Independent and sequential recruitment of NHEJ and HR factors to DNA damage sites in mammalian cells

Damage recognition by repair/checkpoint factors is the critical first step of the DNA damage response. DNA double strand breaks (DSBs) activate checkpoint signaling and are repaired by nonhomologous end-joining (NHEJ) and homologous recombination (HR) pathways. However, in vivo kinetics of the individual factor responses and the mechanism of pathway choice are not well understood. We report cell cycle and time course analyses of checkpoint activation by ataxia-telangiectasia mutated and damage site recruitment of the repair factors in response to laser-induced DSBs. We found that MRN acts as a DNA damage marker, continuously localizing at unrepaired damage sites. Damage recognition by NHEJ factors precedes that of HR factors. HR factor recruitment is not influenced by NHEJ factor assembly and occurs throughout interphase. Damage site retention of NHEJ factors is transient, whereas HR factors persist at unrepaired lesions, revealing unique roles of the two pathways in mammalian cells.     

DNA Damage Signalling and Repair in Dictyostelium discoideum

Repair of DNA double strand breaks (DSBs) is critical for the maintenance of genome integrity. DNA DSBs can be repaired by either homologous recombination (HR) or nonhomologous end-joining (NHEJ). Whilst HR requires sequences homologous to thedamaged DNA template in order to facilitate repair, NHEJ occurs through recognition of DNA DSBs by a variety of proteins that process and rejoin DNA termini by direct ligation. Here we review two recent reports that NHEJ is conserved in the social amoebaDictyostelium discoideum. Certain components of the mammalian NHEJ pathway that are absent in genetically tractable organisms such as yeast are present in Dictyostelium and we discuss potential directions for future research, in addition to considering this organism as a genetic model system for the study of NHEJ in vivo.     

Human SMC5/6 complex promotes sister chromatid homologous recombination by recruiting the SMC1/3 cohesin complex to double-strand breaks

The structural maintenance of chromosomes (SMC) family of proteins has been implicated in the repair of DNA double-strand breaks (DSBs) by homologous recombination (HR). The SMC1/3 cohesin complex is thought to promote HR by maintaining the close proximity of sister chromatids at DSBs. The SMC5/6 complex is also required for DNA repair, but the mechanism by which it accomplishes this is unclear. Here, we show that RNAi-mediated knockdown of the SMC5/6 complex components in human cells increases the efficiency of gene targeting due to a specific requirement for hSMC5/6 in sister chromatid HR. Knockdown of the hSMC5/6 complex decreases sister chromatid HR, but does not reduce nonhomologous end-joining (NHEJ) or intra-chromatid, homologue, or extrachromosomal HR. The hSMC5/6 complex is itself recruited to nuclease-induced DSBs and is required for the recruitment of cohesin to DSBs. Our results establish a mechanism by which the hSMC5/6 complex promotes DNA repair and suggest a novel strategy to improve the efficiency of gene targeting in mammalian somatic cells.     

Analysis of DNA double-strand break repair pathways in mice

During the last years significant new insights have been gained into the mechanism and biological relevance of DNA double-strand break (DSB) repair in relation to genome stability. DSBs are a highly toxic DNA lesion, because they can lead to chromosome fragmentation, loss and translocations, eventually resulting in cancer. DSBs can be induced by cellular processes such as V(D)J recombination or DNA replication. They can also be introduced by exogenous agents DNA damaging agents such as ionizing radiation or mitomycin C. During evolution several pathways have evolved for the repair of these DSBs. The most important DSB repair mechanisms in mammalian cells are nonhomologous end-joining and homologous recombination. By using an undamaged repair template, homologous recombination ensures accurate DSB repair, whereas the untemplated nonhomologous end-joining pathway does not. Although both pathways are active in mammals, the relative contribution of the two repair pathways to genome stability differs in the different cell types. Given the potential differences in repair fidelity, it is of interest to determine the relative contribution of homologous recombination and nonhomologous end-joining to DSB repair. In this review, we focus on the biological relevance of DSB repair in mammalian cells and the potential overlap between nonhomologous end-joining and homologous recombination in different tissues.     

Introduction of double-strand breaks into the genome of mouse cells by expression of a rare-cutting endonuclease.

