Recovery of Agrobacterium tumefaciens T-DNA molecules from whole plants early after transfer

Genomic consequences associated with Agrobacterium-mediated transformation of plants

Attenuated strains of the naturally occurring plant pathogen Agrobacterium tumefaciens can transfer virtually any DNA sequence of interest to model plants and crops. This has made Agrobacterium-mediated transformation (AMT) one of the most commonly used tools in agricultural biotechnology. Understanding AMT, and its functional consequences, is of fundamental importance given that it sits at the intersection of many fundamental fields of study, including plant-microbe interactions, DNA repair/genome stability, and epigenetic regulation of gene expression. Despite extensive research and use of AMT over the last 40 years, the extent of genomic disruption associated with integrating exogenous DNA into plant genomes using this method remains underappreciated. However, new technologies like long-read sequencing make this disruption more apparent, complementing previous findings from multiple research groups that have tackled this question in the past. In this review, we cover progress on the molecular mechanisms involved in Agrobacterium-mediated DNA integration into plant genomes. We also discuss localized mutations at the site of insertion and describe the structure of these DNA insertions, which can range from single copy insertions to large concatemers, consisting of complex DNA originating from different sources. Finally, we discuss the prevalence of large-scale genomic rearrangements associated with the integration of DNA during AMT with examples. Understanding the intended and unintended effects of AMT on genome stability is critical to all plant researchers who use this methodology to generate new genetic variants.

Characterization of T-Circles and Their Formation Reveal Similarities to Agrobacterium T-DNA Integration Patterns

Agrobacterium transfers T-DNA to plants where it may integrate into the genome. Non-homologous end-joining (NHEJ) has been invoked as the mechanism of T-DNA integration, but the role of various NHEJ proteins remains controversial. Genetic evidence for the role of NHEJ in T-DNA integration has yielded conflicting results. We propose to investigate the formation of T-circles as a proxy for understanding T-DNA integration. T-circles are circular double-strand T-DNA molecules, joined at their left (LB) and right (RB) border regions, formed in plants. We characterized LB-RB junction regions from hundreds of T-circles formed in Nicotiana benthamiana or Arabidopsis thaliana. These junctions resembled T-DNA/plant DNA junctions found in integrated T-DNA: Among complex T-circles composed of multiple T-DNA molecules, RB-RB/LB-LB junctions predominated over RB-LB junctions; deletions at the LB were more frequent and extensive than those at the RB; microhomology was frequently used at junction sites; and filler DNA, from the plant genome or various Agrobacterium replicons, was often present between the borders. Ku80 was not required for efficient T-circle formation, and a VirD2 ω mutation affected T-circle formation and T-DNA integration similarly. We suggest that investigating the formation of T-circles may serve as a surrogate for understanding T-DNA integration.

Distinct mechanisms for genomic attachment of the 5' and 3' ends of Agrobacterium T-DNA in plants

Agrobacterium tumefaciens, a pathogenic bacterium capable of transforming plants through horizontal gene transfer, is nowadays the preferred vector for plant genetic engineering. The vehicle for transfer is the T-strand, a single-stranded DNA molecule bound by the bacterial protein VirD2, which guides the T-DNA into the plant's nucleus where it integrates. How VirD2 is removed from T-DNA, and which mechanism acts to attach the liberated end to the plant genome is currently unknown. Here, using newly developed technology that yields hundreds of T-DNA integrations in somatic tissue of Arabidopsis thaliana, we uncover two redundant mechanisms for the genomic capture of the T-DNA 5' end. Different from capture of the 3' end of the T-DNA, which is the exclusive action of polymerase theta-mediated end joining (TMEJ), 5' attachment is accomplished either by TMEJ or by canonical non-homologous end joining (cNHEJ). We further find that TMEJ needs MRE11, whereas cNHEJ requires TDP2 to remove the 5' end-blocking protein VirD2. As a consequence, T-DNA integration is severely impaired in plants deficient for both MRE11 and TDP2 (or other cNHEJ factors). In support of MRE11 and cNHEJ specifically acting on the 5' end, we demonstrate rescue of the integration defect of double-deficient plants by using T-DNAs that are capable of forming telomeres upon 3' capture. Our study provides a mechanistic model for how Agrobacterium exploits the plant's own DNA repair machineries to transform it.

