Analysis of TR-DNA/plant junctions in the genome of a Convolvulus arvensis clone transformed by Agrobacterium rhizogenes strain A4

A Charon 4A phage library, containing insert DNA isolated from a morning glory (Convolvulus arvensis) plant genetically transformed by Ri T-DNA from Agrobacterium rhizogenes strain A4, was used to isolate a lambda clone that contains part of the Ri TL-DNA and the complete TR-DNA. The two Ri T-DNAs were recovered adjacent to each other in a tail-to-tail configuration (i.e. with the TR-DNA inverted with respect to the TL-DNA). Comparison of nucleotide sequences from this lambda clone with the corresponding sequences from the Ri plasmid allowed us to determine the location of the T-DNA/plant junction for the right end of the TL-DNA and the left and right ends of the TR-DNA. We located, near each of these borders, a 24 bp sequence that is similar to the 24 bp consensus sequence found near the pTi T-DNA extremities. In addition, sequences similar to the core overdrive sequence from pTi are located near each right border. Hybridization and nucleotide sequence analysis of the DNA adjacent to the TL/TR junction shows that no plant DNA is located between the TL and TR-DNAs and suggests that the plant DNA adjacent to the end of the TR-DNA may have been rearranged during the integration into the plant genome.     

Frequent spontaneous deletions of Ri T-DNA in Agrobacterium rhizogenes transformed potato roots and regenerated plants

The presence of T-DNA was examined by Southern blot analysis in 16 regenerated shoot lines derived from 6 Agrobacterium rhizogenes-transformed root clones of Solanum tuberosum L. cv. Bintje.TR-DNA, present in regenerated shoot lines from 3 out of 6 root clones was correlated with the presence of opines. One root clone produced opines up to 2.5 years of subculture. However, plant regeneration from and prolonged subculturing of this root clone resulted in loss of opine synthesis, caused by deletion of TR-DNA.TL-DNA inserted at 1 to 5 independent loci was found in 14 of the 16 shoot lines. Surprisingly, 1 to 2 additional insertions next to similar insertions of TL-DNA were found in shoot lines from the same root clone (named sister shoot lines) in 2 out of 4 root clones. Nevertheless, this did not result in gross phenotypic variation between sister shoot lines. Another root clone regenerated 1 shoot line with an Ri phenotype, containing 1 insertion of TL-DNA, and 2 shoot lines with a normal Bintje phenotype without TL-DNA. The 5th root clone showed no difference between sister shoot lines and the 6th root clone produced only 1 shoot line.We conclude that during prolonged root culture and during shoot regeneration from root clones deletion of TL- and TR-DNA insertions can occur. The significance of the frequency of deletion of T-DNA of the Ri plasmid is discussed.     

Common evolutionary origin of the central portions of the Ri TL-DNA of Agrobacterium rhizogenes and the Ti T-DNAs of Agrobacterium tumefaciens

Analysis of published sequences for Ri TL-DNA (root-inducing left-hand transferred DNA) of Agrobacterium rhizogenes revealed several unsuspected structural features. First, Ri TL-DNA genes are redundant. Using redundancy as a criterion, three regions (left, middle and right) were discerned. The left one, ORFs (open reading frames) 1–7, contains no detectable redundancy. In the middle region a highly diverged gene family was detected in ORFs 8, 11, 12, 13 and 14. The right region contains an apparently recent duplication (ORF 15 =18+17). We interpret the phenomenon of redundancy, particularly in the central region that encodes the transformed phenotype, to be an adaptation that ensures function in a variety of host species. Comparison of Ri TL-DNA and Ti T-DNAs from Agrobacterium tumefaciens revealed common structures, unpredicted by previous nucleic acid hybridization studies. Ri TL-DNA ORF 8 is a diverged Ti T-DNA tms1. Both Agrobacterium genes consist of a member of the diverged gene family detected in the central part of the Ri TL-DNA, but fused to a sequence similar to iaaM of Pseudomonas savastonoi. Other members of this gene family were found scattered throughout Ti T-DNA. We argue that the central region of Ri and the part of Ti T-DNA including ORFs 5–10 evolved from a common ancestor. We present the hypothesis that the gene family encodes functions that alter developmental plasticity in higher plants.     

Molecular and genetic analysis of the transferred DNA regions of the root-inducing plasmid of Agrobacterium rhizogenes.

