Genetic requirements for the targeted integration of Agrobacterium T-DNA in Saccharomyces cerevisiae

Agrobacterium tumefaciens delivers transferred DNA (T-DNA) into cells of plants and yeast. In plants, the T-DNA integrates at random positions into the genome by non-homologous recombination (NHR), whereas in yeast the T-DNA preferably integrates by homologous recombination (HR). Here we show that T-DNA integration by HR in yeast requires the recombination/repair proteins Rad51 and Rad52, but not Rad50, Mre11, Xrs2, Yku70 and Lig4. In the HR events a remarkable shift from insertion-type events to replacement events was observed in rad50, mre11 and xrs2 mutants. Residual integration in the rad51 mutant occurred predominantly by HR, whereas in the rad52 mutant integration occurred exclusively by NHR. Previously, we found that T-DNA integration by NHR is abolished in a yku70 mutant. Thus, Rad52 and Yku70 are the key regulators of T-DNA integration, channeling integration into either the HR or NHR pathway.     

Frequency and character of alternative somatic recombination fates of paralogous genes during T-DNA integration

A synthetic RBCSB gene cluster was transformed into Arabidopsis in order to simultaneously evaluate the frequency and character of somatic illegitimate recombination, homologous recombination, and targeted gene replacement events associated with T-DNA-mediated transformation. The most frequent type of recombination event observed was illegitimate integration of the T-DNA without activation of the silent ΔRBCS1B: LUC transgene. Sixteen luc⁺ (firefly luciferase positive) T1 plants were isolated. Six of these were due to illegitimate recombination events resulting in a gene trapping effect. Nine resulted from homologous recombination between paralogous RBCSB sequences associated with T-DNA integration. The frequency of somatic homologous recombination associated with T-DNA integration was almost 200 times higher than previously reported rates of meiotic homologous recombination with the same genes. The distribution of (somatic homologous) recombination resolution sites generally fits a fractional interval length model. However, a small region adjacent to an indel showed a significant over-representation of resolution sites, suggesting that DNA mismatch recognition may also play an important role in the positioning of somatic resolution sites. The frequency of somatic resolution within exon-2 was significantly different from that previously observed during meiotic recombination. Electronic Supplementary Material Supplementary material is available for this article at     

Development of an efficient gene targeting system in Colletotrichum higginsianum using a non-homologous end-joining mutant and Agrobacterium tumefaciens-mediated gene transfer

The hemibiotrophic ascomycete Colletotrichum higginsianum is the casual agent of anthracnose disease of cruciferous plants. High efficiency transformation by Agrobacterium tumefaciens-mediated gene transfer has been established for this fungus. However, targeted gene mutagenesis through homologous recombination rarely occurs in C. higginsianum. We have identified and disrupted the C. higginsianum homologue of the human Ku70 gene, ChKU70, which encodes a protein that plays a role in non-homologous end-joining for repair of DNA breaks. chku70 mutants showed a dramatic increase in the frequency of integration of introduced exogenous DNA fragments by homologous recombination without any detectable phenotypic defects. This result demonstrates that the chku70 mutant is an efficient recipient for targeted gene mutagenesis in C. higginsianum. We have also developed a novel approach [named direct repeat recombination-mediated gene targeting (DRGT)] for targeted gene disruption through Agrobacterium tumefaciens-mediated gene transfer. DRGT utilizes homologous recombination between repeated sequences on the T-DNA flanking a partial fragment of the target gene. Our results suggest that DRGT in the chku70 mutant background could be a useful tool for rapid isolation of targeted gene disruptants in C. higginsianum.     

