The Conjugal Intermediate of Plasmid RSF1010 Inhibits Agrobacterium tumefaciens Virulence and VirB-Dependent Export of VirE2

Agrobacterium tumefaciens causes crown gall disease by transferring oncogenic, single-stranded DNA (T strand), covalently attached to the VirD2 protein, across the bacterial envelope into plant cells where its expression results in tumor formation. The single-stranded DNA binding protein VirE2 is also transferred into the plant cell, though the location at which VirE2 interacts with the T strand is still under investigation. The movement of the transferred DNA and VirE2 from A. tumefaciens to the plant cell depends on the membrane-localized VirB and VirD4 proteins. Further, the movement of the IncQ broad-host-range plasmid RSF1010 between Agrobacterium strains or from Agrobacterium to plants also requires the virB-encoded transfer system. Our earlier studies showed that the presence of the RSF1010 plasmid in wild-type strains of Agrobacterium inhibits both their virulence and their capacity to transport VirE2, as assayed by coinfection with virE mutants. Here we demonstrate that the capacity to form a conjugal intermediate of RSF1010 is necessary for this inhibition, suggesting that the transferred form of the plasmid competes with the VirD2-T strand and/or VirE2 for a common export site.     

Bacterial Conjugation Protein MobA Mediates Integration of Complex DNA Structures into Plant Cells

Agrobacterium tumefaciens transfers T-DNA to plant cells, where it integrates into the genome, a property that is ensured by bacterial proteins VirD2 and VirE2. Under natural conditions, the protein MobA mobilizes its encoding plasmid, RSF1010, between different bacteria. A detailed analysis of MobA-mediated DNA mobilization by Agrobacterium to plants was performed. We compared the ability of MobA to transfer DNA and integrate it into the plant genome to that of pilot protein VirD2. MobA was found to be about 100-fold less efficient than VirD2 in conducting the DNA from the pTi plasmid to the plant cell nucleus. However, interestingly, DNAs transferred by the two proteins were integrated into the plant cell genome with similar efficiencies. In contrast, most of the integrated DNA copies transferred from a MobA-containing strain were truncated at the 5' end. Isolation and analysis of the most conserved 5' ends revealed patterns which resulted from the illegitimate integration of one transferred DNA within another. These complex integration patterns indicate a specific deficiency in MobA. The data conform to a model according to which efficiency of T-DNA integration is determined by plant enzymes and integrity is determined by bacterial proteins.     

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.     

The ternary transformation system: constitutive virG on a compatible plasmid dramatically increases Agrobacterium-mediated plant transformation

This paper describes a so-called ternary transformation system for plant cells. We demonstrate that Agrobacterium tumefaciens strain LBA4404 supplemented with a constitutive virG mutant gene (virGN54D) on a compatible plasmid is capable of very efficient T-DNA transfer to a diverse range of plant species. For the plant species Catharanthus roseus it is shown that increased T-DNA transfer results in increased stable transformation frequencies. Analysis of stably transformed C. roseus cell lines showed that, although the T-DNA transfer frequency is greatly enhanced by addition of virGN54D, only one or a few T-DNA copies are stably integrated into the plant genome. Thus, high transformation frequencies of different plant species can be achieved by introduction of a ternary plasmid carrying a constitutive virG mutant into existing A. tumefaciens strains in combination with standard binary vectors.     

Inhibition of VirB-mediated transfer of diverse substrates from Agrobacterium tumefaciens by the IncQ plasmid RSF1010.

