Exploring the roles of Mus81-Eme1/Mms4 at perturbed replication forks

Cells of all living organisms have evolved complex mechanisms that serve to stabilise, repair and restart stalled, blocked and broken replication forks. The heterodimeric Mus81-Eme1/Mms4 structure-specific endonuclease appears to play an important role(s) in homologous recombination-mediated processing of such perturbed forks. This enzyme has been implicated in the cleavage of stalled and blocked replication forks to initiate recombination, as well as in the processing of recombination intermediates that result from repairing damaged forks. In this review we assess the biochemical and genetic evidence for the mitotic role of Mus81-Eme1/Mms4 at replication forks and in repairing post-replication DNA damage. Mus81 appears to act when replication is impeded by genotoxins or by impairment of the replication machinery, or when arrested replication forks are not adequately protected. We discuss how its action is regulated by the S-phase cell cycle checkpoint, depending on the nature of the stalled or damaged fork. We also present a new way in which Mus81 may limit crossing over during the repair of post-replication gaps, and explore Mus81's interplay with other components of the recombination machinery, including the RecQ helicases that also play important roles in processing replication and recombination intermediates.     

Bloom's syndrome helicase and Mus81 are required to induce transient double-strand DNA breaks in response to DNA replication stress

Perturbed DNA replication either activates a cell cycle checkpoint, which halts DNA replication, or decreases the rate of DNA synthesis without activating a checkpoint. Here we report that at low doses, replication inhibitors did not activate a cell cycle checkpoint, but they did activate a process that required functional Bloom's syndrome-associated (BLM) helicase, Mus81 nuclease and ataxia telangiectasia mutated and Rad3-related (ATR) kinase to induce transient double-stranded DNA breaks. The induction of transient DNA breaks was accompanied by dissociation of proliferating cell nuclear antigen (PCNA) and DNA polymerase α from replication forks. In cells with functional BLM, Mus81 and ATR, the transient breaks were promptly repaired and DNA continued to replicate at a slow pace in the presence of replication inhibitors. In cells that lacked BLM, Mus81, or ATR, transient breaks did not form, DNA replication did not resume, and exposure to low doses of replication inhibitors was toxic. These observations suggest that BLM helicase, ATR kinase, and Mus81 nuclease are required to convert perturbed replication forks to DNA breaks when cells encounter conditions that decelerate DNA replication, thereby leading to the rapid repair of those breaks and resumption of DNA replication without incurring DNA damage and without activating a cell cycle checkpoint.     

Temporal regulation of the Mus81-Mms4 endonuclease ensures cell survival under conditions of DNA damage

The structure-specific Mus81-Eme1/Mms4 endonuclease contributes importantly to DNA repair and genome integrity maintenance. Here, using budding yeast, we have studied its function and regulation during the cellular response to DNA damage and show that this endonuclease is necessary for successful chromosome replication and cell survival in the presence of DNA lesions that interfere with replication fork progression. On the contrary, Mus81-Mms4 is not required for coping with replicative stress originated by acute treatment with hydroxyurea (HU), which causes fork stalling. Despite its requirement for dealing with DNA lesions that hinder DNA replication, Mus81-Mms4 activation is not induced by DNA damage at replication forks. Full Mus81-Mms4 activity is only acquired when cells finish S-phase and the endonuclease executes its function after the bulk of genome replication is completed. This post-replicative mode of action of Mus81-Mms4 limits its nucleolytic activity during S-phase, thus avoiding the potential cleavage of DNA substrates that could cause genomic instability during DNA replication. At the same time, it constitutes an efficient fail-safe mechanism for processing DNA intermediates that cannot be resolved by other proteins and persist after bulk DNA synthesis, which guarantees the completion of DNA repair and faithful chromosome replication when the DNA is damaged.     

