Agrobacterium VirD2-binding protein is involved in tumorigenesis and redundantly encoded in conjugative transfer gene clusters

Agrobacterium tumefaciens can transfer oncogenic T-DNA into plant cells; T-DNA transfer is mechanistically similar to a conjugation process. VirD2 is the pilot protein that guides the transfer, because it is covalently associated with single-stranded T-DNA to form the transfer substrate T-complex. We used the VirD2 protein as an affinity ligand to isolate VirD2-binding proteins (VBPs). By pull-down assays and peptide-mass-fingerprint matching, we identified an A. tumefaciens protein designated VBP1 that could bind VirD2 directly. Genome-wide sequence analysis showed that A. tumefaciens has two additional genes encoding proteins highly similar to VBP1, designated vbp2 and vbp3. Like VBP1, both VBP2 and VBP3 also could bind VirD2; all three VBPs contain a putative nucleotidyltransferase motif. Mutational analysis of vbp demonstrated that the three vbp genes could functionally complement each other. Consequently, only inactivation of all three vbp genes highly attenuated the bacterial ability to cause tumors on plants. Although vbp1 is harbored on the megaplasmid pAtC58, vbp2 and vbp3 reside on the linear chromosome. The vbp genes are clustered with conjugative transfer genes, suggesting linkage between the conjugation and virulence factor. The three VBPs appear to contain C-terminal positively charged residues, often present in the transfer substrate proteins of type IV secretion systems. Inactivation of the three vbp genes did not affect the T-strand production. Our data indicate that VBP is a newly identified virulence factor that may affect the transfer process subsequent to T-DNA production.     

Agrobacterium ParA/MinD-like VirC1 spatially coordinates early conjugative DNA transfer reactions

Agrobacterium tumefaciens translocates T-DNA through a polar VirB/D4 type IV secretion (T4S) system. VirC1, a factor required for efficient T-DNA transfer, bears a deviant Walker A and other sequence motifs characteristic of ParA and MinD ATPases. Here, we show that VirC1 promotes conjugative T-DNA transfer by stimulating generation of multiple copies per cell of the T-DNA substrate (T-complex) through pairwise interactions with the processing factors VirD2 relaxase, VirC2, and VirD1. VirC1 also associates with the polar membrane and recruits T-complexes to cell poles, the site of VirB/D4 T4S machine assembly. VirC1 Walker A mutations abrogate T-complex generation and polar recruitment, whereas the native protein recruits T-complexes to cell poles independently of other polar processing factors (VirC2, VirD1) or T4S components (VirD4 substrate receptor, VirB channel subunits). We propose that A. tumefaciens has appropriated a progenitor ParA/MinD-like ATPase to promote conjugative DNA transfer by: (i) nucleating relaxosome assembly at oriT-like T-DNA border sequences and (ii) spatially positioning the transfer intermediate at the cell pole to coordinate substrate-T4S channel docking.     

Several components of SKP1/Cullin/F-box E3 ubiquitin ligase complex and associated factors play a role in Agrobacterium-mediated plant transformation

? Successful genetic transformation of plants by Agrobacterium tumefaciens requires the import of bacterial T-DNA and virulence proteins into the plant cell that eventually form a complex (T-complex). The essential components of the T-complex include the single stranded T-DNA, bacterial virulence proteins (VirD2, VirE2, VirE3 and VirF) and associated host proteins that facilitate the transfer and integration of T-DNA. The removal of the proteins from the T-complex is likely achieved by targeted proteolysis mediated by VirF and the plant ubiquitin proteasome complex. ? We evaluated the involvement of the host SKP1/culin/F-box (SCF)-E3 ligase complex and its role in plant transformation. Gene silencing, mutant screening and gene expression studies suggested that the Arabidopsis homologs of yeast SKP1 (suppressor of kinetochore protein 1) protein, ASK1 and ASK2, are required for Agrobacterium-mediated plant transformation. ? We identified the role for SGT1b (suppressor of the G2 allele of SKP1), an accessory protein that associates with SCF-complex, in plant transformation. We also report the differential expression of many genes that encode F-box motif containing SKP1-interacting proteins (SKIP) upon Agrobacterium infection. ? We speculate that these SKIP genes could encode the plant specific F-box proteins that target the T-complex associated proteins for polyubiquitination and subsequent degradation by the 26S proteasome.     

