Processing of branched DNA intermediates by a complex of human FEN-1 and PCNA.

In eukaryotic cells, a 5' flap DNA endonuclease activity and a ds DNA 5'-exonuclease activity exist within a single enzyme called FEN-1 [flap endo-nuclease and 5(five)'-exo-nuclease]. This 42 kDa endo-/exonuclease, FEN-1, is highly homologous to human XP-G, Saccharomyces cerevisiae RAD2 and S.cerevisiae RTH1. These structure-specific nucleases recognize and cleave a branched DNA structure called a DNA flap, and its derivative called a pseudo Y-structure. FEN-1 is essential for lagging strand DNA synthesis in Okazaki fragment joining. FEN-1 also appears to be important in mismatch repair. Here we find that human PCNA, the processivity factor for eukaryotic polymerases, physically associates with human FEN-1 and stimulates its endonucleolytic activity at branched DNA structures and its exonucleolytic activity at nick and gap structures. Structural requirements for FEN-1 and PCNA loading provide an interesting picture of this stimulation. PCNA loads on to substrates at double-stranded DNA ends. In contrast, FEN-1 requires a free single-stranded 5' terminus and appears to load by tracking along the single-stranded DNA branch. These physical constraints define the range of DNA replication, recombination and repair processes in which this family of structure-specific nucleases participate. A model explaining the exonucleolytic activity of FEN-1 in terms of its endonucleolytic activity is proposed based on these observations.     

Saccharomyces cerevisiae RAD27 complements its Escherichia coli homolog in damage repair but not mutation avoidance

In eukaryotes, the flap endonuclease of Rad27/Fen-1 is thought to play a critical role in lagging-strand DNA replication by removing ribonucleotides present at the 5' ends of Okazaki fragments, and in base excision repair by cleaving a 5' flap structure that may result during base excision repair. Saccharomyces cerevisiae rad27Delta mutants further display a repeat tract instability phenotype and a high rate of forward mutations to canavanine resistance that result from duplications of DNA sequence, indicating a role in mutation avoidance. Two conserved motifs in Rad27/Fen-1 show homology to the 5' --> 3' exonuclease domain of Escherichia coli DNA polymerase I. The strain defective in the 5' --> 3' exonuclease domain in DNA polymerase I shows essentially the same phenotype as the yeast rad27Delta strain. In this study, we expressed the yeast RAD27 gene in an E. coli strain lacking the 5' --> 3' exonuclease domain in DNA polymerase I in order to test whether eukaryotic RAD27/FEN-1 can complement the defect of its bacterial homolog. We found that the yeast Rad27 protein complements sensitivity to methyl methanesulfonate in an E. coli mutant. On the other hand, Rad27 protein did not reduce the high rate of spontaneous mutagenesis in the E. coli tonB gene which results from duplication of DNA. These results indicate that the yeast Rad27 and E. coli 5' --> 3' exonuclease act on the same substrate. We argue that the lack of mutation avoidance of yeast RAD27 in E. coli results from a lack of interaction between the yeast Rad27 protein and the E. coli replication clamp (beta-clamp).     

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     

Control of DNA end resection by yeast Hmo1p affects efficiency of DNA end-joining

The primary pathways for DNA double strand break (DSB) repair are homologous recombination (HR) and non-homologous end–joining (NHEJ). The choice between HR and NHEJ is influenced by the extent of DNA end resection, as extensive resection is required for HR but repressive to NHEJ. Conversely, association of the DNA end-binding protein Ku, which is integral to classical NHEJ, inhibits resection. In absence of key NHEJ components, a third repair pathway is exposed; this alternative-end joining (A-EJ) is a highly error-prone process that uses micro-homologies at the breakpoints and is initiated by DNA end resection. In Saccharomyces cerevisiae, the high mobility group protein Hmo1p has been implicated in controlling DNA end resection, suggesting its potential role in repair pathway choice. Using a plasmid end-joining assay, we show here that absence of Hmo1p results in reduced repair efficiency and accuracy, indicating that Hmo1p promotes end-joining; this effect is only observed on DNA with protruding ends. Notably, inhibition of DNA end resection in an hmo1Δ strain restores repair efficiency to the levels observed in wild-type cells. In absence of Ku, HMO1 deletion also reduces repair efficiency further, while inhibition of resection restores repair efficiency to the levels observed in kuΔ. We suggest that Hmo1p functions to control DNA end resection, thereby preventing error-prone A-EJ repair and directing repairs towards classical NHEJ. The very low efficiency of DSB repair in kuΔhmo1Δ cells further suggests that excessive DNA resection is inhibitory for A-EJ.     

