Conjugative pili of IncP plasmids, and the Ti plasmid T pilus are composed of cyclic subunits.

TrbC propilin is the precursor of the pilin subunit TrbC of IncP conjugative pili in Escherichia coli. Likewise, its homologue, VirB2 propilin, is processed into T pilin of the Ti plasmid T pilus in Agrobacterium tumefaciens. TrbC and VirB2 propilin are truncated post-translationally at the N terminus by the removal of a 36/47-residue leader peptide, respectively. TrbC propilin undergoes a second processing step by the removal of 27 residues at the C terminus by host-encoded functions followed by the excision of four additional C-terminal residues by a plasmid-borne serine protease. The final product TrbC of 78 residues is cyclized via an intramolecular covalent head-to-tail peptide bond. The T pilin does not undergo additional truncation but is likewise cyclized. The circular structures of these pilins, as verified by mass spectrometry, represent novel primary configurations that conform and assemble into the conjugative apparatus.     

Membrane location of the Ti plasmid VirB proteins involved in the biosynthesis of a pilin-like conjugative structure on Agrobacterium tumefaciens

Abstract The virB operon of the Agrobacterium tumefaciens Ti plasmid encodes 11 proteins. Specific antisera to VirB2, VirB3 and VirB9 were used to locate these virulence proteins in the A. tumefaciens cell. Immunoblot analysis located VirB2 protein to the inner and outer membranes; VirB3 and VirB9 were likewise associated with both membranes, but mainly in the outer membrane. VirB2 is processed from a 12.3-kDa protein into a 7.2-kDa polypeptide. Such sized protein results from cleavage at residue Ala⁴⁷, upstream of which two additional alanine residues Ala⁴⁵-Ala⁴⁶ are contained and bearing resemblance to a signal peptide peptidase-I cleavage sequence. VirB2 and VirB3 sequences are strikingly similar to the pilin biosynthetic proteins TraA and TraL encoded by the tra operon of F and R1-19 plasmids. Since traA encodes a propilin that is cleaved into a 7.2-kDa conjugative pilin product and since this cleavage site is present in both TraA and VirB2, we propose that virB2 encodes a pilin-like protein which together with VirB3 and VirB9 as well as other VirB proteins may be used for interkingdom T-DNA transfer between bacteria and plants.     

VirB2 is a processed pilin-like protein encoded by the Agrobacterium tumefaciens Ti plasmid.

The mechanism of DNA transmission between distinct organisms has remained a subject of long-standing interest. Agrobacterium tumefaciens mediates the transfer of plant oncogenes in the form of a 25-kb T-DNA sector of a resident Ti plasmid. A growing body of evidence leading to the elucidation of the mechanism involved in T-DNA transfer comes from studies on the vir genes contained in six major operons that are required for the T-DNA transfer process. Recent comparative amino acid sequence studies of the products of these vir genes have revealed interesting similarities between Tra proteins of Escherichia coli F factor, which are involved in the biosynthesis and assembly of a conjugative pilus, and VirB proteins encoded by genes of the virB operon of A. tumefaciens pTiC58. We have previously identified VirB2 as a pilin-like protein with processing features similar to those of TraA of the F plasmid and have shown that VirB2 is required for the biosynthesis of pilin on a flagella-free Agrobacterium strain. In the present work, VirB2 is found to be processed and localized primarily to the cytoplasmic membrane in E. coli. Cleavage of VirB2 was predicted previously to occur between alanine and glutamine in the sequence -Pro-Ala-Ala-Ala-Glu-Ser-. This peptidase cleavage sequence was mutated by an amino acid substitution for one of the alanine residues (D for A at position 45 [A45D]), by deletion of the three adjacent alanines, and by a frameshift mutation 22 bp upstream of the predicted Ala-Glu cleavage site. With the exception of the frameshift mutation, the alanine mutations do not prevent VirB2 processing in E. coli, while in A. tumefaciens they result in VirB2 instability, since no holo- or processed protein is detectable. All of the above mutations abolish virulence. The frameshift mutation abolishes processing in both organisms. These results indicate that VirB2 is processed into a 7.2-kDa structural protein. The cleavage site in E. coli appears to differ from that predicted in A. tumefaciens. Yet, the cleavage sites are relatively close to each other since the final cleavage products are similar in size and are produced irrespective of the length of the amino-terminal portion of the holoprotein. As we observed previously, the similarity between the processing of VirB2 in A. tumefaciens and the processing of the propilin TraA of the F plasmid now extends to E. coli.     