Import of Agrobacterium T-DNA into plant nuclei: two distinct functions of VirD2 and VirE2 proteins

To study the mechanism of nuclear import of T-DNA, complexes consisting of the virulence proteins VirD2 and VirE2 as well as single-stranded DNA (ssDNA) were tested for import into plant nuclei in vitro. Import of these complexes was fast and efficient and could be inhibited by a competitor, a nuclear localization signal (NLS) coupled to BSA. For import of short ssDNA, VirD2 was sufficient, whereas import of long ssDNA additionally required VirE2. A VirD2 mutant lacking its C-terminal NLS was unable to mediate import of the T-DNA complexes into nuclei. Although free VirE2 molecules were imported into nuclei, once bound to ssDNA they were not imported, implying that when complexed to DNA, the NLSs of VirE2 are not exposed and thus do not function. RecA, another ssDNA binding protein, could substitute for VirE2 in the nuclear import of T-DNA but not in earlier events of T-DNA transfer to plant cells. We propose that VirD2 directs the T-DNA complex to the nuclear pore, whereas both proteins mediate its passage through the pore. Therefore, by binding to ssDNA, VirE2 may shape the T-DNA complex such that it is accepted for translocation into the nucleus.     

The VirD2 protein of Agrobacterlum tumefaciens carries nuclear localization signals important for transfer of T-DNA to plants

Agrobacterium tumefaciens is able to transfer a piece of DNA, the T-DNA, to the nucleus of the plant cell. The VirD2 protein is required for the production of the T-DNA, it is tightly linked to the T-DNA and it is thought to direct it to the plant genome. Two nuclear localization signals (NLS), one in the N-terminal part and one in the C-terminal part of the VirD2 protein, have been shown to be able to target marker proteins to the plant nucleus. Here we analyze nuclear entry of the T-DNA complex using a new and very sensitive assay for T-DNA transfer. We show that optimal T-DNA transfer requires the VirD2 NLS located in the C-terminal part of the protein, whereas mutations in the N-terminal NLS coding sequence seem to have no effect on T-DNA transfer.     

The VirD2 protein of Agrobacterlum tumefaciens carries nuclear localization signals important for transfer of T-DNA to plants

Agrobacterium tumefaciens is able to transfer a piece of DNA, the T-DNA, to the nucleus of the plant cell. The VirD2 protein is required for the production of the T-DNA, it is tightly linked to the T-DNA and it is thought to direct it to the plant genome. Two nuclear localization signals (NLS), one in the N-terminal part and one in the C-terminal part of the VirD2 protein, have been shown to be able to target marker proteins to the plant nucleus. Here we analyze nuclear entry of the T-DNA complex using a new and very sensitive assay for T-DNA transfer. We show that optimal T-DNA transfer requires the VirD2 NLS located in the C-terminal part of the protein, whereas mutations in the N-terminal NLS coding sequence seem to have no effect on T-DNA transfer.     

Association of the virD2 protein with the 5'' end of T strands in Agrobacterium tumefaciens.

The soil bacterium Agrobacterium tumefaciens can incite tumors in many dicotyledonous plants by transferring a portion (T-DNA) of its Ti plasmid into susceptible plant cells. The T-DNA is flanked by border sequences that serve as recognition sites for specific cleavage by an endonuclease that comprises two virD-encoded proteins (VirD1 and VirD2). After cleavage, both double-stranded, nicked T-DNA molecules and single-stranded T-DNA molecules (T strands) were present. We have determined that a protein is tightly associated with, and probably covalently attached to, the 5' end of the T strands. Analysis of deletion derivatives in Escherichia coli, immunoprecipitation, and a procedure combining immunoblot and nucleic acid hybridization data identified this protein as the gene product of virD2.     

农杆菌T-复合物的形成与转运研究进展

在简要介绍农杆菌T-DNA转运全过程的基础上,结合作者近年的工作,重点对T-复合物的形成和T-复合物在农杆菌细胞内的转运机理的最新进展进行归纳和评述．农杆菌能够将其Ti质粒上的一段DNA以单链DNA-蛋白质复合物(简称T-复合物)的形式,通过其细胞两端的四型分泌系统(typeⅣ secretion system,T4SS)转运到宿主植物中,并使宿主发生遗传转化,因而农杆菌介导的T-DNA转运技术已成为应用最广泛的植物转基因技术,同时,由于转运T-复合物的T4SS也是某些质粒接合转移和许多病源微生物分泌致病效应蛋白的通道,因此,农杆菌T-DNA转运机理的研究受到了广泛的重视和关注,使得这方面的研究进展非常迅速．     

Genetic analysis of the virD operon of Agrobacterium tumefaciens: a search for functions involved in transport of T-DNA into the plant cell nucleus and in T-DNA integration.