To maintain genomic integrity, double-strand breaks (DSBs) in chromosomal DNA must be repaired. In mammalian systems, the analysis of the repair of chromosomal DSBs has been limited by the inability to introduce well-defined DSBs in genomic DNA. In this study, we created specific DSBs in mouse chromosomes for the first time, using an expression system for a rare-cutting endonuclease, I-SceI. A genetic assay has been devised to monitor the repair of DSBs, whereby cleavage sites for I-SceI have been integrated into the mouse genome in two tandem neomycin phosphotransferase genes. We find that cleavage of the I-SceI sites is very efficient, with at least 12% of stably transfected cells having at least one cleavage event and, of these, more than 70% have undergone cleavage at both I-SceI sites. Cleavage of both sites in a fraction of clones deletes 3.8 kb of intervening chromosomal sequences. We find that the DSBs are repaired by both homologous and nonhomologous mechanisms. Nonhomologous repair events frequently result in small deletions after rejoining of the two DNA ends. Some of these appear to occur by simple blunt-ended ligation, whereas several others may occur through annealing of short regions of terminal homology. The DSBs are apparently recombinogenic, stimulating gene targeting of a homologous fragment by more than 2 orders of magnitude. Whereas gene-targeted clones are nearly undetectable without endonuclease expression, they represent approximately 10% of cells transfected with the I-SceI expression vector. Gene targeted clones are of two major types, those that occur by two-sided homologous recombination with the homologous fragment and those that occur by one-sided homologous recombination. Our results are expected to impact a number of areas in the study of mammalian genome dynamics, including the analysis of the repair of DSBs and homologous recombination and, potentially, molecular genetic analyses of mammalian genomes.     

Radiation induced DNA DSBs: Contribution from stalled replication forks?

When cells are exposed to radiation serious lesions are introduced into the DNA including double strand breaks (DSBs), single strand breaks (SSBs), base modifications and clustered damage sites (a specific feature of ionizing radiation induced DNA damage). Radiation induced DNA damage has the potential to initiate events that can lead ultimately to mutations and the onset of cancer and therefore understanding the cellular responses to DNA lesions is of particular importance. Using γH2AX as a marker for DSB formation and RAD51 as a marker of homologous recombination (HR) which is recruited in the processing of frank DSBs or DSBs arising from stalled replication forks, we have investigated the contribution of SSBs and non-DSB DNA damage to the induction of DSBs in mammalian cells by ionizing radiation during the cell cycle. V79-4 cells and human HF19 fibroblast cells have been either irradiated with 0–20 Gy of γ radiation or, for comparison, treated with a low concentration of hydrogen peroxide, which is known to induce SSBs but not DSBs. Inhibition of the repair of oxidative DNA lesions by poly(ADP ribose) polymerase (PARP) inhibitor leads to an increase in radiation induced γH2AX and RAD51 foci which we propose is due to these lesions colliding with replication forks forming replication induced DSBs. It was confirmed that DSBs are not induced in G₁ phase cells by treatment with hydrogen peroxide but treatment does lead to DSB induction, specifically in S phase cells. We therefore suggest that radiation induced SSBs and non-DSB DNA damage contribute to the formation of replication induced DSBs, detected as RAD51 foci.     

DNA homologous recombination repair in mammalian cells

DNA double-strand breaks (DSBs) are the most serious DNA damage. Due to a great variety of factors causing DSBs, the efficacy of their repair is crucial for the cell's functioning and prevents DNA fragmentation, chromosomal translocation and deletion. In mammalian cells DSBs can be repaired by non-homologous end joining (NHEJ), homologous recombination (HRR) and single strand annealing (SSA). HRR can be divided into the first and second phase. The first phase is initiated by sensor proteins belonging to the MRN complex, that activate the ATM protein which target HRR proteins to obtain the second response phase--repair. HRR is precise because it utilizes a non-damaged homologous DNA fragment as a template. The key players of HRR in mammalian cells are MRN, RPA, Rad51 and its paralogs, Rad52 and Rad54.     