The transfer of DNA from Agrobacterium tumefaciens into a plant cell requires the activities of several virulence (vir) genes that reside on the tumor-inducing (Ti) plasmid. The putative transferred intermediate is a single-stranded DNA (T strand), covalently attached to the VirD2 protein and coated with the single-stranded DNA-binding protein, VirE2. The movement of this intermediate out of Agrobacterium cells and into plant cells requires the expression of the virB operon, which encodes 11 proteins that localize to the membrane system. Our earlier studies showed that the IncQ broad-host-range plasmid RSF1010, which can be transferred from Agrobacterium cells to plant cells, inhibits the transfer of T-DNA from pTiA6 in a fashion that is reversed by overexpression of virB9, virB10, and virB11. Here, we examined the specificity of this inhibition by following the transfer of other T-DNA molecules. By using extracellular complementation assays, the effects of RSF1010 on movement of either VirE2 or an uncoated T strand from A. tumefaciens were also monitored. The RSF1010 derivative plasmid pJW323 drastically inhibited the capacity of strains to serve as VirE2 donors but only partially inhibited T-strand transfer from virE2 mutants. Further, we show that all the virB genes tested are required for the movement of VirE2 and the uncoated T strand as assayed by extracellular complementation. Our results are consistent with a model in which the RSF1010 plasmid, or intermediates from it, compete with the T strand and VirE2 for a common transport site.     

In vitro cleavage of double- and single-stranded DNA by plasmid RSF1010-encoded mobilization proteins.

We have used purified RSF1010 mobilization proteins to reproduce in vitro a strand-specific nicking at the plasmid origin of transfer, oriT. In the presence of Mg2+, the proteins MobA (78-kDa form of RSF1010 DNA primase), MobB, and MobC and supercoiled or linear duplex oriT DNA form large amounts of a cleavage complex, which is characterized by its sensitivity to protein-denaturant treatment. Upon addition of SDS to such a complex, a single strand break is generated in the DNA, and MobA is found linked to the 5' nick terminus, presumably covalently. The double-strand nicking activity of MobA requires, in addition to Mg2+, the presence of MobC and is stimulated by the presence of MobB. The nick site has been shown by DNA sequencing to lie at the position cleaved in vivo during transfer, between nucleotides 3138/3139 in the r strand of RSF1010. We have found that MobA will also cleave DNA at sites other than oriT if the DNA is present in single-stranded form. Breakage in this case occurs in the absence of denaturing conditions, and after prolonged incubation, reclosure can be demonstrated.     

Involvement of Rad52 in T‐DNA circle formation during Agrobacterium tumefaciens‐mediated transformation of Saccharomyces cerevisiae

Agrobacterium tumefaciens cells carrying a tumour inducing plasmid (Ti‐plasmid) can transfer a defined region of transfer DNA (T‐DNA) to plant cells as well as to yeast. This process of Agrobacterium‐mediated transformation (AMT) eventually results in the incorporation of the T‐DNA in the genomic DNA of the recipient cells. All available evidence indicates that T‐strand transfer closely resembles conjugal DNA transfer as found between Gram‐negative bacteria. However, where conjugal plasmid DNA transfer starts via relaxase‐mediated processing of a single origin of transfer (oriT), the T‐DNA is flanked by two imperfect direct border repeats which are both substrates for the Ti‐plasmid encoded relaxase VirD2. Yeast was used as a model system to investigate the requirements of the recipient cell for the formation of T‐DNA circles after AMT. It was found that, despite the absence of self‐homology on the T‐DNA, the homologous repair proteins Rad52 and Rad51 are involved in T‐DNA circle formation. A model is presented involving the formation of T‐DNA concatemers derived from T‐strands by a process of strand‐transfer catalysed by VirD2. These concatemers are then resolved into T‐DNA circles by homologous recombination in the recipient cell.     

Agrobacterium tumefaciens oncogenic suppressors inhibit T-DNA and VirE2 protein substrate binding to the VirD4 coupling protein