Functions of RecQ family helicases: possible involvement of Bloom's and Werner's syndrome gene products in guarding genome integrity during DNA replication

Escherichia coli RecQ helicase is a component of the RecF pathway of recombination whose components are required to reassemble a replisome complex at the site of the replication fork after the removal of a lesion. There are at least five RecQ homologues in human cells, including BLM and WRN. The genes encoding BLM and WRN are mutated in the cancer-prone disorder Bloom's syndrome (BS) and the plogeroid disorder Werner's syndrome (WS), respectively. These syndromes are characterized by a high degree of genomic instability, including chromosomal breaks, multiple large deletions, and translocations, and cells derived from BS and WS patients show defects in DNA replication. Recently, it has become clear that a Holliday junction-like structure is formed at stalled replication forks to result in the formation of double-stranded breaks, and recombination plays an important role in the repair of stalled or broken replication forks, leading to the reinitiation of replication. Defects in the processing of stalled replication forks could lead to aberrant recombination events resulting in genetic instability. Recent studies on BLM, WRN, and the RecQ homologue of Saccharomyces cerevisiae, Sgs1, indicate that these RecQ homologues interact with proteins involved in DNA replication, and function in a pathway from the DNA replication check point to homologous recombination.     

Cleavage of stalled forks by fission yeast Mus81/Eme1 in absence of DNA replication checkpoint

During replication arrest, the DNA replication checkpoint plays a crucial role in the stabilization of the replisome at stalled forks, thus preventing the collapse of active forks and the formation of aberrant DNA structures. How this checkpoint acts to preserve the integrity of replication structures at stalled fork is poorly understood. In Schizosaccharomyces pombe, the DNA replication checkpoint kinase Cds1 negatively regulates the structure-specific endonuclease Mus81/Eme1 to preserve genomic integrity when replication is perturbed. Here, we report that, in response to hydroxyurea (HU) treatment, the replication checkpoint prevents S-phase-specific DNA breakage resulting from Mus81 nuclease activity. However, loss of Mus81 regulation by Cds1 is not sufficient to produce HU-induced DNA breaks. Our results suggest that unscheduled cleavage of stalled forks by Mus81 is permitted when the replisome is not stabilized by the replication checkpoint. We also show that HU-induced DNA breaks are partially dependent on the Rqh1 helicase, the fission yeast homologue of BLM, but are independent of its helicase activity. This suggests that efficient cleavage of stalled forks by Mus81 requires Rqh1. Finally, we identified an interplay between Mus81 activity at stalled forks and the Chk1-dependent DNA damage checkpoint during S-phase when replication forks have collapsed.     

The structure-specific endonuclease Mus81-Eme1 promotes conversion of interstrand DNA crosslinks into double-strands breaks

Repair of interstrand crosslinks (ICLs) requires multiple-strand incisions to separate the two covalently attached strands of DNA. It is unclear how these incisions are generated. DNA double-strand breaks (DSBs) have been identified as intermediates in ICL repair, but enzymes responsible for producing these intermediates are unknown. Here we show that Mus81, a component of the Mus81-Eme1 structure-specific endonuclease, is involved in generating the ICL-induced DSBs in mouse embryonic stem (ES) cells in S phase. Given the DNA junction cleavage specificity of Mus81-Eme1 in vitro, DNA damage-stalled replication forks are suitable in vivo substrates. Interestingly, generation of DSBs from replication forks stalled due to DNA damage that affects only one of the two DNA strands did not require Mus81. Furthermore, in addition to a physical interaction between Mus81 and the homologous recombination protein Rad54, we show that Mus81(-/-) Rad54(-/-) ES cells were as hypersensitive to ICL agents as Mus81(-/-) cells. We propose that Mus81-Eme1- and Rad54-mediated homologous recombination are involved in the same DNA replication-dependent ICL repair pathway.     