A large-scale<Emphasis Type="Italic"> Agrobacterium</Emphasis>-mediated transformation procedure with a strong positive-negative selection for gene targeting in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

A large-scale transformation procedure handling an adequate number of stable transformants with highly efficient positive-negative selection is a necessary prerequisite to successful gene targeting by homologous recombination, as the integration of a transgene by somatic homologous recombination in higher plants has been reported to be 10^-3 to 10^-5 compared with random integration by non-homologous end joining. We established an efficient and large-scale Agrobacterium-mediated rice transformation protocol that generated around 10³ stable transformants routinely from 150 seeds and a strong positive-negative selection procedure that resulted in survivors at 10^-2 using the gene for diphtheria toxin A fragment as a negative marker. The established transformation procedure provides a basis for efficient gene targeting in rice.Abbreviations AS: Acetosyringone - 5-FU: 5-Fluorouracil - FW: Fresh weight - GT: Gene targeting - HR: Homologous recombination - NHEJ: Non-homologous end joining Communicated by H. Ebinuma     

Gene targeting in polymerase theta-deficient Arabidopsis thaliana

Agrobacterium tumefaciens-mediated transformation has been for decades the preferred tool to generate transgenic plants. During this process, a T-DNA carrying transgenes is transferred from the bacterium to plant cells, where it randomly integrates into the genome via polymerase theta (Polθ)-mediated end joining (TMEJ). Targeting of the T-DNA to a specific genomic locus via homologous recombination (HR) is also possible, but such gene targeting (GT) events occur at low frequency and are almost invariably accompanied by random integration events. An additional complexity is that the product of recombination between T-DNA and target locus may not only map to the target locus (true GT), but also to random positions in the genome (ectopic GT). In this study, we have investigated how TMEJ functionality affects the biology of GT in plants, by using Arabidopsis thaliana mutated for the TEBICHI gene, which encodes for Polθ. Whereas in TMEJ-proficient plants we predominantly found GT events accompanied by random T-DNA integrations, GT events obtained in the teb mutant background lacked additional T-DNA copies, corroborating the essential role of Polθ in T-DNA integration. Polθ deficiency also prevented ectopic GT events, suggesting that the sequence of events leading up to this outcome requires TMEJ. Our findings provide insights that can be used for the development of strategies to obtain high-quality GT events in crop plants.     

Role of the AtRad1p endonuclease in homologous recombination in plants

Using a specific recombination assay, we show in the plant Arabidopsis thaliana that AtRad1 protein plays a role in the removal of non-homologous tails in homologous recombination. Recombination in the presence of non-homologous overhangs is reduced 11-fold in the atrad1 mutant compared with the wild-type plants. AtRad1p is the A. thaliana homologue of the human Xpf and Saccharomyces cerevisiae Rad1 proteins. Rad1p is a subunit of the Rad1p/Rad10p structure-specific endonuclease that acts in nucleotide excision repair and inter-strand crosslink repair. This endonuclease also plays a role in mitotic recombination to remove non-homologous, 3′-ended overhangs from recombination intermediates. The Arabidopsis atrad1 mutant (uvh1), unlike rad1 mutants known from other eukaryotes, is hypersensitive to ionizing radiation. This last observation may indicate a more important role for the Rad1/Rad10 endonuclease in recombination in plants. This is the first direct demonstration of the involvement of AtRad1p in homologous recombination in plants.     

Ku80 gene is related to non-homologous end-joining and genome stability in Aspergillus niger

In this study, the ku70 and ku80 homologs from the Aspergillus niger genome were identified and their function was analyzed using targeted mutagenesis. The role of the ku80 gene in non-homologous end-joining (NHEJ) was investigated by calculating the frequency of homologous recombination. The transformation test verified that the frequency of homologous recombination significantly increased, from 1.78 to 65.6% in ku80 single deletion strains and to 100% in ku70/ku80 double deletion strains. These results suggest that the ku80 gene is important for non-homologous end-joining. Although the morphology of the ku deletion strains colonies was similar to that of the wildtype strain, mutants were more sensitive to the mutagen phleomycin. Furthermore, the purified ku80 deletion strain produced some sectored colonies on hygromycin B-containing plates. This result suggests that the ku80 gene deletion leads to genomic instability in A. niger.     