Plant DNA Repair and Agrobacterium T-DNA Integration

Agrobacterium species transfer DNA (T-DNA) to plant cells where it may integrate into plant chromosomes. The process of integration is thought to involve invasion and ligation of T-DNA, or its copying, into nicks or breaks in the host genome. Integrated T-DNA often contains, at its junctions with plant DNA, deletions of T-DNA or plant DNA, filler DNA, and/or microhomology between T-DNA and plant DNA pre-integration sites. T-DNA integration is also often associated with major plant genome rearrangements, including inversions and translocations. These characteristics are similar to those often found after repair of DNA breaks, and thus DNA repair mechanisms have frequently been invoked to explain the mechanism of T-DNA integration. However, the involvement of specific plant DNA repair proteins and Agrobacterium proteins in integration remains controversial, with numerous contradictory results reported in the literature. In this review I discuss this literature and comment on many of these studies. I conclude that either multiple known DNA repair pathways can be used for integration, or that some yet unknown pathway must exist to facilitate T-DNA integration into the plant genome.

From Bacteriophage to Plant Genetics

When first asked to write a review of my life as a scientist, I doubted anyone would be interested in reading it. In addition, I did not really want to compose my own memorial. However, after discussing the idea with other scientists who have written autobiographies, I realized that it might be fun to dig into my past and to reflect on what has been important for me, my life, my family, my friends and colleagues, and my career. My life and research has taken me from bacteriophage to Agrobacterium tumefaciens-mediated DNA transfer to plants to the plant genome and its environmentally induced changes. I went from being a naïve, young student to a postdoc and married mother of two to the leader of an ever-changing group of fantastic coworkers-a journey made rich by many interesting scientific milestones, fascinating exploration of all corners of the world, and marvelous friendships.

T-DNA-genome junctions form early after infection and are influenced by the chromatin state of the host genome

Agrobacterium tumefaciens mediated T-DNA integration is a common tool for plant genome manipulation. However, there is controversy regarding whether T-DNA integration is biased towards genes or randomly distributed throughout the genome. In order to address this question, we performed high-throughput mapping of T-DNA-genome junctions obtained in the absence of selection at several time points after infection. T-DNA-genome junctions were detected as early as 6 hours post-infection. T-DNA distribution was apparently uniform throughout the chromosomes, yet local biases toward AT-rich motifs and T-DNA border sequence micro-homology were detected. Analysis of the epigenetic landscape of previously isolated sites of T-DNA integration in Kanamycin-selected transgenic plants showed an association with extremely low methylation and nucleosome occupancy. Conversely, non-selected junctions from this study showed no correlation with methylation and had chromatin marks, such as high nucleosome occupancy and high H3K27me3, that correspond to three-dimensional-interacting heterochromatin islands embedded within euchromatin. Such structures may play a role in capturing and silencing invading T-DNA.

Agrobacterium tumefaciens mediated T-DNA integration is an important tool for genetic engineering in plants. This work compares the genetic and epigenetic landscapes of T-DNA-genome junctions under selective and non-selective conditions. Under selection, preferential junctions in low-nucleosome occupancy and hypomethylated regions were found. In the absence of selection, these biases disappeared and T-DNA-genome junctions were uniformly distributed with a preference for 3D-interacting heterochromatin islands embedded within euchromatin, suggesting that many integration events become transcriptionally inactive.

Formation of complex extrachromosomal T-DNA structures in Agrobacterium tumefaciens-infected plants

Agrobacterium tumefaciens is a unique plant pathogenic bacterium renowned for its ability to transform plants. The integration of transferred DNA (T-DNA) and the formation of complex insertions in the genome of transgenic plants during A. tumefaciens-mediated transformation are still poorly understood. Here, we show that complex extrachromosomal T-DNA structures form in A. tumefaciens-infected plants immediately after infection. Furthermore, these extrachromosomal complex DNA molecules can circularize in planta. We recovered circular T-DNA molecules (T-circles) using a novel plasmid-rescue method. Sequencing analysis of the T-circles revealed patterns similar to the insertion patterns commonly found in transgenic plants. The patterns include illegitimate DNA end joining, T-DNA truncations, T-DNA repeats, binary vector sequences, and other unknown "filler" sequences. Our data suggest that prior to T-DNA integration, a transferred single-stranded T-DNA is converted into a double-stranded form. We propose that termini of linear double-stranded T-DNAs are recognized and repaired by the plant's DNA double-strand break-repair machinery. This can lead to circularization, integration, or the formation of extrachromosomal complex T-DNA structures that subsequently may integrate.

