Influence of pilin glycosylation on Pseudomonas aeruginosa 1244 pilus function

The opportunistic pathogen Pseudomonas aeruginosa is a leading cause of nosocomial pneumonia. Among its virulence factors, the type IV pili of P. aeruginosa strain 1244 contain a covalently linked, three-sugar glycan of previously unknown significance. The work described in this paper was carried out to determine the influence of the P. aeruginosa 1244 pilin glycan on pilus function, as well as a possible role in pathogenesis. To accomplish this, a deletion was introduced into the pilO gene of this organism. The isogenic knockout strain produced, 1244G7, was unable to glycosylate pilin but could produce pili normal in appearance and quantity. In addition, this strain had somewhat reduced twitching motility, was sensitive to pilus-specific bacteriophages, and could form a normal biofilm. Analysis of whole cells and isolated pili from wild-type P. aeruginosa strain 1244 by transmission electron microscopy with a glycan-specific immunogold label showed that this saccharide was distributed evenly over the fiber surface. The presence of the pilin glycan reduced the hydrophobicity of purified pili as well as whole cells. With regard to pathogenicity, P. aeruginosa strains producing glycosylated pili were commonly found among clinical isolates and particularly among those strains isolated from sputum. Competition index analysis using a mouse respiratory model comparing strains 1244 and 1244G7 indicated that the presence of the pilin glycan allowed for significantly greater survival in the lung environment. These results collectively suggest that the pilin glycan is a significant virulence factor and may aid in the establishment of infection.     

Mapping of the T-cell recognition sites of Pseudomonas aeruginosa PAK polar pili.

The polar pili of Pseudomonas aeruginosa consist of a subunit protein, pilin, which is a 144-residue polypeptide that contains a hydrophobic N-terminal region and eight hydrophilic regions distributed throughout the remainder of the molecule. T cells from mice immunized with pili or whole bacteria gave good pilus-specific T-cell proliferation responses. To delineate the T-cell antigenic regions of the pilin, T-cell blasts were generated from lymph nodes of pilus-primed BALB/c mice. These blasts were tested in vitro in T-cell proliferation assays for reactivity against the fragments of the pilin subunit prepared by enzymatic digestion. Citraconylation followed by trypsin digestion (cT) of the pilin subunit cleaved the protein into four fragments, cTI (residues 1 to 30), cTII (residues 31 to 53), cTIII (residues 54 to 120), and cTIV (residues 121 to 144). The ability to stimulate the T cells was found to reside in the cTI and cTIII regions, but not in the cTII or cTIV regions. A subfragment of cTIII, containing residues 82 to 104, was identified as the major T-cell recognition site within the cTIII region of the pilin molecule. A cross-reactivity was observed between pili from two strains of P. aeruginosa, namely, PAK and PAO, at the T-cell level. This cross-reactivity probably resulted from the sequence homology in the hydrophobic N-terminal region of these two molecules.     

Differentiation of Pseudomonas aeruginosa pili based on sequence and B-cell epitope analyses.

The nucleotide sequences of three previously undescribed Pseudomonas aeruginosa pilin structural genes are presented. Comparisons of deduced pilin primary structure and flanking DNA sequence allowed placement of these and six previously published sequences into one of two groups. Epitope mapping, using overlapping immobilized peptides representing the pilin primary structure, with antipilin monoclonal antibodies revealed several B-cell determinants grouped near the carboxyl terminus of P. aeruginosa 1244 pilin. One determinant was found to reside near the pilin constant region. These determinants were found associated with the pili of 31 of 95 P. aeruginosa clinical isolates.     

Pilins from the B serogroup of Bacteroides nodosus: characterization, expression, and cross-protection.

Sequences of pilin genes from four strains of serogroup B of the ovine pathogen Bacteroides nodosus have been determined. These sequences permit comparisons of amino acid sequence between pilins from different subtypes (B1, B2, B3, B4) of the B serogroup and assessment of intraserogroup variation. Pili of B. nodosus strains 234 (B1) and 183 (B2) were produced by Pseudomonas aeruginosa harboring a plasmid-borne B. nodosus pilin gene, and these pili were used in sheep vaccination trials. Pili from strain 183 (B2) were found to be a senior antigen to pili from strains of other B subtypes, providing protection against footrot infection caused by strains of the other B subtypes. Pili of this strain are therefore the most suitable candidate for inclusion in a pilus-based vaccine. Pili of strain 234 from subtype B1, the reference strain of the B serogroup, provided poor protection against infection with other subtypes.     