Structure-specific DNA endonuclease Mus81/Eme1 generates DNA damage caused by Chk1 inactivation

The DNA-damage checkpoint kinase Chk1 is essential in higher eukaryotes due to its role in maintaining genome stability in proliferating cells. CHK1 gene deletion is embryonically lethal, and Chk1 inhibition in replicating cells causes cell-cycle defects that eventually lead to perturbed replication and replication-fork collapse, thus generating endogenous DNA damage. What is the cause of replication-fork collapse when Chk1 is inactivated, however, remains poorly understood. Here, we show that generation of DNA double-strand breaks at replication forks when Chk1 activity is compromised relies on the DNA endonuclease complex Mus81/Eme1. Importantly, we show that Mus81/Eme1-dependent DNA damage--rather than a global increase in replication-fork stalling--is the cause of incomplete replication in Chk1-deficient cells. Consequently, Mus81/Eme1 depletion alleviates the S-phase progression defects associated with Chk1 deficiency, thereby increasing cell survival. Chk1-mediated protection of replication forks from Mus81/Eme1 even under otherwise unchallenged conditions is therefore vital to prevent uncontrolled fork collapse and ensure proper S-phase progression in human cells.     

Bi-directional routing of DNA mismatch repair protein human exonuclease 1 to replication foci and DNA double strand breaks

Human exonuclease 1 (hEXO1) is implicated in DNA metabolism, including replication, recombination and repair, substantiated by its interactions with PCNA, DNA helicases BLM and WRN, and several DNA mismatch repair (MMR) proteins. We investigated the sub-nuclear localization of hEXO1 during S-phase progression and in response to laser-induced DNA double strand breaks (DSBs). We show that hEXO1 and PCNA co-localize in replication foci. This apparent interaction is sustained throughout S-phase. We also demonstrate that hEXO1 is rapidly recruited to DNA DSBs. We have identified a PCNA interacting protein (PIP-box) region on hEXO1 located in its COOH-terminal ((788)QIKLNELW(795)). This motif is essential for PCNA binding and co-localization during S-phase. Recruitment of hEXO1 to DNA DSB sites is dependent on the MMR protein hMLH1. We show that two distinct hMLH1 interaction regions of hEXO1 (residues 390-490 and 787-846) are required to direct the protein to the DNA damage site. Our results reveal that protein domains in hEXO1 in conjunction with specific protein interactions control bi-directional routing of hEXO1 between on-going DNA replication and repair processes in living cells.     

Multiple pathways cooperate to facilitate DNA replication fork progression through alkylated DNA

Eukaryotic genomes are especially vulnerable to DNA damage during the S phase of the cell cycle, when chromosomes must be duplicated. The stability of DNA replication forks is critical to achieve faithful chromosome replication and is severely compromised when forks encounter DNA lesions. To maintain genome integrity, replication forks need to be protected by the S-phase checkpoint and DNA insults must be repaired. Different pathways help to repair or tolerate the lesions in the DNA, but their contribution to the progression of replication forks through damaged DNA is not well known. Here we show in budding yeast that, when the DNA template is damaged with the alkylating agent methyl methanesulfonate (MMS), base excision repair, homologous recombination and DNA damage tolerance pathways, together with a functional S-phase checkpoint, are essential for the efficient progression of DNA replication forks and the maintenance of cell survival. In the absence of base excision repair, replication forks stall reversibly in cells exposed to MMS. This repair reaction is necessary to eliminate the lesions that impede fork progression and has to be coordinated with recombination and damage tolerance activities to avoid fork collapse and allow forks to resume and complete chromosome replication.     

The novel gene mus7(+) is involved in the repair of replication-associated DNA damage in fission yeast

The progression of replication forks is often impeded by obstacles that cause them to stall or collapse, and appropriate responses to replication-associated DNA damage are important for genome integrity. Here we identified a new gene, mus7(+), that is involved in the repair of replication-associated DNA damage in the fission yeast Schizosaccharomyces pombe. The Deltamus7 mutant shows enhanced sensitivity to methyl methanesulfonate (MMS), camptothecin, and hydroxyurea, agents that cause replication fork stalling or collapse, but not to ultraviolet light or X-rays. Epistasis analysis of MMS sensitivity indicates that Mus7 functions in the same pathway as Mus81, a subunit of the Mus81-Eme1 structure-specific endonuclease, which has been implicated in the repair of the replication-associated DNA damage. In Deltamus7 and Deltamus81 cells, the repair of MMS-induced DNA double-strand breaks (DSBs) is severely impaired. Moreover, some cells with either mutation are hyper-elongated or enlarged, and most of these cells accumulate in late G2 phase. Spontaneous Rad22 (recombination mediator protein RAD52 homolog) foci increase in S phase to late G2 phase in Deltamus7 and Deltamus81 cells. These results suggest that replication-associated DSBs accumulate in these cells and that Rad22 foci form in the absence of Mus7 or Mus81. We also found that the rate of spontaneous conversion-type recombination is reduced in mitotic Deltamus7 cells, suggesting that Rhp51- (RAD51 homolog) dependent homologous recombination is disturbed in this mutant. From these data, we propose that Mus7 functions in the repair of replication-associated DSBs by promoting RAD51-dependent conversion-type recombination downstream of Rad22 and Mus81.     

