Absence in monocotyledonous plants of the diffusible plant factors inducing T-DNA circularization and vir gene expression in Agrobacterium

Summary T-DNA circularization is one of the molecular events specifically induced in agrobacterial cells upon their infection of dicotyledonous plant cells. We developed a seedling co-cultivation procedure to determine whether or not monocotyledonous plants have the ability to induce T-DNA circularization and vir gene expression. Co-cultivation of Agrobacterium tumefaciens with seedlings of dicotyledonous plants showed that the circularization event takes place efficiently. The exudates and extracts of the seedlings also effectively induced T-DNA circularization and vir gene expression, indicating that dicotyledonous seedlings contain diffusible factors capable of inducing these molecular events. In contrast, neither T-DNA circularization nor vir gene expression was detectable when Agrobacterium was incubated with seedlings of monocotyledonous plants. Supplementing with acetosyringone, a known inducer of vir gene expression and T-DNA circularization, resulted in the induction of circularization during co-cultivation with monocotyledonous seedlings. These results indicate that the seedlings of monocotyledonous plants have no detectable amounts of diffusible inducers, unlike dicotyledonous seedlings. Therefore, it is unlikely that the vir genes are expressed in Agrobacterium inoculated in monocotyledonous plants. This may be one of the blocks in tumorigenesis of monocotyledonous plants by Agrobacterium.     

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.     

Opine synthesis in wild-type plant tissue

Opine production is associated with crown gall tissue, a neoplastic growth caused by infection of dicotyledonous plants with Agrobacterium tumefaciens. Recent publications have claimed that tissues of certain monocotyledonous plants can also be infected by Agrobacterium. Following infection, a part of the Agrobacterium Ti plasmid, T-DNA, is integrated into the chromosome of the infected plant. T-DNA, which codes for opine-synthesizing enzymes, is now used to add foreign genes to plants. A number of laboratories have used opine production in plant tissue, often after arginine feeding or preincubation as evidence for plant transformation by T-DNA vectors. In this report we provide microbiological, chromatographic, spectroscopic and chemical evidence indicating that opines can be formed in normal callus and plant tissue as a result of arginine metabolism. Therefore, researchers studying T-DNA should be aware of the capability of plant tissue to metabolize arginine to opines. Opine production following infection with T-DNA may not always be sufficient evidence to indicate transformation by the Agrobacterium Ti plasmid.     

Rice scutellum induces Agrobacterium tumefaciens vir genes and T-strand generation

For successful transformation of a plant by Agrobacterium tumefaciens it is essential that the explant used in cocultivation has the ability to induce Agrobacterium tumour-inducing (Ti) plasmid virulence (vir) genes. Here we report a significant variation in different tissues of Indica rice (Oryza sativa L. cv. Co43) in their ability to induce Agrobacterium tumefaciens vir genes and T-strand generation, using explants preincubated in liquid Murashige and Skoog (MS) medium. An analysis of rice leaf segments revealed that they neither induced vir genes nor inhibited vir gene induction. Of different parts of rice plants of different ages analysed only scutellum from four-day old rice seedlings induced vir genes and generation of T-strands. We observed that the physical presence of preincubated scutella is required for vir gene induction. Conditioned medium from which preincubated scutella were removed did not induce the vir genes. Scutellum-derived calli, cultured for 25 days on medium containing 2,4-D, also induced virE to an appreciable level. These results suggest that scutellum and scutellum-derived calli may be the most susceptible tissues of rice for Agrobacterium-mediated transformation.     

Desiccation of plant tissues post-<Emphasis Type="Italic">Agrobacterium</Emphasis> infection enhances T-DNA delivery and increases stable transformation efficiency in wheat

Summary Factors influencing the Agrobacterium-mediated transformation of both monocotyledonous and dicotyledonous plant species have been widely investigated. These factors include manipulating Agrobacterium strains and plasmids, growth conditions for vir gene induction, plant genotype, inoculation and co-culture conditions, and the selection agents and their application regime. We report here a novel physical parameter during co-culture, desiccation of plant cells or tissues post-Agrobacterium infection, which greatly enhances transfer DNA (T-DNA) delivery and increases stable transformation efficiency in wheat. Desiccation during co-culture dramatically suppressed Agrobacterium growth, which is one of the factors known to favor plant cell recovery. Osmotic and abscisic acid treatments and desiccation prior to inoculation did not have the same enhancement effect as desiccation during co-culture on T-DNA delivery in wheat. An efficient transformation protocol has been developed based on desiccation and is suitable for both paromomycin and glyphosate selection. Southern analysis showed approximately 67% of transgenic wheat plants received a single copy of the transgene.     