Model for homologous recombination during transfer of DNA into mouse L cells: role for DNA ends in the recombination process.

We have constructed phage lambda and plasmid DNA substrates (lambda tk2 and ptk2) that contain two defective herpesvirus thymidine kinase (tk) genes that can be used to detect homologous recombination during the transfer of DNA into mouse L cells deficient in thymidine kinase activity. The recombination event reconstructs a wild-type tk gene and is scored because it converts Tk- cells to Tk+. Using this system, we have shown that (i) both intramolecular and intermolecular homologous recombination can be detected after gene transfer; (ii) the degree of recombination decreases with decreasing tk gene homology; and (iii) the efficiency of recombination can be stimulated 10- to 100-fold by cutting the tk2 DNA with restriction enzymes at appropriate sites relative to the recombining sequences. Based on the substrate requirements for these recombination events, we propose a model to explain how recombination might occur in mammalian cells. The essential features of the model are that the cut restriction site ends are substrates for cellular exonucleases that degrade DNA strands. This process exposes complementary strands of the two defective tk genes, which then pair. Removal of unpaired DNA at the junction between the paired and unpaired regions permits a gap repair process to reconstruct an intact gene.     

Cellular response to horizontally transferred DNA in Escherichia coli is tuned by DNA repair systems

We studied how DNA divergence between recombining DNAs and the mismatch repair system modulate the SOS response in Escherichia coli. The observed positive log-linear correlation between SOS induction and DNA divergence, and the negative correlation between SOS induction and frequency of recombination, suggest that the level of SOS induction precisely reflects the difficulty of RecA protein to initiate a productive strand exchange process. Our results suggest that the mismatch repair system could contribute to this SOS induction more by affecting the RecA-catalyzed homology search than by acting on mismatched recombination intermediates. The propensity of the recombination machinery to promote recombination between the blocks of sequences with the highest identity results in the increasing ratios of merodiploids (partial diploids) over genuine recombinants (homologous replacements) with increasing DNA divergence. We discuss the role of molecular mechanisms involved in the control of the recombination between diverged DNA sequences in the maintenance of genomic stability and genome evolution.     

Defective flap endonuclease 1 activity in mammalian cells is associated with impaired DNA repair and prolonged S phase delay.

Flap endonuclease 1 (FEN-1) is a 5'-3' flap exo-/endonuclease that plays an important role in Okazaki fragment maturation, nonhomologous end joining of double-stranded DNA breaks, and long patch base excision repair. Here, we demonstrate that the wild type FEN-1 binds tightly to chromatin in conjunction with proliferating cell nuclear antigen (PCNA) recruitment after MMS treatment, and the nuclease-defective FEN-1 increased the sensitivity of the cells to methylmethane sulfonate (MMS) and to UV light but not to ionizing radiation. In contrast, the cells expressing the nuclease-defective and PCNA binding-defective double mutant FEN-1 exhibited sensitivities similar to those in the cells expressing the wild type FEN-1. MMS treatment caused a prolonged delay of S phase progression and impairment in colony-forming activity of cells expressing nuclease-defective FEN-1. A comet assay demonstrated that DNA repair after MMS or UV treatment was impaired in the cells expressing nuclease-deficient FEN-1 but not in the cells with double-mutated FEN-1. Taken together, these findings suggest that FEN-1 plays an essential role in the DNA repair processes in mammalian cells and that this activity of FEN-1 is PCNA-dependent.     

