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.     

Agrobacterium rhizogenes GALLS protein substitutes for Agrobacterium tumefaciens single-stranded DNA-binding protein VirE2

Agrobacterium tumefaciens and Agrobacterium rhizogenes transfer plasmid-encoded genes and virulence (Vir) proteins into plant cells. The transferred DNA (T-DNA) is stably inherited and expressed in plant cells, causing crown gall or hairy root disease. DNA transfer from A. tumefaciens into plant cells resembles plasmid conjugation; single-stranded DNA (ssDNA) is exported from the bacteria via a type IV secretion system comprised of VirB1 through VirB11 and VirD4. Bacteria also secrete certain Vir proteins into plant cells via this pore. One of these, VirE2, is an ssDNA-binding protein crucial for efficient T-DNA transfer and integration. VirE2 binds incoming ssT-DNA and helps target it into the nucleus. Some strains of A. rhizogenes lack VirE2, but they still transfer T-DNA efficiently. We isolated a novel gene from A. rhizogenes that restored pathogenicity to virE2 mutant A. tumefaciens. The GALLS gene was essential for pathogenicity of A. rhizogenes. Unlike VirE2, GALLS contains a nucleoside triphosphate binding motif similar to one in TraA, a strand transferase conjugation protein. Despite their lack of similarity, GALLS substituted for VirE2.     

Biogenesis of T Pili in Agrobacterium tumefaciens Requires Precise VirB2 Propilin Cleavage and Cyclization

VirB2 propilin is processed by the removal of a 47-amino-acid signal peptide to generate a 74-amino-acid peptide product in both Escherichia coli and Agrobacterium tumefaciens. The cleaved VirB2 protein is further cyclized to form the T pilin in A. tumefaciens but not in E. coli. Mutations in the signal peptidase cleavage sequence of VirB2 propilin cause the formation of aberrant T pilin and also severely attenuate virulence. No T pilus was observed in these mutants. The potential role of the exact VirB2 propilin cleavage and cyclization in T pilus biogenesis and virulence is discussed.     

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.     

The virD operon of Agrobacterium tumefaciens encodes a site-specific endonuclease

Tumor formation by Agrobacterium tumefaciens involves the transfer and integration of a defined segment (T-DNA) of tumor-inducing (Ti) plasmid DNA into the plant nuclear genome. A set of plasmid genes outside the T-DNA, the vir genes, are thought to mediate the transfer process. We report here that the virD operon encodes a site-specific endonuclease that cleaves at a unique site within each of the 24 bp direct repeats that flank the T-DNA. The endonuclease function was further localized to the 5' end of this operon by demonstrating that cleavage does not occur in virD mutant strains of Agrobacterium and that the 5' end of the virD operon is sufficient to direct cleavage in E. coli. Analysis of nucleotide sequence and protein data indicate that two proteins of 16.2 and 47.4 kd are involved.     

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.     

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.     

vir-induced recombination in Agrobacterium. Physical characterization of precise and imprecise T-circle formation

Induction of Ti plasmid virulence (vir) gene expression during the early stages of plant cell transformation by Agrobacterium tumefaciens initiates the generation of several T-DNA-associated molecular events: (1) site-specific nicks at T-DNA border sequences (border nicks); (2) free, unipolar, linear, single-stranded T-DNA copies (T-strands); and (3) double-stranded, circular T-DNA molecules (T-circles). The first two T-DNA products have been detected in A. tumefaciens, while T-circles have only been detected following Escherichia coli transformation or transduction. The relationship between the three events has not been evaluated since the genesis of T-circles in A. tumefaciens has not been clarified. Evidence is presented here that T-circles are not an artefact of E. coli transformation, but are present as free, double-stranded molecules in A. tumefaciens resulting from site-specific reciprocal recombination between the left and right 25-base-pair border sequences that flank the T-DNA. Furthermore, the frequency of T-circle formation correlates with the frequency of formation of its reciprocal product, the Ti plasmid deleted in the T-DNA region. Several types of recombinant T-DNA circles arise after activation of vir gene expression, a major class representing precise site-specific recombination between both T-DNA borders, and a minor class representing recombination events either utilizing only one T-DNA border sequence and other Ti plasmid sequences, or utilizing only Ti plasmid sequences (i.e. no T-DNA borders). Nucleotide sequence analyses show that when one (nicked) border recombines with other Ti plasmid sequences, a small stretch (16 to 17 base-pairs) of local homology suffices to allow crossing over.     