Enhanced oligonucleotide-directed gene targeting in mammalian cells following treatment with DNA damaging agents

Targeted gene repair, a form of oligonucleotide-directed mutagenesis, employs end-modified single-stranded DNA oligonucleotides to mediate single-base changes in chromosomal DNA. In this work, we use a specific 72-mer to direct the repair of a mutated eGFP gene stably integrated in the genome of DLD-1 cells. Corrected cells express eGFP that can be identified and quantitated by FACS. The repair of this mutant gene is dependent on the presence of a specifically designed oligonucleotide and the frequency with which the mutation is reversed is affected by the induction of DNA damage. We used hydroxyurea, VP16 (etoposide), and thymidine to modulate the rate of DNA replication through the stalling of the replication forks or the introduction of lesions. Addition of hydroxyurea or VP16 before the electroporation of the oligonucleotide, results in an accumulation of double-strand breaks (DSB) whose repair is facilitated by either nonhomologous end joining (NHEJ) or homologous recombination (HR). The addition of thymidine results in DNA damage within replication forks, damage that is repaired through the process of homologous recombination. Our data suggest that gene repair activity is elevated when DNA damage induces or activates the homologous recombination pathway.     

Effect of Ku86 and DNA-PKcs deficiency on non-homologous end-joining and homologous recombination using a transient transfection assay

In mammalian cells, DNA double-strand breaks are repaired by non-homologous end-joining and homologous recombination, both pathways being essential for the maintenance of genome integrity. We determined the effect of mutations in Ku86 and DNA-PK on the efficiency and the accuracy of double-strand break repair by non-homologous end-joining and homologous recombination in mammalian cells. We used an assay, based on the transient transfection of a linearized plasmid DNA, designed to simultaneously detect transfection and recombination markers. In agreement with previous results non-homologous end-joining was largely compromised in Ku86 deficient cells, and returned to normal in the Ku86-complemented isogenic cell line. In addition, analysis of DNA plasmids recovered from Ku86 mutant cells showed an increased use of microhomologies at the nonhomologous end joining junctions, and displayed a significantly higher frequency of DNA insertions compared to control cells. On the other hand, the DNA-PKcs deficient cell lines showed efficient double-strand break repair by both mechanisms.     

The dynamic interplay in chromatin remodeling factors polycomb and trithorax proteins in response to DNA damage

The dynamic interplay in polycomb group (PcG) and trithorax group (TrxG) proteins in response to DNA damage directly involves in the DNA double strand breaks (DSBs) sites and potentially function in both homologous recombination (HR) and nonhomologous end joining (NHEJ) pathways. The process includes chromatin remodeling that is a major mechanism used by cells to relax chromatin in DNA damage response (DDR) and repair. PcGs show resistance ability to the process while, some tumor suppressor genes involves in the DDR and repair by interacting with TrxGs. Understanding how the dynamic interplay in PcGs and TrxGs impacts on DDR will shed light on the mechanisms of carcinogenesis and develop a new target from anti-DDR related drugs.     

Nuclear factories for signalling and repairing DNA double strand breaks in living fission yeast

In mammalian and budding yeast cells treated with genotoxic agents, different proteins implicated in detecting, signalling or repairing DNA lesions form nuclear foci. We studied foci formed by proteins involved in these processes in living fission yeast cells, which is amenable to genetic and molecular analysis. Using fluorescent tags, we analysed subnuclear localisations of the DNA damage checkpoint protein Rad9, of the homologous recombination protein Rad22 and of PCNA, which are implicated in many aspects of DNA metabolism. After inducing double strand breaks (DSBs) with ionising radiations, Rad22, Rad9 and PCNA form a low number of nuclear foci. Rad9 recruitment to foci depends on the presence of Rad1, Hus1 and Rad17, but is independent of downstream checkpoint effectors and of homologous recombination proteins. Likewise, Rad22 and PCNA form foci despite inactive homologous recombination repair and impaired DNA damage checkpoint. Rad22 and Rad9 foci co-localise completely, whereas PCNA co-localises with Rad22 and Rad9 only partially. Foci do not disassemble in cells unable to repair DNA by homologous recombination. Thus, in fission yeast, DSBs are detected by the DNA damage checkpoint and are repaired by homologous recombination at a few spatially confined subnuclear compartments where Rad22, Rad9 and PCNA concentrate independently.     

