Molecular recombination and the repair of DNA double-strand breaks in CHO cells.

Molecular recombination and the repair of DNA double-strand breaks (DSB) have been examined in the G-0 and S phase of the cell cycle using a temperature-sensitive CHO cell line to test i) if there are cell cycle restrictions on the repair of DSB's' ii) the extent to which molecular recombination can be induced between either sister chromatids or homologous chromosomes and iii) whether repair of DSB's involves recombination (3). Mitomycin C (1-2 micrograms/ml) or ionizing radiation (50 krad) followed by incubation resulted in molecular recombination (hybrid DNA) in S phase cells. Approximately 0.03 to 0.10% of the molecules (number average molecular weight: 5.6 x 10(6) Daltons after shearing) had hybrid regions for more than 75% of their length. However, no recombination was detected in G-0 cells. Since the repair of DSB was observed in both stages with more than 50% of the breaks repaired in 5 hours, it appears that DSB repair in G-0 cells does not involve recombination between homologous chromosomes. The possibility is not excluded that repair in G-0 cells involves only small regions (less than 4 x 10(6) Daltons).     

The CDK regulates repair of double-strand breaks by homologous recombination during the cell cycle

DNA double-strand breaks (DSBs) are dangerous lesions that can lead to genomic instability and cell death. Eukaryotic cells repair DSBs either by nonhomologous end-joining (NHEJ) or by homologous recombination. We investigated the ability of yeast cells (Saccharomyces cerevisiae) to repair a single, chromosomal DSB by recombination at different stages of the cell cycle. We show that cells arrested at the G1 phase of the cell cycle restrict homologous recombination, but are able to repair the DSB by NHEJ. Furthermore, we demonstrate that recombination ability does not require duplicated chromatids or passage through S phase, and is controlled at the resection step by Clb-CDK activity.     

Homologous recombination and double-strand break repair in the transformation of Rhizopus oryzae

Genetic transformation of the Mucorales fungi has been problematic, since DNA transformed into the host rarely integrates and usually is mitotically unstable in the absence of selective pressure. In this study, transformation of Rhizopus oryzae was investigated to determine if the fate of introduced DNA could be predicted based on double-strand break repair and recombination mechanisms found in other fungi. A transformation system was developed with uracil auxotrophs of Rhizopus oryzae that could be complemented with the pyrG gene isolated in this work. DNA transformed as circular plasmids was maintained extrachromosomally in high-molecular-weight (>23 kb) concatenated arrangement. Type-I crossover integration into the pyrG locus and type-III pyrG gene replacement events occurred in approximately 1-5% of transformants. Linearization of the plasmid pPyr225 with a single restriction enzyme that cleaves within the vector sequence almost always resulted in isolates with replicating concatenated plasmids that had been repaired by end-joining recombination that restored the restriction site. The addition of a 40-bp direct repeat on either side of this cleavage site led to repair by homologous recombination between the repeated sequences on the plasmid, resulting in loss of the restriction site. When plasmid pPyr225 was digested with two different enzymes that cleave within the vector sequence to release the pyrG containing fragment, only pyrG gene replacement recombination occurred in transformants. Linearization of plasmid pPyr225 within the pyrG gene itself gave the highest percentage (20%) of type-I integration at the pyrG locus. However, end-joining repair and gene replacement events were still the predominant types of recombination found in transformations with this plasmid topology.     

Homologous recombination repairs secondary replication induced DNA double-strand breaks after ionizing radiation

