Factors influencing the efficiency of T-DNA transfer during co-cultivation of Antirrhinum majus with Agrobacterium tumefaciens

Summary The effects of varying the pH of the cocultivation medium, additons of vir-inducing phenolic compounds and the strains of wild-type agrobacteria on transformation rates of a number of different varieties of Antirrhinum majus were studied. In general, optimal transformation was found with strains C58 or A281 and was favoured by low pH and the inclusion of acetosyringone in the co-cultivation medium. However, maximal transformation of the least susceptible variety was achieved at high pH and in the presence of syringaldehyde. This demonstrates the need for the optimization of a wide range of culture conditions when working with new genotypes and offers a rational approach towards the development of Agrobacterium-mediated transformation of new species or varieties.Abbreviations BAP 6-benzylaminopurine - MS Murashige and Skoog medium (Murashige and Skoog, 1962) - NOA naphthoxyacetic acid     

Temperature affects the T-DNA transfer machinery of Agrobacterium tumefaciens.

Early studies on Agrobacterium tumefaciens showed that development of tumors on plants following infection by A. tumefaciens was optimal at temperatures around 22 degrees C and did not occur at temperatures above 29 degrees C. To assess whether this inability to induce tumors is due to a defect in the T-DNA transfer machinery, mobilization of an incompatibility group Q (IncQ) plasmid by the T-DNA transfer machinery of A. tumefaciens was tested at various temperatures. Optimal transfer occurred when matings were performed at 19 degrees C, and transfer was not seen when matings were incubated above 28 degrees C. Transfer of the IncQ plasmid was dependent upon induction of the virB and virD operons by acetosyringone but was not dependent upon induction of the tra genes by octopine. However, alterations in the level of vir gene induction could not account for the decrease in transfer with increasing temperature. A. tumefaciens did successfully mobilize IncQ plasmids at higher temperatures when alternative transfer machineries were provided. Thus, the defect in transfer at high temperature is apparently in the T-DNA transfer machinery itself. As these data correlate with earlier tumorigenesis studies, we propose that tumor suppression at higher temperatures results from a T-DNA transfer machinery which does not function properly.     

Site-specific integration of Agrobacterium tumefaciens T-DNA via double-stranded intermediates

Agrobacterium tumefaciens-mediated genetic transformation involves transfer of a single-stranded T-DNA molecule (T strand) into the host cell, followed by its integration into the plant genome. The molecular mechanism of T-DNA integration, the culmination point of the entire transformation process, remains largely obscure. Here, we studied the roles of double-stranded breaks (DSBs) and double-stranded T-DNA intermediates in the integration process. We produced transgenic tobacco (Nicotiana tabacum) plants carrying an I-SceI endonuclease recognition site that, upon cleavage with I-SceI, generates DSB. Then, we retransformed these plants with two A. tumefaciens strains: one that allows transient expression of I-SceI to induce DSB and the other that carries a T-DNA with the I-SceI site and an integration selection marker. Integration of this latter T-DNA as full-length and I-SceI-digested molecules into the DSB site was analyzed in the resulting plants. Of 620 transgenic plants, 16 plants integrated T-DNA into DSB at their I-SceI sites; because DSB induces DNA repair, these results suggest that the invading T-DNA molecules target to the DNA repair sites for integration. Furthermore, of these 16 plants, seven plants incorporated T-DNA digested with I-SceI, which cleaves only double-stranded DNA. Thus, T-strand molecules can be converted into double-stranded intermediates before their integration into the DSB sites within the host cell genome.     

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.     

Crown-gall-resistant transgenic apple trees that Silence Agrobacterium tumefaciens oncogenes

Crown gall disease is an economically significant problem in fruit and nut orchards, vineyards, and nurseries worldwide. Tumors on stems and leaves result from excessive production of the phytohormones auxin and cytokinin in plant cells genetically transformed by Agrobacterium tumefaciens. High phytohormone levels result from expression of three oncogenes transferred stably into the plant genome from A. tumefaciens: iaaM, iaaH, and ipt. The iaaM and iaaH oncogenes direct auxin biosynthesis, and the ipt oncogene causes cytokinin production. In contrast to other tissues, roots do not respond to high cytokinin levels, and auxin overproduction is sufficient to cause tumor growth on roots. Inactivation of iaaM abolished gall formation on apple tree roots. Transgenes designed to express double-stranded RNA from iaaM and ipt sequences prevented crown gall disease on roots of transgenic apple trees.these authors contributed equally to this workthese authors contributed equally to this work     

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.     

