Deviating T-DNA transfer fromAgrobacterium tumefaciens to plants

We analyzed 29 T-DNA inserts in transgenicArabidopsis thaliana plants for the junction of the right border sequences and the flanking plant DNA. DNA sequencing showed that in most lines the right border sequences transferred had been preserved during integration, corroborating literature data. Surprisingly, in four independent transgenic lines a complete right border repeat was present followed by binary vector sequences. Cloning of two of these T-DNA inserts by plasmid rescue showed that in these lines the transferred DNA consisted of the complete binary vector sequences in addition to the T-region. On the basis of the structure of the transferred DNA we propose that in these lines T-DNA transfer started at the left-border repeat, continued through the vector part, passed the right border repeat, and ended only after reaching again this left-border repeat.     

Sequence context of the T-DNA border repeat element determines its relative activity during T-DNA transfer to plant cells

Summary We present a detailed analysis of the function of the right and left T-DNA border regions of the nopaline Ti plasmid of Agrobacterium tumefaciens. An avirulent deletion of the right border of the nopaline Ti plasmid (pGV3852) was used as an acceptor for 14 different T-DNA border constructs. The functional activities of these constructs were assayed by their ability to restore virulence, i.e. transformation on inoculated plants. Tumorigenicities were measured in several independent experiments over a 2 year period and the statistical significance of their relative levels was evaluated. The data indicate: (i) the entire sequence of the 25 bp direct repeat of the T-DNA is required to provide an efficient substrate for mediating T-DNA transfer events; deletion derivatives of either the conserved or the vaiable domain of the repeat are defective in T-DNA transfer; (ii) while the 25 bp direct repeat alone can promote the T-DNA transfer, the flanking sequences of the repeats enhance (on the right) or attenuate (on the left) their activity; and (iii) tumorigenicity measurements vary depending on the plant assay system: potato discs are more sensitive than wounded tobacco leaves in detecting differences in T-DNA border activity.     

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.     

T-DNA transfer to maize plants

Agrobacterium-mediated transformation is the method of choice to engineer desirable genes into plants. Here we describe a protocol for demonstrating T-DNA transfer from Agrobacterium into the economically important graminaceous plant maize. Expression of the T-DNA-located GUS gene was observed with high efficiency on shoots of young maize seedlings after cocultivation with Agrobacterium.     

The Agrobacterium tumefaciens T-DNA gene 6b is an onc gene

In this article it is shown that the T-DNA of Agrobacterium tumefaciens contains besides the well-known cyt and aux genes another gene with an oncogenic effect in plants. The gene in question is called 6^b and causes the formation of small tumors in plant species such as Nicotiana glauca and Kalanchoe tubiflora.     

Transgenic plant production from leaf discs of Moricandia arvensis using Agrobacterium tumefaciens

Summary A high frequency shoot regeneration (80%) was developed from callus of leaf discs and stem internodes of Moricandia arvensis. Leaf discs were shown to be a preferable starting material for transformation experiments. Agrobacterium tumefaciens strain GV3101/pMP90 used in this study contained a binary vector with genes for kanamycin resistance, hygromycin resistance and -glucuronidase (GUS). Maximum transformation efficiency (10.3%) was achieved by using kanamycin at the rate of 200 mg/l as a selection agent. Presence of tobacco suspension culture during co-cultivation and a pre-selection period of seven days after co-cultivation was essential for successful transformation. Transgenic plants grew to maturity and exhibited flowering in a glasshouse. GUS activity was evident in all parts of leaf and the presence of GUS gene in plant gemone was confirmed by PCR analysis.Abbreviations GUS -glucuronidase     

Genetic transformation of cocoa leaf cells using Agrobacterium tumefaciens

Leaf strips from cocoa tree (Theobroma cacao L.) clones ICS-16 and SIC-5 were cocultivated with the supervirulent Agrobacterium tumefaciens strain A281-Kan. A281-Kan contains a wild-type Ti plasmid and an additional plasmid, pGPTV-Kan, which confers kanamycin resistance to transformed plant cells after integration and expression of the neomycin phosphotransferase II (nptII) gene. Transformed cells were selected on callusing medium containing 100 g ml^-1 kanamycin. NptII assays confirmed that kanamycin-resistant cultures of ICS-16 and SIC-5 expressed the nptII gene, whereas control cultures did not. Genomic Southern blot analyses demonstrated single T-DNA insertions into ICS-16 and SIC-5. T-DNA/cocoa DNA border regions from transformed cultures were cloned and sequenced, revealing that in both transformed cell lines, the right T-DNA border was at the 5 end of the 25 bp right border repeat. Cocoa DNA probes from the T-DNA/cocoa DNA insertion sites were used in Southern blot analyses and showed that T-DNA from pGPTV-Kan had inserted into a unique region in ICS-16 and into a repetitive region in SIC-5. This study establishes that foreign genes can be inserted and expressed in cocoa using A. tumefaciens-mediated gene transfer.     