Ti plasmid containing Rhizobium meliloti are non-tumorigenic on plants,despite proper virulence gene induction and T-strand formation

We examined the expression of the vir genes of the Agrobacterium tumefaciens Ti plasmid in Rhizobium meliloti, which remains non-tumorigenic on plants after introduction of a Ti- or Ri-plasmid. Both the levels of virulence (vir) gene expression, induced by the plant phenolic compound acetosyringone, and of subsequent T-strand formation were comparable to what is observed in Agrobacterium. In contrast to the situation in Agrobacterium, though, vir induction in R. meliloti did not require a low pH (5.3) of the induction medium and the optimum temperature for induction in R. meliloti was significantly lower than in Agrobacterium. At 37°C no induction of the vir genes was found both in Agrobacterium and R. meliloti. We postulate that the lack of tumorigenicity of Ti carrying R. meliloti strains is due either to a lack of proper attachment of the bacteria to plant cells, or to an improper assembly of a virB-determined essential structure in the cell wall of R. meliloti.     

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.     

Genetic analysis of transfer and stabilization of Agrobacterium DNA in plant cells

In an attempt to elucidate the transfer and integration mechanism of Agrobacterium DNA upon crown gall induction, we translocated a borderless T-DNA to different sites of the C58 Ti plasmid. As a result of the physical linkage of the T-DNA onc genes with other Ti plasmid functions, the concerned strain retained tumor-inducing capacity. However, when the borderless T-DNA is separated on an independent replicon while all other pTi functions are provided in trans, the strain can no longer induce tumors on plants. We provide evidence that the right T-DNA border region harbors one or more in cis active functions essential in the transfer and/or stabilization of the T-DNA into plant cells. The strains used in these experiments allowed us to conclude that some function(s) of the Ti plasmid can induce plant cell proliferations independently of the T-DNA transformation event. The results described here indicate that other Ti plasmid sequences than solely the T-region can be transferred to plant cells.     

NewAgrobacterium helper plasmids for gene transfer to plants

We describe the construction of new helper Ti plasmids forAgrobacterium-mediated plant transformation. These plasmids are derived from three differentAgrobacterium tumefaciens Ti plasmids, the octopine plasmid pTiB6, the nopaline plasmid pTiC58, and the L,L-succinamopine plasmid pTiBo542. The T-DNA regions of these plasmids were deleted using site-directed mutagenesis to yield replicons carrying thevir genes that will complement binary vectorsin trans. Data are included that demonstrate strain utility. The advantages ofAgrobacterium strains harbouring these disamed Ti plasmids for plant transformation viaAgrobacterium are discussed.     

Phenotypically normal transgenic T-cyt tobacco plants as a model for the investigation of plant gene expression in response to phytohormonal stress

The tumour-inducing T-DNA gene 4 (T-cyt gene) of the nopaline Ti plasmid pTiC58 was cloned and introduced into tobacco cells by leaf disc transformation using Agrobacterium plasmid vectors. Tobacco shoots exposed to elevated cytokinin levels were unable to develop roots and lacked apical dominance. Using exogenously applied phytohormone manipulations we were able to regenerate morphologically normal transgenic tobacco plants which differed in endogenous cytokinin levels from normal untransformed plants. Although T-cyt gene mRNA levels, as revealed by dot-blot hybridization data, in these rooting plants were only about half those in primary transformed shoots the total amount of cytokinins was much lower than in crown gall tissue or cytokinin-type transformed shoots as reported by others. Nevertheless the cytokinin content in T-cyt plants was about 3 times greater than in control tobacco plants.Elevated cytokinin levels have been shown to change the expression of several plant genes, including some nuclear genes encoding chloroplast proteins. Our results show that the mRNA levels of chloroplast rbcL gene increase in cytokinin-type transgenic tobacco plants as compared with untransformed plants. Data obtained suggest that T-cyt transgenic plants are a good model for studying plant gene activity in different parts of the plant under endogenous cytokinin stress.     