Homology Search and Choice of Homologous Partner during Mitotic Recombination

Homologous recombination is an important DNA repair mechanism in vegetative cells. During the repair of double-strand breaks, genetic information is transferred between the interacting DNA sequences (gene conversion). This event is often accompanied by a reciprocal exchange between the homologous molecules, resulting in crossing over. The repair of DNA damage by homologous recombination with repeated sequences dispersed throughout the genome might result in chromosomal aberrations or in the inactivation of genes. It is therefore important to understand how the suitable homologous partner for recombination is chosen. We have developed a system in the yeast Saccharomyces cerevisiae that can monitor the fate of a chromosomal double-strand break without the need to select for recombinants. The broken chromosome is efficiently repaired by recombination with one of two potential partners located elsewhere in the genome. One of the partners has homology to the broken ends of the chromosome, whereas the other is homologous to sequences distant from the break. Surprisingly, a large proportion of the repair is carried out by recombination involving the sequences distant from the broken ends. This repair is very efficient, despite the fact that it requires the processing of a large chromosomal region flanking the break. Our results imply that the homology search involves extensive regions of the broken chromosome and is not carried out exclusively by sequences adjacent to the double-strand break. We show that the mechanism that governs the choice of homologous partners is affected by the length and sequence divergence of the interacting partners, as well as by mutations in the mismatch repair genes. We present a model to explain how the suitable homologous partner is chosen during recombinational repair. The model provides a mechanism that may guard the integrity of the genome by preventing recombination between dispersed repeated sequences.     

Affinity labeling of flap-endonuclease FEN-1 by photoreactive DNAs

Eukaryotic flap-endonuclease (FEN-1) is 42-kD single-subunit structure-specific nuclease that cleaves 5"-flap strands of the branched DNA structure and possesses 5"-exonuclease activity. FEN-1 participates in DNA replication, repair, and recombination. The interaction of FEN-1 with DNA structures generated during replication and repair was studied using two types of photoreactive oligonucleotides. Oligonucleotides bearing a photoreactive arylazido group at the 3"-end of the primer were synthesized in situ by the action of DNA polymerase using base-substituted photoreactive dUTP analogs as the substrates. The photoreactive group was also bound to the 5"-end phosphate group of the oligonucleotide by chemical synthesis. Interaction of FEN-1 with both 5"- and 3"-ends of the nick or with primer–template systems containing 5"- or 3"-protruding DNA strands was shown. Formation of a structure with the 5"-flap containing the photoreactive group results in decrease of the level of protein labeling caused by cleavage of the photoreactive group due to FEN-1 endonuclease activity. Photoaffinity labeling of proteins of mouse fibroblast cell extract was performed using the radioactively labeled DNA duplex with the photoreactive group at the 3"-end and the apurine/apyrimidine site at the 5"-end of the nick. This structure is a photoreactive analog of an intermediate formed during DNA repair and was generated by the action of cell enzymes from the initial DNA duplex containing the 3-hydroxy-2-hydroxymethyltetrahydrofurane residue. FEN-1 is shown to be one of the photolabeled proteins; this indicates possible participation of this enzyme in base excision repair.     

The interaction site of Flap Endonuclease-1 with WRN helicase suggests a coordination of WRN and PCNA

Werner and Bloom syndromes are genetic RecQ helicase disorders characterized by genomic instability. Biochemical and genetic data indicate that an important protein interaction of WRN and Bloom syndrome (BLM) helicases is with the structure-specific nuclease Flap Endonuclease 1 (FEN-1), an enzyme that is implicated in the processing of DNA intermediates that arise during cellular DNA replication, repair and recombination. To acquire a better understanding of the interaction of WRN and BLM with FEN-1, we have mapped the FEN-1 binding site on the two RecQ helicases. Both WRN and BLM bind to the extreme C-terminal 18 amino acid tail of FEN-1 that is adjacent to the PCNA binding site of FEN-1. The importance of the WRN/BLM physical interaction with the FEN-1 C-terminal tail was confirmed by functional interaction studies with catalytically active purified recombinant FEN-1 deletion mutant proteins that lack either the WRN/BLM binding site or the PCNA interaction site. The distinct binding sites of WRN and PCNA and their combined effect on FEN-1 nuclease activity suggest that they may coordinately act with FEN-1. WRN was shown to facilitate FEN-1 binding to its preferred double-flap substrate through its protein interaction with the FEN-1 C-terminal binding site. WRN retained its ability to physically bind and stimulate acetylated FEN-1 cleavage activity to the same extent as unacetylated FEN-1. These studies provide new insights to the interaction of WRN and BLM helicases with FEN-1, and how these interactions might be regulated with the PCNA–FEN-1 interaction during DNA replication and repair.     

