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.     

Roles of the AtErcc1 protein in recombination

Atercc1, the recently characterized Arabidopsis homologue of the Ercc1 (Rad10) protein, is a key component of nucleotide excision repair as part of a structure-specific endonuclease which cleaves 5' to UV photoproducts in DNA. This endonuclease also acts in removing overhanging non-homologous DNA 'tails' in synapsed recombination intermediates. We have previously demonstrated this recombination function of the Arabidopsis thaliana Xpf homologue, AtRad1p, and show here that recombination between plasmid DNA substrates containing non-homologous tails is specifically reduced 12-fold in atercc1 mutant plants compared with the wild type. Furthermore, using chromosomal tandem-repeat recombination substrates, we show that AtErcc1p is required for bleomycin induction of mitotic recombination in the chromosomal context. This work thus confirms both the specific and general recombination roles of the Atercc1 protein in recombination in Arabidopsis .     

Analysis of Gene Targeting and Intrachromosomal Homologous Recombination Stimulated by Genomic Double-Strand Breaks in Mouse Embryonic Stem Cells

To investigate the effects of in vivo genomic DNA double-strand breaks on the efficiency and mechanisms of gene targeting in mouse embryonic stem cells, we have used a series of insertion and replacement vectors carrying two, one, or no genomic sites for the rare-cutting endonuclease I-SceI. These vectors were introduced into the hypoxanthine phosphoribosyltransferase (hprt) gene to produce substrates for gene-targeting (plasmid-to-chromosome) or intrachromosomal (direct repeat) homologous recombination. Recombination at the hprt locus is markedly increased following transfection with an I-SceI expression plasmid and a homologous donor plasmid (if needed). The frequency of gene targeting in clones with an I-SceI site attains a value of 1%, 5,000-fold higher than that in clones with no I-SceI site. The use of silent restriction site polymorphisms indicates that the frequencies with which donor plasmid sequences replace the target chromosomal sequences decrease with distance from the genomic break site. The frequency of intrachromosomal recombination reaches a value of 3.1%, 120-fold higher than background spontaneous recombination. Because palindromic insertions were used as polymorphic markers, a significant number of recombinants exhibit distinct genotypic sectoring among daughter cells from a single clone, suggesting the existence of heteroduplex DNA in the original recombination product.     

Role of ERCC1 in removal of long non-homologous tails during targeted homologous recombination

The XpF/Ercc1 structure-specific endonuclease performs the 5' incision in nucleotide excision repair and is the apparent mammalian counterpart of the Rad1/Rad10 endonuclease from Saccharomyces cerevisiae. In yeast, Rad1/Rad10 endonuclease also functions in mitotic recombination. To determine whether XpF/Ercc1 endonuclease has a similar role in mitotic recombination, we targeted the APRT locus in Chinese hamster ovary ERCC1(+) and ERCC1(-) cell lines with insertion vectors having long or short terminal non-homologies flanking each side of a double-strand break. No substantial differences were evident in overall recombination frequencies, in contrast to results from targeting experiments in yeast. However, profound differences were observed in types of APRT(+) recombinants recovered from ERCC1(-) cells using targeting vectors with long terminal non-homologies-almost complete ablation of gap repair and single-reciprocal exchange events, and generation of a new class of aberrant insertion/deletion recombinants absent in ERCC1(+) cells. These results represent the first demonstration of a requirement for ERCC1 in targeted homologous recombination in mammalian cells, specifically in removal of long non-homologous tails from invading homologous strands.     