Processed VirB2 Is the Major Subunit of the Promiscuous Pilus of Agrobacterium tumefaciens

Previous studies have implicated the obligatory requirement for the vir regulon (or “virulon”) of the Ti plasmid for the transfer of oncogenes from Agrobacterium tumefaciens to plant cells. The machinery used in this horizontal gene transfer has been long thought to be a transformation or conjugative delivery system. Based on recent protein sequence comparisons, the proteins encoded by the virB operon are strikingly similar to proteins involved in the synthesis and assembly of conjugative pili such as the conjugative pilus of F plasmid in Escherichia coli. The F pilus is composed of TraA pilin subunits derived from TraA propilin. In the present study, evidence is provided showing that the counterpart of TraA is VirB2, which like TraA propilin is processed into a 7.2-kDa product that comprises the pilus subunit as demonstrated by biochemical and electron microscopic analyses. The processed VirB2 protein is present exocellularly on medium on which induced A. tumefaciens had grown and appears as thin filaments of 10 nm that react specifically to VirB2 antibody. Exocellular VirB2 is produced abundantly at 19°C as compared with 28°C, an observation that parallels the effect of low temperature on the production of vir gene-specific pili observed previously (K. J. Fullner, L. C. Lara, and E. W. Nester, Science 273:1107–1109, 1996). Export of the processed VirB2 requires other virB genes since mutations in these genes cause the loss of VirB2 pilus formation and result in processed VirB2 accumulation in the cell. The presence of exocellular processed VirB2 is directly correlated with the formation of pili, and it appears as the major protein in the purified pilus preparation. The evidence provides a compelling argument for VirB2 as the propilin whose 7.2-kDa processed product is the pilin subunit of the promiscuous conjugative pilus, hereafter called the “T pilus” of A. tumefaciens.     

VirB7 lipoprotein is exocellular and associates with the Agrobacterium tumefaciens T pilus

Agrobacterium tumefaciens transfers oncogenic T-DNA and effector proteins to plant cells via a type IV secretion pathway. This transfer system, assembled from the products of the virB operon, is thought to consist of a transenvelope mating channel and the T pilus. When screened for the presence of VirB and VirE proteins, material sheared from the cell surface of octopine strain A348 was seen to possess detectable levels of VirB2 pilin, VirB5, and the VirB7 outer membrane lipoprotein. Material sheared from the cell surface of most virB gene deletion mutants also possessed VirB7, but not VirB2 or VirB5. During purification of the T pilus from wild-type cells, VirB2, VirB5, and VirB7 cofractionated through successive steps of gel filtration chromatography and sucrose density gradient centrifugation. A complex containing VirB2 and VirB7 was precipitated from a gel filtration fraction enriched for T pilus with both anti-VirB2 and anti-VirB7 antiserum. Both the exocellular and cellular forms of VirB7 migrated as disulfide-cross-linked dimers and monomers when samples were electrophoresed under nonreducing conditions. A mutant synthesizing VirB7 with a Ser substitution of the lipid-modified Cys15 residue failed to elaborate the T pilus, whereas a mutant synthesizing VirB7 with a Ser substitution for the disulfide-reactive Cys24 residue produced very low levels of T pilus. Together, these findings establish that the VirB7 lipoprotein localizes exocellularly, it associates with the T pilus, and both VirB7 lipid modification and disulfide cross-linking are important for T-pilus assembly. T-pilus-associated VirB2 migrated in nonreducing gels as a monomer and a disulfide-cross-linked homodimer, whereas cellular VirB2 migrated as a monomer. A strain synthesizing a VirB2 mutant with a Ser substitution for the reactive Cys64 residue elaborated T pilus but exhibited an attenuated virulence phenotype. Dithiothreitol-treated T pilus composed of native VirB2 pilin and untreated T pilus composed of the VirB2C64S mutant pilin distributed in sucrose gradients more predominantly in regions of lower sucrose density than untreated, native T pili. These findings indicate that intermolecular cross-linking of pilin monomers is not required for T-pilus production, but cross-linking does contribute to T-pilus stabilization.     

Role of the propilin leader peptide in the maturation of F pilin.