Isolation, expression, and nucleotide sequencing of the pilin structural gene of the Brazilian purpuric fever clone of Haemophilus influenzae biogroup aegyptius.

In this study we isolated the pilin gene from the Brazilian purpuric fever (BPF) clone of Haemophilus influenzae biogroup aegyptius, expressed the gene in Escherichia coli, and determined its nucleotide sequence. Comparison of the nucleotide sequence of the BPF pilin gene with the sequences of pilin genes from strains of H. influenzae sensu stricto demonstrated a high degree of identity. Consistent with this observation, hemagglutination inhibition studies performed with a series of glycoconjugates indicated that BPF pili and H. influenzae type b pili possess the same erythrocyte receptor specificity.     

Identification of a gene essential for piliation in Haemophilus influenzae type b with homology to the pilus assembly platform genes of gram-negative bacteria.

Haemophilus influenzae type b (Hib) pili are complex filamentous surface structures consisting predominantly of pilin protein subunits. The gene encoding the major pilin protein subunit of Hib adherence pili has been cloned and its nucleotide sequence has been determined. In order to identify specific accessory genes involved in pilus expression and assembly, we constructed isogenic Hib mutants containing insertional chromosomal mutations in the DNA flanking the pilin structural gene. These mutants were screened for pilin production, pilus expression, and hemagglutination. Pili and pilin production were assessed by immunoassays with polyclonal antisera specific for pilin and pili of Hib strain Eagan. Hemagglutination was semiquantitatively evaluated in a microtiter plate assay. Six Hib mutants produced proteins immunoreactive with antipilin antiserum but no longer produced structures reactive with antipilus antiserum. In addition, the mutants were unable to agglutinate human erythrocytes. Nucleotide sequence analysis localized the insertion sites in the six mutants to 2.5-kb open reading frame upstream of the pilin structural gene and immediately downstream of an Hib pilin chaperone gene. The amino acid sequence encoded by this open reading frame has significant homology to members of the pilus assembly platform protein family, including FhaA of Bordetella pertussis, MrkC of Klebsiella pneumoniae, and the Escherichia coli assembly platform proteins FimD and PapC. This open reading frame, designated hifC, appears to represent a gene essential to Hib pilus biogenesis that has genetic and functional similarity to the pilus platform assembly genes of other gram-negative rods.     

Serial isolates of Pseudomonas aeruginosa from a cystic fibrosis patient have identical pilin sequences.

Five isolates of Pseudomonas aeruginosa (CD2, CD3, CD4, CD5, and CD10) from a patient with cystic fibrosis were examined with regard to several genotypic and phenotypic characteristics to determine whether the patient was colonized with one or several distinct strains. Isolates CD2, CD3, and CD4 were obtained from a single sputum sample, and CD5 and CD10 were obtained 1 and 2 years later, respectively. On the basis of colonial morphology, serotyping, and antibiograms, the five isolates appeared to be different strains. However, Southern blot analysis with a 1.2-kilobase DNA probe containing the P. aeruginosa PAK pilin gene indicated that all five strains were identical at that genetic locus. The pilin genes of the five isolates were cloned and sequenced at the nucleotide level and found to be identical. Southern blot analysis with a probe from a separate region of the P. aeruginosa chromosome, a 741-base-pair PstI-NruI DNA fragment adjacent to the exotoxin A gene, also revealed genetic identity among these five clinical isolates. On this basis, it was concluded that this patient was colonized with a single strain of P. aeruginosa and that the strain had remained genetically stable over a period of 2 years. The predicted pilin sequence of the CD isolates was almost identical to that of strain PA103 (97% homology) and serologically related to PAO pilin, with which it shared 80% homology. No immunological cross-reactivity was detected between the CD and PAK pilins, which shared the least homology (62%) among the four pilins considered in this study. Although all five CD isolates contained identical pilin genes, three had acquired mutations which prevented normal expression of the pilus system. CD3 was a putative regulatory mutant which was unable to produce normal amounts of pilin, and CD4 and CD10 were putative assembly mutants which produced normal amounts of pilin but were unable to assemble the pilin subunit into intact pili.     

Alteration of the pilin adhesin of Pseudomonas aeruginosa PAO results in normal pilus biogenesis but a loss of adherence to human pneumocyte cells and decreased virulence in mice.

