Subcellular localization of the Agrobacterium tumefaciens T-DNA transport pore proteins: VirB8 is essential for the assembly of the transport pore

Agrobacterium tumefaciens transforms plants by transferring DNA to the plant cell nucleus. The VirB membrane proteins are postulated to form a pore for the transport of the DNA across the bacterial membranes. Immunofluorescence and immunoelectron microscopy were used to study the transport pore complex. Three likely components of the transport pore, VirB8, VirB9 and VirB10, localized primarily to the inner membrane, outer membrane and periplasm respectively. A significant amount of VirB10 was also found associated with the outer membrane. When expressed alone VirB9 and VirB10 were randomly distributed along the cell membrane. Subcellular location of both proteins changed dramatically in the presence of the other VirB proteins. Both proteins localized to fewer sites and most of the gold particles representing protein molecules were found in clusters suggesting that the two proteins are in a protein complex. VirB8, on the other hand, localized to clusters even in the absence of the other VirB proteins. To investigate the role of VirB8 in the formation of VirB9 and VirB10 protein complexes, we studied the effect of deletion of virB8 on the subcellular location of VirB9 and VirB10. In a virB8 deletion mutant both proteins were distributed randomly on the cell membrane indicating that VirB8 is essential for complex assembly.     

The Agrobacterium T-DNA transport pore proteins VirB8, VirB9, and VirB10 interact with one another

The VirB proteins of Agrobacterium tumefaciens form a transport pore to transfer DNA from bacteria to plants. The assembly of the transport pore will require interaction among the constituent proteins. The identification of proteins that interact with one another can provide clues to the assembly of the transport pore. We studied interaction among four putative transport pore proteins, VirB7, VirB8, VirB9 and VirB10. Using the yeast two-hybrid assay, we observed that VirB8, VirB9, and VirB10 interact with one another. In vitro studies using protein fusions demonstrated that VirB10 interacts with VirB9 and itself. These results suggest that the outer membrane VirB7-VirB9 complex interacts with the inner membrane proteins VirB8 and VirB10 for the assembly of the transport pore. Fusions that contain small, defined segments of the proteins were used to define the interaction domains of VirB8 and VirB9. All interaction domains of both proteins mapped to the N-terminal half of the proteins. Two separate domains at the N- and C-terminal ends of VirB9 are involved in its homotypic interaction, suggesting that VirB9 forms a higher oligomer. We observed that the alteration of serine at position 87 of VirB8 to leucine abolished its DNA transfer function. Studies on the interaction of the mutant protein with the other VirB proteins showed that the VirB8S87L mutant is defective in interaction with VirB9. The mutant, however, interacted efficiently with VirB8 and VirB10, suggesting that the VirB8-VirB9 interaction is essential for DNA transfer.     

Subcellular localization of seven VirB proteins of Agrobacterium tumefaciens: implications for the formation of a T-DNA transport structure.

Plant cell transformation by Agrobacterium tumefaciens involves the transfer of a single-stranded DNA-protein complex (T-complex) from the bacterium to the plant cell. One of the least understood and important aspects of this process is how the T-complex exits the bacterium. The eleven virB gene products have been proposed to specify the DNA export channel on the basis of their predicted hydrophobicity. To determine the cellular localization of the VirB proteins, two different cell fractionation methods were employed to separate inner and outer membranes. Seven VirB-specific antibodies were used on Western blots (immunoblots) to detect the proteins in the inner and outer membranes and soluble (containing cytoplasm and periplasm) fractions. VirB5 was in both the inner membrane and cytoplasm. Six of the VirB proteins were detected in the membrane fractions only. Three of these, VirB8, VirB9, and VirB10, were present in both inner and outer membrane fractions regardless of the fractionation method used. Three additional VirB proteins, VirB1, VirB4, and VirB11, were found mainly in the inner membrane fraction by one method and were found in both inner and outer membrane fractions by a second method. These results confirm the membrane localization of seven VirB proteins and strengthen the hypothesis that VirB proteins are involved in the formation of a T-DNA export channel or gate. That most of the VirB proteins analyzed are found in both inner and outer membrane fractions suggest that they form a complex pore structure that spans both membranes, and their relative amounts in the two membrane fractions reflect their differential sensitivity to the experimental conditions.     

