Molecular characterization of T-DNA integration sites in transgenic birch

The integration and structure of a transgene locus can have profound effects on the level and stability of transgene expression. We screened 28 transgenic birch (Betula platyphylla Suk.) lines transformed with an insect-resistance gene (bgt) using Agrobacterium tumefaciens. Among the transgenic plants, the copy number of transgene varied from one to four. A rearrangement or partial deletion had occurred in the process of T-DNA integration. T-DNA repeat formation, detected by reverse primer PCR, was found among randomly screened transgenic lines. Sequencing of the junctions between the T-DNA inserts revealed deletions of 19–589 bp and an additional 45 bp filler DNA sequence was inserted between the T-DNA repeats at one junction. Micro-homologous sequences (1–6 bp) were observed in the junctions between the T-DNA inserts. Using SiteFinding-PCR, a relatively high percentage of AT value was found for the flanking regions. Deletion of the right border repeat was observed in 12/18 of the T-DNA/plant junctions analyzed. The number of nucleotides deleted varied from 3 to 712. Deletions of 17–89 bp were observed in all left T-DNA/plant junctions analyzed. A vector backbone DNA sequence in the transgene loci was also detected using primer pairs outside the left and right T-DNA borders. Approximately 89.3% of the lines contained some vector backbone DNA. These observations revealed that it is important to check the specificity of the integration. A mechanism of T-DNA transport and integration is proposed for this long-lived tree species.     

Transgene repeats in aspen: molecular characterisation suggests simultaneous integration of independent T-DNAs into receptive hotspots in the host genome

Rearrangements of T-DNAs during genetic transformation of plants can result in the insertion of transgenes in the form of repeats into the host genome and frequently lead to loss of transgene expression. To obtain insight into the mechanism of repeat formation we screened 45 transgenic lines of aspen and hybrid aspen transformed with six different gene constructs. The frequency of T-DNA repeat formation among randomly screened transgenic lines was found to be about 21%. In ten transgenic lines direct repeats were detected. An inverted repeat was found in one other transgenic line. Sequencing of the junctions between the T-DNA inserts revealed identical residual right-border repeat sequences at the repeat junctions in all ten transgenic lines that had direct repeats. Formation of "precise" junctions based on short regions of sequence similarity between recombining strands was observed in three transgenic lines transformed with the same plasmid. Additional DNA sequences termed filler DNAs were found to be inserted between the T-DNA repeats at eight junctions where there was no similarity between recombining ends. The length of the filler DNAs varied from 4 to almost 300 bp. Small filler DNAs--a few base pairs long--were in most cases copied from T-DNA near the break points. The large filler sequences of about 300 bp in two transgenic lines were found to be of host plant origin, suggesting that transgene repeat formation occurred as a result of the simultaneous invasion of a receptive site in the host genome by two independent T-DNA strands. On the basis of the results obtained, and in the light of previous reports on T-DNA/plant DNA junctions in aspen and other crop plants, a mechanistic model for transgene rearrangement and filler formation is suggested.     

T-DNA integration: a mode of illegitimate recombination in plants.

Transferred DNA (T-DNA) insertions of Agrobacterium gene fusion vectors and corresponding insertional target sites were isolated from transgenic and wild type Arabidopsis thaliana plants. Nucleotide sequence comparison of wild type and T-DNA-tagged genomic loci showed that T-DNA integration resulted in target site deletions of 29-73 bp. In those cases where integrated T-DNA segments turned out to be smaller than canonical ones, the break-points of target deletions and T-DNA insertions overlapped and consisted of 5-7 identical nucleotides. Formation of precise junctions at the right T-DNA border, and DNA sequence homology between the left termini of T-DNA segments and break-points of target deletions were observed in those cases where full-length canonical T-DNA inserts were very precisely replacing plant target DNA sequences. Aberrant junctions were observed in those transformants where termini of T-DNA segments showed no homology to break-points of target sequence deletions. Homology between short segments within target sites and T-DNA, as well as conversion and duplication of DNA sequences at junctions, suggests that T-DNA integration results from illegitimate recombination. The data suggest that while the left T-DNA terminus and both target termini participate in partial pairing and DNA repair, the right T-DNA terminus plays an essential role in the recognition of the target and in the formation of a primary synapsis during integration.     