Efficient and rapid <Emphasis Type="Italic">Agrobacterium-</Emphasis>mediated genetic transformation of durum wheat (<Emphasis Type="Italic">Triticum turgidum L. var. durum)</Emphasis> using additional virulence genes

Genetic transformation of wheat, using biolistics or Agrobacterium, underpins a range of specific research methods for identifying genes and studying their function in planta. Transgenic approaches to study and modify traits in durum wheat have lagged behind those for bread wheat. Here we report the use of Agrobacterium strain AGL1, with additional vir genes housed in a helper plasmid, to transform and regenerate the durum wheat variety Ofanto. The use of the basic pSoup helper plasmid with no additional vir genes failed to generate transformants, whereas the presence of either virG⁵⁴² or the 15 kb Komari fragment containing virB, virC and virG⁵⁴² produced transformation efficiencies of between 0.6 and 9.7%. Of the 42 transgenic plants made, all but one (which set very few seeds) appeared morphologically normal and produced between 100 and 300 viable seeds. The transgene copy number and the segregation ratios were found to be very similar to those previously reported for bread wheat. We believe that this is the first report describing successful genetic transformation of tetraploid durum wheat (Triticum turgidum L. var. durum) mediated by Agrobacterium tumefaciens using immature embryos as the explant.     

Multiple transformation of plant cells by Agrobacterium may be responsible for the complex organization of T-DNA in crown gall and hairy root

Summary Inoculation of carrot discs and Lotus corniculatus plantlets with mixtures of different Agrobacterium rhizogenes or of A. rhizogenes and A. tumefaciens or with Agrobacterium strains harboring both an Ri and a modified Ti plasmid resulted in frequent multiple (pluribacterial) transformation of cells, as revealed by the mixed opine-type of hairy roots arising from them. Multiple transformation may account for the presence of dispersed T-DNA inserts in crown gall and hairy root lines. A plant genetic engineering strategy based on segregation of T-DNA inserts in the progeny of multiple transformants is proposed.     

Natural genetic engineering of plant cells: the molecular biology of crown gall and hairy root disease

During the past decade, the molecular mechanisms of crown gall and hairy root development have been elucidated in considerable detail. It now appears that the genetic colonization of plant cells by Agrobacterium evolved by continual adaptation of groups of genes that existed long before the evolution of this plant-microbe association. This is most evident for the signal transduction system leading to vir gene induction, and for the early steps of T-DNA transfer to plant cells which have probably evolved from the bacterial conjugation and protein export machinery. However, the later steps, i.e. nuclear targeting of the T-DNA-protein complex, and integration into the host genome by illegitimate recombination are reminiscent of viral infection, where the T-complex resembles a viral particle. The present article reviews the current knowledge of the molecular basis of crown gall and hairy root tumorigenesis, with some emphasis on the mechanisms of signal exchange between plants and bacteria, as well as of T-DNA excision, transfer, integration and expression.The authors are with Plant Molecular Biology, Department of Biology, Biozentrum, Marie-Curie-Str. 9, University of Frankfurt am Main, D-60439 Frankfurt, Germany     

Non-homologous end-joining proteins are required for Agrobacterium T-DNA integration.

Agrobacterium tumefaciens causes crown gall disease in dicotyledonous plants by introducing a segment of DNA (T-DNA), derived from its tumour-inducing (Ti) plasmid, into plant cells at infection sites. Besides these natural hosts, Agrobacterium can deliver the T-DNA also to monocotyledonous plants, yeasts and fungi. The T-DNA integrates randomly into one of the chromosomes of the eukaryotic host by an unknown process. Here, we have used the yeast Saccharomyces cerevisiae as a T-DNA recipient to demonstrate that the non-homologous end-joining (NHEJ) proteins Yku70, Rad50, Mre11, Xrs2, Lig4 and Sir4 are required for the integration of T-DNA into the host genome. We discovered a minor pathway for T-DNA integration at the telomeric regions, which is still operational in the absence of Rad50, Mre11 or Xrs2, but not in the absence of Yku70. T-DNA integration at the telomeric regions in the rad50, mre11 and xrs2 mutants was accompanied by gross chromosomal rearrangements.     

Factors influencing <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of monocotyledonous species