Ionizing radiation (IR) produces direct two-ended DNA double-strand breaks (DSBs) primarily repaired by non-homologous end joining (NHEJ). It is, however, well established that homologous recombination (HR) is induced and required for repair of a subset of DSBs formed following IR. Here, we find that HR induced by IR is drastically reduced when post-DNA damage replication is inhibited in mammalian cells. Both IR-induced RAD51 foci and HR events in the hprt gene are reduced in the presence of replication polymerase inhibitor aphidicolin (APH). Interestingly, we also detect reduced IR-induced toxicity in HR deficient cells when inhibiting post-DNA damage replication. When studying DSB formation following IR exposure, we find that apart from the direct DSBs the treatment also triggers formation of secondary DSBs peaking at 7-9 h after exposure. These secondary DSBs are restricted to newly replicated DNA and abolished by inhibiting post-DNA damage replication. Further, we find that IR-induced RAD51 foci are decreased by APH only in cells replicating at the time of IR exposure, suggesting distinct differences between IR-induced HR in S- and G2-phases of the cell cycle. Altogether, our data indicate that secondary replication-associated DSBs formed following exposure to IR are major substrates for IR-induced HR repair.     

Phosphorylation of Exo1 modulates homologous recombination repair of DNA double-strand breaks

DNA double-strand break (DSB) repair via the homologous recombination pathway is a multi-stage process, which results in repair of the DSB without loss of genetic information or fidelity. One essential step in this process is the generation of extended single-stranded DNA (ssDNA) regions at the break site. This ssDNA serves to induce cell cycle checkpoints and is required for Rad51 mediated strand invasion of the sister chromatid. Here, we show that human Exonuclease 1 (Exo1) is required for the normal repair of DSBs by HR. Cells depleted of Exo1 show chromosomal instability and hypersensitivity to ionising radiation (IR) exposure. We find that Exo1 accumulates rapidly at DSBs and is required for the recruitment of RPA and Rad51 to sites of DSBs, suggesting a role for Exo1 in ssDNA generation. Interestingly, the phosphorylation of Exo1 by ATM appears to regulate the activity of Exo1 following resection, allowing optimal Rad51 loading and the completion of HR repair. These data establish a role for Exo1 in resection of DSBs in human cells, highlighting the critical requirement of Exo1 for DSB repair via HR and thus the maintenance of genomic stability.     

Homologous recombination-mediated double-strand break repair

Exchange of DNA strands between homologous DNA molecules via recombination ensures accurate genome duplication and preservation of genome integrity. Biochemical studies have provided insights into the molecular mechanisms by which homologous recombination proteins perform these essential tasks. More recent cell biological experiments are addressing the behavior of homologous recombination proteins in cells. The challenge ahead is to uncover the relationship between the individual biochemical activities of homologous recombination proteins and their coordinated action in the context of the living cell.     

Mismatch repair converts AID-instigated nicks to double-strand breaks for antibody class-switch recombination

Mismatch repair (MMR) proteins are important for antibody class-switch recombination (CSR), but their roles are unknown. We propose a model for the function of MMR in CSR in which MMR proteins convert single-strand nicks instigated by activation-induced cytidine deaminase (AID) into the double-strand breaks (DSBs) that are required for CSR. This model does not invoke any novel functions for MMR but simply posits that, owing to numerous single-strand nicks in the switch (S) regions of both DNA strands, when MMR proteins are recruited by U:G mismatches, they excise one strand of DNA and soon reach a nick on the opposite strand. This halts excision activity and creates a DSB. This model explains why B cells that lack either S mu and MSH2 or UNG and MSH2 cannot undergo CSR.     

In vitro repair of double-strand breaks accompanied by recombination in bacteriophage T7 DNA.

A double-strand break in a bacteriophage T7 genome significantly reduced the ability of that DNA to produce viable phage when the DNA was incubated in an in vitro DNA replication and packaging system. When a homologous piece of T7 DNA (either a restriction fragment or T7 DNA cloned into a plasmid) that was by itself unable to form a complete phage was included in the reaction, the break was repaired to the extent that many more viable phage were produced. Moreover, repair could be completed even when a gap of about 900 nucleotides was put in the genome by two nearby restriction cuts. The repair was accompanied by acquisition of a genetic marker that was present only on the restriction fragment or on the T7 DNA cloned into a plasmid. These data are interpreted in light of the double-strand gap repair mode of recombination.     