The disulfide loop domain of Pseudomonas aeruginosa PAO pilin was altered by insertion of a chloramphenicol acetyltransferase gene into the pilin gene so that the C-terminal nine amino acids were replaced with 11 new amino acids. The altered pilin gene was transferred into wild-type PAO by recombination, where it did not affect normal piliation as observed by transmission electron microscopy or change of sensitivity to f116, PO4, B9, and Pf1 pilus-specific bacteriophages. However, the binding to human pneumocyte A549 cells was markedly reduced when tested in an in vitro binding assay (2 to 6 bacteria bound per A549 cell for the mutant bacteria compared with 50 bacteria per A549 cell for the wild-type bacteria). Additionally, when susceptible A.BY/SnJ mice were challenged with wild-type P. aeruginosa PAO and with P. aeruginosa PAO-MP (altered pilin gene), a 50% lethal dose of 3 x 10(6) bacteria per mouse was observed for PAO-MP compared with 7 x 10(4) bacteria per mouse for PAO. Approximately 90 of the adherence capability of P. aeruginosa PAO is seemingly attributable to the C-terminal disulfide loop adherence domain of pili. The pilus adherence function contributes significantly to the virulence of P. aeruginosa PAO in the A.BY/SnJ mouse infection model.     

Characterization of the Pseudomonas aeruginosa pilus adhesin: confirmation that the pilin structural protein subunit contains a human epithelial cell-binding domain.

Previous studies have suggested that the Pseudomonas aeruginosa PAK pilus adhesin moiety resides in an epithelial cell-binding domain located in the C-terminal region of the PAK pilin structural protein. Synthetic peptides Ac17red (a synthetic peptide with a sequence identical to that of PAK pilin residues 128 to 144, with the Cys-129 and Cys-142 residues being in the reduced state) and Ac17ox (a synthetic peptide with a sequence identical to that of PAK pilin residues 128 to 144, with a formed disulfide bridge between the amino acid residues Cys-129 and Cys-142), which should contain the epithelial cell-binding domain, were synthesized. Ac17red and Ac17ox both bound to buccal epithelial cells (BECs) and to ciliated tracheal epithelial cells (TECs). Ac17ox had a Km of 6.40 microM for binding to BECs, while Ac17red had a Km of 9.87 microM. Ac17red bound to the same receptor sites that purified pili did and competitively inhibited the binding of purified PAK pili to BECs. BEC glycoproteins with molecular masses of 82, 55 to 51, and 40 kilodaltons immobilized on nitrocellulose exhibited periodate-sensitive receptor activity for Ac17red; similar activity has been found for PAK pili. Ac17red, Ac17ox, and PAK pili bound to the cilia and luminal portions of the cytoplasmic membrane of human TECs, the same regions to which P. aeruginosa whole cells bind. PAK pilin has an epithelial cell-binding domain that resides in the C-terminal region of the protein.     

Cloning, expression, and sequence analysis of the Haemophilus influenzae type b strain M43p+ pilin gene.

By using antiserum against Haemophilus influenzae type b (Hib) strain M43p+ denatured pilin, we screened a genomic library of Hib strain M43p+ and identified a clone that expressed pilin, but not assembled pili, on its surface. Southern blot analysis revealed the presence of one structural gene, which was also present in strain M42p-, a nonpiliated variant. Five exonuclease III deletion mutants, two of which had deletions that extended into the structural gene and failed to express pilin, were used to obtain the nucleotide sequence of the structural gene. The amino acid sequence of the open reading frame agrees with 38 of 40 amino acids from the published sequence of purified Hib M43p+ pilin. The pilin gene coded for a mature protein of 193 amino acids, with a calculated molecular mass of 21,101 daltons. Comparison of the Hib M43p+ pilin amino acid sequence with those of pilins of other bacteria revealed strong conservation of amino- and carboxy-terminal regions in M43p+ and Escherichia coli F17, type 1C, and several members of the P pili family, as well as Klebsiella pneumoniae type 3 MR/K, Bordetella pertussis serotype 2, and Serratia marcescens US46 fimbriae.     

Cross-reactivity of Pseudomonas aeruginosa antipilin monoclonal antibodies with heterogeneous strains of P. aeruginosa and Pseudomonas cepacia.

Much of the morbidity and mortality in patients with cystic fibrosis (CF) is secondary to pulmonary infections with Pseudomonas aeruginosa and, more recently, with Pseudomonas cepacia. Prevention of colonization and subsequent infection would be a useful therapeutic strategy. The pili (fimbriae) of P. aeruginosa are a potential vaccine antigen, as they have been implicated in binding to respiratory epithelium and appear to have limited antigenic diversity. Monoclonal antibodies (MAbs) raised to P. aeruginosa pilin demonstrated significant cross-reactivity, as four of five P. aeruginosa strains with known pilin sequences and 10 of 15 P. aeruginosa clinical isolates hybridized by immunoblot with at least one of the three MAbs tested. The P. cepacia strains demonstrated minimal cross-reactivity with these MAbs, as only 2 of 16 strains hybridized immunologically. The three MAbs decreased the adherence of 35S-labeled P. aeruginosa PA1244 to bovine tracheal cells by 56, 45, and 31%. One of these MAbs decreased the adherence of strains P. aeruginosa PAO1 and P. cepacia 249 to CF epithelial cells by 46 and 25%, respectively. While antibodies to Pseudomonas pili must be shown to be protective in patients with CF, these studies give support for a multivalent vaccine strategy using P. aeruginosa pilin as the immunogen.     

