Unwinding of the nascent lagging strand by Rep and PriA enables the direct restart of stalled replication forks

During origin-independent replisome assembly, the replication restart protein PriC prefers to load the replication fork helicase, DnaB, to stalled replication forks where there is a gap in the nascent leading strand. However, this activity can be obstructed if the 5'-end of the nascent lagging strand is near the template branch point. Here we provide biochemical evidence that the helicase activities of Rep and PriA function to unwind the nascent lagging strand DNA at such stalled replication forks. PriC then loads the replicative helicase, DnaB, onto the newly generated, single-stranded template for the purposes of replisome assembly and duplex unwinding ahead of the replication fork. Direct rescue of replication forks by the Rep-PriC and PriA-PriC pathways in this manner may contribute to genomic stability by avoiding the potential dangers of fork breakage inherent to recombination-dependent restart pathways.     

Replisome fate upon encountering a leading strand block and clearance from DNA by recombination proteins

Replication forks that collapse upon encountering a leading strand lesion are reactivated by a recombinative repair process called replication restart. Using rolling circle DNA substrates to model replication forks, we examine the fate of the helicase and both DNA polymerases when the leading strand polymerase is blocked. We find that the helicase continues over 0.5 kb but less than 3 kb and that the lagging strand DNA polymerase remains active despite its connection to a stalled leading strand enzyme. Furthermore, the blocked leading strand polymerase remains stably bound to the replication fork, implying that it must be dismantled from DNA in order for replication restart to initiate. Genetic studies have identified at least four gene products required for replication restart, RecF, RecO, RecR, and RecA. We find here that these proteins displace a stalled polymerase at a DNA template lesion. Implications of these results for replication fork collapse and recovery are discussed.     

Replisome assembly and the direct restart of stalled replication forks

Failure to reactivate either stalled or collapsed replication forks is a source of genomic instability in both prokaryotes and eukaryotes. In prokaryotes, dedicated fork repair systems that involve both recombination and replication proteins have been identified genetically and characterized biochemically. Replication conflicts are solved through several pathways, some of which require recombination and some of which operate directly at the stalled fork. Some recent biochemical observations support models of direct fork repair in which the removal of the blocking template lesion is not always required for replication restart.     

Polyubiquitinated PCNA Recruits the ZRANB3 Translocase to Maintain Genomic Integrity after Replication Stress

Completion of DNA replication after replication stress depends on PCNA, which undergoes monoubiquitination to stimulate direct bypass of DNA lesions by specialized DNA polymerases or is polyubiquitinated to promote recombination-dependent DNA synthesis across DNA lesions by template switching mechanisms. Here we report that the ZRANB3 translocase, a SNF2 family member related to the SIOD disorder SMARCAL1 protein, is recruited by polyubiquitinated PCNA to promote fork restart following replication arrest. ZRANB3 depletion in mammalian cells results in an increased frequency of sister chromatid exchange and DNA damage sensitivity after treatment with agents that cause replication stress. Using in?vitro biochemical assays, we show that recombinant ZRANB3 remodels DNA?structures mimicking stalled replication forks and disassembles recombination intermediates. We therefore propose that ZRANB3 maintains genomic stability at stalled or collapsed replication forks by facilitating fork restart and limiting inappropriate recombination that could occur during template switching events.     

UV stalled replication forks restart by re-priming in human fibroblasts

Restarting stalled replication forks is vital to avoid fatal replication errors. Previously, it was demonstrated that hydroxyurea-stalled replication forks rescue replication either by an active restart mechanism or by new origin firing. To our surprise, using the DNA fibre assay, we only detect a slightly reduced fork speed on a UV-damaged template during the first hour after UV exposure, and no evidence for persistent replication fork arrest. Interestingly, no evidence for persistent UV-induced fork stalling was observed even in translesion synthesis defective, Polη(mut) cells. In contrast, using an assay to measure DNA molecule elongation at the fork, we observe that continuous DNA elongation is severely blocked by UV irradiation, particularly in UV-damaged Polη(mut) cells. In conclusion, our data suggest that UV-blocked replication forks restart effectively through re-priming past the lesion, leaving only a small gap opposite the lesion. This allows continuation of replication on damaged DNA. If left unfilled, the gaps may collapse into DNA double-strand breaks that are repaired by a recombination pathway, similar to the fate of replication forks collapsed after hydroxyurea treatment.     