The essential virulence protein VirB8 localizes to the inner membrane of Agrobacterium tumefaciens.

Agrobacterium tumefaciens genetically transforms plant cells by transferring a specific DNA fragment from the bacterium through several biological membranes to the plant nucleus where the DNA is integrated. This complex DNA transport process likely involves membrane-localized proteins in both the plant and the bacterium. The 11 hydrophobic or membrane-localized proteins of the virB operon are excellent candidates to have a role in DNA export from agrobacteria. Here, we show by TnphoA mutagenesis and immunogold electron microscopy that one of the VirB proteins, VirB8, is located at the inner membrane. The observation that a virB8::TnphoA fusion restores export of alkaline phosphatase to the periplasm suggests that VirB8 spans the inner membrane. Immunogold labeling of VirB8 was detected on the inner membrane of vir-induced A. tumefaciens by transmission electron microscopy. Compared with that of the controls, VirB8 labeling was significantly greater on the inner membrane than on the other cell compartments. These results confirm the inner membrane localization of VirB8 and strengthen the hypothesis that VirB proteins help form a transfer DNA export channel or gate.     

Self-assembly of the Agrobacterium tumefaciens VirB11 traffic ATPase

The Agrobacterium tumefaciens VirB11 ATPase is a component of a type IV transporter dedicated to T-DNA delivery to plant cells. In this study, we tested a prediction from genetic findings that VirB11 self-associates in vivo. A chimeric protein composed of VirB11 fused to the DNA binding domain of lambda cI repressor protein formed dimers, as shown by immunity of Escherichia coli to lambda superinfection. An allele encoding VirB11 fused at its C terminus to the green fluorescent protein (GFP) exerted strong negative dominance when synthesized in wild-type A. tumefaciens cells. Dominance was suppressed by overproduction of native VirB11, suggestive of titrating or competitive interactions between VirB11 and VirB11::GFP. In support of the titration model, a complex of native VirB11 and VirB11::GFP was recovered by precipitation with anti-GFP antibodies from detergent-solubilized A. tumefaciens cell extracts. VirB11 was shown by cI repressor fusion and immunoprecipitation assays to interact with VirB11 derivatives encoded by (i) 11 dominant negative alleles, (ii) recessive alleles bearing codon substitutions or deletions in the Walker A nucleotide binding motif, and (iii) alleles corresponding to the 5' and 3' halves of virB11. Further immunoprecipitation studies showed a hybrid protein composed of the N-terminal half of VirB11 fused to GFP interacted with mutant proteins exerting dominant effects and with a recessive Walker A deletion mutant (Delta GKT174-176). By contrast, a hybrid protein composed of the C-terminal half fused to GFP interacted with mutants exerting dominant effects but not the Walker A mutant protein. Together, these studies establish that VirB11 assembles as homomultimers in vivo via domains residing in each half of the protein. Furthermore, ATP binding appears to be critical for C-terminal interactions required for assembly of productive homomultimers.     

Functional Expression of Agrobacterium tumefaciens T-DNA onc-genes in Asparagus Crown Gall Tissues

We analyzed Asparagus crown gall tissues transformed with A.tumefaciens C58 and C58C1 (pTiB6S3) and selected for hormoneautotrophic growth. No increased IAA levels were observed inthe Asparagus tumor lines notwithstanding the presence of allthree T-DNA onc genes. The endogenous cytokinin levels indicatethat Asparagus crown gall is dependent on enhanced zeatin ribosideequivalent levels for its growth. We conclude that phytohormone autotrophic growth of Asparaguscrown gall tissue seems only to be dependent upon an activegene 4, inducing enhanced cytokinin levels. Moreover, the presenceof an active gene 1 seems to be lethal as was indicated by theabsence of tryptophan-2-mono-oxygenase activity in transformedtissues and the toxicity of exogenously supplied indole-3-acetamide(IAM) or naphthalene-1-acetamide (NAM) as a substitute for anactive gene 1. (Received August 7, 1989; Accepted October 31, 1989)     

Assembly of the VirB transport complex for DNA transfer from Agrobacterium tumefaciens to plant cells

The VirB transporter is a type IV secretion system that mediates the genetic transformation of plant cells by Agrobacterium tumefaciens. Assembly of this transporter depends on, first, formation of a VirB7/B9 complex that stabilizes many of the VirB proteins, second, formation of a virulence-specific pilus composed primarily of VirB2 and VirB5, and, third, post-translational processing of VirB1 and VirB2.     