Summary Since the success of Agrobacterium-mediated transformation of rice in the early 1990s, significant advances in Agrobacterium-mediated transformation of monocotyledonous plant species have been achieved. Transgenic plants obtained via Agrobacterium-mediated transformation have been regenerated in more than a dozen monocotyledonous species, ranging from the most important cereal crops to ornamental plant species. Efficient transformation protocols for agronomically important cereal crops such as rice, wheat, maize, barley, and sorghum have been developed and transformation for some of these species has become routine. Many factors influencing Agrobacterium-mediated transformation of monocotyledonous plants have been investigated and elucidated. These factors include plant genotype, explant type, Agrobacterium strain, and binary vector. In addition, a wide variety of inoculation and co-culture conditions have been shown to be important for the transformation of monocots. For example, antinecrotic treatments using antioxidants and bactericides, osmotic treatments, desiccation of explants before or after Agrobacterium infection, and inoculation and co-culture medium compositions have influenced the ability to recover transgenic monocols. The plant selectable markers used and the promoters driving these marker genes have also been recognized as important factors influencing stable transformation frequency. Extension of transformation protocols to elite genotypes and to more readily available explants in agronomically important crop species will be the challenge of the future. Further evaluation of genes stimulating plant cell division or T-DNA integration, and genes increasing competency of plant cells to Agrobacterium, may increase transformation efficiency in various systems. Understanding mechanisms by which treatments such as desiccation and antioxidants impact T-DNA delivery and stable transformation will facilitate development of efficient transformation systems.     

Single-stranded DNA transforms plant protoplasts

Summary The transfer of the Agrobacterium T-DNA to plant cells involves the induction of the Ti plasmid virulence genes. This induction results in the generation of linear single-stranded (ss) copies of the T-DNA inside Agrobacterium and such molecules might be directly transferred to the plant cell. A central requirement of this ss transfer model is that the plant cell must generate a second strand and integrate the resulting double-stranded (ds) molecule into its genome. Here we report that incubating plant protoplasts with ss or ds DNA under conditions favouring DNA uptake results in transformation. The frequencies of transformation are similar and analysis of ss transformants suggests that the introduced DNA becomes double stranded and integrated. Analysis of transient expression from introduced ss DNA suggests that generation of the second strand is rapid and extrachromosomal.     

Observation by SEM of the attachment ofAgrobacterium tumefaciens to the surface of vinca,asparagus and rice cells

Transformation of vinca cells was performed by the co-cultivation of cell-wall regenerated vinca protoplasts withAgrobacterium tumefaciens. Using thisin vitro and single cell system, attachment of the bacteria to the surface of vinca cells was observed by scanning electron microscopy (SEM). Figures of the bacteria polarly binding to the plant cell wall were often observed. AsEscherichia coli does not attach to the plant cells at all, the observed attachment ofA. tumefaciens is suggested as a characteristic feature in crown gall induction. Even though no evidence of transformation was obtained by the co-cultivation methods, a similar attachment was observed in the cell-wall regenerated protoplasts of rice. The bacteria also attached to the surface of isolated mesophyll cells of asparagus and root hairs of rice. From these observation, we concluded that the attachment is not the limiting step of crown gall induction byA. tumefaciens in monocotyledonous plants. Extracellular fibrils like pili were observed with a few strains of A.tumefaciens for the first time. These fibrils were observed regardless of their ability of attachment and infectivity.     

Polymerase chain reaction analysis of transgenic plants contaminated byAgrobacterium

Agrobacterium-mediated genetic transformation is a method of choice for the development of transgenic plants. The presence of latentAgrobacterium that multiplies in the plant tissue in spite of antibiotic application confounds the results obtained by polymerase chain reaction (PCR) analysis of putative transgenic plants. The presence ofAgrobacterium can be confirmed by amplification of eitherAgrobacterium chromosomal genes or genes present out of transfer DNA (T-DNA) in the binary vector. However, the transgenic nature ofAgrobacterium-contaminated transgenic plants cannot be confirmed by PCR. Here we report a simple protocol for PCR analysis ofAgrobacterium-contaminated transgenic plants. This protocol is based on denaturation and renaturation of DNA. The contaminating plasmid vector becomes double-stranded after renaturation and is cut by a restriction enzyme having site(s) within the PCR amplicon. As a result, amplification by PCR is not possible. The genomic DNA with a few copies of the transgene remains single-stranded and unaffected by the restriction enzyme, leading to amplification by PCR. This protocol has been successfully tested with 4 different binary vectors and 3Agrobacterium tumefaciens strains: EHA105, LBA4404, and GV3101.     

Environmental conditions differentially affect vir gene induction in different Agrobacterium strains. Role of the VirA sensor protein

The induction of vir gene expression in different types of Agrobacterium strains shows different pH sensitivity profiles. The pH sensitivity pattern demonstrated by octopine Ti strains was similar to that of a supervirulent leucinopine Ti strain, whereas this was different from that shown by nopaline Ti strains and agropine Ri strains. Data are given which indicate that these differences are due to different properties of the virA genes of these wild types. An exceptional case was formed by strains with the limited-host-range plasmid pTiAG57 which showed AS-dependent vir induction only if reduced inoculum sizes were used and the temperature was 28°C or below.     

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.