Stable recombinase-mediated cassette exchange in Arabidopsis using Agrobacterium tumefaciens

Site-specific integration is an attractive method for the improvement of current transformation technologies aimed at the production of stable transgenic plants. Here, we present a Cre-based targeting strategy in Arabidopsis (Arabidopsis thaliana) using recombinase-mediated cassette exchange (RMCE) of transferred DNA (T-DNA) delivered by Agrobacterium tumefaciens. The rationale for effective RMCE is the precise exchange of a genomic and a replacement cassette both flanked by two heterospecific lox sites that are incompatible with each other to prevent unwanted cassette deletion. We designed a strategy in which the coding region of a loxP/lox5171-flanked bialaphos resistance (bar) gene is exchanged for a loxP/lox5171-flanked T-DNA replacement cassette containing the neomycin phosphotransferase (nptII) coding region via loxP/loxP and lox5171/lox5171 directed recombination. The bar gene is driven by the strong 35S promoter, which is located outside the target cassette. This placement ensures preferential selection of RMCE events and not random integration events by expression of nptII from this same promoter. Using root transformation, during which Cre was provided on a cotransformed T-DNA, 50 kanamycin-resistant calli were selected. Forty-four percent contained a correctly exchanged cassette based on PCR analysis, indicating the stringency of the selection system. This was confirmed for the offspring of five analyzed events by Southern-blot analysis. In four of the five analyzed RMCE events, there were no additional T-DNA insertions or they easily segregated, resulting in high-efficiency single-copy RMCE events. Our approach enables simple and efficient selection of targeting events using the advantages of Agrobacterium-mediated transformation.

Analysis of T-DNA- Xa21 loci and bacterial blight resistance effects of the transgene Xa21 in transgenic rice

The genetic loci and phenotypic effects of the transgene Xa21, a bacterial blight (BB) resistance gene cloned from rice, were investigated in transgenic rice produced through an Agrobacterium-mediated transformation system. The flanking sequences of integrated T-DNAs were isolated from Xa21 transgenic rice lines using thermal asymmetric interlaced PCR. Based on the analysis of 24 T-DNA- Xa21 flanking sequences, T-DNA loci in rice could be classified into three types: the typical T-DNA integration with the definite left and right borders, the T-DNA integration linked with the adjacent vector backbone sequences and the T-DNA integration involved in a complicated recombination in the flanking sequences. The T-DNA integration in rice was similar to that in dicotyledonous genomes but was significantly different from the integration produced through direct DNA transformation approaches. All three types of integrated transgene Xa21 could be stably inherited and expressed the BB resistance through derived generations in their respective transgenic lines. The flanking sequences of the typical T-DNA integration consisted of actual rice genomic DNA and could be used as probes to locate the transgene on the rice genetic map. A total of 15 different rice T-DNA flanking sequences were identified. They displayed restriction fragment length polymorphisms (RFLPs) between two rice varieties, ZYQ8 and JX17, and were mapped on rice chromosomes 1, 3, 4, 5, 7, 9, 10, 11 and 12, respectively, by using a double haploid population derived from a cross between ZYQ8 and JX17. The blast search and homology comparison of the rice T-DNA flanking sequences with the rice chromosome-anchored sequence database confirmed the RFLP mapping results. On the basis of genetic mapping of the T-DNA- Xa21 loci, the BB resistance effects of the transgene Xa21 at different chromosome locations were investigated using homozygous transgenic lines with only one copy of the transgene. Among the transgenic lines, no obvious position effects of the transgene Xa21 were observed. In addition, the BB resistance levels of the Xa21 transgenic plants with different transgene copy numbers and on different genetic backgrounds were also investigated. It was observed that genetic background (or genome) effects were more obvious than dosage effects and position effects on the BB resistance level of the transgenic plants.