Agrobacterium tumefaciens uses a type IV secretion (T4S) system composed of VirB proteins and VirD4 to deliver oncogenic DNA (T-DNA) and protein substrates to susceptible plant cells during the course of infection. Here, by use of the Transfer DNA ImmunoPrecipitation (TrIP) assay, we present evidence that the mobilizable plasmid RSF1010 (IncQ) follows the same translocation pathway through the VirB/D4 secretion channel as described previously for the T-DNA. The RSF1010 transfer intermediate and the Osa protein of plasmid pSa (IncW), related in sequence to the FiwA fertility inhibition factor of plasmid RP1 (IncPalpha), render A. tumefaciens host cells nearly avirulent. By use of a semi-quantitative TrIP assay, we show that both of these 'oncogenic suppressor factors' inhibit binding of T-DNA to the VirD4 substrate receptor. Both factors also inhibit binding of the VirE2 protein substrate to VirD4, as shown by coimmunoprecipitation and bimolecular fluorescence complementation assays. Osa fused to the green fluorescent protein (GFP) also blocks T-DNA and VirE2 binding to VirD4, and Osa-GFP colocalizes with VirD4 at A. tumefaciens cell poles. RSF1010 and Osa interfere specifically with VirD4 receptor function and not with VirB channel activity, as shown by (i) TrIP and (ii) a genetic screen for effects of the oncogenic suppressors on pCloDF13 translocation through a chimeric secretion channel composed of the pCloDF13-encoded MobB receptor and VirB channel subunits. Our findings establish that a competing plasmid substrate and a plasmid fertility inhibition factor act on a common target, the T4S receptor, to inhibit docking of DNA and protein substrates to the translocation apparatus.     

Isolation,purification, and identification of the virulence protein VirE2 from <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis>

Bacteria of the genus Agrobacterium are capable of transferring a fragment of their Ti-plasmid T-DNA, in a complex with the proteins VirE2 and VirD2, into the nuclei of plant cells and incorporating it into the chromosome of the host. The mechanisms of T-DNA transportation through the membrane and cytoplasm of the plant cell are unknown. The aim of this work was isolation of the virulence protein VirE2 for studying its role in T-DNA transportation through the membrane and cytoplasm of eukaryotic cells. For VirE2 accumulation, the virE2 gene was cloned into plasmid pQE31. VirE2 was isolated from the cells of E. coli strain XL1-blue, containing the recombinant plasmid pQE31-virE2. The cells were disrupted ultrasonically, and the protein, with six histidine residues at the N-end, was isolated by means of affinity chromatography on a Ni-NTA-superose column. The purified protein was tested by the immunodot method using polyclonal rabbit antibodies and anti-VirE2 miniantibodies. The ability of the recombinant protein VirE2 to bind to single-stranded DNA was judged from the formation of complexes detected by electrophoresis in agarose gel. Thus, we isolated, purified, and partially characterized the Agrobacterium tumefaciens virulence protein VirE2, which is capable of binding to single-stranded T-DNA upon transfer to the plant cell.Translated from Mikrobiologiya, Vol. 74, No. 1, 2005, pp. 92–98.Original Russian Text Copyright © 2005 by Volokhina, Sazonova, Velikov, Chumakov.     

Genetic transformation through the use of hyperhydric tobacco meristems

Exposed shoot meristems from normal and hyperhydric (vitrified) tobacco, Nicotiana tabacum, were bombarded with gold particles either coated with plasmid DNA containing neomycin phosphotransferase (NPTII), rolC and -glucuronidase (GUS) genes (plasmid pGA-GUSGFrolC) or left uncoated. Meristems bombarded with uncoated particles were co-cultivated with Agrobacterium tumefaciens strain EHA 101 harboring the binary vector pGA-GUSGFrolC. Whole-plant transformants were produced from 4 of 40 hyperhydric meristems bombarded with uncoated particles followed by co-cultivation with A. tumefaciens. One transgenic plant was obtained from 40 normal, non-hyperhydric meristems treated. Transformation was verified by growth on kanamycin-containing medium, GUS assays, PCR, and Southern analysis. The plants tested through Southern analysis appeared to have 2 or more copies of the transgene insert. Seeds obtained from self-pollination of these transgenic plants segregated 3:1 or 15:1 (kanamycin resistant:sensitive) when germinated on medium containing 100 mg/l kanamycin, indicating transfer of foreign genes through the sexual cycle. Whole-plant transformants were not produced from 50 normal tobacco meristems bombarded with plasmid-coated gold particles and not exposed to engineered A. tumefaciens, but 1 plant of 60 bombarded hyperhydric meristems produced transgenic roots, the result of a chimera. We suggest that hyperhydric meristems are more readily transformed.     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-<Emphasis Type="Italic">tumefaciens</Emphasis>-mediated transformation of<Emphasis Type="Italic"> Helminthosporium turcicum</Emphasis>, the maize leaf-blight fungus