The T-DNA regions of the root-inducing (Ri) plasmid pRiA4b of Agrobacterium rhizogenes were characterized. Two regions, designated TL-DNA and TR-DNA, were found to be integrated and stably maintained in the plant genome. The TL-DNA spanned a 15- to 20-kilobase region of pRiA4b and was separated from the TR-DNA region by at least 15 kilobases of nonintegrated plasmid DNA. The TR-DNA region also spanned a 15- to 20-kilobase region of pRiA4b and included a region of homology to the tms morphogenic loci of the tumor-inducing (Ti) plasmid of Agrobacterium tumefaciens. Eighteen deletions and 95 transposon insertions were generated in the T-DNA regions and tested for alterations in virulence. Insertions into four loci in the TL-DNA affected the morphology of root formation of Kalancho? diagremontiana leaves and stems, but had no visible effects on other host plants. Insertions into two loci (tms-1 and tms-2) in the TR-DNA eliminated virulence symptoms on all plants tested, with the exception of K. diagremontiana stems, where sparse root formation occurred. Complementation experiments with Ri and Ti plasmid T-DNA mutations indicate that the tms genes of the two plasmids serve similar functions and suggest a functional relationship between one or more genes of the TL-DNA and the cytokinin synthesis locus tmr of the Ti plasmid.     

The Agrobacterium rhizogenes pRi TL-DNA segment as a gene vector system for transformation of plants

Summary A plant gene transfer system was developed from the Agrobacterium rhizogenes pRi15834 TL-DNA region. Intermediate integration vectors constructed from ColE1-derived plasmids served as cloning vectors in Escherichia coli and formed cointegrates into the TL-DNA after transfer to A. rhizogenes. An A. rhizogenes strain with pBR322 plasmid sequences replacing part of the TL-DNA was also constructed. Plasmids unable to replicate in Agrobacterium can integrate into this TL-DNA by homologous recombination through pBR322 sequences. No loss of pathogenicity was observed with the strains formed after integration of intermediate vectors or strains carrying pBR322 in the TL-DNA segment. Up to 15 kb of DNA have been transferred to plant cells with these systems. The T-DNA from a binary vector was cotransformed into hairy roots which developed after transfer of the wild-type pRi T-DNA. Tested on Lotus corniculatus the TL-derived vector system transformed 90% of the developed roots and the T-DNA from the binary vector was cotransformed into 60% of the roots. Minimum copy numbers of one to five were found. Both constitutive and organ-specific plant genes were faithfully expressed after transfer to the legume L. corniculatus.     

T-DNA fragments of hairy root plasmid pRi8196 are distantly related to octopine and nopaline Ti plasmid T-DNA

Agrobacterium Ti (tumor-inducing) and Ri (root-inducing) plasmids transform dicot plant cells by insertion of a specific plasmid sector called T-DNA (transferred DNA) into host plant nuclear DNA. The mannopine-type Ri plasmid pRi8196 contains four BamHI fragments that encompass core T-DNA. We report Southern hybridization studies that show that these four fragments have no strong homology to octopine-, nopaline-, or agropine-type Ti plasmids. We detected and mapped very weak homology regions, most of which are assignable to opine synthase or opine catabolic functions on the Ti plasmid. We found no homology between Ri T-DNA and the region of Ti T-DNA that encodes tumor morphology functions.     

Ars region in TL-DNA on octopine type Ti plasmids

Summary In the TL-DNA region of the octopine type Ti plasmids, an ars region was assigned as the DNA segment conferring the replicational ability to YIp5 in Saccharomyces cerevisiae. T-DNA:YIp5 hybrid plasmids containing a particular T-DNA region could transform yeast cells at a frequency of 10³–10⁴ transformants per g plasmid DNA and they were rescued in Escherichia coli, although the transformed phenotype was mitotically unstable. The instability was inferred to be caused by segregation of the plasmids due to their low efficiency of replication. The ars region was mapped on the noncoding region between the coding regions corresponding to no. 5 and no. 7 mRNA, and its minimal length determined in this experiment was about 150 bp.Abbreviations Ti plasmid tumor inducing plasmid - T-DNA transferred DNA or tumor DNA - TL-DNA left T-DNA - ars autonomously replicating sequences     

T-DNA integration into the Arabidopsis genome depends on sequences of pre-insertion sites

A statistical analysis of 9000 flanking sequence tags characterizing transferred DNA (T-DNA) transformants in Arabidopsis sheds new light on T-DNA insertion by illegitimate recombination. T-DNA integration is favoured in plant DNA regions with an A-T-rich content. The formation of a short DNA duplex between the host DNA and the left end of the T-DNA sets the frame for the recombination. The sequence immediately downstream of the plant A-T-rich region is the master element for setting up the DNA duplex, and deletions into the left end of the integrated T-DNA depend on the location of a complementary sequence on the T-DNA. Recombination at the right end of the T-DNA with the host DNA involves another DNA duplex, 2–3 base pairs long, that preferentially includes a G close to the right end of the T-DNA.     