The DNA sequences of T-DNA junctions suggest that complex T-DNA loci are formed by a recombination process resembling T-DNA integration

After Agrobacterium-mediated plant transformation, multiple T-DNAs frequently integrate at the same position in the plant genome, resulting in the formation of inverted and direct repeats. Because these inverted repeats cannot be amplified and analyzed by PCR, Arabidopsis root cells were co-transformed with two different T-DNAs with distinct sequences adjacent to the T-DNA borders. Nine direct or inverted T-DNA border junctions were analyzed at the sequence level. Precise end-to-end fusions were found between two right border ends, whereas imprecise fusions and filler DNA were present in T-DNA linkages containing a left border end. The results suggest that end-to-end ligation of double-stranded T-DNAs occurs especially between right T-DNA ends and that illegitimate recombination on the basis of microhomology, deletions, repair activities and insertions of filler DNA is involved in the formation of left border T-DNA junctions. Therefore, a similar illegitimate recombination mechanism is proposed that is involved in the formation of complex T-DNA inserts as well as in the integration of the T-DNA in the plant genome.     

T-DNA is organized predominantly in inverted repeat structures in plants transformed with Agrobacterium tumefaciens C58 derivatives

Summary The detailed structural organization of DNA sequences transferred to the plant genome via Agrobacterium tumefaciens has been determined in 11 transgenic tomato plants that carry the transferred DNA (T-DNA) at a single genetic locus. The majority (seven) of these plants were found to carry multiple copies of T-DNA arranged in inverted repeat structures. Such a high frequency of inverted repeats among transgenotes has not been previously reported and appears to be characteristic of transformation events caused by C58/pGV3850 strains of Agrobacterium. The inverted repeats were found to be centered on either the left or the right T-DNA boundary and both types were observed at similar frequency. In several plants both types of inverted repeat were found to coexist in the same linear array of elements. Direct repeats were observed in two plants, each time at the end of an array of inverted repeat elements, and at a lower frequency than inverted repeats. The junctions between T-DNA elements and plant DNA sequences and the junctions between adjacent T-DNA elements were mapped in the same 11 plants, allowing the determination of the distribution of junction points at each end for both types of junction. Based on a total of 17 distinct junctions at the right end of T-DNA and 19 at the left end, the distribution of junction points was found to be much more homogeneous at the right end than at the left end. Left end junctions were found to be distributed over a 3 kb region of T-DNA with two thirds of the junctions within 217 bp of the left repeat. Two thirds of the right end junctions were found to lie within 11 bp of the right repeat with the rest more than 39 bp from the right repeat. T-DNA::plant DNA junctions and T-DNA::T-DNA inverted repeat junctions showed similar distributions of junction points at both right and left ends. The possibilities that T-DNA inverted repeats are unstable in plants and refractory to cloning in wild type Escherichia coli is discussed. Two distinct types of mechanisms for inverted repeat formation are contrasted, replication and ligation mechanisms.     