F-pilin maturation and translocation result in the cleavage of a 51-amino-acid leader sequence from propilin and require LepB and TraQ but not the SecA-SecY secretion pathway. The unusual propilin leader peptide and the dependence of its cleavage on TraQ suggested that TraQ recognition may be specific for the leader peptide. An in vitro propilin cleavage assay yielded propilin (13 kDa), the pilin polypeptide (7 kDa), and a 5.5-kDa protein as the traA products. The 5.5-kDa protein comigrates with the full-length 51-amino-acid leader peptide, and [14C]proline labeling confirmed its identity since the only proline residues of propilin are found within the leader peptide. The in vitro and in vivo propilin-processing reactions proceed similarly in a single polypeptide cleavage step. Furthermore, TraQ dependence is a property of F-pilin maturation specifically rather than a property of the leader peptide. A propilin derivative with an amino-terminal signal sequence generated by deleting codons 2 to 28 required TraQ for processing in vivo. On the other hand, a chimeric protein with the propilin wild-type leader peptide fused to the mature portion of beta-lactamase was processed in a TraQ-independent manner. Thus, despite its unusual length, the propilin leader peptide seems to perform a function similar to that of the typical amino-terminal signal sequence. This work suggests that TraQ is not necessary for the proteolysis of propilin and therefore is likely to act as a chaperone-like protein that promotes the translocation of propilin.     

Promiscuous DNA transfer system of Agrobacterium tumefaciens: role of the virB operon in sex pilus assembly and synthesis

Conjugative transfer of DNA that occurs between bacteria also operates between bacteria and higher organisms. The transfer of DNA between Gram-negative bacteria requires initial contact by a sex pilus followed by DNA traversing four membranes (donor plus recipient) using a transmembrane pore. Accumulating evidence suggests that transfer of the T-DNA from Agrobacterium tumefaciens to plants may also occur via a conjugative mechanism. The virB operon of the Ti plasmid exhibits close homologies to genes that are known to encode the pilin subunits and pilin assembly proteins. The proteins encoded by the PilW operon of IncW plasmid R388 share strong similarities (average similarity=50.8%) with VirB proteins. Similarly, the TraA, TraL and TraC proteins of IncF plasmid F have similarities to VirB2, VirB3 and VirB4 respectively (average similarity = 45.3%). VirB2 protein (12.3 kDa) contains a signal peptidase-I cleavage sequence that generates a polypeptide of 7.2 kDa. Likewise, the 12.8 kDa propilin protein TraA of plasmid F also possesses a peptidase-I cleavage site that generates the 7.2 kDa pilin structural protein. Similar amino acid sequences of the conjugative transfer genes of F, R388 as well as plasmid RP4 and the genes of the ptl operon of Bortedella pertussis suggest the existence of a superfamily of transmembrane proteins adapted to the promiscuous transfer of DNA-protein complexes.     

Characterization of the pilin ortholog of the Helicobacter pylori type IV cag pathogenicity apparatus, a surface-associated protein expressed during infection

The Helicobacter pylori cag pathogenicity island (cag PAI) encodes components of a type IV secretion system (T4SS) involved in host interaction and pathogenicity. Previously, seven cag PAI proteins were identified as homologs of Agrobacterium tumefaciens Vir proteins, which form a paradigm T4SS. The T pilus composed of the processed VirB2 pilin is an external structural part of the A. tumefaciens T4SS. In H. pylori, cag-dependent assembly of pili has not been observed so far, nor has a pilin (VirB2) ortholog been characterized. We have here identified, using a motif-based search, an H. pylori cag island protein (HP0546) that possesses sequence and predicted structural similarities to VirB2-like pilins of other T4SSs. The HP0546 protein displays interstrain variability in its terminal domains. HP0546 was expressed as a FLAG-tagged fusion protein in Escherichia coli, A. tumefaciens, and H. pylori and was detected as either two or three bands of different molecular masses in the insoluble fraction, indicating protein processing. As reported previously, isogenic H. pylori mutants in the putative cag pilin gene had reduced abilities to induce cag PAI-dependent interleukin-8 secretion in gastric epithelial cells. Fractionation analysis of H. pylori, using a specific antiserum raised against an N-terminal HP0546 peptide, showed that the protein is partially surface exposed and that its surface localization depended upon an intact cag system. By immunoelectron microscopy, HP0546 was localized in surface appendages, with surface exposure of an N-terminal epitope. Pronounced strain-to-strain variability of this predicted surface-exposed part of HP0546 indicates a strong selective pressure for variation in vivo.     

VirB6 is required for stabilization of VirB5 and VirB3 and formation of VirB7 homodimers in Agrobacterium tumefaciens