The complexity of DNA double strand breaks is a critical factor enhancing end-resection

DNA double strand breaks (DSBs) induced by ionizing radiation (IR) are deleterious damages. Two major pathways repair DSBs in human cells, DNA non-homologous end-joining (NHEJ) and homologous recombination (HR). It has been suggested that the balance between the two repair pathways varies depending on the chromatin structure surrounding the damage site and/or the complexity of damage at the DNA break ends. Heavy ion radiation is known to induce complex-type DSBs, and the efficiency of NHEJ in repairing these DSBs was shown to be diminished. Taking advantage of the ability of high linear energy transfer (LET) radiation to produce complex DSBs effectively, we investigated how the complexity of DSB end structure influences DNA damage responses. An early step in HR is the generation of 3′-single strand DNA (SSD) via a process of DNA end resection that requires CtIP. To assess this process, we analyzed the level of phosphorylated CtIP, as well as RPA phosphorylation and focus formation, which occur on the exposed SSD. We show that complex DSBs efficiently activate DNA end resection. After heavy ion beam irradiation, resection signals appear both in the vicinity of heterochromatic areas, which is also observed after X-irradiation, and additionally in euchromatic areas. Consequently, ∼85% of complex DSBs are subjected to resection in heavy ion particle tracks. Furthermore, around 20–40% of G1 cells exhibit resection signals. Taken together, our observations reveal that the complexity of DSB ends is a critical factor regulating the choice of DSB repair pathway and drastically alters the balance toward resection-mediated rejoining. As demonstrated here, studies on DNA damage responses induced by heavy ion radiation provide an important tool to shed light on mechanisms regulating DNA end resection.     

聚腺苷二磷酸-核糖聚合酶1与DNA双链断裂修复的相关性

DNA双链断裂(double strand breaks,DSBs)是细胞最严重的DNA损伤形式。细胞通过同源重组(homologous recombination,HR)和非同源末端连接(non-homologous end joining,NHEJ)途径修复DNA双链断裂损伤。聚腺苷二磷酸核糖基化(poly(ADP-ribosyl)ation,PARylation)是蛋白质翻译后修饰过程,这个过程由聚腺苷二磷酸 核糖聚合酶家族(poly(ADP-ribose)polymerases,PARPs)催化完成。PARP1作为PARPs家族最重要的成员,其在DNA损伤应答方面发挥重要作用。研究显示,PARP1在DSBs修复过程中发挥关键作用,参与DSBs的早期应答反应及其具体修复途径,可依据KU蛋白的存在与否发挥不同的特定作用。本文较全面地综述了PARP1在DNA双链断裂修复方面的潜在作用,将为临床疾病的诊治提供新的思路。     

Loss of nonhomologous end joining confers camptothecin resistance in DT40 cells. Implications for the repair of topoisomerase I-mediated DNA damage

DNA topoisomerase I (Top1) generates transient DNA single-strand breaks via the formation of cleavage complexes in which the enzyme is linked to the 3'-phosphate of the cleavage strand. The anticancer drug camptothecin (CPT) poisons Top1 by trapping cleavage complexes, thereby inducing Top1-linked single-strand breaks. Such DNA lesions are converted into DNA double-strand breaks (DSBs) upon collision with replication forks, implying that DSB repair pathways could be involved in the processing/repair of Top1-mediated DNA damage. Here we report that Top1-mediated DNA damage is repaired primarily by homologous recombination, a major pathway of DSB repair. Unexpectedly, however, we found that nonhomologous end joining (NHEJ), another DSB repair pathway, has no positive role in the relevant repair; notably, DT40 cell mutants lacking either of the NHEJ factors (namely, Ku70, DNA-dependent protein kinase catalytic subunit, and DNA ligase IV) were resistant to killing by CPT. In addition, we showed that the absence of NHEJ alleviates the requirement of homologous recombination in the repair of CPT-induced DNA damage. Our results indicate that NHEJ can be a cytotoxic pathway in the presence of CPT, shedding new light on the molecular mechanisms for the formation and repair of Top1-mediated DNA damage in vertebrates. Thus, our data have significant implications for cancer chemotherapy involving Top1 inhibitors.     

Differential regulation of the cellular response to DNA double-strand breaks in G1

Double-strand breaks (DSBs) are potentially lethal DNA lesions that can be repaired by either homologous recombination (HR) or nonhomologous end-joining (NHEJ). We show that DSBs induced by ionizing radiation (IR) are efficiently processed for HR and bound by Rfa1 during G1, while endonuclease-induced breaks are recognized by Rfa1 only after the cell enters S phase. This difference is dependent on the DNA end-binding Yku70/Yku80 complex. Cell-cycle regulation is also observed in the DNA damage checkpoint response. Specifically, the 9-1-1 complex is required in G1 cells to recruit the Ddc2 checkpoint protein to damaged DNA, while, upon entry into S phase, the cyclin-dependent kinase Cdc28 and the 9-1-1 complex both serve to recruit Ddc2 to foci. Together, these results demonstrate that the DNA repair machinery distinguishes between different types of damage in G1, which translates into different modes of checkpoint activation in G1 and S/G2 cells.     