Requirement for repair of DNA double-strand breaks by homologous recombination in split-dose recovery

Utsumi, H., Tano, K., Takata, M., Takeda, S. and Elkind, M. M. Requirement for Repair of DNA Double-Strand Breaks by Homologous Recombination in Split-Dose Recovery. Radiat. Res. 155, 680-686 (2001). Split-dose recovery has been observed under a variety of experimental conditions in many cell systems and is believed to be the result of the repair of sublethal damage. It is considered to be one of the most widespread and important cellular responses in clinical radiotherapy. To study the molecular mechanism(s) of this repair, we analyzed the knockout mutants KU70-/-, RAD54-/-, and KU70-/-/RAD54-/- of the chicken B-cell line, DT40. RAD54 participates in the recombinational repair of DNA double-strand breaks (DSBs), while members of the KU family of proteins are involved in nonhomologous end joining. Split-dose recovery was observed in the parent DT40 and the KU70-/- cells. Moreover, the split-dose survival enhancement had all of the characteristics demonstrated earlier for the repair of sublethal damage, e.g., the reappearance of the shoulder on the survival curve with dose fractionation; cyclic fluctuation in cell survival at 37 degrees C; repair and no cyclic fluctuation at 25 degrees C. These results strongly suggest that repair of sublethal damage is due to DSB repair mediated by homologous recombination, and that these DNA DSBs constitute sublethal damage.     

Homologous recombination protects mammalian cells from replication-associated DNA double-strand breaks arising in response to methyl methanesulfonate

DNA-methylating agents of the S_N2 type target DNA mostly at ring nitrogens, producing predominantly N-methylated purines. These adducts are repaired by base excision repair (BER). Since defects in BER cause accumulation of DNA single-strand breaks (SSBs) and sensitize cells to the agents, it has been suggested that some of the lesions on their own or BER intermediates (e.g. apurinic sites) are cytotoxic, blocking DNA replication and inducing replication-mediated DNA double-strand breaks (DSBs). Here, we addressed the question of whether homologous recombination (HR) or non-homologous end-joining (NHEJ) or both are involved in the repair of DSBs formed following treatment of cells with methyl methanesulfonate (MMS). We show that HR defective cells (BRCA2, Rad51D and XRCC3 mutants) are dramatically more sensitive to MMS-induced DNA damage as measured by colony formation, apoptosis and chromosomal aberrations, while NHEJ defective cells (Ku80 and DNA-PK_CS mutants) are only mildly sensitive to the killing, apoptosis-inducing and clastogenic effects of MMS. On the other hand, the HR mutants were almost completely refractory to the formation of sister chromatid exchanges (SCEs) following MMS treatment. Since DSBs are expected to be formed specifically in the S-phase, we assessed the formation and kinetics of repair of DSBs by γH2AX quantification in a cell cycle specific manner. In the cytotoxic dose range of MMS a significant amount of γH2AX foci was induced in S, but not G1- and G2-phase cells. A major fraction of γH2AX foci colocalized with 53BP1 and phosphorylated ATM, indicating they are representative of DSBs. DSB formation following MMS treatment was also demonstrated by the neutral comet assay. Repair kinetics revealed that HR mutants exhibit a significant delay in DSB repair, while NHEJ mutants completed S-phase specific DSB repair with a kinetic similar to the wildtype. Moreover, DNA-PKcs inhibition in HR mutants did not affect the repair kinetics after MMS treatment. Overall, the data indicate that agents producing N-alkylpurines in the DNA induce replication-dependent DSBs. Further, they show that HR is the major pathway of protection of cells against DSB formation, killing and genotoxicity following S_N2-alkylating agents.     

