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.     

Influence of non-homology between recombining DNA sequences on double-strand break repair in Saccharomyces cerevisiae

In this paper we study the influence of non-homology between plasmid and chromosomal DNA on the efficiency of recombinational repair of plasmid double-strand breaks and gaps in yeast. For this purpose we used different combinations of plasmids and yeast strains carrying various deletions within the yeast LYS2 gene. A 400 by deletion in plasmid DNA had no effect on recombinational plasmid repair. However, a 400 by deletion in chromosomal DNA dramatically reduced the efficiency of this repair mechanism, but recombinational repair of plasmids linearized by a double-strand break with cohesive ends still remained the dominant repair process. We have also studied the competition between recombination and ligation in the repair of linearized plasmids. Our experimental evidence suggests that recombinational repair is attempted but aborted if only one recombinogenic end with homology to chromosomal DNA is present in plasmid DNA. This situation results in a decreased probability of non-recombinational (i.e. ligation) repair of linearized plasmid DNA.     

Influence of non-homology between recombining DNA sequences on double-strand break repair in Saccharomyces cerevisiae

In this paper we study the influence of non-homology between plasmid and chromosomal DNA on the efficiency of recombinational repair of plasmid double-strand breaks and gaps in yeast. For this purpose we used different combinations of plasmids and yeast strains carrying various deletions within the yeast LYS2 gene. A 400 by deletion in plasmid DNA had no effect on recombinational plasmid repair. However, a 400 by deletion in chromosomal DNA dramatically reduced the efficiency of this repair mechanism, but recombinational repair of plasmids linearized by a double-strand break with cohesive ends still remained the dominant repair process. We have also studied the competition between recombination and ligation in the repair of linearized plasmids. Our experimental evidence suggests that recombinational repair is attempted but aborted if only one recombinogenic end with homology to chromosomal DNA is present in plasmid DNA. This situation results in a decreased probability of non-recombinational (i.e. ligation) repair of linearized plasmid DNA.     

Repair of sequence-specific 125I-induced double-strand breaks by nonhomologous DNA end joining in mammalian cell-free extracts

In mammalian cells, nonhomologous DNA end joining (NHEJ) is considered the major pathway of double-strand break (DSB) repair. Rejoining of DSB produced by decay of (125)I positioned against a specific target site in plasmid DNA via a triplex-forming oligonucleotide (TFO) was investigated in cell-free extracts from Chinese hamster ovary cells. The efficiency and quality of NHEJ of the "complex" DSB induced by the (125)I-TFO was compared with that of "simple" DSB induced by restriction enzymes. We demonstrate that the extracts are indeed able to rejoin (125)I-TFO-induced DSB, although at approximately 10-fold decreased efficiency compared with restriction enzyme-induced DSB. The resulting spectrum of junctions is highly heterogeneous exhibiting deletions (1-30 bp), base pair substitutions, and insertions and reflects the heterogeneity of DSB induced by the (125)I-TFO within its target site. We show that NHEJ of (125)I-TFO-induced DSB is not a random process that solely depends on the position of the DSB but is driven by the availability of microhomology patches in the target sequence. The similarity of the junctions obtained with the ones found in vivo after (125)I-TFO-mediated radiodamage indicates that our in vitro system may be a useful tool to elucidate the mechanisms of ionizing radiation-induced mutagenesis and repair.     

Control of sister chromatid recombination by histone H2AX

Histone H2AX has a role in suppressing genomic instability and cancer. However, the mechanisms by which it performs these functions are poorly understood. After DNA breakage, H2AX is phosphorylated on serine 139 in chromatin near the break. We show here that H2AX serine 139 enforces efficient homologous recombinational repair of a chromosomal double-strand break (DSB) by using the sister chromatid as a template. BRCA1, Rad51, and CHK2 contribute to recombinational repair, in part independently of H2AX. H2AX(-/-) cells show increased use of single-strand annealing, an error-prone deletional mechanism of DSB repair. Therefore, the chromatin response around a chromosomal DSB, in which H2AX serine 139 phosphorylation plays a central role, "shapes" the repair process in favor of potentially error-free interchromatid homologous recombination at the expense of error-prone repair. H2AX phosphorylation may help set up a favorable disposition between sister chromatids.     