Agrobacterium-mediated barley (Hordeum vulgare L.) transformation using green fluorescent protein as a visual marker and sequence analysis of the T-DNA∝barley genomic DNA junctions

Agrobacterium-mediated barley transformation promises many advantages compared to alternative gene transfer methods, but has so far been established in only a few laboratories. We describe a protocol that facilitates rapid establishment and optimisation of Agrobacterium-mediated transformation for barley by instant monitoring of the transformation success. The synthetic green fluorescent protein (sgfpS65T) reporter gene was introduced in combination with thehpt selectable marker gene into immature embryos of barley (Hordeum vulgare L.) by cocultivation with Agrobacterium tumefaciens strain AGLO harboring binary vector pYF133. Using green fluorescent protein (GFP) as a non-destructive visual marker allowed us to identify single-cell recipients of T-DNA at an early stage, track their fate and evaluate factors that affect T-DNA delivery. GFP screening was combined with a low level hygromycin selection. Consequently, transgenic plantlets ready to transfer to soil were obtained within 50 days of explant culture. Southern blot- and progeny segregation analyses revealed a single copy T-DNA insert in more than half of the transgenic barley plants. T-DNA/barley genomic DNA junctions were amplified and sequenced. The right T-DNA ends were highly conserved and clustered around the first 4 nucleotides of the right 25 bp border repeat, while the left T-DNA ends were more variable, located either in the left 25 bp border repeat or within 13 bp from the left repeat. T-DNAs were transferred from Agrobacterium to barley with exclusion of vector sequence suggesting a similar molecular T-DNA transfer mechanism as in dicotyledonous plants.     

T-DNA integration patterns in transgenic tobacco plants

To investigate the various integration patterns of T-DNA generated by infection withAgrobacterium, we developed a vector (pRCV2) for the effective T-DNA tagging and applied it to tobacco (Nicotiana tabacum cv. Havana SR1). pRCV2 was constructed for isolating not only intact T-DNA inserts containing both side borders of T-DNA, but also for partial T-DNA inserts that comprise only the right or left side. We also designed PCR confirmation primer sets that can amplify in several important regions within pRCV2 to detect various unpredictable integration patterns. These can also be used for the direct inverse PCR. Leaf disks of tobacco were transformed withAgrobacterium tumefaciens LBA4404 harboring pRCV2. PCR and Southern analysis revealed the expected 584 bp product for thehpt gene as well as one of 600 bp for thegus gene in all transformants; one or two copies were identified for these integrated genes. Flanking plant genomic DNA sequences from the transgenic tobacco were obtained via plasmid rescue and then sequenced. Abnormal integration patterns in the tobacco genome were found in many transgenic lines. Of the 17 lines examined, 11 contained intact vector backbone; a somewhat larger deletion of the left T-DNA portion was encountered in 4 lines. Because nicking sites at the right border showed irregular patterns when the T-DNA was integrated, it was difficult to predict the junction regions between the vector and the flanking plant DNA.     

T-DNA Integration Category and Mechanism in Rice Genome

T-DNA integration is a key step in the process of plant transformation, which is proven to be important for analyzing T-DNA integration mechanism. The structures of T-DNA right borders inserted into the rice (Oryza sativa L.) genome and their flanking sequences were analyzed. It was found that the integrated ends of the T-DNA right border occurred mainly on five nucleotides "TGACA" in inverse repeat (IR)sequence of 25 bp, especially on the third base "A". However, the integrated ends would sometimes lie inward of the IR sequence, which caused the IR sequence to be lost completely. Sometimes the right integrated ends appeared on the vector sequences rightward of the T-DNA right border, which made the TDNA, carrying vector sequences, integrated into the rice genome. These results seemingly suggest that the IR sequence of the right border plays an important role in the process of T-DNA integration into the rice genome, but is not an essential element. The appearance of vector sequences neighboring the T-DNA right border suggested that before being transferred into the plant cell from Agrobacterium, the entire T-DNA possibly began from the left border in synthesis and then read through at the right border. Several nucleotides in the T-DNA right border homologous with plant DNA and filler DNAs were frequently discovered in the integrated position ofT-DNA. Some small regions in the right border could match with the plant sequence, or form better matches, accompanied by the occurrence of filler DNA, through mutual twisting, and then the TDNA was integrated into plant chromosome through a partially homologous recombination mechanism. The appearance of filler DNA would facilitate T-DNA integration. The fragments flanking the T-DNA right border in transformed rice plants could derive from different parts of the inner T-DNA region; that is, disruption and recombination could occur at arbitrary positions in the entire T-DNA, in which the homologous area was comparatively easier to be disrupted. The structure of flanking sequences of T-DNA integrated in the rice chromosome presented various complexities. These complexities were probably a result of different patterns of recombination in the integrating process. Some types of possible integrating mechanism are detailed.     