Comparison and analysis of the nucleotide sequences of pilin genes from Haemophilus influenzae type b strains Eagan and M43.

Previous studies have demonstrated antigenic differences among the pili expressed by various strains of Haemophilus influenzae type b (Hib). In order to understand the molecular basis for these differences, the structural gene for pilin was cloned from Hib strain Eagan (p+) and the nucleotide sequence was compared to those of strains M43 (p+) and 770235 b0f+, which had been previously determined. The pilin gene of Hib strain Eagan (p+) had a 648-bp open reading frame that encoded a 20-amino-acid leader sequence followed by the 196 amino acids found in mature pilin. The translated sequence was three amino acids larger than pilins of strains M43 (p+) and 770235 b0f+ and was 78% identical and 95% homologous when conservative amino acid substitutions were considered. Differences between the amino acid sequences were not localized to any one region but rather were distributed throughout the proteins. Comparison of protein hydrophilicity profiles showed several hydrophilic regions with sequences that were conserved between strain Eagan (p+) and pilins of other Hib strains, and these regions represent potentially conserved antigenic domains. Southern blot analyses using an intragenic probe from the pilin gene of strain Eagan (p+) showed that the pilin gene was conserved among all type b and nontypeable strains of H. influenzae examined, and only a single copy was present in these strains. Homologous genes were not present in the phylogenetically related species Pasteurella multocida, Pasteurella haemolytica, and Actinobacillus pleuropneumoniae. These data indicate that the pilin gene was highly conserved among different strains of H. influenzae and that small differences in the pilin amino acid sequences account for the observed antigenic differences of assembled pili from these strains.     

Cross-reactive and strain-specific antipeptide antibodies to Pseudomonas aeruginosa PAK and PAO pili.

Antipeptide antibodies were raised against synthetic peptides corresponding to the amino acid sequences of eight surface predicted regions of the pilin proteins from Pseudomonas aeruginosa PAK and PAO. Four of the anti-PAK peptide antisera cross-reacted with strain PAO pili, while five anti-PAO peptide antisera cross-reacted with strain PAK pili. Only one region of the two pilin proteins (region 88-97) provided strain-specific antibodies when either strain PAK or strain PAO region 88-97 peptides were used to generate antipeptide antibodies. Our results clearly showed that cross-reactive and strain-specific antibodies cannot be based solely on the degree of homology in the aligned protein sequences. The majority of synthetic peptides bound to their homologous antipilus antiserum, suggesting that linear sequences play a significant role in the immunogenic response of native pili.     

Immune recognition of polar pili from Pseudomonas aeruginosa O.

The B- and T-cell antigenic sites on type O pili from Pseudomonas aeruginosa were determined by using an antipilus antibody competition assay and PAO-immune T-cell blasts in proliferation studies. The citraconylated tryptic digest III region (residues 54 to 120) was determined to be an immunodominant site for both T and B cells on the pilin molecule.     

Adherence of Pseudomonas aeruginosa and Candida albicans to glycosphingolipid (Asialo-GM1) receptors is achieved by a conserved receptor-binding domain present on their adhesins.