The disposition of nascent strands at stalled replication forks dictates the pathway of replisome loading during restart

Rescue of arrested and collapsed replication forks is essential for maintenance of genomic integrity. One system for origin of replication-independent loading of the DnaB replicative helicase and subsequent replisome reassembly requires the structure-specific recognition factor PriA and the assembly factors PriB and DnaT. Here, we provide biochemical evidence for an alternate system for DnaB loading that requires only PriC. Furthermore, the choice of which system is utilized during restart is dictated by the nature of the structure of the stalled replication fork. PriA-dependent reactions are most robust on fork structures with no gaps in the leading strand, such as is found at the junction of a D loop, while the PriC-dependent system preferentially utilizes fork structures with large gaps in the leading strand. These observations suggest that the type of initial damage on the DNA template and how the inactivated fork is processed ultimately influence the choice of enzymatic restart pathway.     

Maintaining replication fork integrity in UV-irradiated Escherichia coli cells

In dividing cells, the stalling of replication fork complexes by impediments to DNA unwinding or by template imperfections that block synthesis by the polymerase subunits is a serious threat to genomic integrity and cell viability. What happens to stalled forks depends on the nature of the offending obstacle. In UV-irradiated Escherichia coli cells DNA synthesis is delayed for a considerable period, during which forks undergo extensive processing before replication can resume. Thus, restart depends on factors needed to load the replicative helicase, indicating that the replisome may have dissociated. It also requires the RecFOR proteins, which are known to load RecA recombinase on single-stranded DNA, implying that template strands are exposed. To gain a further understanding of how UV irradiation affects replication and how replication resumes after a block, we used fluorescence microscopy and BrdU or radioisotope labelling to examine chromosome replication and cell cycle progression. Our studies confirm that RecFOR promote efficient reactivation of stalled forks and demonstrate that they are also needed for productive replication initiated at the origin, or triggered elsewhere by damage to the DNA. Although delayed, all modes of replication do recover in the absence of these proteins, but nascent DNA strands are degraded more extensively by RecJ exonuclease. However, these strands are also degraded in the presence of RecFOR when restart is blocked by other means, indicating that RecA loading is not sufficient to stabilise and protect the fork. This is consistent with the idea that RecA actively promotes restart. Thus, in contrast to eukaryotic cells, there may be no factor in bacterial cells acting specifically to stabilise stalled forks. Instead, nascent strands may be protected by the simple expedient of promoting restart. We also report that the efficiency of fork reactivation is not affected in polB mutants.     

Structural analysis of DNA replication fork reversal by RecG

The stalling of DNA replication forks that occurs as a consequence of encountering DNA damage is a critical problem for cells. RecG protein is involved in the processing of stalled replication forks, and acts by reversing the fork past the damage to create a four-way junction that allows template switching and lesion bypass. We have determined the crystal structure of RecG bound to a DNA substrate that mimics a stalled replication fork. The structure not only reveals the elegant mechanism used by the protein to recognize junctions but has also trapped the protein in the initial stage of fork reversal. We propose a mechanism for how forks are processed by RecG to facilitate replication fork restart. In addition, this structure suggests that the mechanism and function of the two largest helicase superfamilies are distinct.     

Repair and tolerance of DNA damage at the replication fork: A structural perspective

The replication machinery frequently encounters DNA damage and other structural impediments that inhibit progression of the replication fork. Replication-coupled processes that remove or bypass the barrier and restart stalled forks are essential for completion of replication and for maintenance of genome stability. Errors in replication-repair pathways lead to mutations and aberrant genetic rearrangements and are associated with human diseases. This review highlights recent structures of enzymes involved in three replication-repair pathways: translesion synthesis, template switching and fork reversal, and interstrand crosslink repair.     

Non-replicative helicases at the replication fork

Reactivation of stalled or collapsed replication forks is an essential process in bacteria. Restart systems operate to restore the 5'-->3' replicative helicase, DnaB, to the lagging-strand template. However, other non-replicative 3'-->5' helicases play an important role in the restart process as well. Here we examine the DNA-binding specificity of three of the latter group, PriA, Rep, and UvrD. Only PriA and Rep display structure-specific fork binding. Interestingly, their specificity is opposite: PriA binds a leading-strand fork, presumably reflecting its restart activity in directing loading of DnaB to the lagging-strand template. Rep binds a lagging-strand fork, presumably reflecting its role in partially displacing Okazaki fragments that originate near the fork junction. This activity is necessary for generating a single-stranded landing pad for DnaB. While UvrD shows little structure-specificity, there is a slight preference for lagging-strand forks, suggesting that there might be some redundancy between Rep and UvrD and possibly explaining the observed synthetic lethality that occurs when mutations in the genes encoding these two proteins are combined.     