Identification of a chromosomal tra-like region in Agrobacterium tumefaciens

The virD4 gene is one of the virulence genes present on the pTiC58 plasmid of Agrobacterium tumefaciens. Unexpectedly, we found that a pTi-free A. tumefaciens strain carried a protein of similar size to the plasmid-encoded VirD4 protein which reacted with VirD4-specific antibodies. This suggested that this strain may contain a homologue of the VirD4 protein. A chromosomal fragment encoding a protein of similar sequence to VirD4 was isolated and a 7.8 kilobase region surrounding the gene encoding this putative homologue was sequenced. This region contained four open reading frames, encoding putative proteins similar to proteins of known bacterial transfer and conjugation systems, viz., orf1 encoded a putative homologue of the TraA protein of the Rhizobium symbiosis plasmid pNGR234 and the TraA protein encoded by pTiC58 from A. tumefaciens plasmid pTiC58, orf3 encoded a protein very similar to the MobC protein encoded by the IncQ plasmid RSF1010 of E. coli and to MobS encoded by pTF1 from Thiobacillus ferrooxidans, whereas the predicted product of orf4 displayed similarity to the TraG protein encoded by the IncPalpha plasmid RP4 of E. coli, TraG and VirD4 encoded by A. tumefaciens plasmid pTiC58. The product of orf2 showed no significant similarity to any known protein. Preliminary assays with two orf4 mutants suggested that the product of this orf is involved in DNA transfer. The 7.8 kb chromosomal fragment seems to be closely related to the tra region of different conjugative plasmids and appears to be confined to Agrobacterium species, raising the question of the role of a chromosomal tra-like region during evolution.     

Expression of Agrobacterium nopaline-specific VirD1, VirD2, and VirC1 proteins and their requirement for T-strand production in E. coli

Induction of Ti plasmid virulence (vir) genes during early stages of the genetic transformation of plant cells by Agrobacterium tumefaciens results in several molecular events that are involved in generating a transferable T-DNA copy. These events include site-specific nicking at the T-DNA borders and synthesis of free, unipolar, linear, single-stranded copies of the T-DNA (T-strands). Here E. coli was used as a heterologous cell to assay the requirements for T-strand synthesis. Cells of E. coli harbored two compatible plasmids, one containing coding sequences overlapping the virC and virD regions of the nopaline Ti plasmid, and a second plasmid containing a T-DNA region. The amount of vir proteins produced was varied by placing their expression under the control of either native Agrobacterium, tac, or T7 promoters. The data show that VirD1 and VirD2 proteins are absolutely essential for T-strand production in E. coli, and the relative amounts of these polypeptides produced correlate with the amounts of T-strand observed. When VirD1 and VirD2 products are limiting, the VirC1 protein increases T-strand production. The yield of T-strands also varies as a function of the plasmid vector used to clone the T-DNA region substrate; the same T-DNA cloned into pLAFR1 produces more T-strands than that cloned into the higher copy number plasmid pACYC184. In summary, VirD1 and VirD2 proteins are the minimal requirements for T-strand production; however, other factors such as VirC1, the relative concentration of VirD1, VirD2, and the T-DNA substrate, and possibly additional functions (e.g., those specified by pLAFR1) influence the efficiency of T-strand production. Additional results regarding the requirements for expression of VirD1 and VirD2 polypeptides are presented.     

VirD proteins of Agrobacterium tumefaciens are required for the formation of a covalent DNA--protein complex at the 5'' terminus of T-strand molecules.

The T-DNA transfer process of Agrobacterium tumefaciens is activated by the induction of the Ti plasmid virulence (vir) loci by plant signal molecules such as acetosyringone. Upon initiation of the T-DNA transfer process, site-specific nicks occur at the 25-bp border sequences. This cleavage leads to the generation of a free, linear ssT-DNA molecule which is bound by sequence non-specific VirE proteins. Here we present evidence for the involvement of other acetosyringone-induced proteins in the formation of a covalent complex between the T-strand and protein, designated the T-complex. Alkaline gel-electrophoretic analysis showed that proteins specifically bind to the 5' termini of nicked T-DNA molecules. The T-complex can be formed in Escherichia coli when the VirD1 and VirD2 proteins are expressed.     