T-DNA recombination and replication in maize cells

T-DNA recombination and replication was analyzed in 'black mexican sweet' (BMS) cells transformed with T-DNAs containing the replication system from wheat dwarf virus (WDV). Upon recombination between the T-DNA ends, a promoterless marker gene (gusA) was activated. Activation of the recombination marker gene was delayed and increased exponentially over time, suggesting that recombination and amplification of the T-DNA occurred in maize cells. Mutant versions of the viral initiator gene (rep), known to be defective in the replication function, failed to generate recoverable recombinant T-DNA molecules. Circularization of T-DNA by the FLP/FRT site-specific recombination system and/or homologous recombination was not necessary to recover circular T-DNAs. However, replicating T-DNAs appeared to be suitable substrates for site-specific and homologous recombination. Among 33 T-DNA border junctions sequenced, only one pair of identical junction sites was found implying that the population of circular T-DNAs was highly heterogenous. Since no circular T-DNA molecules were detected in treatments without rep, it suggested that T-DNA recombination was linked to replication and might have been stimulated by this process. The border junctions observed in recombinant T-DNA molecules were indicative of illegitimate recombination and were similar to left-border recombination of T-DNA into the genome after Agro-mediated plant transformation. However, recombination between T-DNA molecules differed from T-DNA/genomic DNA junction sites in that few intact right borders were observed. The replicating T-DNA molecules did not enhance genomic random integration of T-DNA in the experimental configuration used for this study.

Transgene integration in aspen: structures of integration sites and mechanism of T-DNA integration

To obtain insight into the mechanism of transferred DNA (T-DNA) integration in a long-lived tree system, we analysed 30 transgenic aspen lines. In total, 27 right T-DNA/plant junctions, 20 left T-DNA/plant junctions, and 10 target insertions from control plants were obtained. At the right end, the T-DNA was conserved up to the cleavage site in 18 transgenic lines (67%), and the right border repeat was deleted in nine junctions. Nucleotides from the left border repeat were present in 19 transgenic lines out of 20 cases analysed. However, only four (20%) of the left border ends were conserved to the processing end, indicating that the T-DNA left and right ends are treated mechanistically differently during the T-DNA integration process. Comparison of the genomic target sites prior to integration to the T-DNA revealed that the T-DNA inserted into the plant genome without any notable deletion of genomic sequence in three out of 10 transgenic lines analysed. However, deletions of DNA ranging in length from a few nucleotides to more than 500 bp were observed in other transgenic lines. Filler DNAs of up to 235 bp were observed on left and/or right junctions of six transgenic lines, which in most cases originated from the nearby host genomic sequence or from the T-DNA. Short sequence similarities between recombining strands near break points, in particular for the left T-DNA end, were observed in most of the lines analysed. These results confirm the well-accepted T-DNA integration model based on single-stranded annealing followed by ligation of the right border which is preserved by the VirD2 protein. However, a second category of T-DNA integration was also identified in nine transgenic lines, in which the right border of the T-DNA was partly truncated. Such integration events are described via a model for the repair of genomic double-strand breaks in somatic plant cells based on synthesis-dependent strand-annealing. This report in a long-lived tree system provides major insight into the mechanism of transgene integration.

How plants make ends meet: DNA double-strand break repair

DNA double-strand breaks (DSBs) lead to serious genomic deficiencies if left unrepaired. Recent studies have provided new insight into the mechanisms, the mutants and the genes involved in DSB repair in plants. These studies indicate that high fidelity DSB repair via homologous recombination is less frequent than non-homologous end-joining. Interestingly, non-homologous end-joining in plants is more error-prone than in other species, being associated with various rearrangements that often include deletions and insertions (filler DNA). We discuss the mechanism of error-prone DSB repair, which is probably an important driving force in plant genome evolution.

Direct repeats of T-DNA integrated in tobacco chromosome: characterization of junction regions

Plant transformation via Agrobacterium frequently results in formation of multiple copy T-DNA arrays at one target site of the chromosome. The T-DNA copies are arranged in repeats, direct or inverted around one of the T-DNA borders. A Ti plasmid-derived transformation vector has been constructed enabling direct selection of transformants carrying at least two linked copies of T-DNA in the same orientation. The selection is based on expression of a promoterless neomycin phosphotransferase gene on one T-DNA copy from a promoter located on the other T-DNA copy. After co-cultivation of tobacco protoplasts with Agrobacterium, as many as 30% of regenerated transformed plants carried directly repeated T-DNA copies. The junction regions between two T-DNAs were amplified and 13 amplified fragments were cloned and sequenced. The involvement of T-DNA left and right border sequences in direct repeat junctions was determined. In some junctions, additional filler DNA was detected. The length of filler DNA varied from a few up to almost 300 bp. The longer filler DNAs from two clones were found to be T-DNA fragments in direct or reverse orientation. We discuss the recently suggested models for T-DNA integration and propose that the formation of direct repeats in genomes does not necessarily result from ligation of intermediates (i.e. T-strands), but more likely from the co-integration of several intermediates into one target site.

