Transfer of T-DNA from agrobacteria into plant cells through cell walls and membranes

Discusses probable routes of agrobacterial penetration through the plant integumental tissues, cell wall, and plant cell plasmodesma. Analyzes the contribution of extracellular structures of agrobacteria in penetration through barriers of a plant cell, primary contact (adhesion), and during DNA transfer from bacterial (E. coli, A. tumefaciens) to recipient (bacterial or plant) cells. Discusses the relationship between donor cell adhesion to recipient cell surface and the infectious and conjugation processes. Considers the probable role of piles in conjugative transfer of agrobacterial DNA through membranes of donor and recipient (bacterial and plant) cells. Analyzes the contribution of the plant cell cytoskeleton to T-DNA transfer. Suggests a model of transport of T-DNA-VirD2 complex and VirE2 proteins through independent channels consisting of vir-coded proteins.     

VirE2: a unique ssDNA-compacting molecular machine

The translocation of single-stranded DNA (ssDNA) across membranes of two cells is a fundamental biological process occurring in both bacterial conjugation and Agrobacterium pathogenesis. Whereas bacterial conjugation spreads antibiotic resistance, Agrobacterium facilitates efficient interkingdom transfer of ssDNA from its cytoplasm to the host plant cell nucleus. These processes rely on the Type IV secretion system (T4SS), an active multiprotein channel spanning the bacterial inner and outer membranes. T4SSs export specific proteins, among them relaxases, which covalently bind to the 5' end of the translocated ssDNA and mediate ssDNA export. In Agrobacterium tumefaciens, another exported protein—VirE2—enhances ssDNA transfer efficiency 2000-fold. VirE2 binds cooperatively to the transferred ssDNA (T-DNA) and forms a compact helical structure, mediating T-DNA import into the host cell nucleus. We demonstrated—using single-molecule techniques—that by cooperatively binding to ssDNA, VirE2 proteins act as a powerful molecular machine. VirE2 actively pulls ssDNA and is capable of working against 50-pN loads without the need for external energy sources. Combining biochemical and cell biology data, we suggest that, in vivo, VirE2 binding to ssDNA allows an efficient import and pulling of ssDNA into the host. These findings provide a new insight into the ssDNA translocation mechanism from the recipient cell perspective. Efficient translocation only relies on the presence of ssDNA binding proteins in the recipient cell that compacts ssDNA upon binding. This facilitated transfer could hence be a more general ssDNA import mechanism also occurring in bacterial conjugation and DNA uptake processes.     

Transfer of genetic information from agrobacteria to bacterial and plant cells: membrane and supramembrane structures involved in transfer

The review deals with the supramembrane and membrane structures involved in the initial contact (attachment) of an agrobacterial cell with a bacterial or plant cell during the transfer of the agrobacterial genetic information. The relationships between the donor cell attachment to the recipient cell surface and the infection and conjugation processes are discussed. Experimental data on the recently found agrobacterial pili and surface protein rhicadhesin, which are involved in the conjugative transfer of the plasmid between agrobacteria, are considered. The role of adhesive and conjugative pili of E. coli in the initial and tight contacts is analyzed in the context of the recently proved similarity between the mechanisms of agrobacterial transformation in plants and conjugative transfer in bacteria. Possible involvement of the pilus in the conjugative transfer of agrobacterial DNA across the membranes of donor and recipient (bacterial and plant) cells is discussed.     

Formation of extracellular structures in conjugated cultures of agrobacteria

Electron microscopy of noncentrifugated agrobacterial cells on a nitrocellulose membrane labeled with colloid gold-conjugated antibodies to VirB1 showed that the labeled complex bound to acetosyringone (AS)-induced cells but failed to form red-colored stains during incubation with Ti aplasmid cells. Supramembrane structures of AS-treated A. tumefaciens cells were for the first time visualized by transmission electron microscopy. Colloid gold labeling of VirB2-specific antibodies showed that VirB2 proteins produce long thin pilus structures emerging at the poles of AS-induced agrobacterial cells but never on the surface untreated with AS and Ti-plasmid-free agrobacterial cells. As a rule, one (or rarely two) thread-like connections and bridges were observed between the cells at the primary contact stage. The bridges were not destroyed by SDS, did not react with VirB2-specific antibodies, and remained visible at 30 degrees C. Visible close contacts between mating bacteria did not cease after SDS treatment. SDS pretreatment of donor cells or a mating cell suspension significantly modified the efficiency of pTd33 plasmid transfer from donor to recipient agrobacterial cells. In the presence of AS the optimal temperature for transfer was 25 degrees C. The frequency of plasmid pTd33 transfer from A. tumefaciens via vir-dependent pathway decreased 2-4-fold due to increase of temperature from 19.25 to 31 degrees C.     