Pseudomonas aeruginosa, a gram-negative bacterium, and Candida albicans, a dimorphic yeast, are evolutionarily distant microorganisms which can utilize filamentous structures termed pili and fimbriae, respectively, to mediate adherence to glycosphingolipids (asialoganglioside-GM1) receptors. The mechanism of adherence to glycosphingolipid receptors was investigated in these studies. By using monoclonal antibodies (MAbs) against purified pili of P. aeruginosa PAK (PK99H) and monospecific anti-peptide antibodies against the PAK pilin peptides [anti-PAK(128-144) and anti-PAK(134-140)], we demonstrated that these antibodies agglutinated C. albicans whole cells and cross-reacted with C. albicans fimbriae in immunoblots. A control MAb, PKL1, and anti-PAK(75-84) peptide antibodies failed to agglutinate C. albicans whole cells or cross-react with the fimbrial proteins. Conversely, the anti-C. albicans fimbrial MAb Fm16, but not Fm34, agglutinated P. aeruginosa PAK whole cells and Western blots (immunoblots). The interactions between PK99H and Fm16 and their respective homologous antigens were competitively inhibited by heterologous antigens; this demonstrated that the interactions between the antibodies and the heterologous antigens, i.e., PK99H with C. albicans fimbriae and Fm16 with P. aeruginosa pili, were highly specific and suggested that both adhesins share a common antigenic determinant. The immunological cross-reactivity between Fm16 and P. aeruginosa PAK pilin is localized onto the PAK(134-140) region as shown by a competitive enzyme-linked immunosorbent assay. The PAK(134-140) region of PAK pilin contains the epitope recognized by PK99H and also constitutes part of the receptor-binding domain of the pilus adhesin. Thus, the results from these studies suggest that common cell surface receptors are recognized by the P. aeruginosa and C. albicans adhesins because of a conserved receptor-binding domain on the adhesins.     

Purification and characterization of a pilus of a Vibrio cholerae strain: a possible colonization factor.

A new flexible type of pilus was purified from Vibrio cholerae non-O1, non-0139 strain NAGV14 and characterized. The molecular mass of the pilin was estimated to be 20 kDa, and the antigenicity differed from that of known pili such as toxin-coregulated pili, mannose-sensitive hemagglutinating pili, V10 pili, and Al-1841 pili. The NAGV14 pilus was regarded as a colonization factor because the purified pili adhered to rabbit intestine and adhesion was inhibited by treating the organisms with the Fab fraction of an antipilus antibody. An intestinal receptor blockade using purified pili failed to inhibit adhesion of the organisms. The NAGV14 pili adhered to the surface of live V. cholerae. An antigen cross-reacting with the NAGV14 pili was widely and specifically distributed among V. cholerae strains irrespective of serotype and biotype. The amino acid sequence of the pilin was homologous with that of MshA. The NAGV14 pili did not agglutinate human and rabbit erythrocytes.     

Surface epitope localization and gene structure of a Babesia bovis 44-kilodalton variable merozoite surface antigen.

Variation of Babesia bovis merozoite surface antigens occurs among geographic strains of the parasite. In this and a concurrent report, we investigate this variation at the gene and protein level. Using a monoclonal antibody (mAb 23/70.174), B. bovis gene sequences were identified that encoded a surface epitope of a 44-kDa merozoite surface antigen (MSA-2). This epitope is variably expressed among geographic isolates of B. bovis. Here, we describe the MSA-2 protein gene sequence, localize this surface epitope to a repeated amino acid sequence, and investigate the genomic organization of the gene in B. bovis strains from Mexico and Australia. The predicted protein sequence had hydrophobic regions at its amino and carboxy termini consistent with a signal peptide and a membrane anchor via glycosylphosphatidyl inositol, respectively. The surface epitope recognized by mAb 23/70.174 was localized within a 24-amino acid sequence which is repeated twice in tandem. Six different EcoRI bands hybridized to the MSA-2 gene sequence with varying intensities in genomic Southern blots of the homologous strain. Two of these appear to be alleles of the MSA-2 gene. Whereas 5' and 3' sequences of the MSA-2 gene sequence were detected in an Australia strain of B. bovis, internal gene sequences encoding the surface epitope were not. The 3' sequences of the MSA-2 gene also had significant sequence similarity with the MSA-1 gene of the Mexico strain B. bovis and a gene from the previously described BabR locus. These data indicate that the MSA-2 protein gene belongs to the BabR locus which encodes variable merozoite surface antigens.     

Biotinylated DNA probes for exotoxin A and pilin genes in the differentiation of Pseudomonas aeruginosa strains.

Biotin-labeled DNA probes derived from Pseudomonas aeruginosa exotoxin A and pilin genes were tested for their ability to distinguish strains among a selected group of P. aeruginosa isolates. Probing of Southern blots of restriction digests of DNA from test strains with the exotoxin A probe demonstrated a unique hybridization pattern for each independently isolated strain containing the exotoxin A gene. Two phenotypically distinct strains isolated from the same patient were found to be identical in their DNA hybridization patterns. By using a pilin gene probe, similar distinction was made between independent strains, while strains from the same source were confirmed to be identical. Furthermore, DNA from a strain of P. aeruginosa lacking the exotoxin A gene yielded a unique pattern of restriction fragments which hybridized to the pilin gene probe. The exotoxin A and the pilin probes may together prove to be useful tools in epidemiological surveys during outbreaks of P. aeruginosa infection.