VirB6 from Agrobacterium tumefaciens is an essential component of the type IV secretion machinery for T pilus formation and genetic transformation of plants. Due to its predicted topology as a polytopic inner membrane protein, it was proposed to form the transport pore for cell-to-cell transfer of genetic material and proteinaceous virulence factors. Here, we show that the absence of VirB6 leads to reduced cellular levels of VirB5 and VirB3, which were proposed to assist T pilus formation as minor component(s) or assembly factor(s), respectively. Overexpression of virB6 in trans restored levels of cell-bound and T pilus-associated VirB5 to wild type but did not restore VirB3 levels. Thus, VirB6 has a stabilizing effect on VirB5 accumulation, thereby regulating T pilus assembly. In the absence of VirB6, cell-bound VirB7 monomers and VirB7-VirB9 heterodimers were reduced and VirB7 homodimer formation was abolished. This effect could not be restored by expression of VirB6 in trans. Expression of TraD, a component of the transfer machinery of the IncN plasmid pKM101, with significant sequence similarity to VirB6, restored neither protein levels nor bacterial virulence but partly permitted T pilus formation in a virB6 deletion strain. VirB6 may therefore regulate T pilus formation by direct interaction with VirB5, and wild-type levels of VirB3 and VirB7 homodimers are not required.     

Vir proteins stabilize VirB5 and mediate its association with the T pilus of Agrobacterium tumefaciens

Three VirB proteins (VirB1*, VirB2, and VirB5) have been implicated as putative components of the T pilus from Agrobacterium tumefaciens, which likely mediates binding to plant cells followed by transfer of genetic material. Recently, VirB2 was indeed shown to be its major component (E.-M. Lai and C. I. Kado, J. Bacteriol. 180:2711-2717, 1998). Here, the influence of other Vir proteins on the stability and cellular localization of VirB1*, VirB2, and VirB5 was analyzed. Solubility of VirB1* and membrane association of VirB2 proved to be inherent features of these proteins, independent of virulence gene induction. In contrast, cellular levels of VirB5 were strongly reduced in the absence of other Vir proteins, indicating its stabilization by protein-protein interactions. The assembly and composition of the T pilus were analyzed in nopaline strain C58(pTiC58), its flagellum-free derivative NT1REB(pJK270), and octopine strain A348(pTiA6) following optimized virulence gene induction on solid agar medium. In all strains VirB2 was the major pilus component and VirB5 cofractionated during several purification steps, such as ultracentrifugation, gel filtration, and sucrose gradient centrifugation. VirB5 may therefore be directly involved in pilus assembly, possibly as minor component. In contrast, secreted VirB1* showed no association with the T pilus. In-frame deletions in genes virB1, virB2, virB5, and virB6 blocked the formation of virulence gene-dependent extracellular high-molecular-weight structures. Thus, an intact VirB machinery as well as VirB2 and VirB5 are required for T-pilus formation.     

CsiA is a bacterial cell wall synthesis inhibitor contributing to DNA translocation through the cell envelope

Agrobacterium tumefaciens VirB10 couples inner membrane (IM) ATP energy consumption to substrate transfer through the VirB/D4 type IV secretion (T4S) channel and also mediates biogenesis of the virB -encoded T pilus. Here, we determined the functional importance of VirB10 domains denoted as the: (i) N-terminal cytoplasmic region, (ii) transmembrane (TM) α-helix, (iii) proline-rich region (PRR) and (iv) C-terminal β-barrel domain. Mutations conferring a transfer- and pilus-minus (Tra^-, Pil^-) phenotype included PRR deletion and β-barrel substitution mutations that prevented VirB10 interaction with the outer membrane (OM) VirB7–VirB9 channel complex. Mutations permissive for substrate transfer but blocking pilus production (Tra⁺, Pil^-) included a cytoplasmic domain deletion and TM domain insertion mutations. Another class of Tra⁺ mutations also selectively disrupted pilus biogenesis but caused release of pilin monomers to the milieu; these mutations included deletions of α-helical projections extending from the β-barrel domain. Our findings, together with results of Cys accessibility studies, indicate that VirB10 stably integrates into the IM, extends via its PRR across the periplasm, and interacts via its β-barrel domain with the VirB7–VirB9 channel complex. The data further support a model that distinct domains of VirB10 regulate formation of the secretion channel or the T pilus.     

Elevated temperature differentially affects virulence, VirB protein accumulation, and T-pilus formation in different Agrobacterium tumefaciens and Agrobacterium vitis strains.