Double-Strand Break Repair by Interchromosomal Recombination: An In Vivo Repair Mechanism Utilized by Multiple Somatic Tissues in Mammals

Homologous recombination (HR) is essential for accurate genome duplication and maintenance of genome stability. In eukaryotes, chromosomal double strand breaks (DSBs) are central to HR during specialized developmental programs of meiosis and antigen receptor gene rearrangements, and form at unusual DNA structures and stalled replication forks. DSBs also result from exposure to ionizing radiation, reactive oxygen species, some anti-cancer agents, or inhibitors of topoisomerase II. Literature predicts that repair of such breaks normally will occur by non-homologous end-joining (in G1), intrachromosomal HR (all phases), or sister chromatid HR (in S/G²). However, no in vivo model is in place to directly determine the potential for DSB repair in somatic cells of mammals to occur by HR between repeated sequences on heterologs (i.e., interchromosomal HR). To test this, we developed a mouse model with three transgenes—two nonfunctional green fluorescent protein (GFP) transgenes each containing a recognition site for the I-SceI endonuclease, and a tetracycline-inducible I-SceI endonuclease transgene. If interchromosomal HR can be utilized for DSB repair in somatic cells, then I-SceI expression and induction of DSBs within the GFP reporters may result in a functional GFP+ gene. Strikingly, GFP+ recombinant cells were observed in multiple organs with highest numbers in thymus, kidney, and lung. Additionally, bone marrow cultures demonstrated interchromosomal HR within multiple hematopoietic subpopulations including multi-lineage colony forming unit–granulocyte-erythrocyte-monocyte-megakaryocte (CFU-GEMM) colonies. This is a direct demonstration that somatic cells in vivo search genome-wide for homologous sequences suitable for DSB repair, and this type of repair can occur within early developmental populations capable of multi-lineage differentiation.     

Targeted mutagenesis in the progeny of maize transgenic plants

We have demonstrated that targeted mutagenesis can be accomplished in maize plants by excision, activation, and subsequent elimination of an endonuclease in the progeny of genetic crosses. The yeast FLP/FRT site-specific recombination system was used to excise and transiently activate the previously integrated yeast I-SceI homing endonuclease in maize zygotes and/or developing embryos. An artificial I-SceI recognition sequence integrated into genomic DNA was analyzed for mutations to indicate the I-SceI endonuclease activity. Targeted mutagenesis of the I-SceI site occurred in about 1% of analyzed F1 plants. Short deletions centered on the I-SceI-produced double-strand break were the predominant genetic lesions observed in the F1 plants. The I-SceI expression cassette was not detected in the mutant F1 plants and their progeny. However, the original mutations were faithfully transmitted to the next generation indicating that the mutations occurred early during the F1 plant development. The procedure offers simultaneous production of double-strand breaks and delivery of DNA template combined with a large number of progeny plants for future gene targeting experiments.     

I-SceI-mediated plasmid deletion and intra-molecular recombination in Spiroplasma citri

S. citri wild-type strain GII3 carries six plasmids (pSci1 to -6) that are thought to encode determinants involved in the transmission of the spiroplasma by its leafhopper vector. In this study we report the use of meganuclease I-SceI for plasmid deletion in S. citri. Plasmids pSci1NT-I and pSci6PT-I, pSci1 and pSci6 derivatives that contain the tetM selection marker and a unique I-SceI recognition site were first introduced into S. citri strains 44 (having no plasmid) and GII3 (carrying pSci1-6), respectively. Due to incompatibility of homologous replication regions, propagation of the S. citri GII3 transformant in selective medium resulted in the replacement of the natural pSci6 by pSci6PT-I. The spiroplasmal transformants were further transformed by an oriC plasmid carrying the I-SceI gene under the control of the spiralin gene promoter. In the S. citri 44 transformant, expression of I-SceI resulted in rapid loss of pSciNT-I showing that expression of I-SceI can be used as a counter-selection tool in spiroplasmas. In the case of the S. citri GII3 transformant carrying pSci6PT-I, expression of I-SceI resulted in the deletion of plasmid fragments comprising the I-SceI site and the tetM marker. Delineating the I-SceI generated deletions proved they had occurred though recombination between homologous sequences. To our knowledge this is the first report of I-SceI mediated intra-molecular recombination in mollicutes.     