Transfer of non-T-DNA portions of the Agrobacterium tumefaciens Ti plasmid pTiA6 from the left terminus of TL-DNA

We introduced a plant selection marker, nptII, to the left of border A in the Agrobacterium Ti plasmid pTiA6. Infection of tobacco leaf discs with the modified Agrobacterium strain gave rise to kanamycin-resistant calli which grew in a hormone-dependent manner. Southern hybridization analysis of DNA isolated from four transformants indicated initiation of DNA transfer at or near border A and absence of T-DNA sequences. These results demonstrate that DNA transfer events starting at a left border on a native Ti plasmid and moving away from the T-DNA region occur and that they can be detected by designing a suitable selection strategy.     

Insights into recognition of the T-DNA border repeats as termination sites for T-strand synthesis by Agrobacterium tumefaciens

The recognition of the T-DNA left border (LB) repeat is affected by its surrounding sequences. Here, the LB regions were further characterized by molecular analysis of transgenic plants, obtained after Agrobacterium tumefaciens-mediated transformation with T-DNA vectors that had been modified in this LB region. At least the 24-bp LB repeat by itself was insufficient to terminate the T-strand synthesis. Addition of the natural inner and/or outer border regions to at least the LB repeat, even when present at a distance, enhanced the correct recognition of the LB repeat, reducing the number of plants containing vector backbone sequences. In tandem occurrence of both the octopine and nopaline LB regions with their repeats terminated the T-strand synthesis most efficiently at the LB, yielding a reproducibly high number of plants containing only the T-DNA. Furthermore, T-strand synthesis did not terminate efficiently at the right border (RB) repeat, which might indicate that signals in the outer RB region inhibit the termination of T-strand synthesis at the RB repeat.     

Detection of T-DNA transfer to plant cells by A. tumefaciens virulence mutants using agroinfection

Summary To test whether virulence mutants of Agrobacterium tumefaciens are capable of promoting T-DNA transfer into plant cells, a tandem array of Cauliflower Mosaic Virus (CaMV) DNA was cloned between T-region border sequences on a wide host range plasmid and introduced into various virulence mutants. The resulting strains were used to infect Brassica rapa cv. Just Right. This assay, recently referred to as agroinfection, is based on the appearance of viral symptoms following transfer of T-DNA to plant cells, and is shown to be at least 100 times more sensitive in detecting T-DNA transfer than tumour formation. Mutants in the loci vir A, B and G, which were avirulent on turnip, failed to induce virus symptoms. Of the two vir D mutants tested, neither induced tumours, but one was capable of inducing virus symptoms. Mutants in vir E, C and F, which induced respectively no, small and normal tumours on turnip, all induced virus symptoms.     

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

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

Initiation of auxin autonomy in Nicotiana glutinosa cells by the cytokinin-biosynthesis gene from Agrobacterium tumefaciens

Agrobacteria carrying mutations at the auxin-biosynthesizing loci (iaaH and iaaM of the Ti plasmid) induce shoot-forming tumors on many plant species. In some cases, e.g. Nicotiana glutinosa L., tumors induced by such mutant strains exhibit an unorganized and fully autonomous phenotype. These characteristics are stable in culture at both the tissue and cellular level. We demonstrate that the cytokinin-biosynthesis gene (ipt) of the Ti plasmid is responsble for the induction of both auxin and cytokinin autonomy in N. glutinosa. Cloned cell lines carrying an ipt gene but lacking iaaH and iaaM are capable of accumulating indole-3-acetic acid. Interestingly, non-transformed N. glutinosa tissues exhibit an auxin-requiring phenotype when they are grown on medium supplemented with an exogenous supply of cytokinin. These results strongly indicate that exogenously supplied cytokinin does not mimic all the effects of the expression of the ipt gene in causing the auxin-autonomous growth of N. glutinosa cells.Abbreviations FW fresh weight - IAA indole-3-acetic acid - I⁶ Ado isopentenyladenosine - kb kilobase - MS Murashige and Skoog (medium) - NAA -naphthaleneacetic acid - NAM -naphthaleneacetamide - T-DNA transferred DNA     

The promoter proximal region in the virD locus of Agrobacterium tumefaciens is necessary for the plant-inducible circularization of T-DNA

Summary The formation of crown gall tumours involves the transfer of the T-DNA region of the Ti plasmid from Agrobacterium to plant cells and its subsequent integration into plant chromosomes. When agrobacteria are incubated with plant protoplasts or exudates of plants, the T-DNA region is circularized by recombination or cleavage and rejoining between the 25 bp terminal repeats; the formation of circular T-DNAs is thought to be one step in T-DNA transfer (Koukolikova-Nicola et al. 1985; Machida et al. 1986). We previously showed that the virulence region of the Ti plasmid is required for T-DNA circularization. In the present paper, we examined the circularization event in agrobacteria harbouring octopine Ti plasmids with mutations in various loci of the virulence region. The results clearly demonstrate that the gene(s) encoded in the virD locus are necessary for T-DNA circularization. In particular, the gene(s) present in the region proximal to the virD promoter are essential. We propose that roduct(s) of this gene have recombinase or endonuclease activity which specifically recognizes the 25 bp terminal repeats of T-DNA.     