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.     

The role of the repair of double-stranded DNA breaks in the radioresistance of yeast cells

The role of DNA double-strand break (DSB) repair in radioresistance of Saccharomyces cerevisiae G1 cells is discussed. The contribution of rapid and slow DNA DSB repair to radioresistance of diploid yeast has been estimated. The contribution of the DNA DSB repair involving no homologous chromosome interaction is shown to be insignificant in comparison with the recombinational repair. The rapid DNA DSB repair efficiency calculation method based on the proposed yeast radiation inactivation model is given. The calculations are in a satisfactory agreement with the experimental data. Possible mechanisms of radiation induction of lethal sectoring in yeast are discussed. This phenomenon is supposed to be due to the DNA DSB processing during vegetative division of irradiated cells. A general scheme of radiation inactivation of yeast cells is proposed.     

Homologous, homeologous, and illegitimate repair of double-strand breaks during transformation of a wild-type strain and a rad52 mutant strain of Saccharomyces cerevisiae.

Different modes of in vivo repair of double-strand breaks (DSBs) have been described for various organisms: the recombinational DSB repair (DSBR) mode, the single-strand annealing (SSA) mode, and end-to-end joining. To investigate these modes of DSB repair in Saccharomyces cerevisiae, we have examined the fate of in vitro linearized replicative plasmids during transformation with respect to several parameters. We found that (i) the efficiencies of both intramolecular and intermolecular linear plasmid DSB repair are homology dependent (according to the amount of DNA used during transformation [100 ng or less], recombination between similar but not identical [homeologous] P450s sequences sharing 73% identity is 2- to 18-fold lower than recombination between identical sequences); (ii) the RAD52 gene product is not essential for intramolecular recombination between homologous and homeologous direct repeats (as in the wild-type strain, recombination occurs with respect to the overall alignment of the parental sequences); (iii) in contrast, the RAD52 gene product is required for intermolecular interactions (the rare transformants which are obtained contain plasmids resulting from deletion-forming intramolecular events involving little or no sequence homology); (iv) similarly, sequencing data revealed examples of intramolecular joining within the few terminal nucleotides of the transforming DNA upon transformation with a linear plasmid with no repeat in the wild-type strain. The recombinant junctions of the rare illegitimate events obtained with S. cerevisiae are very similar to those observed in the repair of DSB in mammalian cells. Together, these and previous results suggest the existence of alternative modes for DSB repair during transformation which differ in their efficiencies and in the structure of their products. We discuss the implications of these results with respect to the existence of alternative pathways and the role of the RAD52 gene product.     

Mutations in two Ku homologs define a DNA end-joining repair pathway in Saccharomyces cerevisiae.

DNA double-strand break (DSB) repair in mammalian cells is dependent on the Ku DNA binding protein complex. However, the mechanism of Ku-mediated repair is not understood. We discovered a Saccharomyces cerevisiae gene (KU80) that is structurally similar to the 80-kDa mammalian Ku subunit. Ku8O associates with the product of the HDF1 gene, forming the major DNA end-binding complex of yeast cells. DNA end binding was absent in ku80delta, hdf1delta, or ku80delta hdf1delta strains. Antisera specific for epitope tags on Ku80 and Hdf1 were used in supershift and immunodepletion experiments to show that both proteins are directly involved in DNA end binding. In vivo, the efficiency of two DNA end-joining processes were reduced >10-fold in ku8Odelta, hdfldelta, or ku80delta hdf1delta strains: repair of linear plasmid DNA and repair of an HO endonuclease-induced chromosomal DSB. These DNA-joining defects correlated with DNA damage sensitivity, because ku80delta and hdf1delta strains were also sensitive to methylmethane sulfonate (MMS). Ku-dependent repair is distinct from homologous recombination, because deletion of KU80 and HDF1 increased the MMS sensitivity of rad52delta. Interestingly, rad5Odelta, also shown here to be defective in end joining, was epistatic with Ku mutations for MMS repair and end joining. Therefore, Ku and Rad50 participate in an end-joining pathway that is distinct from homologous recombinational repair. Yeast DNA end joining is functionally analogous to DSB repair and V(D)J recombination in mammalian cells.     