That gene transfer to plant cells is a temperature-sensitive process has been known for more than 50 years. Previous work indicated that this sensitivity results from the inability to assemble a functional T pilus required for T-DNA and protein transfer to recipient cells. The studies reported here extend these observations and more clearly define the molecular basis of this assembly and transfer defect. T-pilus assembly and virulence protein accumulation were monitored in Agrobacterium tumefaciens strain C58 at different temperatures ranging from 20 degrees C to growth-inhibitory 37 degrees C. Incubation at 28 degrees C but not at 26 degrees C strongly inhibited extracellular assembly of the major T-pilus component VirB2 as well as of pilus-associated protein VirB5, and the highest amounts of T pili were detected at 20 degrees C. Analysis of temperature effects on the cell-bound virulence machinery revealed three classes of virulence proteins. Whereas class I proteins (VirB2, VirB7, VirB9, and VirB10) were readily detected at 28 degrees C, class II proteins (VirB1, VirB4, VirB5, VirB6, VirB8, VirB11, VirD2, and VirE2) were only detected after cell growth below 26 degrees C. Significant levels of class III proteins (VirB3 and VirD4) were only detected at 20 degrees C and not at higher temperatures. Shift of virulence-induced agrobacteria from 20 to 28 or 37 degrees C had no immediate effect on cell-bound T pili or on stability of most virulence proteins. However, the temperature shift caused a rapid decrease in the amount of cell-bound VirB3 and VirD4, and VirB4 and VirB11 levels decreased next. To assess whether destabilization of virulence proteins constitutes a general phenomenon, levels of virulence proteins and of extracellular T pili were monitored in different A. tumefaciens and Agrobacterium vitis strains grown at 20 and 28 degrees C. Levels of many virulence proteins were strongly reduced at 28 degrees C compared to 20 degrees C, and T-pilus assembly did not occur in all strains except "temperature-resistant" Ach5 and Chry5. Virulence protein levels correlated well with bacterial virulence at elevated temperature, suggesting that degradation of a limited set of virulence proteins accounts for the temperature sensitivity of gene transfer to plants.     

The product of the virB4 gene of Agrobacterium tumefaciens promotes accumulation of VirB3 protein.

The process of T-DNA transfer from Agrobacterium tumefaciens to plant cells is thought to involve passage of a DNA-protein complex through a specialized structure in the bacterial membrane. The virB operon of A. tumefaciens encodes 11 proteins, of which 9 are known to be located in the membranes and 10 have been shown to be essential for virulence. Sequence comparisons between proteins encoded by the virB operon and those encoded by operons from conjugative plasmids indicated that VirB proteins may form a structure similar to a conjugative pilus. Here, we examine the effects of mutations in virB4 on the accumulation and localization of other VirB proteins. VirB4 shares amino acid sequence similarity with the TraC protein of plasmid F, which is essential for pilus formation in Escherichia coli, and with the PtlC protein of Bordetella pertussis, which is required for toxin secretion. Polar and nonpolar virB4 mutants were examined, and all were shown to be unable to accumulate VirB3 protein to wild-type levels. A low level of VirB3 protein which was present in induced NT1RE cells harboring virB4 nonpolar mutant pBM1130 was found to associate with the inner membrane fraction only, whereas in wild-type cells VirB3 associated with both inner and outer membranes. The results indicate that for VirB3 to accumulate in the outer membrane, VirB4 must also be present, and it is possible that one role of VirB4 is in the correct assembly of a VirB protein membrane structure.     

Agrobacterium tumefaciens VirB9, an outer-membrane-associated component of a type IV secretion system, regulates substrate selection and T-pilus biogenesis

Agrobacterium tumefaciens translocates DNA and protein substrates between cells via a type IV secretion system (T4SS) whose channel subunits include the VirD4 coupling protein, VirB11 ATPase, VirB6, VirB8, VirB2, and VirB9. In this study, we used linker insertion mutagenesis to characterize the contribution of the outer-membrane-associated VirB9 to assembly and function of the VirB/D4 T4SS. Twenty-five dipeptide insertion mutations were classified as permissive for intercellular substrate transfer (Tra+), completely transfer defective (Tra-), or substrate discriminating, e.g., selectively permissive for transfer only of the oncogenic transfer DNA and the VirE2 protein substrates or of a mobilizable IncQ plasmid substrate. Mutations inhibiting transfer of DNA substrates did not affect formation of close contacts of the substrate with inner membrane channel subunits but blocked formation of contacts with the VirB2 and VirB9 channel subunits, which is indicative of a defect in assembly or function of the distal portion of the secretion channel. Several mutations in the N- and C-terminal regions disrupted VirB9 complex formation with the outer-membrane-associated lipoprotein VirB7 or the inner membrane energy sensor VirB10. Several VirB9.i2-producing Tra+ strains failed to elaborate T pilus at detectable levels (Pil-), and three such Tra+ Pil- mutant strains were rendered Tra- upon deletion of virB2, indicating that the cellular form of pilin protein is essential for substrate translocation. Our findings, together with computer-based analyses, support a model in which distinct domains of VirB9 contribute to substrate selection and translocation, establishment of channel subunit contacts, and T-pilus biogenesis.     

Membrane insertion of the F-pilin subunit is Sec independent but requires leader peptidase B and the proton motive force.