Methylation Status of Arabidopsis DNA Repair Gene Promoters During Agrobacterium Infection Reveals Epigenetic Changes in Three Generations

Agrobacterium tumefaciens is a unique pathogen with the ability to transfer a portion of its DNA, the T-DNA, to other organisms. The role of DNA repair genes in Agrobacterium transformation remains controversial. In order to understand if the host DNA repair response and dynamics was specific to bacterial factors such as Vir proteins, T-DNA, and oncogenes, we profiled the expression and promoter methylation of various DNA repair genes. These genes belonged to nucleotide excision repair (NER), base excision repair (BER), mismatch repair (MMR), homologous recombination (HR), and non-homologous end joining (NHEJ) pathways. We infected Arabidopsis plants with different Agrobacterium strains that lacked one or more of the above components so that the influence of the respective factors could be analysed. Our results revealed that the expression and promoter methylation of most DNA repair genes was affected by Agrobacterium, and it was specific to Vir proteins, T-DNA, oncogenes, or the mere presence of bacteria. In order to determine if Agrobacterium induced any transgenerational epigenetic effect on the DNA repair gene promoters, we studied the promoter methylation in two subsequent generations of the infected plants. Promoters of at least three genes, CEN2, RAD51, and LIG4 exhibited transgenerational memory in response to different bacterial factors. We believe that this is the first report of Agrobacterium-induced transgenerational epigenetic memory of DNA repair genes in plants. In addition, we show that Agrobacterium induces short-lived DNA strand breaks in Arabidopsis cells, irrespective of the presence or absence of virulence genes and T-DNA.

     

Non-recurrent 17p11.2 deletions are generated by homologous and non-homologous mechanisms

Several recurrent common chromosomal deletion and duplication breakpoints have been localized to large, highly homologous, low-copy repeats (LCRs). The mechanism responsible for these rearrangements, viz., non-allelic homologous recombination between LCR copies, has been well established. However, fewer studies have examined the mechanisms responsible for non-recurrent rearrangements with non-homologous breakpoint regions. Here, we have analyzed four uncommon deletions of 17p11.2, involving the Smith–Magenis syndrome region. Using somatic cell hybrid lines created from patient lymphoblasts, we have utilized a strategy based on the polymerase chain reaction to refine the deletion breakpoints and to obtain sequence data at the deletion junction. Our analyses have revealed that two of the four deletions are a product of Alu/Alu recombination, whereas the remaining two deletions result from a non-homologous end-joining mechanism. Of the breakpoints studied, three of eight are located in LCRs, and five of eight are within repetitive elements, including Alu and MER5B sequences. These findings suggest that higher-order genomic architecture, such as LCRs, and smaller repetitive sequences, such as Alu elements, can mediate chromosomal deletions via homologous and non-homologous mechanisms. These data further implicate homologous recombination as the predominant mechanism of deletion formation in this genomic interval.     

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     

Tools for high efficiency genetic manipulation of the human pathogen Penicillium marneffei

Penicillium marneffei is an opportunistic pathogen of humans and displays a temperature dependent dimorphic transition. Like many fungi, exogenous DNA introduced by DNA mediated transformation is integrated randomly into the genome resulting in inefficient gene deletion and position-specific effects. To enhance successful gene targeting, the consequences of perturbing components of the non-homologous end joining recombination pathway have been examined. The deletion of the KU70 and LIG4 orthologs, pkuA and ligD, respectively, dramatically enhanced the observed homologous recombination frequency leading to efficient gene deletion. While ΔpkuA was associated with reduced genetic stability over-time, ΔligD represents a suitable recipient strain for downstream applications and combined with a modified Gateway? system for the rapid generation of gene deletion constructs, this represents an efficient pipeline for characterizing gene function in P. marneffei.     

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.     