Microhomology-mediated end joining in fission yeast is repressed by pku70 and relies on genes involved in homologous recombination

Two DNA repair pathways are known to mediate DNA double-strand-break (DSB) repair: homologous recombination (HR) and nonhomologous end joining (NHEJ). In addition, a nonconservative backup pathway showing extensive nucleotide loss and relying on microhomologies at repair junctions was identified in NHEJ-deficient cells from a variety of organisms and found to be involved in chromosomal translocations. Here, an extrachromosomal assay was used to characterize this microhomology-mediated end-joining (MMEJ) mechanism in fission yeast. MMEJ was found to require at least five homologous nucleotides and its efficiency was decreased by the presence of nonhomologous nucleotides either within the overlapping sequences or at DSB ends. Exo1 exonuclease and Rad22, a Rad52 homolog, were required for repair, suggesting that MMEJ is related to the single-strand-annealing (SSA) pathway of HR. In addition, MMEJ-dependent repair of DSBs with discontinuous microhomologies was strictly dependent on Pol4, a PolX DNA polymerase. Although not strictly required, Msh2 and Pms1 mismatch repair proteins affected the pattern of MMEJ repair. Strikingly, Pku70 inhibited MMEJ and increased the minimal homology length required for efficient MMEJ. Overall, this study strongly suggests that MMEJ does not define a distinct DSB repair mechanism but reflects "micro-SSA."     

Structures of human exonuclease 1 DNA complexes suggest a unified mechanism for nuclease family

Human exonuclease 1 (hExo1) plays important roles in DNA repair and recombination processes that maintain genomic integrity. It is a member of the 5' structure-specific nuclease family of exonucleases and endonucleases that includes FEN-1, XPG, and GEN1. We present structures of hExo1 in complex with a DNA substrate, followed by mutagenesis studies, and propose a common mechanism by which this nuclease family recognizes and processes diverse DNA structures. hExo1 induces a sharp bend in the DNA at nicks or gaps. Frayed 5' ends of nicked duplexes resemble flap junctions, unifying the mechanisms of endo- and exonucleolytic processing. Conformational control of a mobile region in the catalytic site suggests a mechanism for allosteric regulation by binding to protein partners. The relative arrangement of substrate binding sites in these enzymes provides an elegant solution to a complex geometrical puzzle of substrate recognition and processing.     

Rad54, the motor of homologous recombination

Homologous recombination (HR) performs crucial functions including DNA repair, segregation of homologous chromosomes, propagation of genetic diversity, and maintenance of telomeres. HR is responsible for the repair of DNA double-strand breaks and DNA interstrand cross-links. The process of HR is initiated at the site of DNA breaks and gaps and involves a search for homologous sequences promoted by Rad51 and auxiliary proteins followed by the subsequent invasion of broken DNA ends into the homologous duplex DNA that then serves as a template for repair. The invasion produces a cross-stranded structure, known as the Holliday junction. Here, we describe the properties of Rad54, an important and versatile HR protein that is evolutionarily conserved in eukaryotes. Rad54 is a motor protein that translocates along dsDNA and performs several important functions in HR. The current review focuses on the recently identified Rad54 activities which contribute to the late phase of HR, especially the branch migration of Holliday junctions.     