Host factors that promote transpososome disassembly and the PriA-PriC pathway for restart primosome assembly

Initiation of bacteriophage Mu DNA replication by transposition requires the disassembly of the transpososome that catalyses strand exchange and the assembly of a replisome promoted by PriA, PriB, PriC and DnaT proteins, which function in the host to restart stalled replication forks. Once the molecular chaperone ClpX weakens the very tight binding of the transpososome to the Mu ends, host disassembly factors (MRFalpha-DF) promote the dissociation of the transpososome from the DNA template and the assembly of a new nucleoprotein complex. Prereplisome factors (MRFalpha-PR) further alter the complex, allowing PriA binding and loading of major replicative helicase DnaB onto the template promoted by the restart proteins. MRFalpha-PR is essential for DnaB loading by restart proteins even on the deproteinized Mu fork whereas MRFalpha-DF is not required on the deproteinized template. When the transition from transpososome to replisome was reconstituted using MRFalpha-DF and MRFalpha-PR, initiation of Mu DNA replication was strictly dependent upon added PriC and PriA helicase. In contrast, initiation on the deproteinized template was predominantly dependent upon PriB and did not require PriA's helicase activity. The results indicate that transition mechanisms beginning with the transpososome disassembly can determine the pathway of replisome assembly by restart proteins.     

Cleavage of model replication forks by fission yeast Mus81-Eme1 and budding yeast Mus81-Mms4

The blockage of replication forks can result in the disassembly of the replicative apparatus and reversal of the fork to form a DNA junction that must be processed in order for replication to restart and sister chromatids to segregate at mitosis. Fission yeast Mus81-Eme1 and budding yeast Mus81-Mms4 are endonucleases that have been implicated in the processing of aberrant DNA junctions formed at stalled replication forks. Here we have investigated the activity of purified Mus81-Eme1 and Mus81-Mms4 on substrates that resemble DNA junctions that are expected to form when a replication fork reverses. Both enzymes cleave Holliday junctions and substrates that resemble normal replication forks poorly or not at all. However, forks where the equivalents of either both the leading and lagging strands or just the lagging strand are juxtaposed at the junction point, or where either the leading or lagging strand has been unwound to produce a fork with a single-stranded tail, are cleaved well. Cleavage sites map predominantly between 3 and 6 bp 5' of the junction point. For most substrates the leading strand template is cleaved. The sole exception is a fork with a 5' single-stranded tail, which is cleaved in the lagging strand template.     

Identification and characterization of the human mus81-eme1 endonuclease

The faithful and complete replication of DNA is necessary for the maintenance of genome stability. It is known, however, that replication forks stall at lesions in the DNA template and need to be processed so that replication restart can occur. In fission yeast, the Mus81-Eme1 endonuclease complex (Mus81-Mms4 in Saccharomyces cerevisiae) has been implicated in the processing of aberrant replication intermediates. In this report, we identify the human homolog of the Schizosaccharomyces pombe EME1 gene and have purified the human Mus81-Eme1 heterodimer. We show that Mus81-Eme1 is an endonuclease that exhibits a high specificity for synthetic replication fork structures and 3'-flaps in vitro. The nuclease cleaves Holliday junctions inefficiently ( approximately 75-fold less than flap or fork structures), although cleavage can be increased 6-fold by the presence of homologous sequences previously shown to permit base pair "breathing." We conclude that human Mus81-Eme1 is a flap/fork endonuclease that is likely to play a role in the processing of stalled replication fork intermediates.     

EEPD1 Rescues Stressed Replication Forks and Maintains Genome Stability by Promoting End Resection and Homologous Recombination Repair

Replication fork stalling and collapse is a major source of genome instability leading to neoplastic transformation or cell death. Such stressed replication forks can be conservatively repaired and restarted using homologous recombination (HR) or non-conservatively repaired using micro-homology mediated end joining (MMEJ). HR repair of stressed forks is initiated by 5’ end resection near the fork junction, which permits 3’ single strand invasion of a homologous template for fork restart. This 5’ end resection also prevents classical non-homologous end-joining (cNHEJ), a competing pathway for DNA double-strand break (DSB) repair. Unopposed NHEJ can cause genome instability during replication stress by abnormally fusing free double strand ends that occur as unstable replication fork repair intermediates. We show here that the previously uncharacterized Exonuclease/Endonuclease/Phosphatase Domain-1 (EEPD1) protein is required for initiating repair and restart of stalled forks. EEPD1 is recruited to stalled forks, enhances 5’ DNA end resection, and promotes restart of stalled forks. Interestingly, EEPD1 directs DSB repair away from cNHEJ, and also away from MMEJ, which requires limited end resection for initiation. EEPD1 is also required for proper ATR and CHK1 phosphorylation, and formation of gamma-H2AX, RAD51 and phospho-RPA32 foci. Consistent with a direct role in stalled replication fork cleavage, EEPD1 is a 5’ overhang nuclease in an obligate complex with the end resection nuclease Exo1 and BLM. EEPD1 depletion causes nuclear and cytogenetic defects, which are made worse by replication stress. Depleting 53BP1, which slows cNHEJ, fully rescues the nuclear and cytogenetic abnormalities seen with EEPD1 depletion. These data demonstrate that genome stability during replication stress is maintained by EEPD1, which initiates HR and inhibits cNHEJ and MMEJ.     

