Green fluorescent chimeras indicate nonpolar localization of pullulanase secreton components PulL and PulM

The Klebsiella oxytoca pullulanase secreton (type II secretion system) components PulM and PulL were tagged at their N termini with green fluorescent protein (GFP), and their subcellular location was examined by fluorescence microscopy and fractionation. When produced at moderate levels without other secreton components in Escherichia coli, both chimeras were envelope associated, as are the native proteins. Fluorescent GFP-PulM was evenly distributed over the cell envelope, with occasional brighter foci. Under the same conditions, GFP-PulL was barely detectable in the envelope by fluorescence microscopy. When produced together with all other secreton components, GFP-PulL exhibited circumferential fluorescence, with numerous brighter patches. The envelope-associated fluorescence of GFP-PulL was almost completely abolished when native PulL was also produced, suggesting that the chimera cannot compete with PulL for association with other secreton components. The patches of GFP-PulL might represent functional secretons, since GFP-PulM also appeared in similar patches. GFP-PulM and GFP-PulL both appeared in spherical polar foci when made at high levels. In K. oxytoca, GFP-PulM was evenly distributed over the cell envelope, with few patches, whereas GFP-PulL showed only weak envelope-associated fluorescence. These data suggest that, in contrast to their Vibrio cholerae Eps secreton counterparts (M. Scott, Z. Dossani, and M. Sandkvist, Proc. Natl. Acad. Sci. USA 98:13978-13983, 2001), PulM and PulL do not localize specifically to the cell poles and that the Pul secreton is distributed over the cell surface.     

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).     

Membrane Association and Multimerization of Secreton Component PulC

The PulC component of the Klebsiella oxytoca pullulanase secretion machinery (the secreton) was found by subcellular fractionation to be associated with both the cytoplasmic (inner) and outer membranes. Association with the outer membrane was independent of other secreton components, including the outer membrane protein PulD (secretin). The association of PulC with the inner membrane is mediated by the signal anchor sequence located close to its N terminus. These results suggest that PulC forms a bridge between the two membranes that is disrupted when bacteria are broken open for fractionation. Neither the signal anchor sequence nor the cytoplasmic N-terminal region that precedes it was found to be required for PulC function, indicating that PulC does not undergo sequence-specific interactions with other cytoplasmic membrane proteins. Cross-linking of whole cells resulted in the formation of a ca. 110-kDa band that reacted with PulC-specific serum and whose detection depended on the presence of PulD. However, antibodies against PulD failed to react with this band, suggesting that it could be a homo-PulC trimer whose formation requires PulD. The data are discussed in terms of the possible role of PulC in energy transduction for exoprotein secretion.     

Disulfide bond formation in secreton component PulK provides a possible explanation for the role of DsbA in pullulanase secretion

When expressed in Escherichia coli, the 15 Klebsiella oxytoca pul genes that encode the so-called Pul secreton or type II secretion machinery promote pullulanase secretion and the assembly of one of the secreton components, PulG, into pili. Besides these pul genes, efficient pullulanase secretion also requires the host dsbA gene, encoding a periplasmic disulfide oxidoreductase, independently of disulfide bond formation in pullulanase itself. Two secreton components, the secretin pilot protein PulS and the minor pseudopilin PulK, were each shown to posses an intramolecular disulfide bond whose formation was catalyzed by DsbA. PulS was apparently destabilized by the absence of its disulfide bond, whereas PulK stability was not dramatically affected either by a dsbA mutation or by the removal of one of its cysteines. The pullulanase secretion defect in a dsbA mutant was rectified by overproduction of PulK, indicating reduced disulfide bond formation in PulK as the major cause of the secretion defect under the conditions tested (in which PulS is probably present in considerable excess of requirements). PulG pilus formation was independent of DsbA, probably because PulK is not needed for piliation.     

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.     