Comparison of nonhomologous end joining and homologous recombination in human cells

The two major pathways for repair of DNA double-strand breaks (DSBs) are homologous recombination (HR) and nonhomologous end joining (NHEJ). HR leads to accurate repair, while NHEJ is intrinsically mutagenic. To understand human somatic mutation it is essential to know the relationship between these pathways in human cells. Here we provide a comparison of the kinetics and relative contributions of HR and NHEJ in normal human cells. We used chromosomally integrated fluorescent reporter substrates for real-time in vivo monitoring of the NHEJ and HR. By examining multiple integrated clones we show that the efficiency of NHEJ and HR is strongly influenced by chromosomal location. Furthermore, we show that NHEJ of compatible ends (NHEJ-C) and NHEJ of incompatible ends (NHEJ-I) are fast processes, which can be completed in approximately 30 min, while HR is much slower and takes 7h or longer to complete. In actively cycling cells NHEJ-C is twice as efficient as NHEJ-I, and NHEJ-I is three times more efficient than HR. Our results suggest that NHEJ is a faster and more efficient DSB repair pathway than HR.     

Novel function of Rad27 (FEN-1) in restricting short-sequence recombination

Saccharomyces cerevisiae mutants lacking the structure-specific nuclease Rad27 display an enhancement in recombination that increases as sequence length decreases, suggesting that Rad27 preferentially restricts recombination between short sequences. Since wild-type alleles of both RAD27 and its human homologue FEN1 complement the elevated short-sequence recombination (SSR) phenotype of a rad27-null mutant, this function may be conserved from yeast to humans. Furthermore, mutant Rad27 and FEN-1 enzymes with partial flap endonuclease activity but without nick-specific exonuclease activity partially complement the SSR phenotype of the rad27-null mutant. This suggests that the endonuclease activity of Rad27 (FEN-1) plays a role in limiting recombination between short sequences in eukaryotic cells.     

Double-strand break repair in bacteria: a view from Bacillus subtilis

In all living organisms, the response to double-strand breaks (DSBs) is critical for the maintenance of chromosome integrity. Homologous recombination (HR), which utilizes a homologous template to prime DNA synthesis and to restore genetic information lost at the DNA break site, is a complex multistep response. In Bacillus subtilis, this response can be subdivided into five general acts: (1) recognition of the break site(s) and formation of a repair center (RC), which enables cells to commit to HR; (2) end-processing of the broken end(s) by different avenues to generate a 3'-tailed duplex and RecN-mediated DSB 'coordination'; (3) loading of RecA onto single-strand DNA at the RecN-induced RC and concomitant DNA strand exchange; (4) branch migration and resolution, or dissolution, of the recombination intermediates, and replication restart, followed by (5) disassembly of the recombination apparatus formed at the dynamic RC and segregation of sister chromosomes. When HR is impaired or an intact homologous template is not available, error-prone nonhomologous end-joining directly rejoins the two broken ends by ligation. In this review, we examine the functions that are known to contribute to DNA DSB repair in B. subtilis, and compare their properties with those of other bacterial phyla.     

Distinct Cdk1 requirements during single-strand annealing, noncrossover, and crossover recombination

Repair of DNA double-strand breaks (DSBs) by homologous recombination (HR) in haploid cells is generally restricted to S/G2 cell cycle phases, when DNA has been replicated and a sister chromatid is available as a repair template. This cell cycle specificity depends on cyclin-dependent protein kinases (Cdk1 in Saccharomyces cerevisiae), which initiate HR by promoting 5'-3' nucleolytic degradation of the DSB ends. Whether Cdk1 regulates other HR steps is unknown. Here we show that yku70Δ cells, which accumulate single-stranded DNA (ssDNA) at the DSB ends independently of Cdk1 activity, are able to repair a DSB by single-strand annealing (SSA) in the G1 cell cycle phase, when Cdk1 activity is low. This ability to perform SSA depends on DSB resection, because both resection and SSA are enhanced by the lack of Rad9 in yku70Δ G1 cells. Furthermore, we found that interchromosomal noncrossover recombinants are generated in yku70Δ and yku70Δ rad9Δ G1 cells, indicating that DSB resection bypasses Cdk1 requirement also for carrying out these recombination events. By contrast, yku70Δ and yku70Δ rad9Δ cells are specifically defective in interchromosomal crossover recombination when Cdk1 activity is low. Thus, Cdk1 promotes DSB repair by single-strand annealing and noncrossover recombination by acting mostly at the resection level, whereas additional events require Cdk1-dependent regulation in order to generate crossover outcomes.     