The transferred DNA (T-DNA) is transported from Agrobacterium tumefaciens to the nucleus and is stably integrated into the genome of many plant species. It has been proposed that the VirD2 protein, tightly attached to the T-DNA, pilots the T-DNA into the plant cell nucleus and that it is involved in integration. Using agroinfection and beta-glucuronidase expression as two different very sensitive transient assays for T-DNA transfer, together with assays for stable integration, we have shown that the C-terminal half of the VirD2 protein and the VirD3 protein are not involved in T-DNA integration. However, the bipartite nuclear localization signal, which is located within the C terminus of the VirD2 protein and which has previously been shown to be able to target a foreign protein into the plant cell nucleus, was shown to be required for efficient T-DNA transfer. virD4 mutants were shown by agroinfection to be completely inactive in T-DNA transfer.     

Analysis of Vir protein translocation from Agrobacterium tumefaciens using Saccharomyces cerevisiae as a model: evidence for transport of a novel effector protein VirE3

Agrobacterium tumefaciens causes crown gall disease on a variety of plants. During the infection process Agrobacterium transfers a nucleoprotein complex, the VirD2 T-complex, and at least two Vir proteins, VirE2 and VirF, into the plant cell via the VirB/VirD4 type IV secretion system. Recently, we found that T-DNA could also be transferred from Agrobacterium to Saccharomyces cerevisiae. Here, we describe a novel method to also detect trans-kingdom Vir protein transfer from Agrobacterium to yeast, using the Cre/lox system. Protein fusions between Cre and VirE2 or VirF were expressed in Agrobacterium. Transfer of the Cre-Vir fusion proteins from Agrobacterium to yeast was monitored by a selectable excision event resulting from site-specific recombination mediated by Cre on a lox-flanked transgene in yeast. The VirE2 and VirF proteins were transported to yeast via the virB-encoded transfer system in the presence of coupling factor VirD4, analogous to translocation into plant cells. The yeast system therefore provides a suitable and fast model system to study basic aspects of trans-kingdom protein transport from Agrobacterium into host cells. Using this method we showed that VirE2 and VirF protein transfer was inhibited by the presence of the Osa protein. Besides, we found evidence for a novel third effector protein, VirE3, which has a similar C-terminal signature to VirE2 and VirF.     

Will you let me use your nucleus? How Agrobacterium gets its T-DNA expressed in the host plant cell

Agrobacterium is the only known bacterium capable of natural DNA transfer into a eukaryotic host. The genes transferred to host plants are contained on a T-DNA (transferred DNA) molecule, the transfer of which begins with its translocation, along with several effector proteins, from the bacterial cell to the host-cell cytoplasm. In the host cytoplasm, the T-complex is formed from a single-stranded copy of the T-DNA (T-strand) associated with several bacterial and host proteins and it is imported into the host nucleus via interactions with the host nuclear import machinery. Once inside the nucleus, the T-complex is most likely directed to the host genome by associating with histones. Finally, the chromatin-associated T-complex is uncoated from its escorting proteins prior to the conversion of the T-strand to a double-stranded form and its integration into the host genome.     

The Agrobacterium tumefaciens virulence D2 protein is responsible for precise integration of T-DNA into the plant genome.

The VirD2 protein of Agrobacterium tumefaciens was shown to pilot T-DNA during its transfer to the plant cell nucleus. We analyze here its participation in the integration of T-DNA by using a virD2 mutant. This mutation reduces the efficiency of T-DNA transfer, but the efficiency of integration of T-DNA per se is unaffected. Southern and sequence analyses of integration events obtained with the mutated VirD2 protein revealed an aberrant pattern of integration. These results indicate that the wild-type VirD2 protein participates in ligation of the 5'-end of the T-strand to plant DNA and that this ligation step is not rate limiting for T-DNA integration.     