Formation of TRA-dependent surface structures in Agrobacterium tumefaciens and their absence in R1 (deltatraR) mutant

Agrobacteria have Ti plasmid DNA delivering systems for the transfer to recipient cells by the conjugation mechanism. This transfer is absolutely dependent on induction tra genes. It is not clear which tra-dependent surface (extracellular) proteins (structures) are involved in the transport mechanism and whether these proteins also play a role in the contact formation. SDS-PAGE electrophoresis of proteins released from the cell showed disappearance of 63 and 67 kD proteins in R1(delta traR) strain, which were found in the growth medium and triton extract from the outer membrane of Ti plasmid-harboring A. tumefaciens R10 strains. The traR defective mutant did not express these proteins and had a higher hemagglutination and flocculation capacity than the wild strain. On the other hand, the wild strain showed D-galactose and N-acetyl-galactosamine specific hemagglutination which was not shown by traR mutant. Motility and chemotactic behavior of traR mutant in semisolid medium were defective. As a rule, one (or rarely two) thread-like connections in vir(-) and tra(+) conditions were observed on the agrobacterial cell surface. SDS pretreatment of agrobacterial cells had a significant effect on the expression of tra-dependent surface structures.     

Transkingdom Genetic Transfer from Escherichia coli to Saccharomyces cerevisiae as a Simple Gene Introduction Tool

Transkingdom conjugation (TKC) permits transfer of DNA from bacteria to eukaryotic cells using a bacterial conjugal transfer system. However, it is not clear whether the process of DNA acceptance in a recipient eukaryote is homologous to the process of conjugation between bacteria. TKC transfer requires mobilizable shuttle vectors that are capable of conjugal transfer and replication in the donor and recipient strains. Here, we developed TKC vectors derived from plasmids belonging to the IncP and IncQ groups. We also investigated forms of transfer of these vectors from Escherichia coli into Saccharomyces cerevisiae to develop TKC as a simple gene introduction method. Both types of vectors were transferred precisely, conserving the origin of transfer (oriT) sequences, but IncP-based vectors appeared to be more efficient than an IncQ-based vector. Interestingly, unlike in agrobacterial T-DNA (transfer DNA) transfer, the efficiency of TKC transfer was similar between a wild-type yeast strain and DNA repair mutants defective in homologous recombination (rad51Δ and rad52Δ) or nonhomologous end joining (rad50Δ, yku70Δ, and lig4Δ). Lastly, a shuttle vector with two repeats of IncP-type oriT (oriT^P) sequences flanking a marker gene was constructed. TKC transfer of this vector resulted in precise excision of both the oriT^P loci as well as the marker gene, albeit at a low frequency of 17% of all transconjugants. This feature would be attractive in biotechnological applications of TKC. Taken together, these results strongly suggest that in contrast to agrobacterial T-DNA transfer, the circularization of vector single-stranded DNA occurs either before or after transfer but requires a factor(s) from the donor. TKC is a simple method of gene transfer with possible applications in yeast genetics and biotechnology.     

