Repair of double-strand breaks by incorporation of a molecule of homologous DNA

An in vitro system based upon extracts of Escherichia coli infected with bacteriophage T7 was used to monitor repair of double-strand breaks in the T7 genome. The efficiency of double-strand break repair was markedly increased by DNA molecules ('donor' DNA) consisting of a 2.1 kb DNA fragment, generated by PCR, that had ends extending approximately 1 kb on either side of the break site. Repair proceeded with greater than 10% efficiency even when T7 DNA replication was inhibited. When the donor DNA molecules were labelled with 32P, repaired genomes incorporated label only near the site of the double-strand break. When repair was carried out with unlabelled donor DNA and [32P]-dCTP provided as precursor for DNA synthesis the small amount of incorporated label was distributed randomly throughout the entire T7 genome. Repair was performed using donor DNA that had adjacent BamHI and PstI sites. When the BamHI site was methylated and the PstI site was left unmethylated, the repaired genomes were sensitive to PstI but not to BamHI endonuclease, showing that the methyl groups at the BamHI recognition site had not been replaced by new DNA synthesis during repair of the double-strand break. These observations are most consistent with a model for double-strand break repair in which the break is widened to a small gap, which is subsequently repaired by physical incorporation of a patch of donor DNA into the gap.     

DNA双链断裂损伤修复系统研究进展

多种内源或外源因素都能造成细胞基因组DNA损伤,细胞内建立了复杂的修复系统来应对不同形式的损伤。其中DNA双链断裂(DNA double-strand breaks,DSBs)作为最严重的损伤形式,主要激活同源重组修复(Homologous recombination repair)和非同源末端连接(Non-homologous end joining)通路。这两条通路都是由多个修复元件参与、经过多步反应的复杂过程。两者各具特点、协同作用,共同维护细胞基因组的稳定性。对其分子机制的阐明为肿瘤放化疗的辅助治疗提供了潜在的作用靶点。     

Repair of bleomycin-induced DNA double-strand breaks in Vicia faba

As detected by neutral DNA elution, bleomycin induced at the concentrations tested (5, 10 and 50 micrograms/ml) DNA double-strand breaks (dsbs) in in vitro cultured embryos of V. faba. Most of these breaks were repaired during a 4-h incubation period after treatment. Dsbs also occurred after treatment with 2.5 and 5 mM of N-methyl-N-nitrosourea (MNU) but in contrast to those induced by bleomycin, these dsbs remained unrepaired during the 4-h incubation period following the treatment.     

Repair of double-strand breaks by homologous recombination in mismatch repair-defective mammalian cells

Chromosomal double-strand breaks (DSBs) stimulate homologous recombination by several orders of magnitude in mammalian cells, including murine embryonic stem (ES) cells, but the efficiency of recombination decreases as the heterology between the repair substrates increases (B. Elliott, C. Richardson, J. Winderbaum, J. A. Nickoloff, and M. Jasin, Mol. Cell. Biol. 18:93-101, 1998). We have now examined homologous recombination in mismatch repair (MMR)-defective ES cells to investigate both the frequency of recombination and the outcome of events. Using cells with a targeted mutation in the msh2 gene, we found that the barrier to recombination between diverged substrates is relaxed for both gene targeting and intrachromosomal recombination. Thus, substrates with 1.5% divergence are 10-fold more likely to undergo DSB-promoted recombination in Msh2(-/-) cells than in wild-type cells. Although mutant cells can repair DSBs efficiently, examination of gene conversion tracts in recombinants demonstrates that they cannot efficiently correct mismatched heteroduplex DNA (hDNA) that is formed adjacent to the DSB. As a result, >20-fold more of the recombinants derived from mutant cells have uncorrected tracts compared with recombinants from wild-type cells. The results indicate that gene conversion repair of DSBs in mammalian cells frequently involves mismatch correction of hDNA rather than double-strand gap formation. In cells with MMR defects, therefore, aberrant recombinational repair may be an additional mechanism that contributes to genomic instability and possibly tumorigenesis.     

Repair of HZE-particle-induced DNA double-strand breaks in normal human fibroblasts

DNA damage generated by high-energy and high-Z (HZE) particles is more skewed toward multiply damaged sites or clustered DNA damage than damage induced by low-linear energy transfer (LET) X and gamma rays. Clustered DNA damage includes abasic sites, base damages and single- (SSBs) and double-strand breaks (DSBs). This complex DNA damage is difficult to repair and may require coordinated recruitment of multiple DNA repair factors. As a consequence of the production of irreparable clustered lesions, a greater biological effectiveness is observed for HZE-particle radiation than for low-LET radiation. To understand how the inability of cells to rejoin DSBs contributes to the greater biological effectiveness of HZE particles, the kinetics of DSB rejoining and cell survival after exposure of normal human skin fibroblasts to a spectrum of HZE particles was examined. Using gamma-H2AX as a surrogate marker for DSB formation and rejoining, the ability of cells to rejoin DSBs was found to decrease with increasing Z; specifically, iron-ion-induced DSBs were repaired at a rate similar to those induced by silicon ions, oxygen ions and gamma radiation, but a larger fraction of iron-ion-induced damage was irreparable. Furthermore, both DNA-PKcs (DSB repair factor) and 53BP1 (DSB sensing protein) co-localized with gamma-H2AX along the track of dense ionization produced by iron and silicon ions and their focus dissolution kinetics was similar to that of gamma-H2AX. Spatial co-localization analysis showed that unlike gamma-H2AX and 53BP1, phosphorylated DNA-PKcs was localized only at very specific regions, presumably representing the sites of DSBs within the tracks. Examination of cell survival by clonogenic assay indicated that cell killing was greater for iron ions than for silicon and oxygen ions and gamma rays. Collectively, these data demonstrate that the inability of cells to rejoin DSBs within clustered DNA lesions likely contributes to the greater biological effectiveness of HZE particles.     