Unwinding protein complexes in ALTernative telomere maintenance

Telomeres are composed of specialized chromatin that includes DNA repair/recombination proteins, telomere DNA‐binding proteins and a number of three dimensional nucleic acid structures including G‐quartets and D‐loops. A number of studies suggest that the BLM and WRN recQ‐like helicases play important roles in recombination‐mediated mechanisms of telomere elongation or A lternative L engthening of T elomeres (ALT), processes that maintain/elongate telomeres in the absence of telomerase. BLM and WRN localize within ALT‐associated nuclear bodies in telomerase‐negative immortalized cell lines and interact with the telomere‐specific proteins POT1, TRF1 and TRF2. Helicase activity is modulated by these interactions. BLM functions in DNA double‐strand break repair processes such as non‐homologous end joining, homologous recombination‐mediated repair, resolution of stalled replication forks and synthesis‐dependent strand annealing, although its precise functions at the telomeres are speculative. WRN also functions in DNA replication, recombination and repair, and in addition to its helicase domain, includes an exonuclease domain not found in other recQ‐like helicases. The biochemical properties of BLM and WRN are, therefore, important in biological processes other than DNA replication, recombination and repair. In this review, we discuss some previous and recent findings of human rec‐Q‐like helicases and their role in telomere elongation during ALT processes. J. Cell. Biochem. 109: 7–15, 2010. © 2009 Wiley‐Liss, Inc.     

The Werner and Bloom syndrome proteins help resolve replication blockage by converting (regressed) holliday junctions to functional replication forks

Cells cope with blockage of replication fork progression in a manner that allows DNA synthesis to be completed and genomic instability minimized. Models for resolution of blocked replication involve fork regression to form Holliday junction structures. The human RecQ helicases WRN and BLM (deficient in Werner and Bloom syndromes, respectively) are critical for maintaining genomic stability and thought to function in accurate resolution of replication blockage. Consistent with this notion, WRN and BLM localize to sites of blocked replication after certain DNA-damaging treatments and exhibit enhanced activity on replication and recombination intermediates. Here we examine the actions of WRN and BLM on a special Holliday junction substrate reflective of a regressed replication fork. Our results demonstrate that, in reactions requiring ATP hydrolysis, both WRN and BLM convert this Holliday junction substrate primarily to a four-stranded replication fork structure, suggesting they target the Holliday junction to initiate branch migration. In agreement, the Holliday junction binding protein RuvA inhibits the WRN- and BLM-mediated conversion reactions. Importantly, this conversion product is suitable for replication with its leading daughter strand readily extended by DNA polymerases. Furthermore, binding to and conversion of this Holliday junction are optimal at low MgCl(2) concentrations, suggesting that WRN and BLM preferentially act on the square planar (open) conformation of Holliday junctions. Our findings suggest that, subsequent to fork regression events, WRN and/or BLM could re-establish functional replication forks to help overcome fork blockage. Such a function is highly consistent with phenotypes associated with WRN- and BLM-deficient cells.     