Role of Agrobacterium VirB11 ATPase in T-pilus assembly and substrate selection

The VirB11 ATPase is a subunit of the Agrobacterium tumefaciens transfer DNA (T-DNA) transfer system, a type IV secretion pathway required for delivery of T-DNA and effector proteins to plant cells during infection. In this study, we examined the effects of virB11 mutations on VirB protein accumulation, T-pilus production, and substrate translocation. Strains synthesizing VirB11 derivatives with mutations in the nucleoside triphosphate binding site (Walker A motif) accumulated wild-type levels of VirB proteins but failed to produce the T-pilus or export substrates at detectable levels, establishing the importance of nucleoside triphosphate binding or hydrolysis for T-pilus biogenesis. Similar findings were obtained for VirB4, a second ATPase of this transfer system. Analyses of strains expressing virB11 dominant alleles in general showed that T-pilus production is correlated with substrate translocation. Notably, strains expressing dominant alleles previously designated class II (dominant and nonfunctional) neither transferred T-DNA nor elaborated detectable levels of the T-pilus. By contrast, strains expressing most dominant alleles designated class III (dominant and functional) efficiently translocated T-DNA and synthesized abundant levels of T pilus. We did, however, identify four types of virB11 mutations or strain genotypes that selectively disrupted substrate translocation or T-pilus production: (i) virB11/virB11* merodiploid strains expressing all class II and III dominant alleles were strongly suppressed for T-DNA translocation but efficiently mobilized an IncQ plasmid to agrobacterial recipients and also elaborated abundant levels of T pilus; (ii) strains synthesizing two class III mutant proteins, VirB11, V258G and VirB11.I265T, efficiently transferred both DNA substrates but produced low and undetectable levels of T pilus, respectively; (iii) a strain synthesizing the class II mutant protein VirB11.I103T/M301L efficiently exported VirE2 but produced undetectable levels of T pilus; (iv) strains synthesizing three VirB11 derivatives with a four-residue (HMVD) insertion (L75.i4, C168.i4, and L302.i4) neither transferred T-DNA nor produced detectable levels of T pilus but efficiently transferred VirE2 to plants and the IncQ plasmid to agrobacterial recipient cells. Together, our findings support a model in which the VirB11 ATPase contributes at two levels to type IV secretion, T-pilus morphogenesis, and substrate selection. Furthermore, the contributions of VirB11 to machine assembly and substrate transfer can be uncoupled by mutagenesis.     

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.     

Agrobacterium tumefaciens-gene transfer into wheat tissues

DNA can be transferred by Agrobacterium tumefaciens to wheat, albeit at very low frequencies. Transfer of agrobacterial DNA occurred in cultures where the embryos had been subjected to partial enzymatic digestion prior to cocultivation with the bacteria. It is unclear whether this is by the normal process mediated by the Ti virulence genes and the border repeats of the T-DNA. The Southern hybridization patterns indicate that in one cell line the T-DNA had undergone extensive rearrangements, and might indicate that the process of T-DNA transfer and integration might differ in the case of cereals. This could suggest the method of transfer and ultimately the expression of these genes in cereal cells may be different to that observed in other monocotyledonous and dicotyledonous species.     

VirE2-dependent pores for ssDNA transfer across artificial and cell membranes

The transfer of single-stranded (ss) T-DNA from soil bacteria of the genus Agrobacterium with the help of the VirE2 protein, which possibly mediates the delivery of ss-T-DNA across the cell membrane, was demonstrated earlier, but how VirE2 participates in ssDNA transfer across artificial and natural membranes is not known. Using computational methods, we reconstructed model structures composed of two and four VirE2 proteins and showed by the MOLE program the formation of pores with channel diameters of 1.2-1.6 and 1.4-4.6 nm in a model structure formed from two and four VirE2 molecules, respectively. Using light scattering, we recorded the size distribution for recombinant VirE2-dependent complexes in aqueous solutions and found that VirE2 in a buffer solution is present as a complex made up of two or more proteins. We revealed single, long-lived jumps in voltage-dependent membrane conductance during coincubation of planar black membranes with the VirE2 protein. On the addition of VirE2 and FAM-labeled oligonucleotides to HeLa cells, the fluorescence intensity for the cells increased by 56% as compared to that for cells incubated only with oligonucleotides.     

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.     

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.     