Repair of radiation-induced DNA double-strand breaks is dependent upon radiation quality and the structural complexity of double-strand breaks

Mammalian cells primarily repair DSBs by nonhomologous end joining (NHEJ). To assess the ability of human cells to mediate end joining of complex DSBs such as those produced by chemicals, oxidative events, or high- and low-LET radiation, we employed an in vitro double-strand break repair assay using plasmid DNA linearized by these various agents. We found that human HeLa cell extracts support end joining of complex DSBs and form multimeric plasmid products from substrates produced by the radiomimetic drug bleomycin, 60Co gamma rays, and the effects of 125I decay in DNA. End joining was found to be dependent on the type of DSB-damaging agent, and it decreased as the cytotoxicity of the DSB-inducing agent increased. In addition to the inhibitory effects of DSB end-group structures on repair, NHEJ was found to be strongly inhibited by lesions proximal to DSB ends. The initial repair rate for complex non-ligatable bleomycin-induced DSBs was sixfold less than that of similarly configured (blunt-ended) but less complex (ligatable) restriction enzyme-induced DSBs. Repair of DSBs produced by gamma rays was 15-fold less efficient than repair of restriction enzyme-induced DSBs. Repair of the DSBs produced by 125I was near the lower limit of detection in our assay and was at least twofold lower than that of gamma-ray-induced DSBs. In addition, DSB ends produced by 125I were shown to be blocked by 3'-nucleotide fragments: the removal of these by E. coli endonuclease IV permitted ligation.     

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.     

Repair of DNA double-strand breaks in colcemid-arrested mitotic Chinese hamster cells

Chinese hamster V79 cells blocked in mitosis were irradiated with 60Co gamma-rays and incubated for repair in the presence of colcemid. DNA strand breaks were measured using neutral sucrose gradient centrifugation or the alkaline unwinding technique. It was found that mitotic cells repair DNA double-strand breaks (as well as single-strand breaks) efficiently, with a rate similar to exponentially growing asynchronous cells. It is argued that the dense packing of the chromatin in the mitotic chromosome makes a recombinational repair mechanism unlikely.     

Repair of DNA double-strand breaks in Escherichia coli K12 requires a functional recN product

Summary Mutation of the recN gene of Escherichia coli in a recBC sbcB genetic background blocks conjugational recombination and confers increased sensitivity to UV light and mitomycin C. The basis for this phenotype was investigated by monitoring the properties associated with recN mutations in otherwise wild-type strains. It was established that recN single mutants are almost fully resistant to UV irradiation, and that there is no detectable defect in repair of UV lesions by excision, error-prone, or recombinational mechanisms. However, recN mutations confer sensitivity to mitomycin C and ionizing radiation both in wild-type and recB sbcB strains. The sensitivity to ionizing radiation is correlated with a deficiency in the capacity to repair DNA double-strand breaks by a UV inducible mechanism. Recombinant phages that complement the recombination and repair defects of recN recBC sbcB mutants have been identified, and the recN gene has been cloned from these phages into a low copy-number plasmid.     

Increased mobility of double-strand breaks requires Mec1, Rad9 and the homologous recombination machinery

Chromatin mobility is thought to facilitate homology search during homologous recombination and to shift damage either towards or away from specialized repair compartments. However, unconstrained mobility of double-strand breaks could also promote deleterious chromosomal translocations. Here we use live time-lapse fluorescence microscopy to track the mobility of damaged DNA in budding yeast. We found that a Rad52-YFP focus formed at an irreparable double-strand break moves in a larger subnuclear volume than the undamaged locus. In contrast, Rad52-YFP bound at damage arising from a protein-DNA adduct shows no increase in movement. Mutant analysis shows that enhanced double-strand-break mobility requires Rad51, the ATPase activity of Rad54, the ATR homologue Mec1 and the DNA-damage-response mediator Rad9. Consistent with a role for movement in the homology-search step of homologous recombination, we show that recombination intermediates take longer to form in cells lacking Rad9.     

Repair of site-specific double-strand breaks in a mammalian chromosome by homologous and illegitimate recombination.