Multiple pathways for repair of DNA double-strand breaks in mammalian chromosomes

To study repair of DNA double-strand breaks (DSBs) in mammalian chromosomes, we designed DNA substrates containing a thymidine kinase (TK) gene disrupted by the 18-bp recognition site for yeast endonuclease I-SceI. Some substrates also contained a second defective TK gene sequence to serve as a genetic donor in recombinational repair. A genomic DSB was induced by introducing endonuclease I-SceI into cells containing a stably integrated DNA substrate. DSB repair was monitored by selection for TK-positive segregants. We observed that intrachromosomal DSB repair is accomplished with nearly equal efficiencies in either the presence or absence of a homologous donor sequence. DSB repair is achieved by nonhomologous end-joining or homologous recombination, but rarely by nonconservative single-strand annealing. Repair of a chromosomal DSB by homologous recombination occurs mainly by gene conversion and appears to require a donor sequence greater than a few hundred base pairs in length. Nonhomologous end-joining events typically involve loss of very few nucleotides, and some events are associated with gene amplification at the repaired locus. Additional studies revealed that precise religation of DNA ends with no other concomitant sequence alteration is a viable mode for repair of DSBs in a mammalian genome.     

Rapid assessment of two major repair activities against DNA double-strand breaks in vertebrate cells

A linearized plasmid DNA, in which tandem repeats of 400bp flank the breakpoints, was transfected into vertebrate cells, and breakpoint junctions of plasmid DNA circularized in the cells were analyzed to assess the repair activities against DNA double-strand break (DSB) by non-homologous end joining and homology-directed repair (i.e., homologous recombinational repair and single-strand annealing). The circularization by non-homologous end joining repair of the breakpoints depended on the expression of DNA-PKcs, while that by homology-directed repair through the repeats depended on the length of the repeats, indicating that these two DSB repair activities can be rapidly assessed by this assay. Predominance in circularization by either non-homologous end joining or homology-directed repair differed among cells examined, and circularization was exclusively undertaken by homology-directed repair in DT40 cells known to show a high homologous recombination rate against gene-targeting vectors. Thus, this assay will be helpful in studies on mechanisms and inter-cellular variations of DSB repair.     

Repair of dual-stranded DNA in Saccharomyces cerevisiae cells: homolog-dependent ligation and role of the RAD55 gene

In our previous works, a mutation in the RAD57 gene was shown to induce the plasmid DNA double-strand gap (DSG) repair via a special recombinational repair mechanism: homolog-dependent ligation responsible for reuniting disrupted plasmid ends without reconstructing the sequence lost because of the DSG. In this work, the role of the RAD55 gene in the plasmid DNA DSG repair was studied. A cold-sensitive rad55-3 mutation markedly decreased the precision of plasmid DNA DSG repair under conditions of restrictive temperature (23 degrees C): only 5-7% of plasmids can repair DSG, whereas under permissive conditions (36 degrees C), DSGs were repaired in approximately 50% of the cells. In the cold-sensitive mutation rad57-1, the proportion of plasmids in which DSGs were repaired was nearly the same under both permissive and restrictive conditions (5-10%). The results indicate that a disturbance in the function of the RAD55 gene, as in the RAD57 gene, leads to a drastic increase in the contribution of homolog-dependent ligation to the repair of double-strand DNA breaks.     

The dds20+ gene controls a novel Rad51Sp-dependent pathway of recombinational repair in Schizosaccharomyces pombe

Repair of DNA double-strand break (DSB) is an evolutionary conserved Rad51-mediated mechanism. In yeasts, Rad51 paralogs, Saccharomyces cerevisiae Rad55-Rad57 and Schizosaccharomyces pombe Rhp55-Rhp57 are mediators of the nucleoprotein RadS1 filament formation. As shown in this work, a novel RAD51Sp-dependent pathway of DSB repair acts in S. pombe parallel to the pathway mediated by Rad51 paralogs. A new gene dds20+ that controls this pathway was identified. The overexpression of dds20+ partially suppresses defects of mutant rhp55delta in DNA repair. Cells of dds20delta manifest hypersensitivity to a variety of genotoxins. Epistatic analysis revealed that dds20+ is a gene of the recombinational repair group. The role of Dds20 in repair of spontaneous damages occurring in the process of replication and mating-type switching remains unclear. The results obtained suggest that Dds20 has functions beyond the mitotic S phase. The Dds20 protein physically interacts with Rhp51 (Rad51Sp). Dds20 is assumed to operate at early recombinational stages and to play a specific role in the Rad51 protein filament assembly differing from that of Rad51 paralogs.     

