino acid sequence of the peptide encompassing the major antigenic determinant of PAK differs greatly from that of the equivalent region in PAO. The C-terminal regions of these proteins are semiconserved. Few major differences were found when the predicted secondary structures for PAO and PAK pilins were compared. Major nucleotide sequence variation between the equivalent restriction fragments from PAO and PAK occurred within the areas coding for the peptides containing the immunodominant site for PAK pilin and the C termini.     

Mapping of export signals of Pseudomonas aeruginosa pilin with alkaline phosphatase fusions.

Pili of Pseudomonas aeruginosa are assembled from monomers of the structural subunit, pilin, after secretion of this protein across the bacterial membrane. These subunits are initally synthesized as precursors (prepilin) with a six-amino-acid leader peptide that is cleaved off during or after membrane traversal, followed by methylation of the amino-terminal phenylalanine residue. This report demonstrates that additional sequences from the N terminus of the mature protein are necessary for membrane translocation. Gene fusions were made between amino-terminal coding sequences of the cloned pilin gene (pilA) and the structural gene for Escherichia coli alkaline phosphatase (phoA) devoid of a signal sequence. Fusions between at least 45 amino acid residues of the mature pilin and alkaline phosphatase resulted in translocation of the fusion proteins across the cytoplasmic membranes of both P. aeruginosa and E. coli strains carrying recombinant plasmids, as measured by alkaline phosphatase activity and Western blotting. Fusion proteins constructed with the first 10 amino acids of prepilin (including the 6-amino-acid leader peptide) were not secreted, although they were detected in the cytoplasm. Therefore, unlike that of the majority of secreted proteins that are synthesized with transient signal sequences, the membrane traversal of pilin across the bacterial membrane requires the transient six-amino-acid leader peptide as well as sequences contained in the N-terminal region of the mature pilin protein.     

The complete primary structure of pilin fromHaemophilus influenzae type b strain Eagan

Adherence ofHaemophilus influenzae type b (Hib) to human oropharyngeal cells is mediated by pili which are proteinaceous filaments that extend outward from the bacterial cell surface. Pili from Hib strain Eagan were purified, and the primary structure of the major subunit, pilin, was determined. Sequencing of overlapping peptides showed the mature protein to be comprised of 196 amino acids and to have an M_r of 21,152. The amino terminal sequence was found to be homologous with the sequence previously reported for Hib strain M43 and also to have significant homology to pilins of other gram-negative pathogenic bacteria. Furthermore, Hib pilin had two cysteinyl residues in the amino terminal portion of the protein which were separated by 40 residues (positions 21 and 61); a motif found in other bacterial pilins. The data show that Hib pilin has structural features common to other bacterial pilins.     

Amino acid sequences of pilins from serologically distinct strains ofBacteroides nodosus

Amino acid sequences of pilin from a strain of Bacteroides nodosus from serogroup B (234) and serogroup C (217) were determined. The amino-terminal N-methylphenlalanine residue of both proteins was followed by a hydrophobic sequence of 30 residues closely related to the N-terminal sequence of other pili having an amino-terminal residue of N-methylphenylalanine. These data lend support to the hypothesis that in pilins of this type, the amino-terminal sequence functions as a transport signal necessary for pilin to reach its external environment, as well as promoting intersubunit interactions for muintenance of the structural integrity of the pilus. Two hydrophilic hypervariable regions can be discerned across the pilin sequences, indicating possible locations of antigenic domains.     

Amino acid sequences of pilins from serologically distinct strains ofBacteroides nodosus

Amino acid sequences of pilin from a strain of Bacteroides nodosus from serogroup B (234) and serogroup C (217) were determined. The amino-terminal N-methylphenlalanine residue of both proteins was followed by a hydrophobic sequence of 30 residues closely related to the N-terminal sequence of other pili having an amino-terminal residue of N-methylphenylalanine. These data lend support to the hypothesis that in pilins of this type, the amino-terminal sequence functions as a transport signal necessary for pilin to reach its external environment, as well as promoting intersubunit interactions for muintenance of the structural integrity of the pilus. Two hydrophilic hypervariable regions can be discerned across the pilin sequences, indicating possible locations of antigenic domains.     