Structure and assembly of the pseudopilin PulG

The pseudopilin PulG is one of several essential components of the type II pullulanase secretion machinery (the Pul secreton) of the Gram-negative bacterium Klebsiella oxytoca. The sequence of the N-terminal 25 amino acids of the PulG precursor is hydrophobic and very similar to the corresponding region of type IV pilins. The structure of a truncated PulG (lacking the homologous region), as determined by X-ray crystallography, was found to include part of the long N-terminal alpha-helix and the four internal anti-parallel beta-strands that characterize type IV pilins, but PulG lacks the highly variable loop region with a disulphide bond that is found in the latter. When overproduced, PulG forms flexible pili whose structural features, as visualized by electron microscopy, are similar to those of bacterial type IV pili. The average helical repeat comprises 17 PulG subunits and four helical turns. Electron microscopy and molecular modelling show that PulG probably assembles into left-handed helical pili with the long N-terminal alpha-helix tightly packed in the centre of the pilus. As in the type IV pilins, the hydrophobic N-terminal part of the PulG alpha-helix is necessary for its assembly. Subtle sequence variations within this highly conserved segment seem to determine whether or not a type IV pilin can be assembled into pili by the Pul secreton.     

Pseudopilin residue E5 is essential for recruitment by the type 2 secretion system assembly platform

Type II secretion systems (T2SSs) promote secretion of folded proteins playing important roles in nutrient acquisition, adaptation and virulence of Gram‐negative bacteria. Protein secretion is associated with the assembly of type 4 pilus (T4P)‐like fibres called pseudopili. Initially membrane embedded, pseudopilin and T4 pilin subunits share conserved transmembrane segments containing an invariant Glu residue at the fifth position, E5. Mutations of E5 in major T4 pilins and in PulG, the major pseudopilin of the Klebsiella T2SS abolish fibre assembly and function. Among the four minor pseudopilins, only PulH required E5 for secretion of pullulanase, the substrate of the Pul T2SS. Mass‐spectrometry analysis of pili resulting from the co‐assembly of PulG^E5A variant and PulG^WT ruled out an E5 role in pilin processing and N‐methylation. A bacterial two‐hybrid analysis revealed interactions of the full‐length pseudopilins PulG and PulH with the PulJ‐PulI‐PulK priming complex and with the assembly factors PulM and PulF. Remarkably, PulG^E5A and PulH^E5A variants were defective in interaction with PulM but not with PulF, and co‐purification experiments confirmed the E5‐dependent interaction between native PulM and PulG. These results reveal the role of E5 in a recruitment step critical for assembly of the functional T2SS, likely relevant to T4P assembly systems.     

The general secretory pathway of Klebsiella oxytoca: no evidence for relocalization or assembly of pilin-like PulG protein into a multiprotein complex

It has been proposed that the four type IV pilin-like proteins that are required for extracellular protein secretion by the general secretory pathway (GSP) might assemble into a trans-periplasm complex resembling a type IV pilus. To test this idea, we examined the subcellular distribution and oligomeric state of PulG, one of the type IV pilin-like proteins required for pullulanase secretion in Klebsiella oxytoca. Fractionation of Escherichia coli cells carrying a single copy of each pul gene showed that PulG protein was located in two distinct envelope fractions corresponding to the outer and cytoplasmic membranes. The protein was partially released by treating the membranes with Triton X-100 + EDTA or at high pH, but not by Triton X-100 atone or by 8M urea, 6M guanidine hydrochloride or 1 M NaCl. Like type IV pilins, non-sedimentable PuiG that had been released from the membranes at high pH could be sedimented by centrifugation when the pH was lowered. Treatment of whole cells, sphaeroplasts or isolated membranes with a cleavable cross-linking agent produced mainly PulG homodimers. Previous studies showed that both PulO, which cleaves and N-methylates the PulG precursor, and PulE, a putative ATP-binding protein, share extensive sequence identity with proteins known to be required for type IV pilus processing and assembly. However, mutations which disrupted either pulE or pulO, or indeed the complete absence of all other components of the pullulanase secretion apparatus, had little or no effect on any of the properties of PulG protein described above. We conclude that there is no evidence that PulG protein assembles into a stable multiprotein complex or that processing of the PulG precursor causes a detectable change in its subcellular distribution.     

Protein secretion in gram-negative bacteria: transport across the outer membrane involves common mechanisms in different bacteria.