F pilin is the subunit required for the assembly of conjugative pili on the cell surface of Escherichia coli carrying the F plasmid. Maturation of the F-pilin precursor, propilin, involves three F plasmid transfer products: TraA, the propilin precursor; TraQ, which promotes efficient propilin processing; and TraX, which is required for acetylation of the amino terminus of the 7-kDa pilin polypeptide. The mature pilin begins at amino acid 52 of the TraA propilin sequence. We performed experiments to determine the involvement of host cell factors in propilin maturation. At the nonpermissive temperature in a LepBts (leader peptidase B) host, propilin processing was inhibited. Furthermore, under these conditions, only full-length precursor was observed, suggesting that LepB is responsible for the removal of the entire propilin leader peptide. Using propilin processing as a measure of propilin insertion into the plasma membrane, we found that inhibition or depletion of SecA and SecY does not affect propilin maturation. Addition of a general membrane perturbant such as ethanol also had no effect. However, dissipation of the proton motive force did cause a marked inhibition of propilin processing, indicating that membrane insertion requires this energy source. We propose that propilin insertion in the plasma membrane proceeds independently of the SecA-SecY secretion machinery but requires the proton motive force. These results present a model whereby propilin insertion leads to processing by leader peptidase B to generate the 7-kDa peptide, which is then acetylated in the presence of TraX.     

Evidence for VirB4-Mediated Dislocation of Membrane-Integrated VirB2 Pilin during Biogenesis of the Agrobacterium VirB/VirD4 Type IV Secretion System