Agrobacterium tumefaciens has the ability to transfer its T-DNA to plants, yeast, filamentous fungi, and human cells and integrate it into their genome. Conidia of the maize pathogen Helminthosporium turcicum were transformed to hygromycin B resistance by a Agrobacterium-tumefaciens-mediated transformation system using a binary plasmid vector containing the hygromycin B phosphotransferase (hph) and the enhanced green fluorescent protein (EGFP) genes controlled by the gpd promoter from Agaricus bisporus and the CaMV 35S terminator. Agrobacterium-tumefaciens-mediated transformation yielded stable transformants capable of growing on increased concentrations of hygromycin B. The presence of hph in the transformants was confirmed by PCR, and integration of the T-DNA at random sites in the genome was demonstrated by Southern blot analysis. Agrobacterium-tumefaciens-mediated transformation of Helminthosporium turcicum provides an opportunity for advancing studies of the molecular genetics of the fungus and of the molecular basis of its pathogenicity on maize.     

Specificity of Agrobacterium-mediated delivery of maize streak virus DNA to members of the Gramineae

Parameters affecting the efficiency of agroinfection of maize streak virus (MSV) in maize have been determined. Monomeric units, cloned at a number of sites in the MSV genome were not infectious but multimeric units containing partial duplications were equally as infectious as complete tandem dimeric clones. Inoculation of tandem dimeric units conjugated into different strains of Agrobacterium showed that both A. tumefaciens and A. rhizogenes were able to transfer DNA to maize and this ability was Ti (or Ri) plasmid-specific. Nopaline strains of A. tumefaciens and both agropine and mannopine A. rhizogenes strains efficiently transferred MSV DNA to maize. A number of strains were capable of MSV DNA transfer to other members of the Gramineae, providing information which may be essential for Agrobacterium-mediated transformation of monocotyledonous plants.     

Evaluation of transformation in peach Prunus persica explants using green fluorescent protein (GFP) and beta-glucuronidase (GUS) reporter genes

To determine the optimum conditions for Agrobacterium-mediated gene transfer, peach explants including cotyledons, embryonic axes and hypocotyl slices from non-germinated seeds and epicotyl internode slices from germinating seeds were exposed to Agrobacterium-mediated transformation treatments. The GUS (uidA) marker gene was tested using two different A. tumefaciens strains, three plasmids and four promoters [CaMV35s, (Aocs)3AmasPmas (“super-promoter”), mas-CaMV35s, and CAB]. GFP was tested with six A.␣tumefaciens strains, one plasmid (pLC101) and the doubleCaMV35s (dCaMV35s) promoter. The CaMV35s promoter produced more GUS expression than the CAB promoter. A. tumefaciens strains EHA105 and LBA4404 harboring the same plasmid (pBIN19) differed in their effects on GUS expression suggesting an interaction between A. tumefaciens strain and plasmid. A combination of A. tumefaciens EHA105, plasmid pBIN19 and the CaMV35s promoter produced the highest rates of transformation in peach epicotyl internodes (56.8%), cotyledons (52.7%), leaves (20%), and embryonic axes (46.7%) as evaluated by the percentage of explants expressing GUS 14 days after co-cultivation. GFP expression under the control of the dCaMV35s promoter was highest for internode explants but only reached levels of 18–19%. When GFP-containing plasmid pCL101 was combined with each of five A. tumefaciens strains the highest levels of transformation were 20–21% (internode and cotyledons, respectively). When nine peach genotypes were co-cultivated with A. tumefaciens strain EHA105 and GFP-containing plasmid pCL101 the highest levels of transformation were 26–28% (cotyledons and internodes, respectively). While GFP represents a potentially useful transformation marker that allows the non-destructive evaluation of transformation, rates of GFP transformation under the conditions of this study were low. It will be necessary to optimize expression of this marker gene in peach.     