Molecular characterization of transgenic shallots (Allium cepa L.) by adaptor ligation PCR (AL-PCR) and sequencing of genomic DNA flanking T-DNA borders

Genomic DNA blot hybridization is traditionally used to demonstrate that, via genetic transformation, foreign genes are integrated into host genomes. However, in large genome species, such as Allium cepa L., the use of genomic DNA blot hybridization is pushed towards its limits, because a considerable quantity of DNA is needed to obtain enough genome copies for a clear hybridization pattern. Furthermore, genomic DNA blot hybridization is a time-consuming method. Adaptor ligation PCR (AL-PCR) of genomic DNA flanking T-DNA borders does not have these drawbacks and seems to be an adequate alternative to genomic DNA blot hybridization. Using AL-PCR we proved that T-DNA was integrated into the A. cepa genome of three transgenic lines transformed with Agrobacterium tumefaciens EHA105 (pCAMBIA 1301). The AL-PCR patterns obtained were specific and reproducible for a given transgenic line. The results showed that T-DNA integration took place and gave insight in the number of T-DNA copies present. Comparison of AL-PCR and previously obtained genomic DNA blot hybridization results pointed towards complex T-DNA integration patterns in some of the transgenic plants. After cloning and sequencing the AL-PCR products, the junctions between plant genomic DNA and the T-DNA insert could be analysed in great detail. For example it was shown that upon T-DNA integration a 66bp genomic sequence was deleted, and no filler DNA was inserted. Primers located within the left and right flanking genomic DNA in transgenic shallot plants were used to recover the target site of T-DNA integration.     

Transgene integration and organization in Cotton (Gossypium hirsutum L.) genome

While genetically modified upland cotton (Gossypium hirsutum L.) varieties are ranked among the most successful genetically modified organisms (GMO), there is little knowledge on transgene integration in the cotton genome, partly because of the difficulty in obtaining large numbers of transgenic plants. In this study, we analyzed 139 independently derived T0 transgenic cotton plants transformed by Agrobacterium tumefaciens strain AGL1 carrying a binary plasmid pPZP-GFP. It was found by PCR that as many as 31% of the plants had integration of vector backbone sequences. Of the 110 plants with good genomic Southern blot results, 37% had integration of a single T-DNA, 24% had two T-DNA copies and 39% had three or more copies. Multiple copies of the T-DNA existed either as repeats in complex loci or unlinked loci. Our further analysis of two T1 populations showed that segregants with a single T-DNA and no vector sequence could be obtained from T0 plants having multiple T-DNA copies and vector sequence. Out of the 57 T-DNA/T-DNA junctions cloned from complex loci, 27 had canonical T-DNA tandem repeats, the rest (30) had deletions to T-DNAs or had inclusion of vector sequences. Overlapping micro-homology was present for most of the T-DNA/T-DNA junctions (38/57). Right border (RB) ends of the T-DNA were precise while most left border (LB) ends (64%) had truncations to internal border sequences. Sequencing of collinear vector integration outside LB in 33 plants gave evidence that collinear vector sequence was determined in agrobacterium culture. Among the 130 plants with characterized flanking sequences, 12% had the transgene integrated into coding sequences, 12% into repetitive sequences, 7% into rDNAs. Interestingly, 7% had the transgene integrated into chloroplast derived sequences. Nucleotide sequence comparison of target sites in cotton genome before and after T-DNA integration revealed overlapping microhomology between target sites and the T-DNA (8/8), deletions to cotton genome in most cases studied (7/8) and some also had filler sequences (3/8). This information on T-DNA integration in cotton will facilitate functional genomic studies and further crop improvement.     