Isolation of the gene encoding pilin of Bacteroides nodosus (strain 198), the causal organism of ovine footrot

The gene for pilin, the monomeric protein subunit from which the pilus of Bacteroides nodosus is constructed, has been isolated. Isolation was achieved by cloning the fragmented genome of B. nodosus in Escherichia coli RR1 using the plasmid vector pBR322. Pilin-producing colonies were identified by screening with a colony immunoassay using antiserum from a sheep immunized against purified pili from B. nodosus strain 198, and were further characterized by immunoblot analysis. Final confirmation of the presence of the pilin gene was by nucleotide sequence data which translated to the known pilin amino acid sequence.     

Amino acid substitutions in pilin of Pseudomonas aeruginosa. Effect on leader peptide cleavage, amino-terminal methylation, and pilus assembly.

A total of 37 separate mutants containing single and multiple amino acid substitutions in the leader and amino-terminal conserved region of the Type IV pilin from Pseudomonas aeruginosa were generated by oligonucleotide-directed mutagenesis. The effect of these substitutions on the secretion, processing, and assembly of the pilin monomers into mature pili was examined. The majority of substitutions in the highly conserved amino-terminal region of the pilin monomer had no effect on piliation. Likewise, substitution of several of the residues within the six amino acid leader sequence did not affect secretion and leader cleavage (processing), including replacement of one or both of the positively charged lysine residues with uncharged or negatively charged amino acids. One characteristic of the Type IV pili is the presence of an amino-terminal phenylalanine after leader peptide cleavage which is N-methylated prior to assembly of pilin monomers into pili. Substitution of the amino-terminal phenylalanine with a number of other amino acids, including polar, hydrophobic, and charged residues, did not affect proper leader cleavage and subsequent assembly into pili. Amino-terminal sequencing showed that the majority of substitute residues were also methylated. Substitution of the glycine residue at the -1 position to the cleavage site resulted in the inability to cleave the prepilin monomers and blocked the subsequent assembly of monomers into pili. These results indicate that despite the high degree of conservation in the amino-terminal sequences of the Type IV pili, N-methylphenylalanine at the +1 position relative to the leader peptide cleavage site is not strictly required for pilin assembly. N-Methylation of the amino acids substituted for phenylalanine was shown to have taken place in four of the five mutants tested, but it remains unclear as to whether pilin assembly is dependent on this modification. Recognition and proper cleavage of the prepilin by the leader peptidase appears to be dependent only on the glycine residue at the -1 position. Cell fractionation experiments demonstrated that pilin isolated from mutants deficient in prepilin processing and/or assembly was found in both inner and outer membrane fractions, indistinguishable from the results seen with the wild type.     

Type IV pilin is glycosylated in Pseudomonas syringae pv. tabaci 6605 and is required for surface motility and virulence

Type IV pilin (PilA) is a major constituent of pilus and is required for bacterial biofilm formation, surface motility and virulence. It is known that mature PilA is produced by cleavage of the short leader sequence of the pilin precursor, followed by methylation of N-terminal phenylalanine. The molecular mass of the PilA mature protein from the tobacco bacterial pathogen Pseudomonas syringae pv. tabaci 6605 (Pta 6605) has been predicted to be 12 329 Da from its deduced amino acid sequence. Previously, we have detected PilA as an approximately 13-kDa protein by immunoblot analysis with anti-PilA-specific antibody. In addition, we found the putative oligosaccharide-transferase gene tfpO downstream of pilA. These findings suggest that PilA in Pta 6605 is glycosylated. The defective mutant of tfpO (ΔtfpO) shows reductions in pilin molecular mass, surface motility and virulence towards host tobacco plants. Thus, pilin glycan plays important roles in bacterial motility and virulence. The genetic region around pilA was compared among P. syringae pathovars. The tfpO gene exists in some strains of pathovars tabaci, syringae, lachrymans, mori, actinidiae, maculicola and P. savastanoi pv. savastanoi. However, some strains of pathovars tabaci, syringae, glycinea, tomato, aesculi and oryzae do not possess tfpO, and the existence of tfpO is independent of the classification of pathovars/strains in P. syringae. Interestingly, the PilA amino acid sequences in tfpO-possessing strains show higher homology with each other than with tfpO-nonpossessing strains. These results suggest that tfpO and pilA might co-evolve in certain specific bacterial strains.     