Agrobacterium tumefaciens VirB6 protein participates in formation of VirB7 and VirB9 complexes required for type IV secretion

This study characterized the contribution of Agrobacterium tumefaciens VirB6, a polytopic inner membrane protein, to the formation of outer membrane VirB7 lipoprotein and VirB9 protein multimers required for type IV secretion. VirB7 assembles as a disulfide cross-linked homodimer that associates with the T pilus and a VirB7-VirB9 heterodimer that stabilizes other VirB proteins during biogenesis of the secretion machine. Two presumptive VirB protein complexes, composed of VirB6, VirB7, and VirB9 and of VirB7, VirB9, and VirB10, were isolated by immunoprecipitation or glutathione S-transferase pulldown assays from detergent-solubilized membrane extracts of wild-type A348 and a strain producing only VirB6 through VirB10 among the VirB proteins. To examine the biological importance of VirB6 complex formation for type IV secretion, we monitored the effects of nonstoichiometric VirB6 production and the synthesis of VirB6 derivatives with 4-residue insertions (VirB6.i4) on VirB7 and VirB9 multimerization, T-pilus assembly, and substrate transfer. A virB6 gene deletion mutant accumulated VirB7 dimers at diminished steady-state levels, whereas complementation with a plasmid bearing wild-type virB6 partially restored accumulation of the dimers. VirB6 overproduction was correlated with formation of higher-order VirB9 complexes or aggregates and also blocked substrate transfer without a detectable disruption of T-pilus production; these phenotypes were displayed by cells grown at 28 degrees C, a temperature that favors VirB protein turnover, but not by cells grown at 20 degrees C. Strains producing several VirB6.i4 mutant proteins assembled novel VirB7 and VirB9 complexes detectable by nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and two strains producing the D60.i4 and L191.i4 mutant proteins translocated IncQ plasmid and VirE2 effector protein substrates in the absence of a detectable T pilus. Our findings support a model that VirB6 mediates formation of VirB7 and VirB9 complexes required for biogenesis of the T pilus and the secretion channel.     

The Agrobacterium tumefaciens VirB7 lipoprotein is required for stabilization of VirB proteins during assembly of the T-complex transport apparatus.

The Agrobacterium tumefaciens virB7 gene product is a lipoprotein whose function is required for the transmission of oncogenic T-DNA to susceptible plant cells. Three lines of study provided evidence that VirB7 interacts with and stabilizes other VirB proteins during the assembly of the putative T-complex transport apparatus. First, a precise deletion of virB7 from the pTiA6NC plasmid of wild-type strain A348 was correlated with significant reductions in the steady-state levels of several VirB proteins, including VirB4, VirB9, VirB10, and VirB11; trans expression of virB7 in the delta virB7 mutant partially restored the levels of these proteins, and trans coexpression of virB7 and virB8 fully restored the levels of these proteins to wild-type levels. Second, modulation of VirB7 levels resulted in corresponding changes in the levels of other VirB proteins in the following cell types: (i) a delta virB7 mutant expressing virB7 and virB8 from isopropyl-beta-D-thiogalactopyranoside (IPTG)-inducible Plac and other virB genes from acetosyringone (AS)-inducible PvirB; (ii) a delta virB operon mutant expressing virB7 and virB8 from Plac and virB9, virB10, and virB11 from PvirB; and (iii) a delta virB operon mutant expressing virB7 from IPTG-inducible Pklac and virB9 from an AS-inducible PvirB. Third, the synthesis of a VirB7::PhoA fusion protein in strain A348 was correlated with a significant reduction in the steady-state levels of VirB4, VirB5, and VirB7 through VirB11; these cells also exhibited a severely attenuated virulence phenotype, indicating that synthesis of the fusion protein perturbs the assembly of VirB proteins into a stabilized protein complex required for T-complex transport. Extracts of AS-induced cells electrophoresed under nonreducing conditions possessed undetectable levels of the 32-kDa VirB9 and 4.5-kDa VirB7 monomers and instead possessed a 36-kDa complex that cross-reacted with both VirB7 and VirB9 antisera and accumulated as a function of virB7 expression. Our results are consistent with a model in which VirB7 stabilizes VirB9 by formation of a covalent intermolecular cross-link; in turn, the VirB7-VirB9 heterodimer promotes the assembly of a functional T-complex transport machinery.     