End-joining repair of double-strand breaks in Drosophila melanogaster is largely DNA ligase IV independent

Repair of DNA double-strand breaks can occur by either nonhomologous end joining or homologous recombination. Most nonhomologous end joining requires a specialized ligase, DNA ligase IV (Lig4). In Drosophila melanogaster, double-strand breaks created by excision of a P element are usually repaired by a homologous recombination pathway called synthesis-dependent strand annealing (SDSA). SDSA requires strand invasion mediated by DmRad51, the product of the spn-A gene. In spn-A mutants, repair proceeds through a nonconservative pathway involving the annealing of microhomologies found within the 17-nt overhangs produced by P excision. We report here that end joining of P-element breaks in the absence of DmRad51 does not require Drosophila LIG4. In wild-type flies, SDSA is sometimes incomplete, and repair is finished by an end-joining pathway that also appears to be independent of LIG4. Loss of LIG4 does not increase sensitivity to ionizing radiation in late-stage larvae, but lig4 spn-A double mutants do show heightened sensitivity relative to spn-A single mutants. Together, our results suggest that a LIG4-independent end-joining pathway is responsible for the majority of double-strand break repair in the absence of homologous recombination in flies.     

Radiation induction of delayed recombination in Schizosaccharomyces pombe

Ionizing radiation is known to induce delayed chromosome and gene mutations in the descendants of the irradiated tissue culture cells. Molecular mechanisms of such delayed mutations are yet to be elucidated, since high genomic complexity of mammalian cells makes it difficult to analyze. We now tested radiation induction of delayed recombination in the fission yeast Schizosaccharomyces pombe by monitoring the frequency of homologous recombination after X-irradiation. A reporter with 200 bp tandem repeats went through spontaneous recombination at a frequency of 1.0 x 10(-4), and the frequency increased dose-dependently to around 10 x 10(-4) at 500 Gy of X-irradiation. Although the repair of initial DNA damage was thought to be completed before the restart of cell division cycle, the elevation of the recombination frequency persisted for 8-10 cell generations after irradiation (delayed recombination). The delayed recombination suggests that descendants of the irradiated cells keep a memory of the initial DNA damage which upregulates recombination machinery for 8-10 generations even in the absence of DNA double-strand breaks (DSBs). Since radical scavengers were ineffective in inhibiting the delayed recombination, a memory by continuous production of DNA damaging agents such as reactive oxygen species (ROS) was excluded. Recombination was induced in trans in a reporter on chromosome III by a DNA DSB at a site on chromosome I, suggesting the untargeted nature of delayed recombination. Interestingly, Rad22 foci persisted in the X-irradiated population in parallel with the elevation of the recombination frequency. These results suggest that the epigenetic damage memory induced by DNA DSB upregulates untargeted and delayed recombination in S. pombe.     

Inhibition of DNA topoisomerase II may trigger illegitimate recombination in living cells: experiments with a model system

We have developed a plasmid test system to study recombination in vitro and in mammalian cells in vivo, and to analyze the possible role of DNA topoisomerase II. The system is based on a plasmid construct containing an inducible marker gene ccdB ("killer" (KIL) gene) whose product is lethal for bacterial cells, flanked by two different potentially recombinogenic elements. The plasmids were subjected to recombinogenic conditions in vitro or in vivo after transient transfection into COS-1 cells, and subsequently transformed into E. coli which was then grown in the presence of the ccdB gene inducer. Hence, all viable colonies contained recombinant plasmids since only recombination between the flanking regions could remove the KIL gene. Thus, it was possible to detect recombination events and to estimate their frequency. We found that the frequency of topoisomerase II-mediated recombination in vivo is significantly higher than in a minimal in vitro system. The presence of VM-26, an inhibitor of the religation step of the topoisomerase II reaction, increased the recombination frequency by 60%. We propose that cleavable complexes of topoisomerase II are either not religated, triggering error-prone repair of the DNA breaks, or are incorrectly religated resulting in strand exchange. We also studied the influence of sequences known to contain preferential breakpoints for recombination in vivo after chemotherapy with topoisomerase II-targeting drugs, but no preferential stimulation of recombination by these sequences was detected in this non-chromosomal context.