Capture of genomic and T-DNA sequences during double-strand break repair in somatic plant cells

To analyze genomic changes resulting from double-strand break (DSB) repair, transgenic tobacco plants were obtained that carried in their genome a restriction site of the rare cutting endonuclease I-SceI within a negative selectable marker gene. After induction of DSB repair via Agrobacterium-mediated transient expression of I-SceI, plant cells were selected that carried a loss-of-function phenotype of the marker. Surprisingly, in addition to deletions, in a number of cases repair was associated with the insertion of unique and repetitive genomic sequences into the break. Thus, DSB repair offers a mechanism for spreading different kinds of sequences into new chromosomal positions. This may have evolutionary consequences particularly for plants, as genomic alterations occurring in meristem cells can be transferred to the next generation. Moreover, transfer DNA (T-DNA), carrying the open reading frame of I-SceI, was found in several cases to be integrated into the transgenic I-SceI site. This indicates that DSB repair also represents a pathway for the integration of T-DNA into the plant genome.

Termini and telomeres in T-DNA transformation

A T-DNA vector for plant transformation has been constructed in which the cloning site is located 9 bp from the right-border (RB) end and 27 bp from the left-border (LB) end. In this vector cloned DNA homologous to plant chromosomal sequences is located at the T-DNA termini, and will thus be exposed by even limited exonucleolysis in planta. The arabidopsis ADH (alcohol dehydrogenase) locus was mobilized from Agrobacterium, and integration into the recipient genome was studied. Despite the terminal location of ADH homology in this vector, the T-DNA integrated essentially at random in the Arabidopsis genome rather than at the endogenous ADH locus. T-DNA integration was blocked, however, when Arabidopsis telomeric sequences were added to the construct at each end of the ADH homology. Thus the predominant mode by which incoming T-DNA is integrated into the continuity of chromosomal DNA involves free DNA ends, but, in contrast to modes of recombination such as gap repair, does not involve extensive terminal DNA sequence homology.

Translocation of DNA across bacterial membranes

DNA translocation across bacterial membranes occurs during the biological processes of infection by bacteriophages, conjugative DNA transfer of plasmids, T-DNA transfer, and genetic transformation. The mechanism of DNA translocation in these systems is not fully understood, but during the last few years extensive data about genes and gene products involved in the translocation processes have accumulated. One reason for the increasing interest in this topic is the discussion about horizontal gene transfer and transkingdom sex. Analyses of genes and gene products involved in DNA transfer suggest that DNA is transferred through a protein channel spanning the bacterial envelope. No common model exists for DNA translocation during phage infection. Perhaps various mechanisms are necessary as a result of the different morphologies of bacteriophages. The DNA translocation processes during conjugation, T-DNA transfer, and transformation are more consistent and may even be compared to the excretion of some proteins. On the basis of analogies and homologies between the proteins involved in DNA translocation and protein secretion, a common basic model for these processes is presented.

Agrobacterium tumefaciens transfers single-stranded transferred DNA (T-DNA) into the plant cell nucleus

Transferred DNA (T-DNA) is transferred as a single-stranded derivative from Agrobacterium to the plant cell nucleus. This conclusion is drawn from experiments exploiting the different properties of single- and double-stranded DNA to perform extrachromosomal homologous recombination in plant cells. After transfer from Agrobacterium to plant cells, T-DNA molecules recombined much more efficiently if the homologous sequences were of opposite polarity than if they were of the same polarity. This observation reflects the properties of single-stranded DNA; single-stranded DNA molecules of opposite polarity can anneal directly, whereas single-stranded DNA molecules of the same polarity first have to become double stranded to anneal. Judging from the relative amounts of single- to double-stranded T-DNA derivatives undergoing recombination, we infer that the T-DNA derivatives enter the plant nucleus in their single-stranded form.