T-DNA integration in Arabidopsis chromosomes. Presence and origin of filler DNA sequences

To investigate the relationship between T-DNA integration and double-stranded break (DSB) repair in Arabidopsis, we studied 67 T-DNA/plant DNA junctions and 13 T-DNA/T-DNA junctions derived from transgenic plants. Three different types of T-DNA-associated joining could be distinguished. A minority of T-DNA/plant DNA junctions were joined by a simple ligation-like mechanism, resulting in a junction without microhomology or filler DNA insertions. For about one-half of all analyzed junctions, joining of the two ends occurred without insertion of filler sequences. For these junctions, microhomology was strikingly combined with deletions of the T-DNA ends. For the remaining plant DNA/T-DNA junctions, up to 51-bp-long filler sequences were present between plant DNA and T-DNA contiguous sequences. These filler segments are built from several short sequence motifs, identical to sequence blocks that occur in the T-DNA ends and/or the plant DNA close to the integration site. Mutual microhomologies among the sequence motifs that constitute a filler segment were frequently observed. When T-DNA integration and DSB repair were compared, the most conspicuous difference was the frequency and the structural organization of the filler insertions. In Arabidopsis, no filler insertions were found at DSB repair junctions. In maize (Zea mays) and tobacco (Nicotiana tabacum), DSB repair-associated filler was normally composed of simple, uninterrupted sequence blocks. Thus, although DSB repair and T-DNA integration are probably closely related, both mechanisms have some exclusive and specific characteristics.     

Characterization of T-DNA insertions in transgenic grapevines obtained by Agrobacterium-mediated transformation

T-DNA integration patterns in 49 transgenic grapevines produced via Agrobacterium-mediated transformation were analyzed. Inverse PCR (iPCR) was performed to identify T-DNA/plant junctions. Sequence comparison revealed several deletions in the T-DNA right border (RB) and left border (LB), and filler DNA and duplications or deletions of grapevine DNA at the T-DNA insertion loci. In 20 T-DNA/grapevine genome junctions microsimilarities were found associated with the joining points and in all grapevine lines microsimilarities were present near the breaking points along the 30 bases of T-DNA adjacent to the two borders. Analysis of target site preferences of T-DNA insertions indicated a non-random distribution of the T-DNA, with a bias toward the intron regions of the grapevine genes. Compositional analysis of grapevine DNA around the T-DNA insertion sites revealed an inverse relationship between the CG and AT-skews and AT rich sequences present at 300–500 bp upstream the insertion points, near the RB of the T-DNA. PCR assays showed that vector backbone sequences were integrated in 28.6% of the transgenic plants analyzed and multiple T-DNAs frequently integrated at the same position in the plant genome, resulting in the formation of tandem and inverted repeats.     

Analysis of integration sites of T-DNA insertions in transgenic tobacco plants

DNA fragments containing T-DNA/plant DNA junctions isolated from 17 transgenic tobacco plants were amplified using inverse PCR. Analysis of the nucleotide sequences of 34 cloned DNA fragments revealed 100% homology with vector sequences outside T-DNA in 10 cases. Nine nucleotide sequences had homology with the repeats in the tobacco genome. The percentage of homology varied from 70 to 90%, with the identified repeats belonging to different types. In most clones no homology was revealed with the GENEBANK sequences. Alignment of the sequences truncated during the integration of the left and the right borders of the T-DNA insertions demonstrated significant clusterization (10 bp region) of truncation sites for the left border. Five sequences had identical truncation sites (+23 T) that showed the perferable use of this nucleotide. The AT content varied from 51 to 72% which was close to the total percentage of AT pairs in the tobacco genome.     