Genetic and molecular events in transformation ofHaemophilus influenzae with plasmid RSF 0885 carrying cloned segments of chromosomal DNA

InHaemophilus influenzae genetic transformation for a plasmid marker is significantly increased when recombinant plasmid RSF 0885 DNA carrying chromosomal DNA segments is used instead of the plasmid DNA alone. Chromosomal DNA by itself, added even a few minutes after the addition of plasmid DNA to competent cells, stopped further uptake of the plasmid DNA. These observations are consistent with the idea that plasmid RSF 0885 contains a ‘degenerate’ version of the required eleven base-pair ‘uptake sequence’ inHaemophilus. The transformation activity of the recombinant plasmid DNA is recoverable after its entry into cells, although the specific biological activity of the re-isolated plasmid DNA is less than that of the parental recombinant plasmid DNA. Therec 1 gene function of the host is necessary for obtaining higher transformation frequencies with recombinant DNA from five different clones. The reduced transformation frequencies seen inrec 1 ^- strain is not all due to a permanent damage to the donor DNA since the recovered recombinant plasmid DNA from such cells can increase the transformation efficiency onrec 1 ⁺ strain.     

Efficient transformation of<Emphasis Type="Italic"> Medicago truncatula</Emphasis> cv. Jemalong using the hypervirulent<Emphasis Type="Italic"> Agrobacterium tumefaciens</Emphasis> strain AGL1

The efficiency of Agrobacterium tumefaciens transformation of the model legume Medicago truncatula cv. Jemalong (genotype 2HA) was evaluated for strains LBA 4404, C58pMP90, C58pGV2260 and AGL1. Binary vectors carrying promoter-gus/gfp reporter gene fusions and the nptII gene as selectable marker were used for plant in vitro transformation/regeneration. The highest transformation efficiency was obtained with the disarmed hypervirulent strain AGL1 (Ti plasmid TiBo542), for which the percentage of explants forming kanamycin (Km)-resistant calli was double that obtained with each of the other three strains. In addition, we were able to reduce the time necessary for plant regeneration using AGL1, with 24% of the explants generating Km-resistant transgenic plantlets within only 4–5 months of culture. Transgene expression in planta was analysed and found to be conserved in the T₁ descendents.Communicated by R.J. Rose     

A disarmed binary vector from Agrobacterium tumefaciens functions in Agrobacterium rhizogenes

Summary Binary Ti plasmid vector systems consist of two plasmids in Agrobacterium, where one plasmid contains the DNA that can be transferred to plant cells and the other contains the virulence (vir) genes which are necessary for the DNA transfer but are not themselves stably transferred. We have constructed two nononcogenic vectors (pARC4 and pARC8) based on the binary Ti plasmid system of Agrobacterium tumefaciens for plant transformation. Each vector contains the left and right termini sequences from pTiT37. These sequences, which determine the extent of DNA transferred to plant cells, flank unique restriction enzyme sites and a marker gene that functions in the plant (nopaline synthase in pARC4 or neomycin phosphotransferase in pARC8). After construction in vitro, the vectors can be conjugatively transferred from E. coli to any of several Agrobacterium strains containing vir genes. Using A. rhizogenes strain A4 containing the resident Ri plasmid plus a vector with the nopaline synthase marker, we found that up to 50% of the hairy roots resulting from the infection of alfalfa or tomato synthesized nopaline. Thus, vector DNA encoding an unselected marker was frequently co-transferred with Ri plasmid DNA to an alfalfa or a tomato cell. In contrast, the frequency of co-transfer to soybean cells was difficult to estimate because we encountered a high background of non-transformed roots using this species. Up to five copies of the vector DNA between the termini sequences were faithfully transferred and maintained in most cases suggesting that the termini sequences and the vir genes from the Ri and Ti plasmids are functionally equivalent.     