An xrcc4 defect or Wortmannin stimulates homologous recombination specifically induced by double-strand breaks in mammalian cells

Non-homologous end joining (NHEJ) and homologous recombination (HR) are two alternative/competitor pathways for the repair of DNA double-strand breaks (DSBs). To gain further insights into the regulation of DSB repair, we detail here the different HR pathways affected by (i) the inactivation of DNA-PK activity, by treatment with Wortmannin, and (ii) a mutation in the xrcc4 gene, involved in a late NHEJ step, using the XR-1 cell line. Here we have analyzed not only the impact of NHEJ inactivation on recombination induced by a single DSB targeted to the recombination substrate (using I-SceI endonuclease) but also on γ-ray- and UV-C-induced and spontaneous recombination and finally on Rad51 foci formation, i.e. on the assembly of the homologous recombination complex, at the molecular level. The results presented here show that in contrast to embryonic stem cells, the xrcc4 mutation strongly stimulates I-SceI-induced HR in adult hamster cells. More precisely, we show here that both single strand annealing and gene conversion are stimulated. In contrast, Wortmannin does not affect I-SceI-induced HR. In addition, γ-ray-induced recombination is stimulated by both xrcc4 mutation and Wortmannin treatment in an epistatic-like manner. In contrast, neither spontaneous nor UV-C-induced recombination was affected by xrcc4 mutation, showing that the channeling from NHEJ to HR is specific to DSBs. Finally, we show here that xrcc4 mutation or Wortmannin treatment results in a stimulation of Rad51 foci assembly, thus that a late NHEJ step is able to affect Rad51 recombination complex assembly. The present data suggest a model according to which NHEJ and HR do not simply compete for DSB repair but can act sequentially: a defect in a late NHEJ step is not a dead end and can make DSB available for subsequent Rad51 recombination complex assembly.     

Rad10 exhibits lesion-dependent genetic requirements for recruitment to DNA double-strand breaks in Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, the Rad1–Rad10 protein complex participates in nucleotide excision repair (NER) and homologous recombination (HR). During HR, the Rad1–Rad10 endonuclease cleaves 3′ branches of DNA and aberrant 3′ DNA ends that are refractory to other 3′ processing enzymes. Here we show that yeast strains expressing fluorescently labeled Rad10 protein (Rad10-YFP) form foci in response to double-strand breaks (DSBs) induced by a site-specific restriction enzyme, I-SceI or by ionizing radiation (IR). Additionally, for endonuclease-induced DSBs, Rad10-YFP localization to DSB sites depends on both RAD51 and RAD52, but not MRE11 while IR-induced breaks do not require RAD51. Finally, Rad10-YFP colocalizes with Rad51-CFP and with Rad52-CFP at DSB sites, indicating a temporal overlap of Rad52, Rad51 and Rad10 functions at DSBs. These observations are consistent with a putative role of Rad10 protein in excising overhanging DNA ends after homology searching and refine the potential role(s) of the Rad1–Rad10 complex in DSB repair in yeast.     

I-SceI endonuclease: a new tool for DNA repair studies and genetic manipulations in streptomycetes

Actinomycetes are Gram-positive bacteria with a complex life cycle. They produce many pharmaceutically relevant secondary metabolites, including antibiotics and anticancer drugs. However, there is a limited number of biotechnological applications available as opposed to genetic model organisms like Bacillus subtilis or Escherichia coli. We report here a system for the functional expression of a synthetic gene encoding the I-SceI homing endonuclease in several streptomycetes. Using the synthetic sce(a) gene, we were able to create controlled genomic DNA double-strand breaks. A mutagenesis system, based on the homing endonuclease I-SceI, has been developed to construct targeted, non-polar, unmarked gene mutations in Streptomyces sp. Tü6071. In addition, we have shown that homologous recombination is a major pathway in streptomycetes to repair an I-SceI-generated DNA double-strand break. This novel I-SceI-based tool will be useful in fundamental studies on the repair mechanism of DNA double-strand breaks and for a variety of biotechnological applications.     