The lipoprotein VirB7 interacts with VirB9 in the membranes of Agrobacterium tumefaciens.

VirB9 and VirB7 are essential components of the putative VirB membrane channel required for transfer of the T-complex from Agrobacterium tumefaciens into plants. In this report, we present a biochemical analysis of their interaction and cellular localization. A comparison of relative electrophoretic mobilities under nonreducing and reducing conditions suggested that they form thiol-sensitive complexes with other proteins. Two-dimensional gel electrophoresis identified one complex as a heterodimer of VirB9 and VirB7 covalently linked by a disulfide bond, as well as VirB7 homodimers and monomers. Immunoprecipitation with VirB9-specific antiserum isolated the heterodimeric VirB9-VirB7 complex. Incubation with reducing agent split the complex into its constituent VirB9 and VirB7, which further confirmed linkage via cysteine residues. The interaction between VirB9 and VirB7 also was observed in the yeast two-hybrid system. Membrane attachment of VirB9-VirB7 may be conferred by lipoprotein modification, since labeling with [3H]palmitic acid in A. tumefaciens verified that VirB7 is a lipoprotein associated with VirB9. VirB9 and VirB7 showed equal distribution between inner and outer membranes, in accord with their proposed association with the transmembrane VirB complex.     

Characterization of membrane and protein interaction determinants of the Agrobacterium tumefaciens VirB11 ATPase.

The VirB11 ATPase is a putative component of the transport machinery responsible for directing the export of nucleoprotein particles (T complexes) across the Agrobacterium tumefaciens envelope to susceptible plant cells. Fractionation and membrane treatment studies showed that approximately 30% of VirB11 partitioned as soluble protein, whereas the remaining protein was only partially solubilized with urea from cytoplasmic membranes of wild-type strain A348 as well as a Ti-plasmidless strain expressing virB11 from an IncP replicon. Mutations in virB11 affecting protein function were mapped near the amino terminus (Q6L, P13L, and E25G), just upstream of a region encoding a Walker A nucleotide-binding site (F154H;L155M), and within the Walker A motif (P170L, K175Q, and delta GKT174-176). The K175Q and delta GKT174-176 mutant proteins partitioned almost exclusively with the cytoplasmic membrane, suggesting that an activity associated with nucleotide binding could modulate the affinity of VirB11 for the cytoplasmic membrane. The virB11F154H;L155M allele was transdominant over wild-type virB11 in a merodiploid assay, providing strong evidence that at least one form of VirB11 functions as a homo- or heteromultimer. An allele with a deletion of the first half of the gene, virB11 delta1-156, was transdominant in a merodiploid assay, indicating that the C-terminal half of VirB11 contains a protein interaction domain. Products of both virB11 delta1-156 and virB11 delta158-343, which synthesizes the N-terminal half of VirB11, associated tightly with the A. tumefaciens membrane, suggesting that both halves of VirB11 contain membrane interaction determinants.     

An essential virulence protein of Agrobacterium tumefaciens,VirB4, requires an intact mononucleotide binding domain to function in transfer of T-DNA

The 11 gene products of the Agrobacterium tumefaciens virB operon, together with the VirD4 protein, are proposed to form a membrane complex which mediates the transfer of T-DNA to plant cells. This study examined one putative component of that complex, VirB4. A deletion of the virB4 gene on the Ti plasmid pTiA6NC was constructed by replacing the virB4 gene with the kanamycin resistance-conferring nptII gene. The virB4 gene was found to be necessary for virulence on plants and for the transfer of IncQ plasmids to recipient cells of A. tumefaciens. Genetic complementation of the deletion strain by the virB4 gene under control of the virB promoter confirmed that the deletion was nonpolar on downstream virB genes. Genetic complementation was also achieved with the virB4 gene placed under control of the lac promoter, even though synthesis of the VirB4 protein from this promoter is far below wild-type levels. Having shown a role for the VirB4 protein in DNA transfer, lysine-439, found within the conserved mononucleotide binding domain of VirB4, was changed to a glutamic acid, methionine, or arginine by oligonucleotide-directed mutagenesis. virB4 genes bearing these mutations were unable to complement the virB4 deletion for either virulence or for IncQ transfer, showing that an intact mononucleotide binding site is necessary for the function of VirB4 in DNA transfer. The necessity of the VirB4 protein with an intact mononucleotide binding site for extracellular complementation of virE2 mutants was also shown. In merodiploid studies, lysine-439 mutations present in trans decreased IncQ plasmid transfer frequencies, suggesting that VirB4 functions within a complex to facilitate DNA transfer.     

