PuIO, a component of the pullulanase secretion pathway of Klebsiella oxytoca, correctly and efficiently processes gonococcal type IV prepilin in Escherichia coli

The PulO protein required for extracellular secretion of pullulanase by Klebsiella oxytoca is known to be highly homologous to two type IV prepilin peptidases, namely XcpA(PilD) (Pseudomonas aeruginosa) and TcpJ (Vibrio cholerae). The predicted prepilin peptidase activity of PulO was confirmed by showing that it could correctly process the product of the cloned pilE.1 type IV pilin structural gene from Neisseria gonorrhoeae in Escherichia coli. The P. aeruginosa prepilin peptidase and another putative prepilin peptidase, ComC from Bacillus subtilis, also processed prePilE. Subcellular fractionation showed that the pilE gene product that had been processed by PulO remained associated with the cytoplasmic membrane, as did the unprocessed precursor. PulO was also shown to process three of the four prePilE-PhoA hybrids tested. Southern hybridization experiments suggest that a pulO homologue is present in the N. gonorrhoeae chromosome.     

An enzyme with type IV prepilin peptidase activity is required to process components of the general extracellular protein secretion pathway of Klebsiella oxytoca

The last gene (pulO) of the pulC-O pullulanase secretion gene operon of Klebsiella oxytoca codes for a protein that is 52% identical to the product of the pilD/xcpA gene required for extracellular protein secretion and type IV pilus biogenesis in Pseudomonas aeruginosa. The PilD/XcpA protein is known to remove the first six amino acids of the signal sequence of the type IV pilin precursor by cleaving after the glycine residue in the conserved sequence GF(M)XXXE (where X represents hydrophobic amino acids). This prepilin peptidase cleavage site is present in the products of four genes in the pulC-O operon (PulG, PulH, Pull and PulJ proteins). It is shown here that PulO processes the pulG gene product in vivo. Processing was maximal within 15 seconds, but experiments in which the expression of pulO was uncoupled from that of the other genes in the secretion operon suggest that processing can also occur post-translationally. The products of two pulG derivatives with internal inframe deletions were also processed by PulO, but the three PulG-PhoA hybrids, two PulJ-PhoA hybrids and the single PulH-PhoA hybrid tested did not appear to be processed. Sucrose gradient fraction experiments showed that both precursor and mature forms of PulG appear to be associated with low-density, outer membrane vesicles prepared by osmotic lysis of sphaeroplasts. Neither the xcpA gene nor the Bacillus subtilis gene comC, which is also homologous to pulO and codes for a protein with type IV prepilin peptidase activity, can correct the pullulanase secretion defect in an Escherichia coli strain carrying all of the genes required for secretion except pulO. Furthermore, neither XcpA nor ComC is able to process prePulG protein in vivo.     

Type IV prepilin peptidase gene of Neisseria gonorrhoeae MS11: presence of a related gene in other piliated and nonpiliated Neisseria strains.

The assembly of type IV pili in Neisseria gonorrhoeae is a complex process likely to require the products of many genes. One of these is the enzyme prepilin peptidase, which cleaves and then N methylates the precursor pilin subunits prior to their assembly into pili. We have used a PCR amplification strategy to clone the N. gonorrhoeae prepilin peptidase gene, pilDNg. A single copy of the gene is shown to be present in the chromosome. Its product promotes correct cleavage of the gonococcal prepillin in Escherichia coli cells carrying both the prepilin peptidase gene and the pilin structural gene. PilDNg also cleaves prePulG, a type IV pilin-like protein of Klebsiella oxytoca. Moreover, PilDNg complements a mutation in the gene coding for the prepilin peptidase-like protein of K. oxytoca, pulO, partially restoring PulG-PulO-dependent extracellular secretion of the enzyme pullulanase. Finally, we show that genes homologous to pilDNg are present and expressed in a variety of species in the genus Neisseria, including some commensal strains.     

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.     