Structure and organization of rhodophyte and chromophyte plastid genomes: implications for the ancestry of plastids

Summary Recombinational repair is the means by which DNA double-strand breaks (DSBs) are repaired in yeast. DNA divergence between chromosomes was shown previously to inhibit repair in diploid G1 cells, resulting in chromosome loss at low nonlethal doses of ionizing radiation. Furthermore, 15–20% divergence prevents meiotic recombination between individual pairs of Saccharomyces cerevisiae and S. carlsbergensis chromosomes in an otherwise S. cerevisiae background. Based on analysis of the efficiency of DSB-induced chromosome loss and direct genetic detection of intragenic recombination, we conclude that limited DSB recombinational repair can occur between homoeologous chromosomes. There is no difference in loss between a repair-proficient Pms⁺ strain and a mismatch repair mutant, pms1. Since DSB recombinational repair is tolerant of diverged DNAs, this type of repair could lead to novel genes and altered chromosomes. The sensitivity to DSB-induced loss of 11 individual yeast artificial chromosomes (YACs) containing mouse or human (chromosome 21 or HeLa) DNA was determined. Recombinational repair between a pair of homologous HeLa YACs appears as efficient as that between homologous yeast chromosomes in that there is no loss at low radiation doses. Single YACs exhibited considerable variation in response, although the response for individual YACs was highly reproducible. Based on the results with the yeast homoeologous chromosomes, we propose that the potential exists for intra- YAC recombinational repair between diverged repeat DNA and that the extent of repair is dependent upon the amount of repeat DNA and the degree of divergence. The sensitivity of YACs containing mammalian DNA to ionizing radiation-induced loss may thus be an indicator of the extent of repeat DNA.     

XRCC3 is required for efficient repair of chromosome breaks by homologous recombination

XRCC3 was originally identified as a human gene able to complement the DNA damage sensitivity, chromosomal instability and impaired growth of the mutant hamster cell line irs1SF. More recently, it has been cloned, sequenced and found to bear sequence homology to the highly conserved eukaryotic repair and recombination gene RAD51. The phenotype of irs1SF and the identification of XRCC3 as a member of the RAD51 gene family have suggested a role for XRCC3 in repair of DNA damage by homologous recombination. Homologous recombinational repair (HRR) of a specifically induced chromosomal double-strand break (DSB) was assayed in irs1SF cells with and without transient complementation by human XRCC3. Complementation with XRCC3 increased the frequencies of repair by 34- to 260-fold. The results confirm a role for XRCC3 in HRR of DNA DSB, and the importance of this repair pathway for the maintenance of chromosomal integrity in mammalian cells.     

The roles of REV3 and RAD57 in double-strand-break-repair-induced mutagenesis of Saccharomyces cerevisiae

The DNA synthesis associated with recombinational repair of chromosomal double-strand breaks (DSBs) has a lower fidelity than normal replicative DNA synthesis. Here, we use an inverted-repeat substrate to monitor the fidelity of repair of a site-specific DSB. DSB induction made by the HO endonuclease stimulates recombination >5000-fold and is associated with a >1000-fold increase in mutagenesis of an adjacent gene. We demonstrate that most break-repair-induced mutations (BRIMs) are point mutations and have a higher proportion of frameshifts than do spontaneous mutations of the same substrate. Although the REV3 translesion DNA polymerase is not required for recombination, it introduces approximately 75% of the BRIMs and approximately 90% of the base substitution mutations. Recombinational repair of the DSB is strongly dependent upon genes of the RAD52 epistasis group; however, the residual recombinants present in rad57 mutants are associated with a 5- to 20-fold increase in BRIMs. The spectrum of mutations in rad57 mutants is similar to that seen in the wild-type strain and is similarly affected by REV3. We also find that REV3 is required for the repair of MMS-induced lesions when recombinational repair is compromised. Our data suggest that Rad55p/Rad57p help limit the generation of substrates that require pol zeta during recombination.     