RecQ helicases: guardian angels of the DNA replication fork

Since the original observations made in James German’s Laboratory that Bloom’s syndrome cells lacking BLM exhibit a decreased rate of both DNA chain elongation and maturation of replication intermediates, a large body of evidence has supported the idea that BLM, and other members of the RecQ helicase family to which BLM belongs, play important roles in DNA replication. More recent evidence indicates roles for RecQ helicases in what can broadly be defined as replication fork ‘repair’ processes when, for example, forks encounter lesions or adducts in the template, or when forks stall due to lack of nucleotide precursors. More specifically, several roles in repair of damaged forks via homologous recombination pathways have been proposed. RecQ helicases are generally only recruited to sites of DNA replication following fork stalling or disruption, and they do so in a checkpoint-dependent manner. There, in addition to repair functions, they aid the stabilisation of stalled replication complexes and seem to contribute to the generation and/or transduction of signals that enforce S-phase checkpoints. RecQ helicases also interact physically and functionally with several key players in DNA replication, including RPA, PCNA, FEN1 and DNA polymerase δ. In this paper, we review the evidence that RecQ helicases contribute to the impressively high level of fidelity with which genome duplication is effected.     

WRN is required for ATM activation and the S-phase checkpoint in response to interstrand cross-link-induced DNA double-strand breaks

Werner syndrome (WS) is a human genetic disorder characterized by extensive clinical features of premature aging. Ataxia-telengiectasia (A-T) is a multisystem human genomic instability syndrome that includes premature aging in some of the patients. WRN and ATM, the proteins defective in WS and A-T, respectively, play significant roles in the maintenance of genomic stability and are involved in several DNA metabolic pathways. A role for WRN in DNA repair has been proposed; however, this study provides evidence that WRN is also involved in ATM pathway activation and in a S-phase checkpoint in cells exposed to DNA interstrand cross-link–induced double-strand breaks. Depletion of WRN in such cells by RNA interference results in an intra-S checkpoint defect, and interferes with activation of ATM as well as downstream phosphorylation of ATM target proteins. Treatment of cells under replication stress with the ATM kinase inhibitor KU 55933 results in a S-phase checkpoint defect similar to that observed in WRN shRNA cells. Moreover, γH2AX levels are higher in WRN shRNA cells than in control cells 6 and 16 h after exposure to psoralen DNA cross-links. These results suggest that WRN and ATM participate in a replication checkpoint response, in which WRN facilitates ATM activation in cells with psoralen DNA cross-link–induced collapsed replication forks.     

A novel cell-cycle-regulated interaction of the Bloom syndrome helicase BLM with Mcm6 controls replication-linked processes

The Bloom syndrome DNA helicase BLM contributes to chromosome stability through its roles in double-strand break repair by homologous recombination and DNA replication fork restart during the replication stress response. Loss of BLM activity leads to Bloom syndrome, which is characterized by extraordinary cancer risk and small stature. Here, we have analyzed the composition of the BLM complex during unperturbed S-phase and identified a direct physical interaction with the Mcm6 subunit of the minichromosome maintenance (MCM) complex. Using distinct binding sites, BLM interacts with the N-terminal domain of Mcm6 in G1 phase and switches to the C-terminal Cdt1-binding domain of Mcm6 in S-phase, with a third site playing a role for Mcm6 binding after DNA damage. Disruption of Mcm6-binding to BLM in S-phase leads to supra-normal DNA replication speed in unperturbed cells, and the helicase activity of BLM is required for this increased replication speed. Upon disruption of BLM/Mcm6 interaction, repair of replication-dependent DNA double-strand breaks is delayed and cells become hypersensitive to DNA damage and replication stress. Our findings reveal that BLM not only plays a role in the response to DNA damage and replication stress, but that its physical interaction with Mcm6 is required in unperturbed cells, most notably in S-phase as a negative regulator of replication speed.     