Genetically Transformed Plant Roots as a Model for Studying Specific Metabolism and Symbiotic Contacts of the Root System

Genetic transformation of plants mediated by Ri plasmid ofAgrobacterium rhizogenes occupies a special place in plant cell engineering, since this technique based on a natural phenomenon allows cultivation of isolated growing plant roots on hormone-free media. Application of wild-type unmodified agrobacterial strains allows us to obtain root cultures capable of long-term growth in vitro due to an increased sensitivity of the cells to auxins while other biochemical properties remain unaltered. A collection of pRi T-DNA transformed roots of certain dicotyledons was made; some strains in it are used to study synthesis of secondary metabolites in root cells. Thein vitro cultivated roots could synthesize root-specific metabolites, which makes possible their application for large-scale biotechnological production of ecologically pure crude drugs. Cocultivation of pRi T-DNA transformed roots with arbuscular mycorrhizal fungi makes possible vital study of all stages of obligate symbiont development and interaction with plant roots. Dual axenic culture of AM fungi and pRi T-DNA transformed plants can be used to make a collection of the most valuable endomycorrhizal fungal species and to produce considerable quantities of homogeneous fungal inoculums.     

Functional domains of Agrobacterium tumefaciens single-stranded DNA-binding protein VirE2.

The transferred DNA (T-DNA) portion of the Agrobacterium tumefaciens tumor-inducing (Ti) plasmid enters infected plant cells and integrates into plant nuclear DNA. Direct repeats define the T-DNA ends; transfer begins when the VirD2 endonuclease produces a site-specific nick in the right-hand border repeat and attaches to the 5' end of the nicked strand. Subsequent events liberate the lower strand of the T-DNA from the Ti plasmid, producing single-stranded DNA molecules (T strands) that are covalently linked to VirD2 at their 5' ends. A. tumefaciens appears to transfer T-DNA into plant cells as a T-strand-VirD2 complex. The bacterium also transports VirE2, a cooperative single-stranded DNA-binding protein, into plant cells during infection. Both VirD2 and VirE2 contain nuclear localization signals that may direct these proteins, and bound T strands, into plant nuclei. Here we report the locations of functional regions of VirE2 identified by eight insertions of XhoI linker oligonucleotides, and one deletion mutation, throughout virE2. We examined the effects of these mutations on virulence, single-stranded DNA (ssDNA) binding, and accumulation of VirE2 in A. tumefaciens. Two of the mutations in the C-terminal half of VirE2 eliminated ssDNA binding, whereas two insertions in the N-terminal half altered cooperativity. Four of the mutations, distributed throughout virE2, decreased the stability of VirE2 in A. tumefaciens. In addition, we isolated a mutation in the central region of VirE2 that decreased tumorigenicity but did not affect ssDNA binding or VirE2 accumulation. This mutation may affect export of VirE2 into plant cells or nuclear localization of VirE2, or it may affect an uncharacterized activity of VirE2.     

Transfer of cytoplasmic and nuclear proteins between cells in culture

Evidence is presented for transfer of proteins between cells in culture, using techniques which previously have shown RNA transfer and the lack of DNA transfer between cells in culture. These techniques involved making donor cells heavier than recipient cells by having them ingest tantalum particles. After coculture of donor and recipient cells the two cell types were separated by centri- fugation on Ficoll gradients and the recipient cells analyzed for radioactively labeled proteins that may have passed from the prelabeled donor cells.These techniques also provided evidence for passage of donor cell proteins to recipient cell nuclei. Examination of the nuclear proteins in the recipient cells revealed that histones were transferred intercellularly to a greater extent than other nuclear proteins. The histone subfractions in the recipient cell nuclei were studied by acrylamide gel electrophoresis. No major differences were found in the proportion of each histone subfraction that was transferred to the recipient cell nuclei.     

Supramolecular complexes of the <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis> virulence protein VirE2

Virulence protein VirE2 from Agrobacterium tumefaciens is involved in plant infection by transferring a fragment of agrobacterial Ti plasmid ssT-DNA in complex with VirE2-VirD2 proteins into the plant cell nucleus. The VirE2 protein interactions with ssDNA and formation of VirE2 protein complexes in vitro and in silico have been studied. Using dynamic light scattering we found that purified recombinant protein VirE2 exists in buffer solution in the form of complexes of 2–4 protein molecules of 12–18 nm size. We used computer methods to design models of complexes consisting of two and four individual VirE2 proteins, and their dimensions were estimated. Dimensions of VirE2 complexes with ssDNA (550 and 700 nucleotide residues) were determined using transmission electron microscopy and dynamic light scattering. We found that in vitro, upon interaction with ssDNA recombinant protein, VirE2 is able to alter conformation of the latter by shortening the initial length of the ssDNA.     