Assessment of the efficiency of cotransformation of the T-DNA of disarmed binary vectors derived from Agrobacterium tumefaciens and the T-DNA of A. rhizogenes

Co-transfer of Agrobacterium rhizogenes T-DNA and T-DNA from the A. tumefaciens binary vector pBin19 (Bevan, 1984) was studied in detail using Nicotiana rustica. High frequencies of co-transfer of T-DNA's were observed, even when no selection pressure was exerted. Increased levels of pBin19 T-DNA were found in hairy root cultures with selection at higher levels of kanamycin sulphate (50–200 g ml^–1). Several other species were also transformed by A. rhizogenes carrying pBin19 and A. rhizogenes harbouring a different binary factor, pAGS125 (Van den Elzen et al., 1985), was used to transform N. rustica hairy roots to confer hygromycin B resistance.     

Processing of the T-DNA of Agrobacterium tumefaciens generates border nicks and linear, single-stranded T-DNA.

Transfer and integration of a defined region (T-DNA) of the tumor-inducing (Ti) plasmid of Agrobacterium tumefaciens is essential for tumor formation. We used a physical assay to study structural changes induced in Agrobacterium T-DNA by cocultivation with plant cells. We show that nicks are introduced at unique, identical locations in each of the 24-base-pair imperfect direct repeats which flank the T-DNA and present evidence that a linear, single-stranded molecule is generated. We propose that these changes result from processing of the T-DNA for transfer and that they occur by a mechanism similar to DNA processing during conjugative DNA transfer between bacteria.     

农杆菌介导转基因植物T-DNA的整合方式

农杆菌介导的遗传转化已被广泛应用于植物转基因研究。作为外源基因的载体,农杆菌T-DNA片段在植物基因组中的整合方式,不仅影响外源基因的整合效率及稳定性,还会影响外源基因的表达特性。文章就农杆菌介导的T-DNA整合的两种主要模式、规律及相关研究手段进行综述,为农杆菌介导的转基因及T-DNA插入突变等相关研究提供借鉴。     

Trans-kingdom T-DNA transfer from Agrobacterium tumefaciens to Saccharomyces cerevisiae.

Agrobacterium tumefaciens transfers part of its tumour-inducing (Ti) plasmid, the transferred or T-DNA, to plants during tumourigenesis. This represents the only example of naturally occurring trans-kingdom transfer of genetic material. Here we report that A.tumefaciens can transfer its T-DNA not only to plant cells, but also to another eukaryote, namely the yeast Saccharomyces cerevisiae. The Ti plasmid virulence (vir) genes that mediate T-DNA transfer to plants were found to be essential for transfer to yeast as well. Transgenic S.cerevisiae strains were analysed for their T-DNA content. Results showed that T-DNA circles were formed in yeast with precise fusions between the left and right borders. Such T-DNA circles were stably maintained by the yeast if the replicator from the yeast 2 mu plasmid was present in the T-DNA. Integration of T-DNA in the S.cerevisiae genome was found to occur via homologous recombination. This contrasts with integration in the plant genome, where T-DNA integrates preferentially via illegitimate recombination. Our results thus suggest that the process of T-DNA integration is predominantly determined by host factors.     

Functional analysis of the Agrobacterium tumefaciens T-DNA transport pore protein VirB8

The VirB8 protein of Agrobacterium tumefaciens is essential for DNA transfer to plants. VirB8, a 237-residue polypeptide, is an integral membrane protein with a short N-terminal cytoplasmic domain. It interacts with two transport pore proteins, VirB9 and VirB10, in addition to itself. To study the role of these interactions in DNA transfer and to identify essential amino acids of VirB8, we introduced random mutations in virB8 by the mutagenic PCR method. The putative mutants were tested for VirB8 function by the ability to complement a virB8 deletion mutant in tumor formation assays. After multiple rounds of screening 13 mutants that failed to complement the virB8 deletion mutation were identified. Analysis of the mutant strains by DNA sequence analysis, Western blot assays, and reconstruction of new point mutations led to the identification of five amino acid residues that are essential for VirB8 function. The substitution of glycine-78 to serine, serine-87 to leucine, alanine-100 to valine, arginine-107 to proline or alanine, and threonine-192 to methionine led to the loss of VirB8 activity. When introduced into the wild-type strain, virB8(S87L) partially suppressed the tumor forming ability of the wild-type protein. Analysis of protein-protein interaction by the yeast two-hybrid assay indicated that VirB8(R107P) is defective in interactions with both VirB9 and VirB10. A second mutant VirB8(S87L) is defective in interaction with VirB9.     

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.