IMPa-4, an Arabidopsis importin alpha isoform, is preferentially involved in agrobacterium-mediated plant transformation

Successful transformation of plants by Agrobacterium tumefaciens requires that the bacterial T-complex actively escorts T-DNA into the host's nucleus. VirD2 and VirE2 are virulence proteins on the T-complex that have plant-functional nuclear localization signal sequences that may recruit importin alpha proteins of the plant for nuclear import. In this study, we evaluated the involvement of seven of the nine members of the Arabidopsis thaliana importin alpha family in Agrobacterium transformation. Yeast two-hybrid, plant bimolecular fluorescence complementation, and in vitro protein-protein interaction assays demonstrated that all tested Arabidopsis importin alpha members can interact with VirD2 and VirE2. However, only disruption of the importin IMPa-4 inhibited transformation and produced the rat (resistant to Agrobacterium transformation) phenotype. Overexpression of six importin alpha members, including IMPa-4, rescued the rat phenotype in the impa-4 mutant background. Roots of wild-type and impa-4 Arabidopsis plants expressing yellow fluorescent protein-VirD2 displayed nuclear localization of the fusion protein, indicating that nuclear import of VirD2 is not affected in the impa-4 mutant. Somewhat surprisingly, VirE2-yellow fluorescent protein mainly localized to the cytoplasm of both wild-type and impa-4 Arabidopsis cells and to the cytoplasm of wild-type tobacco (Nicotiana tabacum) cells. However, bimolecular fluorescence complementation assays indicated that VirE2 could localize to the nucleus when IMPa-4, but not when IMPa-1, was overexpressed.     

Polar location and functional domains of the Agrobacterium tumefaciens DNA transfer protein VirD4

Agrobacterium tumefaciens VirD4 is essential for DNA transfer to plants. VirD4 presumably functions as a coupling factor that facilitates communication between a substrate and the transport pore. To serve as a coupling protein, VirD4 may be required to localize near the transport apparatus. In a previous study, we observed that several constituents of the transport apparatus localize to the cell membranes. In this study, we demonstrate that VirD4 has a unique cellular location. In immunofluorescence microscopy, cells probed with anti-VirD4 antibodies had foci of fluorescence primarily at the cell poles, indicating that VirD4 localizes to the cell pole. Polar location of VirD4 was not dependent on T-DNA processing, the formation of the transport apparatus and the presence of other Vir proteins. VirD4 is an integral membrane protein with one periplasmic domain. The large cytoplasmic region contains a nucleotide-binding domain. To investigate the role of these domains in DNA transfer, we introduced mutations in virD4 and studied the effect of a mutation on substrate transfer. A deletion of most of the periplasmic domain as well as the alterations of glycine 151 to serine and lysine 152 to alanine led to the complete loss of DNA transfer, indicating that both domains are essential for substrate transfer. Subcellular localization of the mutant proteins indicated that both the periplasmic and the nucleotide-binding domains are required for polar localization of VirD4. The periplasmic domain mutant VirD4Delta36-61 was distributed throughout the cell membrane, whereas the nucleotide binding site mutant VirD4G151S localized to sites other than the cell poles. Polar location of VirD4 suggests a role for the cell pole in DNA transfer.     

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.     

VirD4-independent transformation by CloDF13 evidences an unknown factor required for the genetic colonization of plants via Agrobacterium

Agrobacterium uses a mechanism similar to conjugation for trans-kingdom transfer of its oncogenic T-DNA. A defined VirB/VirD4 Type IV secretion system is responsible for such a genetic transfer. In addition, certain virulence proteins as VirE2 can be mobilized into host cells by the same apparatus. VirE2 is essential to achieve plant but not yeast transformation. We found that the limited host range plasmid CloDF13 can be recruited by the virulence apparatus of Agrobacterium for transfer to eukaryotic hosts. As expected the VirB transport complex was required for such trans-kingdom DNA transfer. However, unexpectedly, the coupling factor VirD4 turned out to be necessary for transfer to plants but not for transport into yeast. The CloDF13 encoded coupling factor (Mob) was essential for transfer to both plants and yeast though. This is interpreted by the different specificities of Mob and VirD4. Hence, Mob being required for the transport of the CloDF13 transferred DNA (to both plants and yeast) and VirD4 being required for transport of virulence proteins such as VirE2. Nevertheless, the presence of the VirE2 protein in the host plant was not sufficient to restore the deficiency for VirD4 in the transforming bacteria. We propose that Mob functions encoded by the plasmid CloDF13 are sufficient for DNA mobilization to eukaryotic cells but that the VirD4-mediated pathway is essential to achieve DNA nuclear establishment specifically in plants. This suggests that other Agrobacterium virulence proteins besides VirE2 are translocated and essential for plant transformation.     