Processing and methylation of PulG, a pilin-like component of the general secretory pathway of Klebsiella oxytoca

The signal sequence of the Klebsiella oxytoca pulG gene product, which is required for extracellular secretion of the enzyme pullulanase, is similar in many respects to the corresponding segment of the precursors of type IV (me-Phe) pilins. The significance of this similarity is confirmed by the observation that the pulO gene product processes prePulG at the consensus type IV prepilin peptidase cleavage site at the amino-terminal end of the PulG signal sequence. Like most type IV pilins, processed PuiG was found to have a methylated amino-terminal phenylaianine residue. Site-directed mutagenesis was used to replace amino acids in prePulG that correspond to residues shown by others to be essential for processing, methylation and assembly of type IV pilins. The glycine residue on the amino-terminal side of the prePulG cleavage site is absolutely required for processing and for pullulanase secretion. The glutamate residue at position 11 (+5) is also required for pullulanase secretion but not for processing or methylation. This result contrasts with that reported for corresponding variants of Pseudomonas aeruginosa type IV prepilin, which were processed but only inefficiently IV-methylated. Cleavage of prePulG and pullulanase secretion were both unaffected by replacement of the phenylalanine residue on the car-boxy-terminal side of the cleavage site by leucine, isoleucine or valine, by a conservative substitution within the hydrophobic core of the prePulG signal sequence, or by a glutamine to proline substitution within the processed segment. However, replacement of the same glutamine residue by arginine abolished secretion without affecting either processing or methylation.     

Pilus formation and protein secretion by the same machinery in Escherichia coli

The secreton (type II secretion) and type IV pilus biogenesis branches of the general secretory pathway in Gram-negative bacteria share many features that suggest a common evolutionary origin. Five components of the secreton, the pseudopilins, are similar to subunits of type IV pili. Here, we report that when the 15 genes encoding the pullulanase secreton of Klebsiella oxytoca were expressed on a high copy number plasmid in Escherichia coli, one pseudopilin, PulG, was assembled into pilus-like bundles. Assembly of the 'secreton pilus' required most but not all of the secreton components that are essential for pullulanase secretion, including some with no known homologues in type IV piliation machineries. Two other pseudopilins, pullulanase and two outer membrane-associated secreton components were not associated with pili. Thus, PulG is probably the major component of the pilus. Expression of a type IV pilin gene, the E.coli K-12 gene ppdD, led to secreton-dependent incorporation of PpdD pilin into pili without diminishing pullulanase secretion. This is the first demonstration that pseudopilins can be assembled into pilus-like structures.     

A plasmid-encoded prepilin peptidase gene from enteropathogenic Escherichia coli.

Enteropathogenic Escherichia coli, a leading agent of infantile diarrhea worldwide, adheres to tissue culture cells in a pattern called "localized adherence." Localized adherence is associated with bundle-forming pili encoded by the plasmid bfpA gene, the product of which is homologous with the major structural subunit proteins of type IV fimbriae in other bacteria. Several of these proteins have been shown to be processed from a precursor by a specific prepilin peptidase. We cloned restriction fragments downstream of the bfpA gene into an E. coli-Pseudomonas aeruginosa shuttle vector and mobilized them into a P. aeruginosa prepilin peptidase (pilD) mutant. A plasmid containing a 1.3-kb PstI-BamHI fragment was able to complement the pilD mutation, as demonstrated by restoration of sensitivity to the pilus-specific bacteriophage PO4. The DNA sequence of this fragment revealed an open reading frame, designated bfpP, the predicted product of which is homologous to other prepilin peptidases, including TcpJ of Vibrio cholerae (30% identical amino acids), PulO of Klebsiella oxytoca (29%), and PilD of P. aeruginosa (28%). A bfpA::TnphoA mutant complemented with a bfpA-containing DNA fragment only partially processes the BfpA protein. When complemented with a larger fragment containing bfpP as well as bfpA, the mutant expresses the fully processed BfpA protein. P. aeruginosa PAK, but not a pilD mutant of PAK, expresses mature BfpA protein when the bfpA gene is mobilized into this strain. Thus, as in other type IV fimbria systems, enteropathogenic E. coli utilizes a specific prepilin peptidase to process the major subunit of the bundle-forming pilus. This prepilin petidase contains sequence and reciprocal functional homologies with the PilD protein of P. aeruginosa.     