The chromatin remodeler Chd1 supports MRX and Exo1 functions in resection of DNA double-strand breaks

Repair of DNA double-strand breaks (DSBs) by homologous recombination (HR) requires that the 5’-terminated DNA strands are resected to generate single-stranded DNA overhangs. This process is initiated by a short-range resection catalyzed by the MRX (Mre11-Rad50-Xrs2) complex, which is followed by a long-range step involving the nucleases Exo1 and Dna2. Here we show that the Saccharomyces cerevisiae ATP-dependent chromatin-remodeling protein Chd1 participates in both short- and long-range resection by promoting MRX and Exo1 association with the DSB ends. Furthermore, Chd1 reduces histone occupancy near the DSB ends and promotes DSB repair by HR. All these functions require Chd1 ATPase activity, supporting a role for Chd1 in the opening of chromatin at the DSB site to facilitate MRX and Exo1 processing activities.     

The FEN-1 family of structure-specific nucleases in eukaryotic dna replication,recombination and repair

Unlike the most well-characterized prokaryotic polymerase, E. Coli DNA pol I, none of the eukaryotic polymerases have their own 5′ to 3′ exonuclease domain for nick translation and Okazaki fragment processing. In eukaryotes, FEN-1 is an endo-and exonuclease that carries out this function independently of the polymerase molecules. Only seven nucleases have been cloned from multicellular eukaryotic cells. Among these, FEN-1 is intriguing because it has complex structural preferences; specifically, it cleaves at branched DNA structures. The cloning of FEN-1 permitted establishment of the first eukaryotic nuclease family, predicting that S. cerevisiae RAD2 (S. pombe Rad13) and its mammalian homolog, XPG, would have similar structural specficity. The FEN-1 nuclease family includes several similar enzymes encoded by bacteriophages. The crystal structures of two enzymes in the FEN-1 nuclease family have been solved and they provide a structural basis for the interesting steric requirements of FEN-1 substrates. Because of their unique structural specificities, FEN-1 and its family members have important roles in DNA replication, repair and, potentially, recombination. Recently, FEN-1 was found to specifically associate with PCNA, explaining some aspects of FEN-1 function during DNA replication and potentially in DNA repair.     

Chromodomain helicase DNA-binding protein 4 (CHD4) regulates homologous recombination DNA repair, and its deficiency sensitizes cells to poly(ADP-ribose) polymerase (PARP) inhibitor treatment

To ensure genome stability, cells have evolved a robust defense mechanism to detect, signal, and repair damaged DNA that is generated by exogenous stressors such as ionizing radiation, endogenous stressors such as free radicals, or normal physiological processes such as DNA replication. Homologous recombination (HR) repair is a critical pathway of repairing DNA double strand breaks, and it plays an essential role in maintaining genomic integrity. Previous studies have shown that BRIT1, also known as MCPH1, is a key regulator of HR repair. Here, we report that chromodomain helicase DNA-binding protein 4 (CHD4) is a novel BRIT1 binding partner that regulates the HR repair process. The BRCA1 C-terminal domains of BRIT1 are required for its interaction with CHD4. Depletion of CHD4 and overexpression of the ATPase-dead form of CHD4 impairs the recruitment of BRIT1 to the DNA damage lesions. As a functional consequence, CHD4 deficiency sensitizes cells to double strand break-inducing agents, reduces the recruitment of HR repair factor BRCA1, and impairs HR repair efficiency. We further demonstrate that CHD4-depleted cells are more sensitive to poly(ADP-ribose) polymerase inhibitor treatment. In response to DNA damage induced by poly(ADP-ribose) polymerase inhibitors, CHD4 deficiency impairs the recruitment of DNA repair proteins BRIT1, BRCA1, and replication protein A at early steps of HR repair. Taken together, our findings identify an important role of CHD4 in controlling HR repair to maintain genome stability and establish the potential therapeutic implications of targeting CHD4 deficiency in tumors.