Recombinational and mutagenic repair of psoralen interstrand cross-links in Saccharomyces cerevisiae

Psoralen photoreacts with DNA to form interstrand cross-links, which can be repaired by both nonmutagenic nucleotide excision repair and recombinational repair pathways and by mutagenic pathways. In the yeast Saccharomyces cerevisiae, psoralen cross-links are processed by nucleotide excision repair to form double-strand breaks (DSBs). In yeast, DSBs are repaired primarily by homologous recombination, predicting that cross-link and DSB repair should induce similar recombination end points. We compared psoralen cross-link, psoralen monoadduct, and DSB repair using plasmid substrates with site-specific lesions and measured the patterns of gene conversion, crossing over, and targeted mutation. Psoralen cross-links induced both recombination and mutations, whereas DSBs induced only recombination, and monoadducts were neither recombinogenic nor mutagenic. Although the cross-link- and DSB-induced patterns of plasmid integration and gene conversion were similar in most respects, they showed opposite asymmetries in their unidirectional conversion tracts: primarily upstream from the damage site for cross-links but downstream for DSBs. Cross-links induced targeted mutations in 5% of the repaired plasmids; all were base substitutions, primarily T --> C transitions. The major pathway of psoralen cross-link repair in yeast is error-free and involves the formation of DSB intermediates followed by homologous recombination. A fraction of the cross-links enter an error-prone pathway, resulting in mutations at the damage site.     

Coordination of DNA ends during double-strand-break repair in bacteriophage T4

The extensive chromosome replication (ECR) model of double-strand-break repair (DSBR) proposes that each end of a double-strand break (DSB) is repaired independently by initiating extensive semiconservative DNA replication after strand invasion into homologous template DNA. In contrast, several other DSBR models propose that the two ends of a break are repaired in a coordinated manner using a single repair template with only limited DNA synthesis. We have developed plasmid and chromosomal recombinational repair assays to assess coordination of the broken ends during DSBR in bacteriophage T4. Results from the plasmid assay demonstrate that the two ends of a DSB can be repaired independently using homologous regions on two different plasmids and that extensive replication is triggered in the process. These findings are consistent with the ECR model of DSBR. However, results from the chromosomal assay imply that the two ends of a DSB utilize the same homologous repair template even when many potential templates are present, suggesting coordination of the broken ends during chromosomal repair. This result is consistent with several coordinated models of DSBR, including a modified version of the ECR model.     

The Saccharomyces cerevisiae PDS1 and RAD9 checkpoint genes control different DNA double-strand break repair pathways

In response to DNA damage, the Saccharomyces cerevisiae securin Pds1 blocks anaphase promotion by inhibiting ESP1-dependent degradation of cohesins. PDS1 is positioned downstream of the MEC1- and RAD9-mediated DNA damage-induced signal transduction pathways. Because cohesins participate in postreplicative repair and the pds1 mutant is radiation sensitive, we identified DNA repair pathways that are PDS1-dependent. We compared the radiation sensitivities and recombination phenotypes of pds1, rad9, rad51 single and double mutants, and found that whereas pds1 rad9 double mutants were synergistically more radiation sensitive than single mutants, pds1 rad51 mutants were not. To determine the role of PDS1 in recombinational repair pathways, we measured spontaneous and DNA damage-associated sister chromatid exchanges (SCEs) after exposure to X rays, UV and methyl methanesulfonate (MMS) and after the initiation of an HO endonuclease-generated double-strand break (DSB). The rates of spontaneous SCE and frequencies of DNA damage-associated SCE were similar in wild type and pds1 strains, but the latter exhibited reduced viability after exposure to DNA damaging agents. To determine whether pds1 mutants were defective in other pathways for DSB repair, we measured both single-strand annealing (SSA) and non-homologous end joining (NHEJ) in pds1 mutants. We found that the pds1 mutant was defective in SSA but efficient at ligating cohesive ends present on a linear plasmid. We therefore suggest that checkpoint genes control different pathways for DSB repair, and PDS1 and RAD9 have different roles in recombinational repair.