Characterisation of a new reporter system allowing high throughput in planta screening for recombination events before and after controlled DNA double strand break induction

DNA double strand breaks (DSBs) are created either by DNA damaging reagents or in a programmed manner, for example during meiosis. Homologous recombination (HR) can be used to repair DSBs, a process vital both for cell survival and for genetic rearrangement during meiosis. In order to easily quantify this mechanism, a new HR reporter gene that is suitable for the detection of rare recombination events in high-throughput screens was developed in Arabidopsis thaliana. This reporter, pPNP, is composed of two mutated Pat genes and has also one restriction site for the meganuclease I-SceI. A functional Pat gene can be reconstituted by an HR event giving plants which are resistant to the herbicide glufosinate. The basal frequency of intra-chromosomal recombination is very low (10^?5) and can be strongly increased by the expression of I-SceI which creates a DSB. Expression of I-SceI under the control of the 35S CaMV promoter dramatically increases HR frequency (10,000 fold); however the measured recombinant events are in majority somatic. In contrast only germinal recombination events were measured when the meganuclease was expressed from a floral-specific promoter. Finally, the reporter was used to test a dexamethasone inducible I-SceI which could produce up to 200× more HR events after induction. This novel inducible I-SceI should be useful in fundamental studies of the mechanism of repair of DSBs and for biotechnological applications.     

Processing by MRE11 is involved in the sensitivity of subtelomeric regions to DNA double-strand breaks

The caps on the ends of chromosomes, called telomeres, keep the ends of chromosomes from appearing as DNA double-strand breaks (DSBs) and prevent chromosome fusion. However, subtelomeric regions are sensitive to DSBs, which in normal cells is responsible for ionizing radiation-induced cell senescence and protection against oncogene-induced replication stress, but promotes chromosome instability in cancer cells that lack cell cycle checkpoints. We have previously reported that I-SceI endonuclease-induced DSBs near telomeres in a human cancer cell line are much more likely to generate large deletions and gross chromosome rearrangements (GCRs) than interstitial DSBs, but found no difference in the frequency of I-SceI-induced small deletions at interstitial and subtelomeric DSBs. We now show that inhibition of MRE11 3′–5′ exonuclease activity with Mirin reduces the frequency of large deletions and GCRs at both interstitial and subtelomeric DSBs, but has little effect on the frequency of small deletions. We conclude that large deletions and GCRs are due to excessive processing of DSBs, while most small deletions occur during classical nonhomologous end joining (C-NHEJ). The sensitivity of subtelomeric regions to DSBs is therefore because they are prone to undergo excessive processing, and not because of a deficiency in C-NHEJ in subtelomeric regions.     

Promiscuous patching of broken chromosomes in mammalian cells with extrachromosomal DNA

To study double-strand break (DSB)-induced mutations in mammalian chromosomes, we stably transfected thymidine kinase (tk)-deficient mouse fibroblasts with a DNA substrate containing a recognition site for yeast endonuclease I-SceI embedded within a functional tk gene. Cells were then electroporated with a plasmid expressing endonuclease I-SceI to induce a DSB, and clones that had lost tk function were selected. In a previous study of DSB-induced tk-deficient clones, we found that ~8% of recovered tk mutations involved the capture of one or more DNA fragments at the DSB site. Almost half of the DNA capture events involved the I-SceI expression plasmid, and several events involved retrotransposable elements. To learn whether only certain DNA sequences or motifs are efficiently captured, in the current work we electroporated an I-SceI expression plasmid along with HaeIII fragments of X174 genomic DNA. We report that 18 out of 132 tk-deficient clones recovered had captured DNA fragments, and 14 DNA capture events involved one or more fragments of X174 DNA. Microhomology existed at most junctions between X174 DNA and genomic sequences. Our work suggests that virtually any extrachromosomal DNA molecule may be recruited for the patching of DSBs in a mammalian genome.     