The Arabidopsis AtLIG4 gene is required for the repair of DNA damage,but not for the integration of Agrobacterium T-DNA

The joining of breaks in the chromosomal DNA backbone by ligases in processes of replication, recombination and repair plays a crucial role in the maintenance of genomic stability. Four ATP-dependent ligases, designated DNA ligases I–IV, have been identified in higher eukaryotes, and each one has distinct functions. In mammals and yeast, DNA ligase IV is exclusively involved in the repair of DNA double-strand breaks by non-homologous end joining. Recently, an Arabidopsis thaliana orthologue of the yeast and mammalian DNA ligase IV gene was found and termed AtLIG4. Here we describe the isolation and functional characterisation of a plant line with a T-DNA insertion in the AtLIG4 gene. Plants homozygous for the T-DNA insertion did not display any growth or developmental defects and were fertile. However, mutant seedlings were hypersensitive to the DNA-damaging agents methyl methanesulfonate and X-rays, demonstrating that AtLIG4 is required for the repair of DNA damage. Recently, we showed that a yeast lig4 mutant is deficient in Agrobacterium T-DNA integration. However, using tumorigenesis and germline transformation assays, we found that the plant AtLIG4 mutant is not impaired in T-DNA integration. Thus, in contrast to yeast, DNA ligase IV is not required for T-DNA integration in plants.     

Development of a binary vector system for plant transformation based on the supervirulent Agrobacterium tumefaciens strain Chry5

This report describes the disarming of Agrobacterium tumefaciens Chry5, a strain highly tumorigenic on soybean. Disarming was achieved by removing an approximately 16.5-kb segment of the 285-kb Ti plasmid pTiChry5, including approximately 4 kb of the oncogenic T-DNA and an extended region right of the T-DNA, and replacing it with a gene for carbenicillin resistance, through homologous recombination. The deletion was confirmed with Southern analysis, and the loss of tumorigenicity was verified in tobacco and tomato plant stem inoculation assays. The deletion mutant, named KYRT1, successfully transferred the β-glucuronidase (GUS) gene into tobacco leaf tissue, producing GUS-expressing callus which could be regenerated into viable plants. In a comparative study, the transformation efficiency of A. tumefaciens KYRT1, GV3850, and EHA105 was assayed by inoculating cotyledonary node explants. The results of this study revealed that, in a binary vector system, KYRT1 is equally or more effective than EHA105 or GV3850 at delivering DNA into soybean. Received: 30 January 1997 / Revision received: 10 June 1997 / Accepted: 5 July 1997     

Ku80 plays a role in non-homologous recombination but is not required for T-DNA integration in Arabidopsis

Chromosomal breaks are repaired by homologous recombination (HR) or non-homologous end joining (NHEJ) mechanisms. The Ku70/Ku80 heterodimer binds DNA ends and plays roles in NHEJ and telomere maintenance in organisms ranging from yeast to humans. We have previously identified a ku80 mutant of the model plant Arabidopsis thaliana and shown the role of Ku80 in telomere homeostasis in plant cells. We show here that this mutant is hypersensitive to the DNA-damaging agent methyl methane sulphonate and has a reduced capacity to carry out NHEJ recombination. To understand the interplay between HR and NHEJ in plants, we measured HR in the absence of Ku80. We find that the frequency of intrachromosomal HR is not affected by the absence of Ku80. Previous work has clearly implicated the Ku heterodimer in Agrobacterium-mediated T-DNA transformation of yeast. Surprisingly, ku80 mutant plants show no defect in the efficiency of T-DNA transformation of plants with Agrobacterium, showing that an alternative pathway must exist in plants.     

Integration of an insertion-type transferred DNA vector from Agrobacterium tumefaciens into the Saccharomyces cerevisiae genome by gap repair.

Recently, it was shown that Agrobacterium tumefaciens can transfer transferred DNA (T-DNA) to Saccharomyces cerevisiae and that this T-DNA, when used as a replacement vector, is integrated via homologous recombination into the yeast genome. To test whether T-DNA can be a suitable substrate for integration via the gap repair mechanism as well, a model system developed for detection of homologous recombination events in plants was transferred to S. cerevisiae. Analysis of the yeast transformants revealed that an insertion type T-DNA vector can indeed be integrated via gap repair. Interestingly, the transformation frequency and the type of recombination events turned out to depend strongly on the orientation of the insert between the borders in such an insertion type T-DNA vector.     