Mms22 preserves genomic integrity during DNA replication in Schizosaccharomyces pombe

The faithful replication of the genome, coupled with the accurate repair of DNA damage, is essential for the maintenance of chromosomal integrity. The MMS22 gene of Saccharomyces cerevisiae plays an important but poorly understood role in preservation of genome integrity. Here we describe a novel gene in Schizosaccharomyces pombe that we propose is a highly diverged ortholog of MMS22. Fission yeast Mms22 functions in the recovery from replication-associated DNA damage. Loss of Mms22 results in the accumulation of spontaneous DNA damage in the S- and G2-phases of the cell cycle and elevated genomic instability. There are severe synthetic interactions involving mms22 and most of the homologous recombination proteins but not the structure-specific endonuclease Mus81-Eme1, which is required for survival of broken replication forks. Mms22 forms spontaneous nuclear foci and colocalizes with Rad22 in cells treated with camptothecin, suggesting that it has a direct role in repair of broken replication forks. Moreover, genetic interactions with components of the DNA replication fork suggest that Mms2 functions in the coordination of DNA synthesis following damage. We propose that Mms22 functions directly at the replication fork to maintain genomic integrity in a pathway involving Mus81-Eme1.     

The Werner syndrome protein confers resistance to the DNA lesions N3-methyladenine and O6-methylguanine: implications for WRN function

The Werner syndrome (WS) protein (WRN), a DNA helicase/exonuclease, is required for genomic stability and avoidance of cancer. Current evidence suggests that WRN is involved in the resolution of stalled and/or collapsed replication forks. This function is indicated, in part, by replication defects in WS cells and by hypersensitivity to agents causing major structural aberrations in DNA that block replication. We show here that antisense suppression of WRN in two human glioma cell lines reproduces hallmarks of the drug cytotoxicity profile of WS cells, namely, hypersensitivity to 4-nitroquinoline 1-oxide, camptothecin and hydroxyurea. We also show that antisense-treated cells are hypersensitive to methyl-lexitropsin, a site-specific alkylating agent that produces mainly N3-methyladenine, a cytotoxic and replication-blocking lesion. Antisense-treated cells are hypersensitive to O(6)-methylguanine adducts as well, but only when repair by O(6)-methylguanine-DNA methyltransferase is lacking. Our results illustrate the drug sensitivity caused by deficiency of WRN in a uniform genetic background. They extend the WRN DNA damage sensitivity spectrum to methyl base adducts that can result in blocked replication, and suggest that WRN may be required for resumption of processive replication when incomplete repair of DNA damage leaves blocking lesions at forks. The evidence that highly disparate lesions fall within the purview of WRN, and that abrogating DNA repair can reveal dependence on WRN, suggests that WRN may protect the genome from the lethal, mutagenic and carcinogenic effects of widely diverse DNA damage arising from endogenous processes and environmental agents.     

Werner's syndrome protein (WRN) migrates Holliday junctions and co-localizes with RPA upon replication arrest

Individuals affected by the autosomal recessive disorder Werner’s syndrome (WS) develop many of the symptoms characteristic of premature ageing. Primary fibroblasts cultured from WS patients exhibit karyotypic abnormalities and a reduced replicative life span. The WRN gene encodes a 3′–5′ DNA helicase, and is a member of the RecQ family, which also includes the product of the Bloom’s syndrome gene (BLM). In this work, we show that WRN promotes the ATP-dependent translocation of Holliday junctions, an activity that is also exhibited by BLM. In cells arrested in S-phase with hydroxyurea, WRN localizes to discrete nuclear foci that coincide with those formed by the single-stranded DNA binding protein replication protein A. These results are consistent with a model in which WRN prevents aberrant recombination events at sites of stalled replication forks by dissociating recombination intermediates.     

The Werner and Bloom syndrome proteins catalyze regression of a model replication fork

The premature aging and cancer-prone diseases Werner and Bloom syndromes are caused by loss of function of WRN and BLM proteins, respectively. At the cellular level, WRN or BLM deficiency causes replication abnormalities, DNA damage hypersensitivity, and genome instability, suggesting that these proteins might participate in resolution of replication blockage. Although WRN and BLM are helicases belonging to the RecQ family, both have been recently shown to also facilitate pairing of complementary DNA strands. In this study, we demonstrate that both WRN and BLM (but not other selected helicases) can coordinate their unwinding and pairing activities to regress a model replication fork substrate. Notably, fork regression is widely believed to be the initial step in responding to replication blockage. Our findings suggest that WRN and/or BLM might regress replication forks in vivo as part of a genome maintenance pathway, consistent with the phenotypes of WRN- and BLM-deficient cells.