Improvements to a Markerless Allelic Exchange System for Bacillus anthracis

A system was previously developed for conducting I-SceI-mediated allelic exchange in Bacillus anthracis. In this system, recombinational loss of a chromosomally-integrated allelic exchange vector is stimulated by creation of a double-stranded break within the vector by the homing endonuclease I-SceI. Although this system is reasonably efficient and represents an improvement in the tools available for allelic exchange in B. anthracis, researchers are nonetheless required to “pick and patch” colonies in order to identify candidate "exchangeants." In the present study, a number of improvements have been made to this system: 1) an improved I-SceI-producing plasmid includes oriT so that both plasmids can now be introduced by conjugation, thus avoiding the need for preparing electro-competent cells of each integration intermediate; 2) antibiotic markers have been changed to allow the use of the system in select agent strains; and 3) both plasmids have been marked with fluorescent proteins, allowing the visualization of plasmid segregation on a plate and obviating the need for “picking and patching.” These modifications have made the process easier, faster, and more efficient, allowing for parallel construction of larger numbers of mutant strains. Using this improved system, the genes encoding the tripartite anthrax toxin were deleted singly and in combination from plasmid pXO1 of Sterne strain 34F2. In the course of this study, we determined that DNA transfer to B. anthracis could be accomplished by conjugation directly from a methylation-competent E. coli strain.     

Efficient repair of DNA double-strand breaks in malignant cells with structural instability

Aberrant repair of DNA double-strand breaks (DSBs) is thought to be important in the generation of gross chromosomal rearrangements (GCRs). To examine how DNA DSBs might lead to GCRs, we investigated the repair of a single DNA DSB in a structurally unstable cell line. An I-SceI recognition site was introduced into OVCAR-8 cells between a constitutive promoter (EF1α) and the Herpes simplex virus thymidine kinase (TK) gene, which confers sensitivity to gancyclovir (GCV). Expression of I-SceI in these cells caused a single DSB. Clones with aberrant repair could acquire resistance to GCV by separation of the EF1α promoter from the TK gene, or deletion of either the EF1α promoter or the TK gene. All mutations that we identified were interstitial deletions. Treatment of cells with etoposide or bleomycin, agents known to produce DNA DSBs following expression of I-SceI also did not generate GCRs. Because we identified solely interstitial deletions using the aforementioned negative selection system, we developed a positive selection system to produce GCR. A construct containing an I-SceI restriction site immediately followed by a hygromycin phosphotransferase cDNA, with no promoter, was stably integrated into OVCAR-8 cells. DNA DSBs were produced by an I-SceI expression vector. None of the hygromycin resistant clones recovered had linked the hygromycin phosphotransferase cDNA to an endogenous promoter, but had instead captured a portion of the I-SceI expression vector. These results indicate that even in a structurally unstable malignant cell line, the majority of DNA DSBs are repaired by religation of the two broken chromosome ends, without the introduction of a GCR.     

Actinomycetes genome engineering approaches

This review provides an overview of new technologies for DNA manipulations in actinomycetes exploiting recombinogenic engineering (Flp-FRT, Cre-loxP, Dre-rox, Tn5, GusA and I-SceI systems). We will describe some new vectors recently developed for engineering of complex phenotypes in actinomycetes. Several site-specific recombinases, transposons, reporter genes and I-SceI endonuclease have been utilized for genome manipulation in actinomycetes. Novel molecular tools will help to overcome many technical difficulties and will encourage new efforts to address the function of actinomycete genes.     

NurA,a novel 5'-3' nuclease gene linked to rad50 and mre11 homologs of thermophilic Archaea

We isolated and characterized a new nuclease (NurA) exhibiting both single-stranded endonuclease activity and 5′–3′ exonuclease activity on single-stranded and double-stranded DNA from the hyperthermophilic archaeon Sulfolobus acidocaldarius. Nuclease homologs are detected in all thermophilic archaea and, in most species, the nurA gene is organized in an operon-like structure with rad50 and mre11 archaeal homologs. This nuclease might thus act in concert with Rad50 and Mre11 proteins in archaeal recombination/repair. To our knowledge, this is the first report of a 5′–3′ nuclease potentially associated with Rad50 and Mre11-like proteins that may lead to the processing of double-stranded breaks in 3′ single-stranded tails.