Relocation of a cytoplasmic yeast linear plasmid to the nucleus is associated with circularization via nonhomologous recombination involving inverted terminal repeats

The linear plasmid pCLU1 from the yeast Kluyveromyces lactis normally replicates in the cytoplasm, with the aid of the helper linear plasmid pGKL2, using terminal protein (TP) as a primer. However, it relocates to the nucleus when selection is applied for the expression of a plasmid-borne nuclear marker. Migration to the nucleus occurred in K. lactis at a frequency of about 10⁻³/cell ten or more times higher than the rate observed in Saccharomyces cerevisiae. The nuclear plasmids existed only in a circularized form in K. lactis, while in S. cerevisiae a telomere-associated linear form is also found. Sequence analysis showed that circularization in K. lactis was caused by non-homologous recombination between the inverted terminal repeat (ITR) at the ends of the linear form and non-specific internal target sites in pCLU1. No sequence similarity existed among the junction sites, indicating that the free ITR end plays a crucial role in circularization. In S. cerevisiae, circular plasmids were generated not only by non-homologous recombination, but also by homologous recombination between short direct repeats within pCLU1. Circularization via the ITR end was observed independently of RAD52 activity. Sequences highly homologous to ARS core elements, 5′-ATTTATTGTTTT-3′ for K. lactis and 5′-(A/T)TTTAT(T/G)TTT(A/T)-3′ for S. cerevisiae, were detected at multiple sites in the nuclear forms of the plasmids. Received: 25 October 1999 / Accepted: 13 March 2000     

Recombination in the Plant Genome and its Application in Biotechnology

Genetic variation within and between species is based on recombination of DNA molecules. Recombination also plays a very important role in the repair of damaged DNA. Clarity about the mechanism by which recombination occurs is of profound interest not only to understand how this process assures the maintenance of genome integrity and at the same time is the driving force of evolution, but also for its application in biotechnology. The isolation of genes involved in recombination and the elucidation of the role of many of the corresponding gene products in Escherichia coli and Saccharomyces cerevisiae has formed the basis for comparative analysis in other, more complex eukaryotic systems. The identification of homologous genes from different organisms, including plants, suggests a conservation of the general mechanisms of recombination. Transgenes introduced in an organism may be incorporated in the genome by either homologous or nonhomologous recombination (end joining). The preferred pathway differs strongly between organisms. In plants there is a preference for random integration of the introduced DNA by nonhomologous recombination, which might lead to the accidental inactivation of important genes and to variable and unpredictable expression of the transgene itself. Therefore, there is an urgent need for the development and improvement of techniques for the directed integration of transgenes at specific locations in the genome. The integration of transgenes by homologous recombination would allow specific modification or disruption of endogenous genes, providing a tool for more detailed analysis of gene function. In combination with the recent introduction of site-specific recombination systems from E. coli or yeast into plants, this may lead to the development of versatile systems for modification of the plant genome.     

Efficient transfer of base changes from a vector to the rice genome by homologous recombination: involvement of heteroduplex formation and mismatch correction

Gene targeting refers to the alteration of a specific DNA sequence in an endogenous gene at its original locus in the genome by homologous recombination. Through a gene-targeting procedure with positive–negative selection, we previously reported the generation of fertile transgenic rice plants with a positive marker inserted into the Adh2 gene by using an Agrobacterium-mediated transformation vector containing the positive marker flanked by two 6-kb homologous segments for recombination. We describe here that base changes within the homologous segments in the vector could be efficiently transferred into the corresponding genomic sequences of rice recombinants. Interestingly, a few sequences from the host genome were flanked by the changed sequences derived from the vector in most of the recombinants. Because a single-stranded T-DNA molecule in Agrobacterium-mediated transformation is imported into the plant nucleus and becomes double-stranded, both single-stranded and double-stranded T-DNA intermediates can serve in gene-targeting processes. Several alternative models, including the occurrence of the mismatch correction of heteroduplex molecules formed between the genomic DNA and either a single-stranded or double-stranded T-DNA intermediate, are compared to explain the observation, and implications for the modification of endogenous genes for functional genomic analysis by gene targeting are discussed.