Overdrive, a T-DNA transmission enhancer on the A. tumefaciens tumour-inducing plasmid

During crown gall tumorigenesis a specific segment of the Agrobacterium tumefaciens tumour-inducing (Ti) plasmid, the T-DNA, integrates into plant nuclear DNA. Similar 23-bp direct repeats at each end of the T region signal T-DNA borders, and T-DNA transmission (transfer and integration) requires the right-hand direct repeat. A chemically synthesized right border repeat in its wild-type orientation promotes T-DNA transmission at a low frequency; Ti plasmid sequences which normally flank the right repeat greatly stimulate the process. To identify flanking sequences required for full right border activity, we tested the activity of a border repeat surrounded by different amounts of normal flanking sequences. Efficient T-DNA transmission required a conserved sequence (5' TAAPuTPy-CTGTPuT-TGTTTGTTTG 3') which lies to the right of the two known right border repeats. In either orientation, a synthetic oligonucleotide containing this conserved sequence greatly stimulated the activity of a right border repeat, and a deletion removing 15 bp from the right end of this sequence destroyed it stimulatory effect. Thus, wild-type T-DNA transmission required both the 23-bp right border repeat and a conserved flanking sequence which we call overdrive.     

Transgene structures in T-DNA-inserted rice plants

T-DNA is commonly used for delivery of foreign genes and as an insertional mutagen. Although ample information exists regarding T-DNA organization in dicotyledonous plants, little is known about the monocot rice. Here, we investigated the structure of T-DNA in a large number of transgenic rice plants. Analysis of the T-DNA borders revealed that more than half of the right ends were at the cleavage site, whereas the left ends were not conserved and were deleted up to 180 bp from the left border (LB) cleavage site. Three types of junctions were found between T-DNA and genomic DNA. In the first, up to seven nucleotide overlaps were present. The frequency of this type was much higher in the LB region than at the right border (RB). In the second type, which was more frequent in RB, the link was direct, without any overlaps or filler DNA. Finally, the third type showed filler DNA between T-DNA and the plant sequences. Out of 171 samples examined, 77 carried the vector backbone sequence, with the majority caused by the failure of T-strand termination at LB. However, a significant portion also resulted from co-integration of T-DNA and the vector backbone to a single locus. Most linkages between T-DNA and the vector backbone were formed between two 3 ends or two 5 ends of the transferred DNAs. The 3 ends were mostly linked through 3–6 bp of the complementing sequence, whereas the 5 ends were linked through either precise junctions or imprecise junctions with filler DNA.     

T-DNA vector backbone sequences are frequently integrated into the genome of transgenic plants obtained by Agrobacterium-mediated transformation

Transgenic Arabidopsis and tobacco plants (125) derived from seven Agrobacterium-mediated transformation experiments were screened by polymerase chain reaction and DNA gel blot analysis for the presence of vector `backbone' sequences. The percentage of plants with vector DNA not belonging to the T-DNA varied between 20% and 50%. Neither the plant species, the explant type used for transformation, the replicon type nor the selection seem to have a major influence on the frequency of vector transfer. Only the border repeat sequence context could have an effect because T-DNA vector junctions were found in more than 50% of the plants of three different transformation series in which T-DNAs with octopine borders without inner border regions were used. Strikingly, many transgenic plants contain vector backbone sequences linked to the left T-DNA border as well as vector junctions with the right T-DNA border. DNA gel blots indicate that in most of these plants the complete vector sequence is integrated. We assume that integration into the plant genome of complete vector backbone sequences could be the result of a conjugative transfer initiated at the right border and subsequent continued copying at the left and right borders, called read-through. This model would imply that the left border is not frequently recognized as an initiation site for DNA transfer and that the right border is not efficiently recognized as a termination site for DNA transfer.     

