Molecular analysis of <Emphasis Type="Italic">Agrobacterium</Emphasis> T-DNA integration in tomato reveals a role for left border sequence homology in most integration events

Studies in several plants have shown that Agrobacterium tumefaciens T-DNA can integrate into plant chromosomal DNA by different mechanisms involving single-stranded (ss) or double-stranded (ds) forms. One mechanism requires sequence homology between plant target and ssT-DNA border sequences and another double-strand-break repair in which preexisting chromosomal DSBs “capture” dsT-DNAs. To learn more about T-DNA integration in Solanum lycopersicum we characterised 98 T-DNA/plant DNA junction sequences and show that T-DNA left border (LB) and right border transfer is much more variable than previously reported in Arabidopsis thaliana and Populus tremula. The analysis of seven plant target sequences showed that regions of homology between the T-DNA LB and plant chromosomal DNA plays an important role in T-DNA integration. One T-DNA insertion generated a target sequence duplication that resulted from nucleolytic processing of a LB/plant DNA heteroduplex that generated a DSB in plant chromosomal DNA. One broken end contained a captured T-DNA that served as a template for DNA repair synthesis. We propose that most T-DNA integrations in tomato require sequence homology between the ssT-DNA LB and plant target DNA which results in the generation of DSBs in plant chromosomal DNA.     

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     

Number and Accuracy of T-DNA Insertions in Transgenic Banana (Musa spp.) Plants Characterized by an Improved Anchored PCR Technique

Nineteen transgenic banana plants, produced via Agrobacterium-mediated transformation, were analyzed for the integration of T-DNA border regions using an improved anchored PCR technique. The method described is a relatively fast, three-step procedure (restriction digestion of genomic DNA, ligation of ‘vectorette’-type adaptors, and a single round of suppression PCR) for the amplification of specific T-DNA border-containing genomic fragments. Most transgenic plants carried a low number of inserts and the method was suitable for a detailed characterization of the integration events, including T-DNA border integrity as well as the insertion of non-T-DNA vector sequences, which occurred in 26% of the plants. Furthermore, the particular band pattern generated by four enzyme/primer combinations for each individual plant served as a fingerprint, allowing the identification of plants representing identical transformation events. Genomic Southern hybridization and nucleotide sequence analysis of amplification products confirmed the data obtained by anchored PCR. Sequencing of seven right or left border junction regions revealed different T-DNA processing events for each plant, indicating a relatively low frequency of precisely nicked T-DNA integration among the plants studied.     

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.     

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.     

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.     

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.     

Gene stability in transgenic aspen ( Populus ). I. Flanking DNA sequences and T-DNA structure

The stability of transgenes in the genome of transformed plants depends strongly on their correct physical integration into the host genome as well as on flanking target DNA sequences. For long-lived species like trees, however, no information is available so far concerning inactivation or loss of transgenes due to gene silencing or somatic genome rearrangement events. In this study, four independently transformed 35S-rolC transgenic hybrid aspen plants (Populus tremula L. × tremuloides Michx.), each harbouring one copy of the transgene, were investigated during continuous growth in the greenhouse. In one of these transgenic lines (Esch5:35S-rolC-##1) individuals frequently show phenotypic reversions, while in the remaining three lines (Esch5:35S-rolC-#3, -#5, -#16) the gene was essentially stable. Molecular analysis including PCR, Southern and Northern assays clearly showed that the transgene had been lost in the revertant tissue of the unstable line. Sequencing of T-DNA right and left borders, and flanking DNA regions, in all four transgenic aspen lines revealed no differences either in the type of flanking DNA (G-C to A-T ratio) or with respect to the presence of enhancers or MAR (matrix associated repeats)-like structures. Primers located within the left and right flanking regions in the three stable lines could be used to recover the target sites from the untransformed plants. This was not possible, however, with the unstable line, indicating that at least one flanking sequence does not derive from the plant target DNA but is of unknown origin. PCR using other primer pairs, and inverse PCR analysis, revealed an additional truncated T-DNA copy of 1050 nucleotides adjacent to the left border of the complete copy in this line. Sequencing of this truncated T-DNA revealed that it represented an inverted copy of part of the right half of the original construct. This special feature would allow the inverted repeat to pair with right border sequences of the complete copy. This would explain the frequently observed reversion resulting in transgene loss as due to intrachromosomal base-pairing leading to double-stranded loops of single-stranded DNA during mitotic cell divisions. Received: 9 June 1998 / Accepted: 6 October 1998     

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 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.     