DNA repeat rearrangements mediated by DnaK-dependent replication fork repair

We propose that rearrangements between short tandem repeated sequences occur by errors made during a replication fork repair pathway involving a replication template switch. We provide evidence here that the DnaK chaperone of E. coli controls this template switch repair process. Mutants in dnaK are sensitive to replication fork damage and exhibit high expression of the SOS response, indicative of repair deficiency. Deletion and expansion of tandem repeats that occur by replication misalignment ("slippage") are also DnaK dependent. Because mutations in dnaX encoding the gamma and tau subunits of DNA polymerase III mimic dnaK phenotypes and are genetically epistatic, we propose that the DnaKJ chaperone remodels the replisome to facilitate repair. The fork remains largely intact because PriA or PriC restart proteins are not required. We also suggest that the poorly defined RAD6-RAD18-RAD5 mechanism of postreplication repair in eukaryotes occurs by an analogous mechanism to the DnaK template-switch pathway in prokaryotes.     

DNA2 drives processing and restart of reversed replication forks in human cells

Accurate processing of stalled or damaged DNA replication forks is paramount to genomic integrity and recent work points to replication fork reversal and restart as a central mechanism to ensuring high-fidelity DNA replication. Here, we identify a novel DNA2- and WRN-dependent mechanism of reversed replication fork processing and restart after prolonged genotoxic stress. The human DNA2 nuclease and WRN ATPase activities functionally interact to degrade reversed replication forks with a 5′-to-3′ polarity and promote replication restart, thus preventing aberrant processing of unresolved replication intermediates. Unexpectedly, EXO1, MRE11, and CtIP are not involved in the same mechanism of reversed fork processing, whereas human RECQ1 limits DNA2 activity by preventing extensive nascent strand degradation. RAD51 depletion antagonizes this mechanism, presumably by preventing reversed fork formation. These studies define a new mechanism for maintaining genome integrity tightly controlled by specific nucleolytic activities and central homologous recombination factors.     

Repriming DNA synthesis: an intrinsic restart pathway that maintains efficient genome replication

To bypass a diverse range of fork stalling impediments encountered during genome replication, cells possess a variety of DNA damage tolerance (DDT) mechanisms including translesion synthesis, template switching, and fork reversal. These pathways function to bypass obstacles and allow efficient DNA synthesis to be maintained. In addition, lagging strand obstacles can also be circumvented by downstream priming during Okazaki fragment generation, leaving gaps to be filled post-replication. Whether repriming occurs on the leading strand has been intensely debated over the past half-century. Early studies indicated that both DNA strands were synthesised discontinuously. Although later studies suggested that leading strand synthesis was continuous, leading to the preferred semi-discontinuous replication model. However, more recently it has been established that replicative primases can perform leading strand repriming in prokaryotes. An analogous fork restart mechanism has also been identified in most eukaryotes, which possess a specialist primase called PrimPol that conducts repriming downstream of stalling lesions and structures. PrimPol also plays a more general role in maintaining efficient fork progression. Here, we review and discuss the historical evidence and recent discoveries that substantiate repriming as an intrinsic replication restart pathway for maintaining efficient genome duplication across all domains of life.     

PriA mediates DNA replication pathway choice at recombination intermediates

We report the reconstitution of the initial steps of the double-strand break-repair pathway where joint molecule formation between a duplex DNA fragment and a circular template by the combined action of RecA, RecBCD, and the single-stranded DNA binding protein provides the substrate for replication fork formation by the restart primosome and the DNA polymerase III holoenzyme. We show that PriA dictates the pathway of replication from the recombination intermediate by inhibiting a nonspecific, strand displacement DNA synthesis reaction and favoring the formation of a bona fide replication fork. Furthermore, we find that RecO and RecR significantly stimulate this recombination-directed DNA replication reaction, and that this stimulation is modulated by the presence of RecF, suggesting that the latter protein may also act as a regulator of the pathway of resolution of the recombination intermediate.     

Replication fork reversal and the maintenance of genome stability

The progress of replication forks is often threatened in vivo, both by DNA damage and by proteins bound to the template. Blocked forks must somehow be restarted, and the original blockage cleared, in order to complete genome duplication, implying that blocked fork processing may be critical for genome stability. One possible pathway that might allow processing and restart of blocked forks, replication fork reversal, involves the unwinding of blocked forks to form four-stranded structures resembling Holliday junctions. This concept has gained increasing popularity recently based on the ability of such processing to explain many genetic observations, the detection of unwound fork structures in vivo and the identification of enzymes that have the capacity to catalyse fork regression in vitro. Here, we discuss the contexts in which fork regression might occur, the factors that may promote such a reaction and the possible roles of replication fork unwinding in normal DNA metabolism.