Novel class of mutations of pilS mutants, encoding plasmid R64 type IV prepilin: interface of PilS-PilV interactions

The type IV pili of plasmid R64 belonging to the type IVB group are required only for liquid mating. They consist of the major and minor components PilS pilin and PilV adhesin, respectively. PilS pilin is first synthesized as a 22-kDa prepilin from the pilS gene and is then processed to a 19-kDa mature pilin by PilU prepilin peptidase. In a previous genetic analysis, we identified four classes of the pilS mutants (T. Horiuchi and T. Komano, J. Bacteriol. 180:4613-4620, 1998). The products of the class I pilS mutants were not processed by prepilin peptidase; the products of the class II mutants were not secreted; in the class III mutants type IV pili with reduced activities in liquid mating were produced; and in the class IV mutants type IV pili with normal activities were produced. Here, we describe a novel class, class V, of pilS mutants. Mutations in the pilS gene at Gly-56 or Tyr-57 produced type IV pili lacking PilV adhesin, which were inactive in liquid mating. Residues 56 and 57 of PilS pilin are suggested to function as an interface of PilS-PilV interactions.     

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.     

Analysis of the <Emphasis Type="Italic">pilU</Emphasis> gene for the prepilin peptidase involved in the biogenesis of type IV pili encoded by plasmid R64

In many type IV pili, the N-terminal amino acid of the pilin subunit is N-methylated phenylalanine. A prepilin peptidase removes the leader peptide from the precursor and methylates the amino group of the newly formed phenylalanine. PilS, the precursor of the pilin encoded by plasmid R64, is processed by the prepilin peptidase PilU, but the N-terminal amino acid of the mature pilin is a non-methylated tryptophan that is otherwise modified. To study the relationship between the structure and function of PilU, 42 missense pilU mutations were constructed by PCR and site-directed mutagenesis, and the ability of these pilU mutants to complement a pilU null mutant for mating in liquid culture was analyzed. Although practically no conjugation was noted for 21 of the mutants, the remaining 21 supported varying levels of residual plasmid transfer activity. Two mutants with aspartic acid replacements in conserved motifs exhibited no PilU activity, suggesting that the product of the pilU gene is an aspartic acid peptidase, like TcpJ, the prepilin peptidare of Vibrio cholerae. No PilS processing was detected in 21 of the mutants, but the remaining 21 exhibited varying levels of residual PilS processing. A close correlation was noted between residual PilS processing activity and conjugative transfer, suggesting that the pilU gene product possesses prepilin peptidase activity, but is unable to methylate the N-terminal tryptophan. Based on the activity of pilU-phoA and pilU-lacZ fusion genes encoding different segments of PilU, a model for the membrane topology of the protein is also proposed. Furthermore, some amino acid substitutions in the pilU portion of the pilU-phoA and pilU-lacZ fusion genes were found to alter the membrane topology of the product.     

Identification of the hopG gene, a component of Escherichia coli K-12 type II export system, and its conservation among different pathogenic Escherichia coli and Shigella isolates.

The Escherichia coli K-12 gene coding for a component of a type II export system was identified and characterized. The HopG protein contains a typical prepilin peptidase cleavage site and has a high degree of homology with proteins PulG, OutG, and ExeG, which are components of type II secretion systems from Klebsiella pneumoniae, Erwinia carotovora, and Aeromonas hydrophila.     