Analysis of the mobilization region of the broad-host-range IncQ-like plasmid pTC-F14 and its ability to interact with a related plasmid, pTF-FC2

Plasmid pTC-F14 is a 14.2-kb plasmid isolated from Acidithiobacillus caldus that has a replicon that is closely related to the promiscuous, broad-host-range IncQ family of plasmids. The region containing the mobilization genes was sequenced and encoded five Mob proteins that were related to those of the DNA processing (Dtr or Tra1) region of IncP plasmids rather than to the three-Mob-protein system of the IncQ group 1 plasmids (e.g., plasmid RSF1010 or R1162). Plasmid pTC-F14 is the second example of an IncQ family plasmid that has five mob genes, the other being pTF-FC2. The minimal region that was essential for mobilization included the mobA, mobB, and mobC genes, as well as the oriT gene. The mobD and mobE genes were nonessential, but together, they enhanced the mobilization frequency by approximately 300-fold. Mobilization of pTC-F14 between Escherichia coli strains by a chromosomally integrated RP4 plasmid was more than 3,500-fold less efficient than the mobilization of pTF-FC2. When both plasmids were coresident in the same E. coli host, pTC-F14 was mobilized at almost the same frequency as pTF-FC2. This enhanced pTC-F14 mobilization frequency was due to the presence of a combination of the pTF-FC2 mobD and mobE gene products, the functions of which are still unknown. Mob protein interaction at the oriT regions was unidirectionally plasmid specific in that a plasmid with the oriT region of pTC-F14 could be mobilized by pTF-FC2 but not vice versa. No evidence for any negative effect on the transfer of one plasmid by the related, potentially competitive plasmid was obtained.     

Genetic transformation of a hepatoprotective plant, <Emphasis Type="Italic">Phyllanthus amarus</Emphasis>

Phyllanthus amarus Schum & Thonn. is a source of various pharmacologically active compounds such as phyllanthin, hypophyllanthin, gallic acid, catechin, and nirurin, a flavone glycoside. A genetic transformation method using Agrobacterium tumefaciens was developed for this plant species for the first time. Shoot tips of full grown plants were used as explants for Agrobacterium-mediated transformation. Transgenic plants were obtained by co-cultivation of shoot tips explants and A. tumefaciens strain LBA4404 containing the pCAMBIA 2301 plasmid harboring neomycin phosphotransferase II (NPT II) and β-glucuronidase encoding (GUS) genes in the T-DNA region in the presence of 200 μM acetosyringone. Integration of the NPT II gene into the genome of transgenic plants was verified by PCR and Southern blot analyses. Expression of the NPT II gene was confirmed by RT-PCR analysis. An average of 25 explants was used, out of which an average of 19 explants produced kanamycin-resistant shoots, which rooted to produce 13 complete transgenic plants.     

Mechanisms of crown gall formation: T-DNA transfer fromAgrobacterium tumefaciens to plant cells

Agrobacterium tumefaciens harbouring the Ti plasmid incites crown gall tumor on dicotyledonous species. Upon infection of these plants, T-DNA in the Ti plasmid is transferred by unknown mechanisms to plant cells to be integrated into nuclear DNA. WhenAgrobacterium is incubated with protoplasts or seedlings of dicotyledonous plants, circulation of T-DNA and expression ofvir (virulence) genes on the Ti plasmid are induced. The circularization event is efficiently induced by mesophyll protoplasts of tobacco which are highly competent for transformation by the T-DNA, and is also induced by diffusible phenolic compounds excreted from the protoplasts. The circularization and formation of crown gall both require the expression of thevirD locus, one of the induciblevir genes. These results suggest that the circularization of T-DNA reflects one of steps of the T-DNA transfer during formation of crown gall. In contrast to dicotyledonous plants, monocotyledonous plants are thought to be unresponsive to infection byAgrobacterium. We showed that monocotyledonous plants do not excrete diffusible inducers for the expression ofvir genes, while they contain a novel type of a signal substance(s). This inducer is not detected in the exudates of seedlings of monocotyledonous plants, but is found in the extracts from the seedlings, and also those from the seeds, bran and germ of wheat and oats. This finding suggests that T-DNA processing, and possibly its transfer, should take place whenAgrobacterium invades seedlings and seeds of monocotyledonous plants. Recipient of the Botanical Society Award for Young Scientists, 1987.