RNA-directed repair of DNA double-strand breaks

DNA double-strand breaks (DSBs) are among the most deleterious DNA lesions, which if unrepaired or repaired incorrectly can cause cell death or genome instability that may lead to cancer. To counteract these adverse consequences, eukaryotes have evolved a highly orchestrated mechanism to repair DSBs, namely DNA-damage-response (DDR). DDR, as defined specifically in relation to DSBs, consists of multi-layered regulatory modes including DNA damage sensors, transducers and effectors, through which DSBs are sensed and then repaired via DNAprotein interactions. Unexpectedly, recent studies have revealed a direct role of RNA in the repair of DSBs, including DSB-induced small RNA (diRNA)-directed and RNA-templated DNA repair. Here, we summarize the recent discoveries of RNA-mediated regulation of DSB repair and discuss the potential impact of these novel RNA components of the DSB repair pathway on genomic stability and plasticity.     

RNA polymerase III is required for the repair of DNA double-strand breaks by homologous recombination

1. Download : Download high-res image (94KB)
2. Download : Download full-size image

     

Different genetic requirements for repair of replication-born double-strand breaks by sister-chromatid recombination and break-induced replication

Homologous recombination (HR) is the major mechanism used to repair double-strand breaks (DSBs) that result from replication, but a study of repair of DSBs specifically induced during S-phase is lacking. Using an inverted-repeat assay in which a DSB is generated by the encountering of the replication fork with nicks, we can physically detect repair by sister-chromatid recombination (SCR) and intra-chromatid break-induced replication (IC-BIR). As expected, both events depend on Rad52, but, in contrast to previous data, both require Rad59, suggesting a prominent role of Rad59 in repair of replication-born DSBs. In the absence of Rad51, SCR is severely affected while IC-BIR increases, a phenotype that is also observed in the absence of Rad54 but not of its paralog Rdh54/Tid1. These data are consistent with SCR occurring by Rad51-dependent mechanisms assisted by Rad54, and indicate that in the absence of strand exchange-dependent SCR, breaks can be channeled to IC-BIR, which works efficiently in the absence of Rad51. Our study provides molecular evidence for inversions between repeats occurring by BIR followed by single-strand annealing (SSA) in the absence of strand exchange.     

Modeling the repair of radiation-induced DNA double-strand breaks

A problem often overlooked in the study of the repair of radiation-induced DNA double-strand breads (DSBs) is the question of what the status of a regular site is in the DNA duplex immediately after a radiation treatment. Here, we suggest a mixed repair mechanism which consists of a gradual process and an instantaneous process. A comparison of the present kinetic model with those which have appeared in the literature shows that the former is a generalization of the latter. We have shown that different repair mechanisms may lead to equivalent mathematical representations. Therefore, care must be taken in interpreting the repair mechanism on the basis of the experimentally observed transient number of DSBs.     

Induction of recombination between homologous and diverged DNAs by double-strand gaps and breaks and role of mismatch repair.

Sequence homology is expected to influence recombination. To further understand mechanisms of recombination and the impact of reduced homology, we examined recombination during transformation between plasmid-borne DNA flanking a double-strand break (DSB) or gap and its chromosomal homolog. Previous reports have concentrated on spontaneous recombination or initiation by undefined lesions. Sequence divergence of approximately 16% reduced transformation frequencies by at least 10-fold. Gene conversion patterns associated with double-strand gap repair of episomal plasmids or with plasmid integration were analyzed by restriction endonuclease mapping and DNA sequencing. For episomal plasmids carrying homeologous DNA, at least one input end was always preserved beyond 10 bp, whereas for plasmids carrying homologous DNA, both input ends were converted beyond 80 bp in 60% of the transformants. The system allowed the recovery of transformants carrying mixtures of recombinant molecules that might arise if heteroduplex DNA--a presumed recombination intermediate--escapes mismatch repair. Gene conversion involving homologous DNAs frequently involved DNA mismatch repair, directed to a broken strand. A mutation in the PMS1 mismatch repair gene significantly increased the fraction of transformants carrying a mixture of plasmids for homologous DNAs, indicating that PMS1 can participate in DSB-initiated recombination. Since nearly all transformants involving homeologous DNAs carried a single recombinant plasmid in both Pms+ and Pms- strains, stable heteroduplex DNA appears less likely than for homologous DNAs. Regardless of homology, gene conversion does not appear to occur by nucleolytic expansion of a DSB to a gap prior to recombination. The results with homeologous DNAs are consistent with a recombinational repair model that we propose does not require the formation of stable heteroduplex DNA but instead involves other homology-dependent interactions that allow recombination-dependent DNA synthesis.     