Identification of the Vibrio cholerae type 4 prepilin peptidase required for cholera toxin secretion and pilus formation

Cholera toxin secretion is dependent upon the extracellular protein secretion apparatus encoded by the eps gene locus of Vibrio cholerae . Although the eps gene locus encodes several type four prepilin-like proteins, the peptidase responsible for processing these proteins has not been identified. This report describes the identification of a prepilin peptidase from the V. cholerae genomic database by virtue of its homology with the PilD prepilin peptidase of Pseudomonas aeruginosa . Plasmid disruption or deletion of this peptidase gene in either El Tor or classical V. cholerae O1 biotype strains results in a dramatic decrease in cholera toxin secretion. In the case of the El Tor biotype mutants, surface expression of the type 4 pilus responsible for mannose-sensitive haemagglutination is abolished. The cloned V. cholerae peptidase processes either EpsI or MshA preproteins when co-expressed in E. coli . Mutation of the V. cholerae peptidase gene also results in a defect in virulence and decreased levels of OmpU. The V. cholerae peptidase gene sequence shows 80% homology with the Vibrio vulnificus VvpD type 4 prepilin peptidase required for pilus assembly and cytolysin secretion in V. vulnificus . Accordingly, the V. cholerae type 4 prepilin peptidase required for pilus assembly and cholera toxin secretion has been designated VcpD.     

Overexpression of Methanococcus voltae Flagellin Subunits in Escherichia coli and Pseudomonas aeruginosa: a Source of Archaeal Preflagellin

Methanococcus voltae is a flagellated member of the Archaea. Four highly similar flagellin genes have previously been cloned and sequenced, and the presence of leader peptides has been demonstrated. While the flagellins of M. voltae are predicted from their gene sequences to be approximately 22 to 25 kDa, sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis of purified flagella revealed flagellin subunits with apparent molecular masses of 31 and 33 kDa. Here we describe the expression of a M. voltae flagellin in the bacteria Escherichia coli and Pseudomonas aeruginosa. Both of these systems successfully generated a specific expression product with an apparently uncleaved leader peptide migrating at approximately 26.5 kDa. This source of preflagellin was used to detect the presence of preflagellin peptidase activity in the membranes of M. voltae. In addition to the native flagellin, a hybrid flagellin gene containing the sequence encoding the M. voltae FlaB2 mature protein fused to the P. aeruginosa pilin (PilA) leader peptide was constructed and transformed into both wild-type P. aeruginosa and a prepilin peptidase (pilD) mutant of P. aeruginosa. Based on migration in SDS-PAGE, the leader peptide appeared to be cleaved in the wild-type cells. However, the archaeal flagellin could not be detected by immunoblotting when expressed in the pilD mutant, indicating a role of the peptidase in the ultimate stability of the fusion product. When the +5 position of the mature flagellin portion of the pilin-flagellin fusion was changed from glycine to glutamic acid (as in the P. aeruginosa pilin) and expressed in both wild-type and pilD mutant P. aeruginosa, the product detected by immunoblotting migrated slightly more slowly in the pilD mutant, indicating that the fusion was likely processed by the prepilin peptidase present in the wild type. Potential assembly of the cleaved fusion product by the type IV pilin assembly system in a P. aeruginosa PilA-deficient strain was tested, but no filaments were noted on the cell surface by electron microscopy.     

Effects of bfp mutations on biogenesis of functional enteropathogenic Escherichia coli type IV pili

Enteropathogenic Escherichia coli expresses a type IV fimbria known as the bundle-forming pilus (BFP) that is required for autoaggregation and localized adherence (LA) to host cells. A cluster of 14 genes is sufficient to reconstitute BFP biogenesis in a laboratory strain of E. coli. We have undertaken a systematic mutagenesis of the individual genes to determine the effect of each mutation on BFP biogenesis and LA. Here we report the construction and analysis of nonpolar mutations in six genes of the bfp cluster, bfpG, bfpB, bfpC, bfpD, bfpP, and bfpH, as well as the further analysis of a previously described bfpA mutant strain that is unable to express bundlin, the pilin protein. We found that mutations in bfpB, which encodes an outer membrane protein; bfpD, which encodes a putative nucleotide-binding protein; and bfpG and bfpC, which do not have sequence homologues in other type IV pilus systems, do not affect prebundlin expression or processing but block both BFP biogenesis and LA. The mutation in bfpP, the prepilin peptidase gene, does not affect prebundlin expression but blocks signal sequence cleavage of prebundlin, BFP biogenesis, and LA. The mutation in bfpH, which is predicted to encode a lytic transglycosylase, has no effect on prebundlin expression, prebundlin processing, BFP biogenesis, or LA. For each mutant for which altered phenotypes were detected, complementation with a plasmid containing the corresponding wild-type allele restored the wild-type phenotypes. We also found that association of prebundlin or bundlin with sucrose density flotation gradient fractions containing both inner and outer membrane proteins does not require any accessory proteins. These studies indicate that many bfp gene products are required for biogenesis of functional type IV pili but that mutations in the individual genes do not lead to the identification of new phases of pilus assembly.     