Ti plasmid type affects T-DNA processing in Agrobacterium tumefaciens

Agrobacterium tumefaciens can transfer the T-DNA region of a Ti plasmid to a recipient plant cell. An accepted model that describes the T-DNA transfer mechanism proposes that single-stranded T-complexes are transferred to a recipient plant via a conjugation-like mechanism. This model has been based on examination of a limited number of Ti plasmids. In this study, the type of processed T-DNA molecule created from multiple Ti plasmids was determined. The form of the processed T-DNA was found to vary and was correlated with whether the T-DNA region was organized as a single continuous region or two adjacent regions.     

Protein transfer into the recipient cell during bacterial conjugation: studies with F and RP4

Transfer of donor cell proteins to the recipient bacterium was examined in F- and RP4-mediated conjugation. Transfer of a 120 kD polypeptide, identified as the larger product of the plasmid DNA primase gene, was readily detected during RP4-promoted conjugation. The protein was transmitted to the cytoplasm of the recipient, presumably complexed to the transferred ssDNA. F DNA was transferred without detectable association with any cytoplasmic tra protein or with the ssDNA-binding protein encoded by the plasmid. However, a 92 kD protein, possibly F TraD product, was transmitted to the membrane fraction of the recipient cell.     

Expression of VirB2 protein-containing structures on Agrobacterium in mating cultures

Exocellular structures containing VirB2 proteins were, for the first time, localized on the surface of Agrobacterium by transmission electron microscopy. Using colloidal gold (CG)-labeled VirB2-specific antibodies, it was shown that VirB2 proteins enter into the composition of short surface pili, which emerge at the poles of acetosyringone (AS)-induced Agrobacterium cells. However, cells of the Ti plasmidless A. tumefaciens strain UBAPF-2 and cells not induced with AS were incapable of pilus synthesis. In suspension, mating Agrobacterium cells were connected together by short thick bridges. It was found that these bridges did not include as part of their structure CG-labeled VirB1 and VirB2 proteins. We did not find the tetracycline-resistant transconjugants after mating of A. tumefaciens donor cells harboring binary systems with plasmid-free A. tumefaciens GM-I 9023 in vir-induced and vir-uninduced conditions. However, the same strains can transfer pSUP106 plasmid via a vir-dependent way. We found that activated vir genes slightly stimulate pTd33 plasmid transfer via a tra-dependent pathway to plasmid-free strain UBAPF-2. It seems, that vir-induced T-DNA/plasmid DNA transfer machinery is not essential for the conjugation process between agrobacterial cells but may participate in this process.     

Isolation, purification, and identification of the virulence protein VirE2 from Agrobacterium tumefaciens

Bacteria of the genus Agrobacterium can transfer a portion of their Ti plasmid (T-DNA) in complex with the VirE2 and VirD2 proteins into the plant-cell nucleus and cause it to be integrated in the host-cell chromosomes. The mechanism of T-DNA transfer across the plant-cell membrane and cytoplasm is unknown. The aim of this study was to isolate the virulence protein VirE2 in order to explore its role in T-DNA transfer across the eukaryotic-cell membrane and cytoplasm. To obtain VirE2, we cloned the virE2 gene into plasmid pQE31 in Escherichia coli cells. VirE2 protein was isolated from E. coli XL-1 blue cells containing a recombinant plasmid, pQE31-virE2. The cells were ultrasonically disrupted, and the protein containing six histidine residues at the N-terminal end was isolated by affinity chromatography on Ni-NTA agarose. The purified preparation was tested by immunodot, by using polyclonal rabbit antibodies and miniantibodies produced toward VirE2. The capacity of the recombinant protein VirE2 for interacting with single-stranded DNA was tested by the formation of complexes, recorded by agarose-gel electrophoresis. In summary, A. tumefaciens virulence protein VirE2, capable of forming a complex with single-stranded T-DNA during transfer into the plant cell, was isolated, purified, and partially characterized. Anti-VirE2 miniantibodies were obtained, and direct labeling of VirE2 with colloidal gold was done for the first time.