The xcp genes are required for protein secretion by Pseudomonas aeruginosa. They are involved in the second step of the process, i.e. the translocation across the outer membrane, after the exoproteins have reached the periplasm in a signal peptide dependent fashion. The nucleotide sequence of a 2.5 kb DNA fragment containing xcp genes showed at least two complete open reading frames, potentially encoding proteins with molecular weights of 41 and 19 kd. Products with these apparent molecular weights were identified after expression of the DNA fragment in vitro and in vivo. Subcloning and complementation experiments showed that both proteins are required for secretion. The two products are located in the inner membrane and share highly significant homologies with the PulL and PulM proteins which are required for the specific secretion of pullulanase in Klebsiella pneumoniae. These homologies reveal the existence of a common mechanism for protein secretion in Pseudomonas aeruginosa and Klebsiella pneumoniae.     

Pullulanase secretion in Escherichia coli K-12 requires a cytoplasmic protein and a putative polytopic cytoplasmic membrane protein

The previously uncharacterized third and fourth genes (pulE and pulF) of the pullulanase secretion gene operon of Klebsiella oxytoca strain UNF5023 are, respectively, predicted to encode a 55 kDa polypeptide with a putative nucleotide-binding site, and a highly hydrophobic 44 kDa polypeptide that probably spans the cytoplasmic membrane several times. Expression of pulE in minicells or under the control of a strong bacteriophage T7 promoter resulted in the production of a c. 58 kDa cytoplasmic protein. A representative PulE-beta-galactosidase hybrid protein created by Tnlac mutagenesis was also found mainly in the cytoplasm. These results are in line with the predicted absence from PulE of a region of sufficient hydrophobicity to function as a signal sequence. The PulF polypeptide could not be detected either in minicells or when the gene was transcribed from the T7 promoter, but the acquirement of three pulF-lacZ gene fusions that encoded hybrid proteins with relatively high levels of beta-galactosidase activity indicates that this gene can be transcribed and translated. Gene disruption experiments indicated that both pulE and pulF are required for pullulanase secretion in Escherichia coli K-12. Both proteins exhibit considerable homology throughout their entire lengths with other proteins involved in protein secretion, pilin assembly, conjugation and transformation competence in a variety of bacteria. In addition, PulE protein has consensus sequences found in a wide variety of nucleotide-binding proteins. This study completes the initial characterization of the pullulanase secretion gene operon, which comprises 13 genes that are all essential for the transport of pullulanase across the outer membrane.     

Multimers of the precursor of a type IV pilin-like component of the general secretory pathway are unrelated to pili

Both the mature and precursor forms of PulG, a type IV pilin-like component of the general secretory pathway of Klebsiella oxytoca, can be chemically cross-linked into multimers similar to those obtained by cross-linking the components of type IV pili. To explore the possibility that the PulG precursor could form a pilus-like structure, the PulG sequence was altered in a variety of ways, including (i) replacement of the characteristic hydrophobic region, which is required for the assembly of type IV pilins by the MalE signal peptide, or (ii) fusion of β-lactamase (βlaM) to the C-terminus. Neither of these changes affected multimerization. PulG precursor could be post-translationally processed by pre-pilin peptidase (PulO), indicating that the N-terminus of pre PulG remains on the cytoplasmic side of the cytoplasmic membrane where it is accessible to the catalytic site of this enzyme. Finally, precursor and mature forms of PulG could be efficiently cross-linked in a mixed dimer, indicating that at least a subpopu-lation of the two forms of the protein are probably located in clusters in the cytoplasmic membrane. These results provide further evidence that the cross-linked multimers of the precursor form of PulG are unrelated to type IV pilus-like structures. It is still unclear whether a subpopulation of processed PulG can be assembled into a rudimentary pilus-like structure.     

Protein secretion by gram-negative bacteria. Characterization of two membrane proteins required for pullulanase secretion by Escherichia coli K-12

Pullulanase secretion in Escherichia coli depends on the expression of a MalT-regulated operon called pulC. Characterization of the first two genes of this operon showed that they encode, respectively, a 31,000-Da protein (PulC) and a 70,600-Da protein (PulD) which has a putative signal peptide and that these two proteins are required for pullulanase secretion. The analysis of alkaline phosphatase hybrid proteins generated by TnphoA mutagenesis of pulC and pulD showed that both PulC and PulD contain export signals which can direct the alkaline phosphatase segment of the hybrids across the inner membrane. A representative PulC-PhoA hybrid protein fractionated mainly with the inner membrane upon isopycnic sucrose gradient centrifugation of membrane vesicles. This, together with sequencing data, suggests that PulC is an inner membrane protein. Antibodies raised against a purified PulD-PhoA hybrid protein were used to show that PulD was enriched in low density outer membrane vesicles.     