Maturation of IncP pilin precursors resembles the catalytic Dyad-like mechanism of leader peptidases

The pilus subunit, the pilin, of conjugative IncP pili is encoded by the trbC gene. IncP pilin is composed of 78 amino acids forming a ring structure (R. Eisenbrandt, M. Kalkum, E.-M. Lai, C. I. Kado, and E. Lanka, J. Biol. Chem. 274:22548-22555, 1999). Three enzymes are involved in maturation of the pilin: LepB of Escherichia coli for signal peptide removal and a yet-unidentified protease for removal of 27 C-terminal residues. Both enzymes are chromosome encoded. Finally, the inner membrane-associated IncP TraF replaces a four-amino-acid C-terminal peptide with the truncated N terminus, yielding the cyclic polypeptide. We refer to the latter process as "prepilin cyclization." We have used site-directed mutagenesis of trbC and traF to unravel the pilin maturation process. Each of the mutants was analyzed for its phenotypes of prepilin cyclization, pilus formation, donor-specific phage adsorption, and conjugative DNA transfer abilities. Effective prepilin cyclization was determined by matrix-assisted laser desorption-ionization-mass spectrometry using an optimized sample preparation technique of whole cells and trans-3-indolyl acrylic acid as a matrix. We found that several amino acid exchanges in the TrbC core sequence allow prepilin cyclization but disable the succeeding pilus assembly. We propose a mechanism explaining how the signal peptidase homologue TraF attacks a C-terminal section of the TrbC core sequence via an activated serine residue. Rather than cleaving and releasing hydrolyzed peptides, TraF presumably reacts as a peptidyl transferase, involving the N terminus of TrbC in the aminolysis of a postulated TraF-acetyl-TrbC intermediate. Under formal loss of a C-terminal tetrapeptide, a new peptide bond is formed in a concerted action, connecting serine 37 with glycine 114 of TrbC.     

The secretion apparatus of Pseudomonas aeruginosa: identification of a fifth pseudopilin, XcpX (GspK family)

The xcp gene products in Pseudomonas aeruginosa are required for the secretion of proteins across the outer membrane. Four of the Xcp proteins, XcpT, U, V and W, present sequence homology to the subunits of type IV pili at their N-termini, and they were therefore designated pseudopilins. In this study, we characterized the xcpX gene product, a bitopic cytoplasmic membrane protein. Remarkably, amino acid sequence comparisons also suggested that the XcpX protein resembles the pilins and pseudopilins at the N-terminus. We show that XcpX could be processed by the prepilin peptidase, PilD/XcpA, and that the highly conserved glycine residue preceding the hydrophobic segment could not be mutated without loss of the XcpX function. We, therefore, classified XcpX (GspK) as the fifth pseudopilin of the system.     