Silent T-DNA genes in plant lines transformed by Agrobacterium tumefaciens are activated by grafting and by 5-azacytidine treatment

Summary A shooty tumor induced by a shooter mutant of an octopine strain of Agrobacterium tumefaciens was cloned. One clone obtained (TS038) behaved aberrantly in that it grew as a shooty tumor tissue on phytohormone free medium, but did not contain octopine synthase activity. In line TS038 the genes for octopine synthase and for the enzymes involved in agropine and mannopine synthesis were present, but were not transcribed. However, the above genes became active in TS038 tumor shoots after grafting as well as after treatment with the hypomethylating agent 5-azacytidine. After an unusually long incubation period in the growth cabinet shoot cultures appeared to have developed small shoots from the top of the leaves. This unusual form of differentiation was found to be accompanied by the induction of octopine synthase activity.     

A plant transformation vector with a minimal T-DNA

Plant transformation, viaAgrobacterium tumefaciens, is usually performed with binary vectors. Most of the available binary vectors contain within the T-DNA (which is transferred to the plant genome) components not required for the intended modification. These additional sequences may cause potential risks during field testing of the transgenic plants or even more in the case of commercialization. The aim of this study was to produce a plant transformation vector which only contains a selectable and screenable marker gene and a multiple cloning site for insertion of promoter::foreign gene::terminator cassettes from other plasmids.     

Genetic studies on the role of octopine T-DNA border regions in crown gall tumor formation

Summary Crown gall tumors result from transfer and integration of the T-DNA from the Ti plasmid of Agrobacterium tumefaciens into plant nuclear DNA. In the present study, recombinant plasmids containing deletion and rearrangement deriviatives of the T-DNA region of the octopine Ti plasmid pTiA6 were tested in a binary tumorigenesis system (Hoekema et al. 1983) to determine the requirements for T-DNA border regions in tumor formation. Since two defined segments of the T-DNA region of octopine Ti plasmids can be detected in tumor DNA (the left (T_L-) and right (T_R-) DNA), four border regions exist in this Ti plasmid. Agrobacteria harboring plasmid constructs which contain a T-DNA gene capable of inciting tumors (gene 4, the tmr gene, which is involved in cytokinin biosynthesis) and various T-DNA border regions were tested for ability to cause tumors on Nicotiana glauca and other host plants. Such tmr constructs containing as their only border region the right border of either the T_L-DNA or the T_R-DNA are fully tumorigenic. Analogous tmr constructs containing only the T_L-DNa left border region are not tumorigenic. These results do not depend on the orientation or position of the single border with respect to the tmr gene; furthermore, the T_R-DNA right border can confer tumor-forming ability despite the presence of an intervening copy of the T_L-DNA left border.These results for relatively small plasmids are contrasted with previously determined requirements for border regions in tumorigenesis by intact Ti plasmids. A model previously proposed by Wang et al. (1984) for the role of border regions in DNA transfer to plant cells is extended in order to explain the tumor-forming ability of plasmid constructs containing a single border region. The results of this study interpreted according to the model suggest that the octopine T_L-DNA left border is defective in this DNA-transfer process.     

Delivery of T-DNA from the Agrobacterium tumefaciens chromosome into plant cells

The intact T-region of the B6Ti plasmid of Agrobacterium tumefaciens was stepwise cloned into a site in transposon Tn3. In this way a suitable vehicle (Tn1882) was obtained for translocating the T-region to different replicons, i.e., to other plasmids or the chromosome. The IncP plasmid R772::Tn1882 conferred tumorigenicity on Agrobacterium if the virulence genes were provided in trans in the same cell. This result showed that the T-region present on Tn1882 was transferred efficiently to plant cells. Normal tumor development also occurred if the T-region was placed in the chromosome of A. tumefaciens and an R' plasmid was present carrying virA–E or virA–F. We conclude that the plasmid location of the T-region is not a prerequisite for transfer to the plant cell. The apparently normal delivery of the T-DNA from a bacterial chromosomal location supports a model involving a processing step within Agrobacterium effecting transfer of the T-region as a separate entity.     

Presence of a plant cell wall is not required for transformation of Nicotiana by Agrobacterium tumefaciens

Agrobacterium has been used to transform zero to six-day-old cell wall nonregenerating (CWNR) and cell wall regenerating (CWR) leaf protoplasts of tobacco. Transformed cells were selected by phoytohormone autotrophic growth and were verified by detection of the presence of lysopine dehydrogenase. Transformation frequencies in CWNR protoplasts were at least as high as those in CWR protoplasts, indicating that a plant cell wall is not required for the process of crown gall tumorigenesis. Transformation frequencies were highest in two-day-old protoplasts. This age coincides with the onset of DNA synthesis and the first mitosis within the cell populations. We suggest that the initiation of cell cycle activity may be important for the transformation process.