Agrobacterium VirB2 pilin is required for assembly of the VirB/VirD4 type IV secretion system (T4SS). The propilin is processed by signal sequence cleavage and covalent linkage of the N and C termini, and the cyclized pilin integrates into the inner membrane (IM) as a pool for assembly of the secretion channel and T pilus. Here, by use of the substituted cysteine accessibility method (SCAM), we defined the VirB2 IM topology and then identified distinct contributions of the T4SS ATPase subunits to the pilin structural organization. Labeling patterns of Cys-substituted pilins exposed to the membrane-impermeative, thiol-reactive reagent 3-(N-maleimidopropionyl)biocytin (MPB) supported a topology model in which two hydrophobic stretches comprise transmembrane domains, an intervening hydrophilic loop (residues 90 to 94) is cytoplasmic, and the hydrophilic N and C termini joined at residues 48 and 121 form a periplasmic loop. Interestingly, the VirB4 ATPase, but not a Walker A nucleoside triphosphate (NTP) binding motif mutant, induced (i) MPB labeling of Cys94, a residue that in the absence of the ATPase is located in the cytoplasmic loop, and (ii) release of pilin from the IM upon osmotic shock. These findings, coupled with evidence for VirB2-VirB4 complex formation by coimmunoprecipitation, support a model in which VirB4 functions as a dislocation motor to extract pilins from the IM during T4SS biogenesis. The VirB11 ATPase functioned together with VirB4 to induce a structural change in the pilin that was detectable by MPB labeling, suggestive of a role for VirB11 as a modulator of VirB4 dislocase activity.The Agrobacterium tumefaciens VirB/VirD4 type IV secretion system (T4SS) delivers effector proteins and DNA to plant cells during infection (1, 14). The 11 VirB proteins and VirD4 substrate receptor mediate assembly of the envelope-spanning translocation channel, whereas the VirB proteins independently of VirD4 are required for polymerization of the extracellular T pilus (6, 32, 46). These T4SS subunits include the three ATPases VirD4, VirB4, and VirB11; a trans-envelope core complex comprised of VirB7, VirB9, and VirB10; subunits involved in assembly or spatial positioning of the core complex (VirB1, VirB6, and VirB8); and other structural components (VirB2 pilin, VirB3, and pilus-associated VirB5) (1, 14, 43, 48, 55, 70). The VirB/VirD4 subunits are conserved among many Gram-negative bacterial T4SSs, and recent structures of homologs of VirD4, VirB5, VirB8, VirB10, and VirB11 and a VirB7/VirB9/VirB10 machine subassembly are supplying exciting new information about T4SS machine architectures (11, 28, 29).The pilin subunit VirB2 is a component of both the secretion channel and T pilus (39, 47, 48). Its role in substrate transfer was established with a modified chromatin immunoprecipitation (ChIP) assay termed transfer DNA (T-DNA) immunoprecipitation (TrIP), wherein the pilin (but not the T pilus) was shown to form formaldehyde-cross-linkable contacts with the translocating T-DNA substrate (10). TrIP studies with virB mutant strains also supplied evidence that VirB2 occupies a distal portion of the translocation channel near or at the outer membrane (OM) (10). Complementary genetic studies identified mutations in several VirB subunits, including VirB6, VirB9, VirB10, and VirB11, that selectively block T pilus production without affecting substrate transfer (39, 40, 41, 62). These Tra⁺ Pil⁻ “uncoupling” mutations do not bypass the requirement for VirB2 production for substrate transfer, as the further deletion of virB2 from the Tra⁺ Pil⁻ mutant strains renders these strains transfer defective (39, 41, 62). Therefore, VirB2 pilin, but not an intact T pilus, is required for passage of substrates to target cells.The pathways culminating in the integration of VirB2 into the two terminal organelles, the secretion channel and T pilus, are fundamentally poorly understood. The early VirB protein-independent reactions involve insertion of the 12.3-kDa propilin into the inner membrane (IM); cleavage of a long, 47-residue signal sequence, presumably by LepB signal peptidase; and covalent joining of the N-terminal Gln48 and C-terminal Ser121 to form the mature, cyclic pilin (24). This unusual head-to-tail cyclization reaction was also shown for the VirB2 homolog, TrbC (24/51% sequence identity/similarity) of plasmid RP4 (24, 34, 44). Other VirB2 homologs, such as F plasmid TraA (19/47% identity/similarity) (67), remain linear although their N termini are modified by N acetylation (54).Prevailing models suggest that mature forms of conjugative pilins accumulate in the IM as pools for use in assembly of the channel/pilus upon receipt of an unknown morphogenetic signal(s). The IM-integrated VirB2, TraA_F, and TrbC_RP4 pilins likely adopt similar topologies, as deduced from similar predicted secondary structures and results of reporter fusion studies with periplasmically active alkaline phosphatase (PhoA) (5, 22, 56). Two hydrophobic domains are thought to orient across the IM so that a small, intervening hydrophilic loop is cytoplasmic and the hydrophilic N and C termini are periplasmic. Detailed studies confirming this overall topology are lacking, and limited information exists regarding the nature of pilin interactions with other T4SS subunits (36, 51). Furthermore, little is known about the mechanism or energetic requirements for dislocation of membrane-integrated forms of conjugative pilins during machine morphogenesis.In A. tumefaciens, mutations in the Walker A nucleoside triphosphate (NTP) binding site motifs of the VirB4 and VirB11 ATPases render cells defective for substrate transfer and pilus production, indicating that NTP energy consumption by both ATPases is essential for assembly of the two terminal organelles (6, 7, 58, 62, 68). VirB4-like subunits are signatures of all T4SSs described to date, whereas VirB11-like proteins are common but not ubiquitous among the T4SSs (1). Some T4SSs, such as the conjugation machines encoded by Escherichia coli F-like plasmids, lack VirB11 homologs, and yet their conjugative pili extend and retract dynamically by a mechanism(s) dependent on VirB4 homologs (18, 65). On the basis of these observations, it is reasonable to propose that the VirB4-like subunits catalyze early reactions associated with assembly of conjugative pili.Here, we used the scanning cysteine accessibility method (SCAM) (9) to define the IM topology of cyclized VirB2. We then assayed for contributions of VirB subunits to the pilin structural organization. We present biochemical evidence for VirB4-mediated dislocation of VirB2 pilin from the membrane and also for a contribution by VirB11 in modulating pilin tertiary or quaternary structure. We discuss our findings in the context of recent advances in our understanding of T4SS machine assembly and architecture.     

VirB2 and VirB5 proteins: specialized adhesins in bacterial type-IV secretion systems?

Many type-IV secretion systems (T4SSs) of plant and human pathogens assemble a pilus used to inject virulence molecules (effectors) into host target cells. The T4SS of Agrobacterium tumefaciens consists of VirB1-VirB11 and VirD4 proteins. Whether targeting of T4SSs to the host requires a T4SS-adhesin that specifically engages host receptors for delivery of effectors has, until recently, remained unclear. Recent data of Agrobacterium and Helicobacter indicate that two classes of T4SS components, VirB2 and VirB5, might function as adhesins that mediate host-cell targeting through binding to specific host receptors. Here, we discuss this important issue and recent progress in the field.     

The Agrobacterium tumefaciens virB7 gene product, a proposed component of the T-complex transport apparatus, is a membrane-associated lipoprotein exposed at the periplasmic surface.