The TadV protein of Actinobacillus actinomycetemcomitans is a novel aspartic acid prepilin peptidase required for maturation of the Flp1 pilin and TadE and TadF pseudopilins

The tad locus of Actinobacillus actinomycetemcomitans encodes genes for the biogenesis of Flp pili, which allow the bacterium to adhere tenaciously to surfaces and form strong biofilms. Although tad (tight adherence) loci are widespread among bacterial and archaeal species, very little is known about the functions of the individual components of the Tad secretion apparatus. Here we characterize the mechanism by which the pre-Flp1 prepilin is processed to the mature pilus subunit. We demonstrate that the tadV gene encodes a prepilin peptidase that is both necessary and sufficient for proteolytic maturation of Flp1. TadV was also found to be required for maturation of the TadE and TadF pilin-like proteins, which we term pseudopilins. Using site-directed mutagenesis, we show that processing of pre-Flp1, pre-TadE, and pre-TadF is required for biofilm formation. Mutation of a highly conserved glutamic acid residue at position +5 of Flp1, relative to the cleavage site, resulted in a processed pilin that was blocked in assembly. In contrast, identical mutations in TadE or TadF had no effect on biofilm formation, indicating that the mechanisms by which Flp1 pilin and the pseudopilins function are distinct. We also determined that two conserved aspartic acid residues in TadV are critical for function of the prepilin peptidase. Together, our results indicate that the A. actinomycetemcomitans TadV protein is a member of a novel subclass of nonmethylating aspartic acid prepilin peptidases.     

Type II protein secretion by Pseudomonas aeruginosa: genetic suppression of a conditional mutation in the pilin-like component XcpT by the cytoplasmic component XcpR

Pseudomonas aeruginosa exports a number of hydrolytic enzymes and toxins using the type II or general secretion pathway, found in a variety of Gram-negative bacteria and requiring the functions of at least 12 gene products (XcpP–Z and PilD/XcpA in P. aeruginosa ). A number of these gene products are homologues of components of the type IV pilus biogenesis system, including four proteins, XcpT–W, which are highly similar to the pilin subunit in their size, localization and post-translational modifications. These proteins, in addition to the pilin subunit, are cleaved and methylated by the PilD/XcpA prepilin peptidase, but their interactions with other components of the export apparatus are unclear. Using a medium developed for the selection of export-proficient P. aeruginosa strains, we have isolated temperature-sensitive mutations in the xcpT gene and extragenic suppressors for one of the mutants. These suppressors fall into two classes, one that maps outside of the xcpP–Z gene cluster and may define additional cellular functions that are required for export, and a second that maps to the xcpR gene product and indicates a potential protein–protein interaction connecting two different cellular compartments and required for the assembly or function of the export apparatus.     

Type IV-like pili formed by the type II secreton: specificity,composition, bundling,polar localization,and surface presentation of peptides

The secreton or type II secretion machinery of gram-negative bacteria includes several type IV pilin-like proteins (the pseudopilins) that are absolutely required for secretion. We previously reported the presence of a bundled pilus composed of the pseudopilin PulG on the surface of agar-grown Escherichia coli K-12 cells expressing the Klebsiella oxytoca pullulanase (Pul) secreton genes at high levels (N. Sauvonnet, G. Vignon, A. P. Pugsley, and P. Gounon, EMBO J. 19:2221-2228, 2000). We show here that PulG is the only pseudopilin in purified pili and that the phenomenon is not restricted to the Pul secreton reconstituted in E. coli or to PulG. For example, high-level expression of the endogenous E. coli gsp secreton genes caused production of bundled pili composed of the pseudopilin GspG, and the Pul secreton was able to form pili composed of PulG-like proteins from secreton systems of other bacteria. PulG derivatives in which the C terminus was extended by the addition of eight different peptides were also assembled into pili and functioned in secretion. Three of the C-terminal peptides were shown to be exposed along the entire length of the assembled pili. Hence, the C terminus of PulG may represent a permissive site for the insertion of immunogenic epitopes or other peptide sequences. One of these PulG variants, with a six-histidine tag at its C terminus, formed nonpolar, nonbundled pili, suggesting that bundle formation and polar localization are not correlated with the ability of PulG to function in secretion. We propose that the PulG pilus is an artifactual manifestation of a periplasmic "pseudopilus" and that cycles of pseudopilus extension and retraction within the periplasm propel pullulanase through secretin channels in the outer membrane. Abnormally long pili that extend beyond the outer membrane are produced only when pilus length control and retraction are deregulated by overproduction of the major pseudopilus subunit (PulG).