Dimerization of the Agrobacterium tumefaciens VirB4 ATPase and the effect of ATP-binding cassette mutations on the assembly and function of the T-DNA transporter

The Agrobacterium tumefaciens VirB4 ATPase functions with other VirB proteins to export T-DNA to susceptible plant cells and other DNA substrates to a variety of prokaryotic and eukaryotic cells. Previous studies have demonstrated that VirB4 mutants with defects in the Walker A nucleotide-binding motif are non-functional and exert a dominant negative phenotype when synthesized in wild-type cells. This study characterized the oligomeric structure of VirB4 and examined the effects of Walker A sequence mutations on complex formation and transporter activity. VirB4 directed dimer formation when fused to the amino-terminal portion of cI repressor protein, as shown by immunity of Escherichia coli cells to lambda phage infection. VirB4 also dimerized in Agrobacterium tumefaciens, as demonstrated by the recovery of a detergent-resistant complex of native protein and a functional, histidine-tagged derivative by precipitation with anti-His6 antibodies and by Co2+ affinity chromatography. Walker A sequence mutants directed repressor dimerization in E. coli and interacted with His-VirB4 in A. tumefaciens, indicating that ATP binding is not required for self-association. A dimerization domain was localized to a proposed N-terminal membrane-spanning region of VirB4, as shown by the dominance of an allele coding for the N-terminal 312 residues and phage immunity of host cells expressing cI repressor fusions to alleles for the first 237 or 312 residues. A recent study reported that the synthesis of a subset of VirB proteins, including VirB4, in agrobacterial recipients has a pronounced stimulatory effect on the virB-dependent conjugal transfer of plasmid RSF1010 by agrobacterial donors. VirB4'312 suppressed the stimulatory effect of VirB proteins for DNA uptake when synthesized in recipient cells. In striking contrast, Walker A sequence mutants contributed to the stimulatory effect of VirB proteins to the same extent as native VirB4. These findings indicate that the oligomeric structure of VirB4, but not its capacity to bind ATP, is important for the assembly of VirB proteins as a DNA uptake system. The results of these studies support a model in which VirB4 dimers or homomultimers contribute structural information for the assembly of a transenvelope channel competent for bidirectional DNA transfer, whereas an ATP-dependent activity is required for configuring this channel as a dedicated export machine.     

Sequence similarities between the RP4 Tra2 and the Ti VirB region strongly support the conjugation model for T-DNA transfer.

Transfer genes of the IncP plasmid RP4 are grouped in two separate regions, designated Tra1 and Tra2. Tra2 gene products are proposed to be mainly responsible for the formation of mating pairs in conjugating cells. To provide information relevant to understanding the function of Tra2 gene products, the nucleotide sequence of the entire RP4 Tra2 region is presented here. Twelve open reading frames were identified in the Tra2 core region, being essential for intraspecific Escherichia coli matings. Predicted sizes of 11 of the 12 Tra2 polypeptides could be verified by expression in E. coli. Based on hydropathy plot analysis, most of the Tra2 open reading frames encode proteins that may interact with membranes. Interestingly, six of the predicted Tra2 gene products exhibited significant sequence similarities to gene products encoded by the VirB operon of the Agrobacterium Ti plasmid. VirB proteins are thought to function in the formation of a transmembrane structure that mediates the passage of T-DNA molecules from bacteria into plant cells. Because of this analogy and the hydropathy of Tra2 gene products, we assume that the DNA transfer machineries acting in bacterial conjugation and T-DNA transfer are structurally and functionally similar. Therefore, the data presented here, support the hypothesis that Ti vir and IncP tra genes evolved from a common ancestor. This suggestion is favored by previous findings of sequence similarities between the IncP and Ti DNA transfer system.     

Interactions of VirB9, -10, and -11 with the membrane fraction of Agrobacterium tumefaciens: solubility studies provide evidence for tight associations.