Possible integration of Trypanosoma cruzi kDNA minicircles into the host cell genome by infection

Infection with Trypanosoma cruzi is known to induce the division of peritoneal macrophages in BALB/c mice. We have demonstrated, by cytogenetic analysis, that accessory DNA elements are associated with the metaphase macrophage chromosomes of such infected macrophages. The identification of these accessory DNA elements with T. cruzi DNA is strongly supported by the association of 3H-label with some chromatids in macrophages previously infected with T. cruzi which had been labelled with 3H-methyl-thymidine. The karyotyping consistently showed preferential associations of T. cruzi DNA with chromosomes 3, 6 and 11. A conclusive demonstration of the parasite origin of the integrated DNA came from fluorescein in situ hybridization studies using specific parasite DNAs as probes. In order to determine the identity of the inserted DNA and to investigate the nature of the integration mechanism, Southern blot analyses were performed on DNA extracted from both uninfected and infected (but parasite-free) macrophages. Hybridizations of BamHI, EcoRI and TaqI digests of DNA from T. cruzi-infected host cells all revealed the presence of a 1.7-kb DNA fragment when probed with kDNA. The covalent association of kDNA with that of the host was confirmed by the fact that AluI and Hinf-I digests of DNA from infected host cells produced a number of bands, in a size range of 0.8-3.6 kb, which hybridized with kDNA minicircles. None of these bands was found in DNA purified from cell-free preparations of the parasite and thus it must be concluded that they represent insertion fragments between parasite and host cell DNA. These results strongly suggest that kDNA minicircles from T. cruzi have been integrated into the genome of the host cell following infection.

Two-way chemical signaling in Agrobacterium-plant interactions

The discovery in 1977 that Agrobacterium species can transfer a discrete segment of oncogenic DNA (T-DNA) to the genome of host plant cells has stimulated an intense interest in the molecular biology underlying these plant-microbe associations. This attention in turn has resulted in a series of insights about the biology of these organisms that continue to accumulate at an ever-increasing rate. This excitement was due in part to the notion that this unprecedented interkingdom DNA transfer could be exploited to create transgenic plants containing foreign genes of scientific or commercial importance. In the course of these discoveries, Agrobacterium became one of the best available models for studying the molecular interactions between bacteria and higher organisms. One extensively studied aspect of this association concerns the exchange of chemical signals between Agrobacterium spp. and host plants. Agrobacterium spp. can recognize no fewer than five classes of low-molecular-weight compounds released from plants, and other classes probably await discovery. The most widely studied of these are phenolic compounds, which stimulate the transcription of the genes needed for infection. Other compounds include specific monosaccharides and acidic environments which potentiate vir gene induction, acidic polysaccharides which induce one or more chromosomal genes, and a family of compounds called opines which are released from tumorous plant cells to the bacteria as nutrient sources. Agrobacterium spp. in return release a variety of chemical compounds to plants. The best understood is the transferred DNA itself, which contains genes that in various ways upset the balance of phytohormones, ultimately causing neoplastic cell proliferation. In addition to transferring DNA, some Agrobacterium strains directly secrete phytohormones. Finally, at least some strains release a pectinase, which degrades a component of plant cell walls.

Illegitimate recombination in plants: a model for T-DNA integration

Agrobacterium tumefaciens is a soil bacterium capable of transferring DNA (the T-DNA) to the genome of higher plants, where it is then stably integrated. Six T-DNA inserts and their corresponding preinsertion sites were cloned from Arabidopsis thaliana and analyzed. Two T-DNA integration events from Nicotiana tabacum were included in the analysis. Nucleotide sequence comparison of plant target sites before and after T-DNA integration showed that the T-DNA usually causes only a small (13-28 bp) deletion in the plant DNA, but larger target rearrangements can occur. Short homologies between the T-DNA ends and the target sites, as well as the presence of filler sequences at the junctions, indicate that T-DNA integration is mediated by illegitimate recombination and that these processes in plants are very analogous to events in mammalian cells. We propose a model for T-DNA integration on the basis of limited base-pairing for initial synapsis, followed by DNA repair at the junctions. Variations of the model can explain the formation of filler DNA at the junctions by polymerase slipping and template switching during DNA repair synthesis and the presence of larger plant target DNA rearrangements.