The Agrobacterium tumefaciens virB7 gene product contains a typical signal sequence ending with a consensus signal peptidase II cleavage site characteristic of bacterial lipoproteins. VirB7 was shown to be processed as a lipoprotein by (i) in vivo labeling of native VirB7 and a VirB7::PhoA fusion with [3H]palmitic acid and (ii) inhibition of VirB7 processing by globomycin, a known inhibitor of signal peptidase II. A VirB7 derivative sustaining a Ser substitution for the invariant Cys-15 residue within the signal peptidase II cleavage site could not be visualized immunologically and failed to complement a delta virB7 mutation, establishing the importance of this putative lipid attachment site for VirB7 maturation and function. VirB7 partitioned predominantly with outer membrane fractions from wild-type A348 cells as well as a delta virB operon derivative transformed with a virB7 expression plasmid. Expression of virB7 fused to phoA, the alkaline phosphatase gene of Escherichia coli, gave rise to high alkaline phosphatase activities in E. coli and A. tumefaciens cells, providing genetic evidence for the export of VirB7 in these hosts. VirB7 was shown to be intrinsically resistant to proteinase K; by contrast, a VirB7::PhoA derivative was degraded by proteinase K treatment of A. tumefaciens spheroplasts and remained intact upon treatment of whole cells. Together, the results of these studies favor a model in which VirB7 is topologically configured as a monotopic protein with its amino terminus anchored predominantly to the outer membrane and with its hydrophilic carboxyl domain located in the periplasmic space. Parallel studies of VirB5, VirB8, VirB9, and VirB10 established that each of these membrane-associated proteins also contains a large periplasmic domain whereas VirB11 resides predominantly or exclusively within the interior of the cell.     

An Agrobacterium VirB10 mutation conferring a type IV secretion system gating defect

Agrobacterium VirB7, VirB9, and VirB10 form a "core complex" during biogenesis of the VirB/VirD4 type IV secretion system (T4SS). VirB10 spans the cell envelope and, in response to sensing of ATP energy consumption by the VirB/D4 ATPases, undergoes a conformational change required for DNA transfer across the outer membrane (OM). Here, we tested a model in which VirB10 regulates substrate passage by screening for mutations that allow for unregulated release of the VirE2 secretion substrate to the cell surface independently of target cell contact. One mutation, G272R, conferred VirE2 release and also rendered VirB10 conformationally insensitive to cellular ATP depletion. Strikingly, G272R did not affect substrate transfer to target cells (Tra(+)) but did block pilus production (Pil(-)). The G272R mutant strain displayed enhanced sensitivity to vancomycin and SDS but did not nonspecifically release periplasmic proteins or VirE2 truncated of its secretion signal. G272 is highly conserved among VirB10 homologs, including pKM101 TraF, and in the TraF X-ray structure the corresponding Gly residue is positioned near an α-helical domain termed the antenna projection (AP), which is implicated in formation of the OM pore. A partial AP deletion mutation (ΔAP) also confers a Tra(+) Pil(-) phenotype; however, this mutation did not allow VirE2 surface exposure but instead allowed the release of pilin monomers or short oligomers to the milieu. We propose that (i) G272R disrupts a gating mechanism in the core chamber that regulates substrate passage across the OM and (ii) the G272R and ΔAP mutations block pilus production at distinct steps of the pilus biogenesis pathway.     

The N- and C-terminal portions of the Agrobacterium VirB1 protein independently enhance tumorigenesis

Genetic transformation of plants by Agrobacterium tumefaciens is mediated by a virulence (vir)-specific type IV secretion apparatus assembled from 11 VirB proteins and VirD4. VirB1, targeted to the periplasm by an N-terminal signal peptide, is processed to yield VirB1*, comprising the C-terminal 73 amino acids. The N-terminal segment, which shares homology with chicken egg white lysozyme as well as lytic transglycosylases, may provide local lysis of the peptidoglycan cell wall to create channels for transporter assembly. Synthesis of VirB1* followed by its secretion to the exterior of the cell suggests that VirB1* may also have a role in virulence. In the present study, we provide evidence for the dual roles of VirB1 in tumorigenesis as well as the requirements for processing and secretion of VirB1*. Complementation of a virB1 deletion strain with constructs expressing either the N-terminal lysozyme-homologous region or VirB1* results in tumors intermediate in size between those induced by a wild-type strain and a virB1 deletion strain, suggesting that each domain has a unique role in tumorigenesis. The secretion of VirB1* translationally fused to the signal peptide indicates that processing and secretion are not coupled. When expressed independently of all other vir genes, VirB1 was processed and VirB1* was secreted. When restricted to the cytoplasm by deletion of the signal peptide, VirB1 was neither processed nor secreted and did not restore virulence to the virB1 deletion strain. Thus, factors that mediate processing of VirB1 and secretion of VirB1* are localized in the periplasm or outer membrane and are not subject to vir regulation.