Purification of the Escherichia coli type 1 pilin and minor pilus proteins and partial characterization of the adhesin protein.

Type 1 pili of Escherichia coli contain three integral minor proteins with apparent molecular weights (Mr) of 28,000 (28K protein), 16,500, and 14,500 attached to rods composed of Mr-17,000 pilin subunits (Hanson and Brinton, Nature [London] 322:265-268). We describe here an improvement on our earlier method of pilus purification, which gives higher yields and higher purity. Also reported are methods allowing fractionation of intact type 1 pili into rods of pure pilin and free minor proteins, as well as fractionation of the 28K tip adhesion protein from the 16.5K and 14.5K proteins. We have determined the amino acid composition and amino-terminal sequence of the adhesion protein. This sequence shows limited homology with the amino-terminal sequences of several E. coli pilins, including type 1.     

Cable (cbl) type II pili of cystic fibrosis-associated Burkholderia (Pseudomonas) cepacia: nucleotide sequence of the cblA major subunit pilin gene and novel morphology of the assembled appendage fibers.

Previous studies have shown that appendage pili of Burkholderia cepacia strains isolated from patients with cystic fibrosis (CF) at The Hospital for Sick Children, Toronto, Canada, mediate adherence to mucus glycoproteins and also enhance adherence to epithelial cells. The specific pilin-associated adhesin molecule is a 22-kDa protein. In the present study we purified the major subunit pilin (17 kDa) and immunolocalized it to peritrichously arranged pili. On the basis of their novel morphological appearance as giant intertwined fibers, we refer to them as cable (Cbl) pili. Using an oligonucleotide probe corresponding to regions of the N-terminal amino acid sequence of the pilin subunit, we detected the encoding cblA gene in a chromosomal DNA library. Sequencing revealed this structural gene to be 555 bp in length, encoding a leader sequence of 19 amino acids, a cleavage site between the alanine at position 19 and the valine at position 20, and a mature pilin sequence of 165 amino acids. The calculated molecular mass is 17.3 kDa. Hydrophobic plus apolar amino acids account for 60% of the total residues. The pilin exhibits some similarities in its amino acid sequence to colonization factor antigen I and CS1 fimbriae of Escherichia coli. With the cblA gene used as a probe, hybridization assays of 59 independent isolates, including those from several geographically separated CF centers, plus environmental and clinical (non-CF) strains, gave positive results with all of the 15 CF-associated B. cepacia isolates from Toronto, plus a single strain from one other CF center (Jackson, Mississippi). The cblA gene is the first pilin subunit gene of B. cepacia to be identified.     

Primary structure of pilin protein from Bacteroides nodosus strain 216: comparison with the corresponding protein from strain 198

The amino acid sequence of pilin protein from Bacteroides nodosus strain 216 was determined. The protein had a calculated molecular weight of 15962 and contained the same number of amino acid residues (151) as the pilin from the previously sequenced strain 198. The sequence of the first 44 residues was common to both strains, including the unusual amino-terminal amino acid, N-methylphenylalanine. Of the remaining 107 residues, 37% of them differed between the two strains. Comparison of hydrophilicity profiles constructed from the sequence data indicated that a conserved region around residues 71-72 was probably the site of an antigenic determinant.     

Molecular Characterization of Low-Molecular-Weight Component Protein,Flp, in Actinobacillus actinomycetemcomitans Fimbriae

Fimbriae preparation from Actinobacillus actinomycetemcomitans was found to contain an abundant low-molecular-weight protein (termed Flp) with an apparent molecular mass of approximately 6.5 kDa, in addition to a small amount of 54-kDa protein. Immunogold electron microscopy localized the Flp protein at the bacterial fimbriae but not at the cell surface. The DNA fragment including the flp gene was cloned from A. actinomycetemcomitans 304-a and its nucleotide sequence was determined. An open reading frame of the flp gene was composed of 225 bp encoding a protein of 75 amino acids. Comparison of the translated amino acid sequence with the sequence of native Flp determined by Edman degradation indicated that the N-terminal part of 26 amino acids is leader peptide. The N-terminal sequence of mature Flp exhibited some similarity to type-IV pilin. Furthermore, the processing site of premature Flp is also similar to that of type-IV prepilin, and a gene encoding a protein homologous to type-IV prepilin-like protein leader peptidase was found downstream of the flp gene. These findings indicate that Flp is the major component protein of A. actinomycetemcomitans fimbriae.     