The eleven predicted gene products of the Agrobacterium tumefaciens virB operon are believed to form a transmembrane pore complex through which T-DNA export occurs. The VirB10 protein is required for virulence and is a component of an aggregate associated with the membrane fraction of A. tumefaciens. Removal of the putative membrane-spanning domain (amino acids 22 through 55) disrupts the membrane topology of VirB10 (J. E. Ward, E. M. Dale, E. W. Nester, and A. N. Binns, J. Bacteriol. 172:5200-5210, 1990). Deletion of the sequences encoding amino acids 22 to 55 abolishes the ability of plasmid-borne virB10 to complement a null mutation in the virB10 gene, suggesting that the proper topology of VirB10 in the membrane may indeed play a crucial role in T-DNA transfer to the plant cell. Western blot (immunoblot) analysis indicated that the observed loss of virulence could not be attributed to a decrease in the steady-state levels of the mutant VirB10 protein. Although the deletion of the single transmembrane domain would be expected to perturb membrane association, VirB10 delta 22-55 was found exclusively in the membrane fraction. Urea extraction studies suggested that this membrane localization might be the result of a peripheral membrane association; however, the mutant protein was found in both inner and outer membrane fractions separated by sucrose density gradient centrifugation. Both wild-type VirB10 and wild-type VirB9 were only partially removed from the membranes by extraction with 1% Triton X-100, while VirB5 and VirB8 were Triton X-100 soluble. VirB11 was stripped from the membranes by 6 M urea but not by a more mild salt extraction. The fractionation patterns of VirB9, VirB10, and VirB11 were not dependent on each other or on VirB8 or VirD4. The observed tight association of VirB9, VirB10, and VirB11 with the membrane fraction support the notion that these proteins may exist as components of multiprotein pore complexes, perhaps spanning both the inner and outer membranes of Agrobacterium cells.     

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.     

Transfer of the Ti plasmid from Agrobacterium tumefaciens into Escherichia coli cells

We have screened strains of Agrobacterium tumefaciens for spontaneous mutants showing constitutive transfer of the nopaline Ti plasmid pTiC58 during conjugation. The Ti plasmid derivatives obtained could be transferred not only to A. tumefaciens but also to E. coli cells. The Ti plasmid cannot survive as a freely replicating plasmid in E. coli, but it can occasionally integrate into the E. coli chromosome. However, insertion in tandem of plasmids carrying fd replication origins (pfd plasmids) into the T-DNA provides an indicator for all transfer events into E. coli cells, providing fd gene 2 protein is present in these cells. This viral protein causes the excision of one copy of the pfd plasmid and allows its propagation in the host cell. By using this specially designed Ti plasmid, which was also made constitutive in transfer functions, we found plasmid exchange among A. tumefaciens strains and between A. tumefaciens and E. coli cells to be equally efficient. A Ti plasmid with repressed transfer functions was transferred to E. coli with a rate similar to the low frequency at which it was transferred to A. tumefaciens. The expression of transfer functions of plasmid RP4 either in A. tumefaciens or in E. coli did not increase the transfer of the Ti plasmid into E. coli cells, nor did the addition of acetosyringone, an inducer of T-DNA transfer to plant cells. The results show that A. tumefaciens can transfer the Ti plasmid to E. coli with the same efficiency as within its own species. Conjugational transmission of extrachromosomal DNA like the narrow-host-range Ti plasmid may often not only occur among partners allowing propagation of the plasmid, but also on a 'try-all' basis including hosts which do not replicate the transferred DNA.     

Agrobacterium tumefaciens VirB11 protein requires a consensus nucleotide-binding site for function in virulence.

virB11, one of the 11 genes of the virB operon, is absolutely required for transport of T-DNA from Agrobacterium tumefaciens into plant cells. Previous studies reported that VirB11 is an ATPase with autophosphorylation activity and localizes to the inner membrane even though the protein does not contain the consensus N-terminal export sequence. In this report, we show that VirB11 localizes to the inner membrane even in the absence of other tumor-inducing (Ti) plasmid-encoded proteins. To facilitate the further characterization of VirB11, we purified this protein from the soluble fraction of an Escherichia coli extract by fusing VirB11 to the maltose-binding protein. The maltose-binding protein-VirB11 fusion was able to complement a virB11 deletion mutant of A. tumefaciens for tumor formation and also localized properly to the inner membrane of A. tumefaciens. The 72-kDa protein, purified from E. coli, exhibited no autophosphorylation, ATPase activity, or ATP-binding activity. To study the importance of the Walker nucleotide-binding site present in VirB11, mutations were generated to replace the conserved lysine residue with either alanine or arginine. Expression of the virB11K175A mutant gene resulted in an avirulent phenotype, and expression of the virB11K175R mutant gene gave rise to an attenuated virulence phenotype. Both mutant proteins were present at levels three to four times higher than that of VirB11 in the wild-type strain. The mutant genes did not exhibit a transdominant phenotype on tumor formation in bacteria that were expressing wild-type virB11. The mutant proteins also localized properly to the inner membrane of A. tumefaciens, but the VirB11K175R protein appeared to be unstable after lysis of the cells.