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.     

Gene stability in transgenic aspen (Populus). I. Flanking DNA sequences and T-DNA structure

The stability of transgenes in the genome of transformed plants depends strongly on their correct physical integration into the host genome as well as on flanking target DNA sequences. For long-lived species like trees, however, no information is available so far concerning inactivation or loss of transgenes due to gene silencing or somatic genome rearrangement events. In this study, four independently transformed 35S-rolC transgenic hybrid aspen plants (Populus tremula L.?×?tremuloides Michx.), each harbouring one copy of the transgene, were investigated during continuous growth in the greenhouse. In one of these transgenic lines (Esch5:35S-rolC-##1) individuals frequently show phenotypic reversions, while in the remaining three lines (Esch5:35S-rolC-#3, -#5, -#16) the gene was essentially stable. Molecular analysis including PCR, Southern and Northern assays clearly showed that the transgene had been lost in the revertant tissue of the unstable line. Sequencing of T-DNA right and left borders, and flanking DNA regions, in all four transgenic aspen lines revealed no differences either in the type of flanking DNA (G-C to A-T ratio) or with respect to the presence of enhancers or MAR (matrix associated repeats)-like structures. Primers located within the left and right flanking regions in the three stable lines could be used to recover the target sites from the untransformed plants. This was not possible, however, with the unstable line, indicating that at least one flanking sequence does not derive from the plant target DNA but is of unknown origin. PCR using other primer pairs, and inverse PCR analysis, revealed an additional truncated T-DNA copy of 1050 nucleotides adjacent to the left border of the complete copy in this line. Sequencing of this truncated T-DNA revealed that it represented an inverted copy of part of the right half of the original construct. This special feature would allow the inverted repeat to pair with right border sequences of the complete copy. This would explain the frequently observed reversion resulting in transgene loss as due to intrachromosomal base-pairing leading to double-stranded loops of single-stranded DNA during mitotic cell divisions.     

Agrobacterium T-DNA integration in Arabidopsis is correlated with DNA sequence compositions that occur frequently in gene promoter regions

Mobile insertion elements such as transposons and T-DNA generate useful genetic variation and are important tools for functional genomics studies in plants and animals. The spectrum of mutations obtained in different systems can be highly influenced by target site preferences inherent in the mechanism of DNA integration. We investigated the target site preferences of Agrobacterium T-DNA insertions in the chromosomes of the model plant Arabidopsis thaliana. The relative frequencies of insertions in genic and intergenic regions of the genome were calculated and DNA composition features associated with the insertion site flanking sequences were identified. Insertion frequencies across the genome indicate that T-strand integration is suppressed near centromeres and rDNA loci, progressively increases towards telomeres, and is highly correlated with gene density. At the gene level, T-DNA integration events show a statistically significant preference for insertion in the 5 and 3 flanking regions of protein coding sequences as well as the promoter region of RNA polymerase I transcribed rRNA gene repeats. The increased insertion frequencies in 5 upstream regions compared to coding sequences are positively correlated with gene expression activity and DNA sequence composition. Analysis of the relationship between DNA sequence composition and gene activity further demonstrates that DNA sequences with high CG-skew ratios are consistently correlated with T-DNA insertion site preference and high gene expression. The results demonstrate genomic and gene-specific preferences for T-strand integration and suggest that DNA sequences with a pronounced transition in CG- and AT-skew ratios are preferred targets for T-DNA integration.Electronic Supplementary Material Supplementary material is available for this article at .This revised version was published online in March 2005 with corrections to Dr. Tatarinovas name.     

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.     

灰葡萄孢菌（Botrytis cinerea）基因组中T-DNA整合模式分析

摘要：【目的】研究灰葡萄孢菌（Botrytis cinerea）基因组中T-DNA插入位点的整合模式特征。【方法】利用农杆菌（Agrobactirium tumfacience）介导法构建灰葡萄孢菌T-DNA插入突变体库。利用热不对称交错PCR（TAIL-PCR）技术对转化子中T-DNA的旁侧序列进行扩增和克隆,对获得的旁侧序列进行比对分析。【结果】T-DNA插入在灰葡萄孢菌基因组非编码区的占69%,插入在外显子的占30%。T-DNA在插入的过程中发生了碱基缺失、增加等重组现象,其中左边界（left border,LB）整合到基因组碱基缺失较少,有的保持完整,而右边界（right border,RB）及其近邻的T-DNA区域缺失碱基较多。T-DNA的插入位点还发现有额外的序列插入。【结论】对灰葡萄孢菌中插入T-DNA的整合模式的分析为开展该菌的功能基因组学奠定了基础。     