Construction of transposon Tn3phoA: its application in defining the membrane topology of the Agrobacterium tumefaciens DNA transfer proteins

Protein fusion with the Escherichia coli alkaline phosphatase is used extensively for the analysis of the topology of membrane proteins. To study the topology of the Agrobacterium T-DNA transfer proteins, we constructed a transposon, Tn 3phoA . The transposon mobilizes into plasmids at a high frequency, is stable after transposition, can produce phoA translational fusions and can be used for the analysis of protein topology directly in the bacterium of interest. For studies on the DNA transfer proteins, an Agrobacterium strain deficient in phoA under our experimental conditions was constructed by chemical mutagenesis. A plasmid containing virB and virD4 was used as a target for mutagenesis. Twenty-eight unique phoA -positive clones that mapped to eight virB genes were isolated. Multiple insertions throughout VirB1, VirB5, VirB7, VirB9 and VirB10 indicated that these proteins primarily face the periplasm. Insertions in VirB2, VirB6 and VirB8 allowed the identification of their periplasmic domains. No insertions were found in VirB3, VirB4 and VirB11. These proteins either lack or have a short periplasmic domain. No insertions mapped to VirD4 either. To study VirD4 topology, targeted phoA fusions and random lacZ fusions were constructed. Analysis of the fusion proteins indicated that VirD4 contains a single periplasmic domain near the N-terminus, and most of the protein lies in the cytoplasm. A hypothetical model for the T-DNA transport pore is presented.     

Caspase-resistant VirD2 protein provides enhanced gene delivery and expression in plants

Agrobacterium tumefaciens VirD2 protein is one of the key elements of Agrobacterium-mediated plant transformation, a process of transfer of T-DNA sequence from the Agrobacterium tumour inducing plasmid into the nucleus of infected plant cells and its integration into the host genome. The VirD2 protein has been shown to be a substrate for a plant caspase-like protease activity (PCLP) in tobacco. We demonstrate here that mutagenesis of the VirD2 protein to prevent cleavage by PCLP increases the efficiency of reporter gene transfer and expression. These results indicate that PCLP cleavage of the Agrobacterium VirD2 protein acts to limit the effectiveness of T-DNA transfer and is a novel resistance mechanism that plants utilise to combat Agrobacterium infection. Brian Reavy and Svetlana Bagirova contributed equally to this work.     

VirE2, a type IV secretion substrate,interacts with the VirD4 transfer protein at cell poles of Agrobacterium tumefaciens

Agrobacterium tumefaciens transfers oncogenic DNA and effector proteins to plant cells during the course of infection. Substrate translocation across the bacterial cell envelope is mediated by a type IV secretion (TFS) system composed of the VirB proteins, as well as VirD4, a member of a large family of inner membrane proteins implicated in the coupling of DNA transfer intermediates to the secretion machine. In this study, we demonstrate with novel cytological screens - a two-hybrid (C2H) assay and bimolecular fluorescence complementation (BiFC) - and by immunoprecipitation of chemically cross-linked protein complexes that the VirE2 effector protein interacts directly with the VirD4 coupling protein at cell poles of A. tumefaciens. Analyses of truncation derivatives showed that VirE2 interacts via its C terminus with VirD4, and, further, an NH2-terminal membrane-spanning domain of VirD4 is dispensable for complex formation. VirE2 interacts with VirD4 independently of the virB-encoded transfer machine and T pilus, the putative periplasmic chaperones AcvB and VirJ, and the T-DNA transfer intermediate. Finally, VirE2 is recruited to polar-localized VirD4 as a complex with its stabilizing secretion chaperone VirE1, yet the effector-coupling protein interaction is not dependent on chaperone binding. Together, our findings establish for the first time that a protein substrate of a type IV secretion system is recruited to a member of the coupling protein superfamily.     

Right-hand border regions of octopine T-DNA are recognized by RNA polymerase of Agrobacterium as well as by VirD1 and VirD2 proteins.

The T-DNA of octopine Ti plasmid of Agrobacterium tumefaciens contains TL- and TR-DNA regions each bounded by 25 base-pair-repeats (designated A, B, C and D from left to right). Short DNA segments containing the borders B, C and D were found to function as promoter when placed in the rightward orientation upstream of promoter-less lacZ. Promoter consensus sequence of Agrobacterium were found within these border repeats and in their adjacent regions. The expression of lacZ was low when the segments contained the overdrive, a sequence known to enhance T-DNA transfer. Simultaneous overproduction of VirD1 and D2 proteins, endonuclease acting on the border repeats, interfered with the promoter functions of the border segments. In spite of their activity under these conditions, the border regions do not seem to be involved in the gene expression, because they are not followed by appropriate open reading frames. We propose that RNA polymerase of Agrobacterium competes with VirD products for T-DNA borders and thereby affects the transfer of T-DNA.