A pathway for generation and processing of double-strand breaks during meiotic recombination in S. cerevisiae

We have identified and analyzed a meiotic reciprocal recombination hot spot in S. cerevisiae. We find that double-strand breaks occur at two specific sites associated with the hot spot and that occurrence of these breaks depends upon meiotic recombination functions RAD50 and SPO11. Furthermore, these breaks occur in a processed form in wild-type cells and in a discrete, unprocessed form in certain nonnull rad50 mutants, rad50S, which block meiotic prophase at an intermediate stage. The breaks observed in wild-type cells are similar to those identified independently at another recombination hot spot, ARG4. We show here that the breaks at ARG4 also occur in discrete form in rad50S mutants. Occurrence of breaks in rad50S mutants is also dependent upon SPO11 function. These observations provide additional evidence that double-strand breaks are a prominent feature of meiotic recombination in yeast. More importantly, these observations begin to define a pathway for the physical changes in DNA that lead to recombination and to define the roles of meiotic recombination functions in that pathway.     

Chromatin remodeling and repair of DNA double-strand breaks

Eukaryotic cells have developed conserved mechanisms to efficiently sense and repair DNA damage that results from constant chromosomal lesions. DNA repair has to proceed in the context of chromatin, and both histone-modifiers and ATP-dependent chromatin remodelers have been implicated in this process. Here, we review the current understanding and new hypotheses on how different chromatin-modifying activities function in DNA repair in yeast and metazoan cells.     

DNA双链断裂修复与重症联合免疫缺陷

DNA双链断裂(double-strand breaks, DSBs)是细胞DNA损伤的主要类型,它的修复通过同源重组(HR)和非同源末端连接(NHEJ)两种机制实现.NHEJ是人和哺乳动物细胞DSBs修复的重要通路,主要由DNA依赖性蛋白激酶(DNA-PK)、X射线修复交叉互补蛋白4(XRCC4)、DNA连接酶Ⅳ、Artemis、XLF/Cernunnos和其它DNA损伤修复辅助因子组成.本文重点介绍了NHEJ机制主要成分的特性及其功能,以及这些组分的基因发生突变或缺失所引起的DSBs修复缺陷与辐射敏感性重症联合免疫缺陷(radiosensitive severe combined immunodeficiencies, RS-SCIDs).     

Homologous recombinational repair of double-strand breaks in yeast is enhanced by MAT heterozygosity through yKU-dependent and -independent mechanisms

DNA double-strand breaks (DSBs) are repaired by homologous recombination (HR) and nonhomologous end-joining (NHEJ). NHEJ in yeast chromosomes has been observed only when HR is blocked, as in rad52 mutants or in the absence of a homologous repair template. We detected yKu70p-dependent imprecise NHEJ at a frequency of approximately 0.1% in HR-competent Rad+ haploid cells. Interestingly, yku70 mutation increased DSB-induced HR between direct repeats by 1.3-fold in a haploid strain and by 1.5-fold in a MAT homozygous (a/a) diploid, but yku70 had no effect on HR in a MAT heterozygous (a/alpha) diploid. yku70 might increase HR because it eliminates the competing precise NHEJ (religation) pathway and/or because yKu70p interferes directly or indirectly with HR. Despite the yku70-dependent increase in a/a cells, HR remained 2-fold lower than in a/alpha cells. Cell survival was also lower in a/a cells and correlated with the reduction in HR. These results indicate that MAT heterozygosity enhances DSB-induced HR by yKu-dependent and -independent mechanisms, with the latter mechanism promoting cell survival. Surprisingly, yku70 strains survived a DSB slightly better than wild type. We propose that this reflects enhanced HR, not by elimination of precise NHEJ since this pathway produces viable products, but by elimination of yKu-dependent interference of HR.