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

Summary 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 by border and ca. 350 by 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. The homology may promote close association of both termini of a T-DNA molecule on a target sequence; then TDNA may in some cases be integrated by a mechanism at least in part analogous to homologous recombination.Shogo Matsumoto is on leave from Biochemical Research Institute, Nippon Menard Cosmetic Co., Ltd, Ogaki, Gifu-ken 503, Japan     

Targeted integration of T-DNA into the tobacco genome at double-stranded breaks: new insights on the mechanism of T-DNA integration

Agrobacterium tumefaciens T-DNA normally integrates into random sites in the plant genome. We have investigated targeting of T-DNA by nonhomologous end joining process to a specific double-stranded break created in the plant genome by I-CeuI endonuclease. Sequencing of genomic DNA/T-DNA junctions in targeted events revealed that genomic DNA at the cleavage sites was usually intact or nearly so, whereas donor T-DNA ends were often resected, sometimes extensively, as is found in random T-DNA inserts. Short filler DNAs were also present in several junctions. When an I-CeuI site was placed in the donor T-DNA, it was often cleaved by I-CeuI endonuclease, leading to precisely truncated targeted T-DNA inserts. Their structure requires that T-DNA cutting occurred before or during integration, indicating that T-DNA is at least partially double stranded before integration is complete. This method of targeting full-length T-DNA with considerable fidelity to a chosen break point in the plant genome may have experimental and practical applications. Our findings suggest that insertion at break points by nonhomologous end joining is one normal mode of entry for T-DNA into the plant genome.     

DNA rearrangement associated with the integration of T-DNA in tobacco: an example for multiple duplications of DNA around the integration target

Transferred DNA (T-DNA) of the tumor-inducing (Ti) plasmid is transferred from Agrobacterium tumefaciens to plant cells and is stably integrated into the plant nuclear genome. By the inverse polymerase chain reaction DNA fragments were amplified that contained the T-DNA/plant DNA junctions from the total DNA of a transgenic tobacco plant that had a single copy of the T-DNA in a repetitive region of its genome. A DNA fragment containing the target site was amplified from the total DNA of non-transformed tobacco by the polymerase chain reaction using high-stringency conditions. Comparison of the nucleotide sequence of the target site with those of the T-DNA/plant DNA junctions revealed that various duplications of short stretches of nucleotide sequences around the target and in the incoming T-DNA had accompanied the integration of the T-DNA. A deletion of 16 bp at the target site was also found and the target site was similar, in terms of nucleotide sequence, to regions around the breakpoints of the T-DNA. This finding provides a clear example of the occurrence of complex rearrangements during the integration of T-DNA.     

Microhomologies between T-DNA ends and target sites often occur in inverted orientation and may be responsible for the high frequency of T-DNA-associated inversions

Sequence analysis of left and right border integration sites of independent, single-copy T-DNA inserts in Arabidopsis thaliana revealed three previously unrecognized concomitants of T-DNA integration. First, genomic pre-insertion sites shared sequence similarity not only with the T-DNA left and right border regions, as was previously reported, but also at high frequency with the inverted complement of the T-DNA right border region. Second, palindromic sequences were frequently found to overlap or lie adjacent to genomic target sites, suggesting a high recombinogenic potential for palindromic elements during T-DNA integration and a possible role during the primary contact between the T-DNA and the target DNA. Third, “filler” DNA sequences between genomic pre-insertion site DNA and T-DNA often derive from sequences in the T-DNA left and right border regions that are clustered around palindromic sequences in these T-DNA regions, suggesting that these palindromic elements are “hot spots” for filler DNA formation. The discovery of inverted sequence similarities at the right border suggests a previously unrecognized mode of T-DNA integration that involves heteroduplex formation at both T-DNA borders and with opposite strands of the target DNA. Scanning for sequence similarities in both direct and inverted orientation may increase the probability and/or effectiveness of anchoring the T-DNA to the target DNA. Variations on this scheme may also account for inversion events at the target site of T-DNA integration and inverted T-DNA repeat formation, common sequence organization patterns associated with T-DNA integration. Electronic Supplementary Material Supplementary material is available in the online version of this article at and is accessible for authorized users.