Identification of XcpP domains that confer functionality and specificity to the Pseudomonas aeruginosa type II secretion apparatus

Gram-negative bacteria have evolved several types of secretion mechanisms to release proteins into the extracellular medium. One such mechanism, the type II secretory system, is a widely conserved two-step process. The first step is the translocation of signal peptide-bearing exoproteins across the inner membrane. The second step, the translocation across the outer membrane, involves the type II secretory apparatus or secreton. The secretons are made up of 12-15 proteins (Gsp) depending on the organism. Even though the systems are conserved, heterologous secretion is mostly species restricted. Moreover, components of the secreton are not systematically exchangeable, especially with distantly related microorganisms. In closely related species, two components, the GspC and GspD (secretin) family members, confer specificity for substrate recognition and/or secreton assembly. We used Pseudomonas aeruginosa as a model organism to determine which domains of XcpP (GspC member) are involved in specificity. By constructing hybrids between XcpP and OutC, the Erwinia chrysanthemi homologue, we identified a region of 35 residues that was not exchangeable. We showed that this region might influence the stability of the XcpYZ secreton subcomplex. Remarkably, XcpP and OutC have domains, coiled-coil and PDZ, respectively, which exhibit the same function but that are structurally different. Those two domains are exchangeable and we provided evidence that they are involved in the formation of homomultimeric complexes of XcpP.     

Signal recognition particle-dependent inner membrane targeting of the PulG Pseudopilin component of a type II secretion system

The pseudopilin PulG is an essential component of the pullulanase-specific type II secretion system from Klebsiella oxytoca. PulG is the major subunit of a short, thin-filament pseudopilus, which presumably elongates and retracts in the periplasm, acting as a dynamic piston to promote pullulanase secretion. It has a signal sequence-like N-terminal segment that, according to studies with green and red fluorescent protein chimeras, anchors unassembled PulG in the inner membrane. We analyzed the early steps of PulG inner membrane targeting and insertion in Escherichia coli derivatives defective in different protein targeting and export factors. The beta-galactosidase activity in strains producing a PulG-LacZ hybrid protein increased substantially when the dsbA, dsbB, or all sec genes tested except secB were compromised by mutations. To facilitate analysis of native PulG membrane insertion, a leader peptidase cleavage site was engineered downstream from the N-terminal transmembrane segment (PrePulG*). Unprocessed PrePulG* was detected in strains carrying mutations in secA, secY, secE, and secD genes, including some novel alleles of secY and secD. Furthermore, depletion of the Ffh component of the signal recognition particle (SRP) completely abolished PrePulG* processing, without affecting the Sec-dependent export of periplasmic MalE and RbsB proteins. Thus, PulG is cotranslationally targeted to the inner membrane Sec translocase by SRP.     

The secretin-specific, chaperone-like protein of the general secretory pathway: separation of proteolytic protection and piloting functions

The chaperone-like protein of the main terminal branch of the general secretory pathway from Klebsiella oxytoca , the outer membrane lipoprotein PulS, protects the multimeric secretin PulD from degradation and promotes its correct localization to the outer membrane. To determine whether these are separable functions, or whether resistance to proteolysis results simply from correct localization of PulD, we replaced the lipoprotein-type signal peptide of PulS by the signal peptide of periplasmic maltose-binding protein. The resulting periplasmic PulS retained its ability to protect PulD, but not its ability to localize PulD to the outer membrane and to function in pullulanase secretion. Periplasmic PulS competed with wild-type PulS to prevent pullulanase secretion, presumably again by causing mislocalization of PulD. A hybrid protein comprising the mature part of PulS fused to the C-terminus of full-length maltose-binding protein (MalE–PulS) had similar properties to the periplasmic PulS protein. Moreover, MalE–PulS was shown to associate with PulD by amylose-affinity chromatography. The MalE–PulS hybrid was rendered completely functional (i.e. it restored pullulanase secretion in a pulS mutant) by replacing its signal peptide with a lipoprotein-type signal peptide. However, this fatty-acylated hybrid protein was only functional if it also carried a lipoprotein sorting signal that targeted it to the outer membrane. Thus, the two functions of PulS are separate and fully dissociable. Incorrect localization, rather than proteolysis, of PulD in the absence of PulS was shown to be the factor that causes high-level induction of the phage shock response. The Erwinia chrysanthemi PulS homologue, OutS, can substitute for PulS, and PulS can protect the secretin OutD from proteolysis in Escherichia coli , indicating the possible existence of a family of PulS-like chaperone proteins.     