Agrobacterium tumefaciens Type IV Secretion Protein VirB3 Is an Inner Membrane Protein and Requires VirB4, VirB7, and VirB8 for Stabilization

Agrobacterium tumefaciens VirB proteins assemble a type IV secretion apparatus and a T-pilus for secretion of DNA and proteins into plant cells. The pilin-like protein VirB3, a membrane protein of unknown topology, is required for the assembly of the T-pilus and for T-DNA secretion. Using PhoA and green fluorescent protein (GFP) as periplasmic and cytoplasmic reporters, respectively, we demonstrate that VirB3 contains two membrane-spanning domains and that both the N and C termini of the protein reside in the cytoplasm. Fusion proteins with GFP at the N or C terminus of VirB3 were fluorescent and, like VirB3, localized to a cell pole. Biochemical fractionation studies demonstrated that VirB3 proteins encoded by three Ti plasmids, the octopine Ti plasmid pTiA6NC, the supervirulent plasmid pTiBo542, and the nopaline Ti plasmid pTiC58, are inner membrane proteins and that VirB4 has no effect on membrane localization of pTiA6NC-encoded VirB3 (pTiA6NC VirB3). The pTiA6NC and pTiBo542 VirB2 pilins, like VirB3, localized to the inner membrane. The pTiC58 VirB4 protein was earlier found to be essential for stabilization of VirB3. Stabilization of pTiA6NC VirB3 requires not only VirB4 but also two additional VirB proteins, VirB7 and VirB8. A binary interaction between VirB3 and VirB4/VirB7/VirB8 is not sufficient for VirB3 stabilization. We hypothesize that bacteria use selective proteolysis as a mechanism to prevent assembly of unproductive precursor complexes under conditions that do not favor assembly of large macromolecular structures.Bacteria use type IV secretion (T4S) to deliver macromolecules to prokaryotes and eukaryotes (12). Animal and human pathogens deliver proteins to their eukaryotic hosts to affect cellular processes causing disease. The plant-pathogenic bacterium Agrobacterium tumefaciens delivers both proteins and DNA to plants and other eukaryotes. DNA delivered by Agrobacterium directs constitutive synthesis of phytohormones in a transformed plant cell, promoting cancerous growth (56). The Ptl toxin of Bordetella pertussis modifies G proteins by ADP-ribosylation, affecting intracellular cell signaling, and CagA of Helicobacter pylori disrupts epithelial cell polarity by inhibiting PAR1 kinase activity (37, 44, 47). T4S is ancestrally related to bacterial conjugation, a mechanism used by bacteria for interbacterial plasmid transfer, enabling them to acquire novel genes for antibiotic resistance, degradation of organic molecules, toxin production, and other virulence traits (29).The VirD4/VirB family of proteins, found conserved in many alphaproteobacteria, mediates T4S (12). The Ti plasmid-encoded Agrobacterium T4S system requires VirD4 and 11 VirB proteins, VirB1 to VirB11, for efficient DNA transfer (7, 54). The membrane and membrane-associated VirB proteins assemble a macromolecular structure at the cell membrane to promote substrate transfer (12). The octopine Ti plasmid pTiA6NC-encoded VirB6 to VirB11 proteins assemble the T4S apparatus at a cell pole (34, 35, 39). The VirD4 coupling protein targets the VirE2 substrate protein to the cell pole (4). A recent study found that the nopaline Ti plasmid pTiC58 T4S system (T4SS) and its substrates form a helical array around the cell circumference (1). Structural studies using Escherichia coli conjugative plasmid pKM101-encoded VirB homologues showed that TraN (VirB7), TraO (VirB9), and TraF (VirB10) form the core complex and that TraF forms a channel at the outer membrane (11, 23). The Agrobacterium VirB proteins assemble a T-pilus, an appendage composed primarily of VirB2, with VirB5 and VirB7 as its minor constituents (38, 40, 41, 48, 50, 55). VirB3, a homolog of the pilin-like TraL protein encoded in E. coli plasmids, is postulated to function in T-pilus assembly (52). Three ATP-utilizing proteins, VirB4, VirB11, and