Integration of Agrobacterium T-DNA into a tobacco chromosome: possible involvement of DNA homology between T-DNA and plant DNA

We established tobacco tumour cell lines from crown galls induced by Agrobacterium. Restriction fragments containing T-DNA/plant DNA junctions were cloned from one of the cell lines, which has a single copy of the T-DNA in a unique region of its genome. We also isolated a DNA fragment that contained the integration target site from nontransformed tobacco cells. Nucleotide sequence analyses showed that the right and left breakpoints of the T-DNA mapped ca. 7.3 kb internal to the right 25 bp border and ca. 350 bp internal to the left border respectively. When the nucleotide sequences around these breakpoints were compared with the sequence of the target, significant homology was seen between the region adjacent to the integration target site and both external regions of the T-DNA breakpoints. In addition, a short stretch of plant DNA in the vicinity of the integration site was deleted. This deletion seems to have been promoted by homologous recombination between short repeated sequences that were present on both sides of the deleted stretch. Minor rearrangements, which included base substitutions, insertions and deletions, also took place around the integration site in the plant DNA. These results, together with previously reported results showing that in some cases sequences homologous to those in T-DNA are present in plant DNA regions adjacent to left recombinational junctions, indicate that sequence homology between the incoming T-DNA and the plant chromosomal DNA has an important function in T-DNA integration.(ABSTRACT TRUNCATED AT 250 WORDS)

The virD genes from the vir region of the Ti plasmid: T-region border dependent processing steps in different rec mutants of Escherichia coli

We evaluated the substrate requirements for virD-mediated T-circle formation in an in vivo binary test system in Escherichia coli. Two copies of the 25-bp sequence which defines the right border of the T-DNA (transferred DNA) are sufficient, and the right and the left copy of the border are equivalent in function in this system. Experiments with different rec mutants show that the occurrence and frequency of circular double-stranded and single-stranded T-DNA equivalents strongly depend on rec functions of the host. These results are discussed in the context of processing of the tumor-inducing Ti plasmid preceding the T-DNA transfer from agrobacteria to plants.

Plant chromosome/marker gene fusion assay for study of normal and truncated T-DNA integration events

During Agrobacterium tumefaciens infection, the T-DNA flanked by 24 bp imperfect direct repeats is transferred and stably integrated into the plant chromosome at random positions. Here we measured the frequency with which a promoterless reporter gene is activated after insertion into the Nicotiana tabacum SR1 genome. When adjacent to the right or left T-DNA border sequences, at least 35% of the transformants express the marker gene, suggesting preferential T-DNA insertion (greater than 70%) in transcriptionally active regions of the plant genome. When the promoterless neomycin phosphotransferase II (nptII) gene is located internally in the T-DNA, the activation frequency drops to 1% since gene activation requires T-DNA truncation. These truncation events in the nptII upstream region occur independently of the nature of the upstream sequence and of the T-DNA length. Deletion of the right border region prevents the detection of activated marker genes. Therefore, T-DNA truncation probably occurs after synthesis of a normal T-DNA intermediate during the transfer and/or integration process. In the absence of border regions, expression of the nptII selectable marker directed by the nopaline synthase promoter was detected in 1 out of 10(5) regenerated calli, suggesting the possibility that any DNA sequence from the Ti plasmid can be transformed into the plant genome, albeit at a low frequency.

Covalently bound VirD2 protein of Agrobacterium tumefaciens protects the T-DNA from exonucleolytic degradation

We show that upon induction of Agrobacterium tumefaciens, free linear double-stranded T-DNA molecules as well as the previously described T-strands are generated from the Ti plasmid. A majority of these molecules are bound to a protein. We show that this protein is the product of the virulence gene virD2. This protein was found to be attached to the 5' terminus of processed T-DNA at the right border and to the rest of the Ti plasmid at the left border. The protein remnant after Pronase digestion rendered the right end of the double-stranded T-DNA resistant to 5'----3' exonucleolytic attack in vitro. The protein-DNA association was resistant to SDS, mercaptoethanol, mild alkali, piperidine, and hydroxylamine, indicating that it involves a covalent linkage. The possible involvement of this T-DNA-protein complex in replication, transduction to the plant, nuclear targeting, and integration into the plant nuclear DNA is discussed.