Nucleotide sequence analysis of the gene encoding the Caulobacter crescentus paracrystalline surface layer protein.

The entire nucleotide sequence of the rsaA gene, encoding the paracrystalline surface (S) layer protein (RsaA) of Caulobacter crescentus CB15A, was determined. The rsaA gene encoded a protein of 1026 amino acids, with a predicted molecular weight of 98,132. Protease cleavage of mature RsaA protein and amino acid sequencing of retrievable peptides yielded two peptides: one aligned with a region approximately two-thirds the way into the predicted amino acid sequence and the second peptide corresponded to the predicted carboxy terminus. Thus, no cleavage processing of the carboxy portion of the RsaA protein occurred during export, and with the exception of the removal of the initial methionine residue, the protein was not processed by cleavage to produce the mature protein. The predicted RsaA amino acid profile was unusual, with small neutral residues predominating. Excepting aspartate, charged amino acids were in relatively low proportion, resulting in an especially acidic protein, with a predicted pI of 3.46. As with most other sequenced S-layer proteins, RsaA contained no cysteine residues. A homology scan of the Swiss Protein Bank 17 produced no close matches to the predicted RsaA sequence. However, RsaA protein shared measurable homology with some exported proteins of other bacteria, including the hemolysins. Of particular interest was a specific region of the RsaA protein that was homologous to the repeat regions of glycine and aspartate residues found in several proteases and hemolysins. These repeats are implicated in the binding of calcium for proper structure and biological activity of these proteins. Those present in the RsaA protein may perform a similar function, since S-layer assembly and surface attachment requires calcium. RsaA protein also shared some homology with 10 other S-layer proteins, with the Campylobacter fetus S-layer protein scoring highest.     

Assembly of mutant pilins in Pseudomonas aeruginosa: formation of pili composed of heterologous subunits.

Recently, we reported the degree of N-terminal processing within the cytoplasmic membranes of three mutant pilins from Pseudomonas aeruginosa PAK with respect to leader peptide removal and the methylation of the N-terminal phenylalanine (B. L. Pasloske and W. Paranchych, Mol. Microbiol. 2:489-495, 1988). The results of those experiments showed that the deletion of 4 or 8 amino acids within the highly conserved N terminus greatly inhibited leader peptide removal. On the other hand, the mutation of the glutamate at position 5 to a lysine permitted leader peptide cleavage but inhibited transmethylase activity. In this report, we have examined the effects of these mutant pilins upon pilus assembly in a P. aeruginosa PAO host with or without the chromosomally encoded pilin gene present. Pilins with deletions of 4 or 8 amino acids in the N-terminal region were not incorporated into pili. Interestingly, pilin subunits containing the glutamate-to-lysine mutation were incorporated into compound pili together with PAO wild-type subunits. However, the mutant pilins were unable to polymerize as a homopolymer. When wild-type PAK and PAO pilin subunits were expressed in the same bacterial strain, the pilin subunits assembled into homopolymeric pili containing one or the other type of subunit.     

Structure-function relationship of type-IV prepilin peptidase of Pseudomonas aeruginosa – a review

The bifunctional enzyme prepilin peptidase (PilD) from Pseudomonas aeruginosa is a key determinant in both type-IV pilus biogenesis and extracellular protein secretion, in its roles as a leader peptidase and MTase. It is responsible for endopeptidic cleavage of the unique leader peptides that characterize type-IV pilin precursors, as well as proteins with homologous leader sequences that are essential components of the general secretion pathway found in a variety of Gram-negative pathogens. Following removal of the leader peptides, the same enzyme is responsible for the second posttranslational modification that characterizes the type-IV pilins and their homologues, namely N-methylation of the newly exposed N-terminal amino acid residue. This review discusses some of the work begun in order to answer questions regarding the structure-function relationships of the active sites of this unique enzyme.