Inverse Relationship between Polyamine Levels and the Degree of Phenotypic Alteration Induced by the Root-Inducing, Left-Hand Transferred DNA from Agrobacterium rhizogenes

Floral induction in plants is a paradigm for signal perception, transduction, and physiological response. The introduction of root-inducing, left-hand transferred DNA (Ri T-DNA) into the genomes of several plants results in modifications of flowering (D Tepfer [1984] Cell 47: 959-967), including a delay in flowering in tobacco (Nicotiana tabacum). Conjugated polyamines are markers for flowering in numerous species of plants. In tobacco their accumulation is correlated with the onset of flowering (F Cabanne et al. [1981] Physiol Plant 53: 399-404). Using tobacco, we have explored the possibility of a correlation between the expression of Ri TL-DNA and changes in polyamine metabolism. We made use of two levels of phenotypic change, designated T and T′, that retard flowering by 5 to 10 and 15 to 20 days, respectively. We show that delay in flowering is correlated with a reduction in polyamine accumulation and with a delay in appearance of conjugated polyamines, and we propose that genes carried by the Ri TL-DNA intervene either directly in polyamine metabolism or that polyamine metabolism is closely linked to direct effects of Ri T-DNA expression.     

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.     

Independent induction of transformed roots by the TL and TR regions of the Ri plasmid of agropine type Agrobacterium rhizogenes

Summary To analyse the respective role of TL- and TR-DNA in root induction by agropine-type Agrobacterium rhizogenes Ri plasmids, deletions covering the TL- or the TR-regions were constructed in vitro and introduced into pRiA4 by marker exchange. Each T-region of pRiHRI was also cloned separately on an independent replicon and used in a binary system with the virulence functions of either an Ri or a Ti plasmid provided in trans. Transformed roots were induced on tobacco and tomato explants by TL-DNA as well as by TR-DNA, suggesting that agropine type Ri plasmids from strains A4 and HRI can induce root proliferation by two independent transformation mechanisms. The root induction by the TR-DNA is probably due to auxin biosynthesis by gene products of aux loci homologous to the tms genes of Ti plasmid T-DNA. The molecular mechanism of root proliferation induced by the TL-DNA is probably equivalent to that of mannopine type Ri plasmid T-DNA.     

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.     

Characterization of ornamental Datura plants transformed by Agrobacterium rhizogenes

Summary Datura arborea and D. sanguinea hairy roots were produced by cocultivation of leaf fragments with Agrobacterium rhizogenes strain NCPP 1855. Adventitious buds emerged spontaneously, without exogenous growth regulators, from seven hairy root clones of D. arborea and from one hairy root clone of D. sanguinea. Regenerated plants were successfully acclimatized in the greenhouse. The integration of the bacterial TL-DNA into the genome of the putative transformed plants was confirmed by Southern blot analysis. Transgenic plants displayed increased ability to root in vivo. Morphological traits with relevant ornamental value like plant height, leaf number, size and shape, internode number, and internode length were also affected. Transformation by wild-type Ri TL-DNA provided the chance to study plant growth and differentiation and to select improved genotypes.     

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.     

Sequence of the cellular T-DNA in the untransformed genome of Nicotiana glauca that is homologous to ORFs 13 and 14 of the Ri plasmid and analysis of its expression in genetic tumors of N. glauca x N. langsdorffii

A region homologous to the TL-DNA of Agrobacterium rhizogenes was previously detected in the genome of untransformed Nicotiana glauca and designated cellular T-DNA (cT-DNA). Subsequently, part of this region was sequenced and two genes, which corresponded to rolB and rolC and were named NgrolB and NgrolC, were found. We have now sequenced a region of the cT-DNA other than the region that includes NgrolB and C and we have found two other open reading frames (ORFs), NgORF13 and NgORF14. These ORFs correspond to ORFs 13 and 14 of the TL-DNA of A. rhizogenes and exhibit a high degree of homology to these ORFs, without having a nonsense codon. We have not found any sequence homologous to rolD (ORF15). The two genes, NgORF13 and 14, as well as the NgrolB and C genes, are expressed in genetic tumors of hybrids between N. glauca and N. langsdorffii but not in leaf tissues of the hybrid.     

Cloning and molecular analysis of the Arabidopsis gene Terminal Flower 1

The Arabidopsis gene Terminal Flower 1 (TFL1) controls inflorescence meristem identity. A terminal flower (tfl1) mutant, which develops a terminal flower at the apex of the inflorescence, was induced by transformation with T-DNA. Using a plant DNA fragment flanking the integrated T-DNA as a probe, a clone was selected from a wild-type genomic library. Comparative sequence analysis of this clone with an EST clone (129D7T7) suggested the existence of a gene encoding a protein similar to that encoded by the cen gene which controls inflorescence meristem identity in Antirrhinum. Nucleotide sequences of the region homologous to this putative TFL1 gene were compared between five chemically induced tfl1 mutants and their parental wild-type ecotypes. Every mutant was found to have a nucleotide substitution which could be responsible for the tfl1 phenotype. This result confirmed that the cloned gene is TFL1 itself. In our tfl1 mutant, no nucleotide substitution was found in the transcribed region of the gene, and the T-DNA-insertion site was located at 458?bp downstream of the putative polyadenylation signal, suggesting that an element important for expression of the TFL1 gene exists in this area.