VirD4, supply energy for substrate translocation (3, 9, 34).The membrane topology of all the VirB proteins, except for VirB3, was determined by analyses of random phoA insertion mutants, targeted phoA fusions, and targeted bla fusions (6, 14, 15, 21, 22, 31, 35, 53). phoA and bla, which encode alkaline phosphatase and β-lactamase, respectively, serve as excellent markers for periplasmic proteins, as they are enzymatically active only when targeted to the cell periplasm (8, 30). Green fluorescent protein (GFP) is an ideal cytoplasmic marker because it fluoresces only when located in the cytoplasm (19, 20). When GFP is targeted to the periplasm through fusion with a membrane-spanning domain (MSD), it fails to fold properly and does not fluoresce.The prevailing view, based on in silico analysis, is that VirB3 is a bitopic membrane protein with a periplasmic C terminus. No phoA-positive insertions in virB3, however, were identified in two random mutagenesis studies of the virB operon (6, 15). The small size of VirB3, a polypeptide of 108 amino acids (aa), could be a contributing factor to the negative findings. Yet several PhoA-positive insertions in two smaller VirB proteins, VirB2 (74-aa mature peptide) and VirB7 (41-aa mature peptide), were successfully obtained in both studies. Therefore, the negative findings may also be indicative of the presence of a small periplasmic domain in VirB3. Biochemical studies showed that the nopaline Ti plasmid pTiC58-encoded VirB3 protein (pTiC58 VirB3) associates with the bacterial outer membrane, while VirB2 associates with both the inner and outer membranes (52). The pTiC58 VirB4 protein is required for localization of VirB3 to the outer membrane (33). VirB4 is also required for VirB3 stability (33, 55). A low level of VirB3 accumulated in a nonpolar pTiC58 virB6 deletion mutant; however, addition of virB6 in trans did not restore the level of the protein, even though it restored tumorigenicity (27). VirB3 participates in the formation of protein complexes with the T-pilus proteins VirB2 and VirB5 (55).Homologues of VirB3 are found in many alphaproteobacteria with a T4SS. While most VirB3 homologues are small proteins, several recently identified homologues are fusions of VirB3 and the immediate downstream protein VirB4 (5, 10, 24). These fusion homologs, which include Actinobacillus MagB03 (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAG24434","term_id":"10880920","term_text":"AAG24434"}}AAG24434), Campylobacter CmgB3/4 ({"type":"entrez-protein","attrs":{"text":"EAQ71805","term_id":"87248841","term_text":"EAQ71805"}}EAQ71805), Yersinia pseudotuberculosis TriC ({"type":"entrez-protein","attrs":{"text":"CAF25448","term_id":"51591645","term_text":"CAF25448"}}CAF25448), Citrobacter koseri PilX3-4 ({"type":"entrez-protein","attrs":{"text":"ABV12046","term_id":"157082368","term_text":"ABV12046"}}ABV12046), and Klebsiella pneumoniae PilX3-4 ({"type":"entrez-protein","attrs":{"text":"BAF49490","term_id":"134048868","term_text":"BAF49490"}}BAF49490), have VirB3 at the N terminus and VirB4 at the C terminus. Agrobacterium VirB4 is an integral membrane protein with a cytoplasmic N terminus (14). Its homologues are expected to have a similar topology. The prevailing view that pTi VirB3 has a periplasmic C terminus is inconsistent with the cytoplasmic location of the N terminus of VirB4 in the VirB3-VirB4 fusion protein homologues.In this study, we report the membrane topology of Agrobacterium VirB3 and demonstrate that the C terminus of the protein resides in the cytoplasm. We also demonstrate that VirB3 is an inner membrane protein, not an outer membrane protein as previously reported (52). The octopine Ti plasmid pTiA6NC VirB4 protein does not affect membrane localization of VirB3 but does stabilize VirB3. VirB4, however, is not sufficient for pTiA6NC VirB3 stabilization. Two additional proteins, VirB7 and VirB8, are required for the stabilization of pTiA6NC VirB3.     