Generation and flanking sequence analysis of a rice T-DNA tagged population

Insertional mutagenesis provides a rapid way to clone a mutated gene. Transfer DNA (T-DNA) of Agrobacterium tumefaciens has been proven to be a successful tool for gene discovery in Arabidopsis and rice (Oryza sativa L. ssp. japonica). Here, we report the generation of 5,200 independent T-DNA tagged rice lines. The T-DNA insertion pattern in the rice genome was investigated, and an initial database was constructed based on T-DNA flanking sequences amplified from randomly selected T-DNA tagged rice lines using Thermal Asymmetric Interlaced PCR (TAIL-PCR). Of 361 T-DNA flanking sequences, 92 showed long T-DNA integration (T-DNA together with non-T-DNA). Another 55 sequences showed complex integration of T-DNA into the rice genome. Besides direct integration, filler sequences and microhomology (one to several nucleotides of homology) were observed between the T-DNA right border and other portions of the vector pCAMBIA1301 in transgenic rice. Preferential insertion of T-DNA into protein-coding regions of the rice genome was detected. Insertion sites mapped onto rice chromosomes were scattered in the genome. Some phenotypic mutants were observed in the T₁ generation of the T-DNA tagged plants. Our mutant population will be useful for studying T-DNA integration patterns and for analyzing gene function in rice.Electronic Supplementary Material Supplementary material is available in the online version of this article at .Communicated by D. Mackill     

稻瘟菌突变体T-DNA插入位点的精细定位和插入模式的研究

随机挑取已构建的37个稻瘟菌T-DNA突变株,利用TAIL-PCR技术扩增出T-DNA插入位点的侧翼序列,测序并进行比对分析。结果显示:成功获得扩增产物并测序的序列共有39条,T-DNA边界序列为稻瘟菌序列的有19条,其余20条为载体主干序列。在这有效扩增为稻瘟菌序列的19条中,有10条是T-DNA右侧翼序列与稻瘟菌序列,9条为左侧翼序列加稻瘟菌序列。分析T-DNA剪切位点,10条右侧翼序列中有9条的剪切位点相同,这与农杆菌介导T-DNA转化植物一样。而左边界的剪切位点就没有这种规律性。研究也精细确定了17个不同突变株的T-DNA插入位置,为后续的基因功能研究奠定基础。     

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.     

A rice gene activation/knockout mutant resource for high throughput functional genomics

Using transfer DNA (T-DNA) with functions of gene trap and gene knockout and activation tagging, a mutant population containing 55,000 lines was generated. Approximately 81% of this population carries 1–2 T-DNA copies per line, and the retrotransposon Tos17 was mostly inactive in this population during tissue culture. A total of 11,992 flanking sequence tags (FSTs) have been obtained and assigned to the rice genome. T-DNA was preferentially (∼80%) integrated into genic regions. A total of 19,000 FSTs pooled from this and another T-DNA tagged population were analyzed and compared with 18,000 FSTs from a Tos17 tagged population. There was difference in preference for integrations into genic, coding, and flanking regions, as well as repetitive sequences and centromeric regions, between T-DNA and Tos17; however, T-DNA integration was more evenly distributed in the rice genome than Tos17. Our T-DNA contains an enhancer octamer next to the left border, expression of genes within genetics distances of 12.5 kb was enhanced. For example, the normal height of a severe dwarf mutant, with its gibberellin 2-oxidase (GA2ox) gene being activated by T-DNA, was restored upon GA treatment, indicating GA2ox was one of the key enzymes regulating the endogenous level of GA. Our T-DNA also contains a promoterless GUS gene next to the right border. GUS activity screening facilitated identification of genes responsive to various stresses and those regulated temporally and spatially in large scale with high frequency. Our mutant population offers a highly valuable resource for high throughput rice functional analyses using both forward and reverse genetic approaches. Electronic Supplementary Material Supplementary material is available in the online version of this article at and is accessible for authorized users. Yue-Ie Hsing, Chyr-Guan Chern, and Ming-Jen Fan have contributed equally.