In mammalian cells, chromosomal double-strand breaks are efficiently repaired, yet little is known about the relative contributions of homologous recombination and illegitimate recombination in the repair process. In this study, we used a loss-of-function assay to assess the repair of double-strand breaks by homologous and illegitimate recombination. We have used a hamster cell line engineered by gene targeting to contain a tandem duplication of the native adenine phosphoribosyltransferase (APRT) gene with an I-SceI recognition site in the otherwise wild-type APRT+ copy of the gene. Site-specific double-strand breaks were induced by intracellular expression of I-SceI, a rare-cutting endonuclease from the yeast Saccharomyces cerevisiae. I-SceI cleavage stimulated homologous recombination about 100-fold; however, illegitimate recombination was stimulated more than 1,000-fold. These results suggest that illegitimate recombination is an important competing pathway with homologous recombination for chromosomal double-strand break repair in mammalian cells.     

Repair of double-strand breaks in plasmid DNA in the yeast Saccharomyces cerevisiae

Summary We studied the repair of double-strand breaks (DSB) in plasmid DNA introduced into haploid cells of the yeast Saccharomyces cerevisiae. The efficiency of repair was estimated from the frequency of transformation of the cells by an autonomously replicated linearized plasmid. The frequency of lithium transformation of Rad⁺ cells was increased greatly (by 1 order of magnitude and more) compared with that for circular DNA if the plasmid was initially linearized at the XhoI site within the LYS2 gene. This effect is due to recombinational repair of the plasmid DNA. Mutations rad52, rad53, rad54 and rad57 suppress the repair of DSB in plasmid DNA. The kinetics of DSB repair in plasmid DNA are biphasic: the first phase is completed within 1 h and the second within 14–18 h of incubating cells on selective medium.     

The processing of DNA ends at double-strand breaks during homologous recombination: different roles for the two ends

We have investigated the role of DNA ends during gap repair by homologous recombination. Mouse cells were transfected with a gapped plasmid carrying distinctive ends: on one side mouse LINE-1 repetitive sequences (LlMd-A2), and on the other rat LINE-1 sequences (LlRn-3). The gap could be repaired by homologous recombination with endogenous mouse genomic LINE-1 elements, which are on average 95% and 85% homologous to LlMd-A2 and LlRn-3 ends, respectively. Both LlMd-A2 and LlRn-3 ends were found to initiate gap repair with equal efficiency. However, there were two types of gap repair products – precise and imprecise – the occurrence of which appears to depend on which end had been used for initiation and thus which end was left available for subsequent steps in recombination. These results, together with sequence analysis of recombinants obtained with plasmids having either mouse or rat LINE-1 sequences flanking the gap, strongly suggest that the two DNA ends played different roles in recombinational gap repair. One end was used to initiate the gap repair process, while the other end was involved at later steps, in the resolution of the recombination event. Received: 16 April 1997 / Accepted: 24 June 1997     

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.     

DNA mismatch repair-induced double-strand breaks

Escherichia coli dam mutants are sensitized to the cytotoxic action of base analogs, cisplatin and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), while their mismatch repair (MMR)-deficient derivatives are tolerant to these agents. We showed previously, using pulse field gel electrophoresis (PFGE), that MMR-mediated double-strand breaks (DSBs) are produced by cisplatin in dam recB(Ts) cells at the non-permissive temperature. We demonstrate here that the majority of these DSBs require DNA replication for their formation, consistent with a model in which replication forks collapse at nicks or gaps formed during MMR. DSBs were also detected in dam recB(Ts) ada ogt cells exposed to MNNG in a dose- and MMR-dependent manner. In contrast to cisplatin, the formation of these DSBs was not affected by DNA replication and it is proposed that two separate mechanisms result in DSB formation. Replication-independent DSBs arise from overlapping base excision and MMR repair tracts on complementary strands and constitute the majority of detectable DSBs in dam recB(Ts) ada ogt cells exposed to MNNG. Replication-dependent DSBs result from replication fork collapse at O(6)-methylguanine (O(6)-meG) base pairs undergoing MMR futile cycling and are more likely to contribute to cytotoxicity. This model is consistent with the observation that fast-growing dam recB(Ts) ada ogt cells, which have more chromosome replication origins, are more sensitive to the cytotoxic effect of MNNG than the same cells growing slowly.     

Repair of DNA double-strand breaks in Escherichia coli, which requires recA function and the presence of a duplicate genome.

A method was devised for extracting, from cells of Escherichia coli K12, DNA molecules which sedimented on neutral sucrose gradients as would be expected for free DNA molecules approaching the genome in size. Gamma ray irradiation of oxygenated cells produced 0.20 DNA double-strand breaks per kilorad per 10⁹ daltons. Incubation after irradiation of cells grown in K medium, with four to five genomes per cell, showed repair of the double-strand breaks. No repair of double-strand breaks was found in cells grown in aspartate medium, with only 1.3 genomes per cell, although DNA single-strand breaks were still efficiently repaired. Cells which were recA^? or recA^?recB^? also did not repair double-strand breaks. These results suggest that repair of DNA double-strand breaks may occur by a recombinational event involving another DNA double helix with the same base sequence.