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.     

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.     

Temperature affects the T-DNA transfer machinery of Agrobacterium tumefaciens.

Early studies on Agrobacterium tumefaciens showed that development of tumors on plants following infection by A. tumefaciens was optimal at temperatures around 22 degrees C and did not occur at temperatures above 29 degrees C. To assess whether this inability to induce tumors is due to a defect in the T-DNA transfer machinery, mobilization of an incompatibility group Q (IncQ) plasmid by the T-DNA transfer machinery of A. tumefaciens was tested at various temperatures. Optimal transfer occurred when matings were performed at 19 degrees C, and transfer was not seen when matings were incubated above 28 degrees C. Transfer of the IncQ plasmid was dependent upon induction of the virB and virD operons by acetosyringone but was not dependent upon induction of the tra genes by octopine. However, alterations in the level of vir gene induction could not account for the decrease in transfer with increasing temperature. A. tumefaciens did successfully mobilize IncQ plasmids at higher temperatures when alternative transfer machineries were provided. Thus, the defect in transfer at high temperature is apparently in the T-DNA transfer machinery itself. As these data correlate with earlier tumorigenesis studies, we propose that tumor suppression at higher temperatures results from a T-DNA transfer machinery which does not function properly.     

Extracellular VirB5 enhances T-DNA transfer from Agrobacterium to the host plant

VirB5 is a type 4 secretion system protein of Agrobacterium located on the surface of the bacterial cell. This localization pattern suggests a function for VirB5 which is beyond its known role in biogenesis and/or stabilization of the T-pilus and which may involve early interactions between Agrobacterium and the host cell. Here, we identify VirB5 as the first Agrobacterium virulence protein that can enhance infectivity extracellularly. Specifically, we show that elevating the amounts of the extracellular VirB5--by exogenous addition of the purified protein, its overexpression in the bacterium, or transgenic expression in and secretion out of the host cell--enhances the efficiency the Agrobacterium-mediated T-DNA transfer, as measured by transient expression of genes contained on the transferred T-DNA molecule. Importantly, the exogenous VirB5 enhanced transient T-DNA expression in sugar beet, a major crop recalcitrant to genetic manipulation. Increasing the pool of the extracellular VirB5 did not complement an Agrobacterium virB5 mutant, suggesting a dual function for VirB5: in the bacterium and at the bacterium-host cell interface. Consistent with this idea, VirB5 expressed in the host cell, but not secreted, had no effect on the transformation efficiency. That the increase in T-DNA expression promoted by the exogenous VirB5 was not due to its effects on bacterial growth, virulence gene induction, bacterial attachment to plant tissue, or host cell defense response suggests that VirB5 participates in the early steps of the T-DNA transfer to the plant cell.     

Site-specific integration of Agrobacterium tumefaciens T-DNA via double-stranded intermediates

Agrobacterium tumefaciens-mediated genetic transformation involves transfer of a single-stranded T-DNA molecule (T strand) into the host cell, followed by its integration into the plant genome. The molecular mechanism of T-DNA integration, the culmination point of the entire transformation process, remains largely obscure. Here, we studied the roles of double-stranded breaks (DSBs) and double-stranded T-DNA intermediates in the integration process. We produced transgenic tobacco (Nicotiana tabacum) plants carrying an I-SceI endonuclease recognition site that, upon cleavage with I-SceI, generates DSB. Then, we retransformed these plants with two A. tumefaciens strains: one that allows transient expression of I-SceI to induce DSB and the other that carries a T-DNA with the I-SceI site and an integration selection marker. Integration of this latter T-DNA as full-length and I-SceI-digested molecules into the DSB site was analyzed in the resulting plants. Of 620 transgenic plants, 16 plants integrated T-DNA into DSB at their I-SceI sites; because DSB induces DNA repair, these results suggest that the invading T-DNA molecules target to the DNA repair sites for integration. Furthermore, of these 16 plants, seven plants incorporated T-DNA digested with I-SceI, which cleaves only double-stranded DNA. Thus, T-strand molecules can be converted into double-stranded intermediates before their integration into the DSB sites within the host cell genome.