The conserved tetracysteine motif in the general secretory pathway component PulE is required for efficient pullulanase secretion

The PulE component of the pullulanase secretion pathway, a typical main terminal branch of the general secretory pathway, has a tetracysteine motif (4Cys) that is also present in almost all of the many PulE homologues, including those involved in type-IV piliation and conjugal DNA transfer. The 4Cys resembles a zinc-binding motif found in other proteins such as adenylate kinases, which may be pertinent in view of the fact that PulE has a consensus ATP-binding motif and since at least one PulE homologue has been reported to have kinase activity. In PulE, the Cys residues of this motif form scrambled intra- and intermolecular disulfide bonds when cells are disrupted. Replacement of one or more Cys of this motif by Ser reduces PulE function, but at least two adjacent Cys must be replaced to prevent intramolecular disulfide bond formation.     

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.     

Insertion of an outer membrane protein in Escherichia coli requires a chaperone-like protein.

Only one of the characterized components of the main terminal branch of the general secretory pathway (GSP) in Gram-negative bacteria, GspD, is an integral outer membrane protein that could conceivably form a channel to permit protein transport across this membrane. PulD, a member of the GspD protein family required for pullulanase secretion by Klebsiella oxytoca, is shown here to form outer membrane-associated complexes which are not readily dissociated by SDS treatment. The outer membrane association of PulD is absolutely dependent on another component of the GSP, the outer membrane-anchored lipoprotein PulS. Furthermore, the absence of PulS resulted in limited proteolysis of PulD and caused induction of the so-called phage shock response, as measured by increased expression of the pspA gene. We propose that PulS may be the first member of a new family of periplasmic chaperones that are specifically required for the insertion of a group of outer membrane proteins into this membrane. PulS is only the second component of the main terminal branch of the GSP for which a precise function can be proposed.     

Minor pseudopilin self-assembly primes type II secretion pseudopilus elongation

In Gram-negative bacteria, type II secretion systems (T2SS) assemble inner membrane proteins of the major pseudopilin PulG (GspG) family into periplasmic filaments, which could drive protein secretion in a piston-like manner. Three minor pseudopilins PulI, PulJ and PulK are essential for protein secretion in the Klebsiella oxytoca T2SS, but their molecular function is unknown. Here, we demonstrate that together these proteins prime pseudopilus assembly, without actively controlling its length or secretin channel opening. Using molecular dynamics, bacterial two-hybrid assays, cysteine crosslinking and functional analysis, we show that PulI and PulJ nucleate filament assembly by forming a staggered complex in the plasma membrane. Binding of PulK to this complex results in its partial extraction from the membrane and in a 1-nm shift between their transmembrane segments, equivalent to the major pseudopilin register in the assembled PulG filament. This promotes fully efficient pseudopilus assembly and protein secretion. Therefore, we propose that PulI, PulJ and PulK self-assembly is thermodynamically coupled to the initiation of pseudopilus assembly, possibly setting the assembly machinery in motion.     

<Superscript>1</Superscript>H, <Superscript>15</Superscript>N and <Superscript>13</Superscript>C resonance assignments and secondary structure of PulG,the major pseudopilin from <Emphasis Type="Italic">Klebsiella oxytoca</Emphasis> type 2 secretion system

Bacteria use complex transporters to secrete functionally relevant proteins to the extracellular medium. The type 2 secretion system (T2SS) translocates folded proteins involved in bacterial nutrient acquisition, virulence and adaptation. The T2SS pseudopilus is a periplasmic filament, assembled by the polymerization of PulG subunits, the major pseudopilin. Pseudopilin proteins have a conserved N-terminal hydrophobic segment followed by a more variable C-terminal periplasmic and globular domain. To better understand the mechanism of assembly and function of the T2SS, we have been studying the structure and dynamics of PulG by NMR, as well as its interaction with other components of the secretion machinery. As a first step on this study, here we reported the chemical shift assignments of PulG C-terminal domain and its secondary structure prediction based on NMR data.