Replisome stability at defective DNA replication forks is independent of S phase checkpoint kinases

The S phase checkpoint pathway preserves genome stability by protecting defective DNA replication forks, but the underlying mechanisms are still understood poorly. Previous work with budding yeast suggested that the checkpoint kinases Mec1 and Rad53 might prevent collapse of the replisome when nucleotide concentrations are limiting, thereby allowing the subsequent resumption of DNA synthesis. Here we describe a direct analysis of replisome stability in budding yeast cells lacking checkpoint kinases, together with a high-resolution view of replisome progression across the genome. Surprisingly, we find that the replisome is stably associated with DNA replication forks following replication stress in the absence of Mec1 or Rad53. A component of the replicative DNA helicase is phosphorylated within the replisome in a Mec1-dependent manner upon replication stress, and our data indicate that checkpoint kinases control replisome function rather than stability, as part of a multifaceted response that allows cells to survive defects in chromosome replication.     

Enhancement of repair replication in mammalian cells by hydroxyurea

The effect of hydroxyurea on DNA repair replication has been studied in Chinese hamster ovary cells. Mitotic cells were treated with UV irradiation, methyl methanesulfonate or nitrogen mustard and incuated in the presence of each of the 4 [³H]deoxyribonucleosides plus BrdUrd and FdUrd for 2 h. The amount of repair replication was quantitated on CsCl gradients and similar values were obtained for each nucleoside. In all cases addition of HU during the incubation period increased these values approximately 2-fold. Following MMS treatment, pool sizes for each of the nucleosides were estimated by varying the amount of exogenously supplied nucleoside. They were found to be insensitive to the addition of HU and it is concluded that the increased incorporation of [³H]deoxyribonucleosides in the presence of HU reflects an increased amount of repair replication.     

Radiation down-regulates replication origin activity throughout the S phase in mammalian cells.

An asynchronous culture of mammalian cells responds acutely to ionizing radiation by inhibiting the overall rate of DNA replication by approximately 50% for a period of several hours, presumably to allow time to repair DNA damage. At low and moderate doses, this S phase damage-sensing (SDS) pathway appears to function primarily at the level of individual origins of replication, with only a modest inhibition of chain elongation per se. We have shown previously that the majority of the inhibition observed in an asynchronous culture can be accounted for by late G1cells that were within 2-3 h of entering the S period at the time of irradiation and which then fail to do so. A much smaller effect was observed on the overall rate of replication in cells that had already entered the S phase. This raised the question whether origins of replication that are activated within S phase per se are inhibited in response to ionizing radiation. Here we have used a two-dimensional gel replicon mapping strategy to show that cells with an intact SDS pathway completely down-regulate initiation in both early- and late-firing rDNA origins in human cells. We also show that initiation in mid- or late-firing rDNA origins is not inhibited in cells from patients with ataxia telangiectasia, confirming the suggestion that these individuals lack the SDS pathway.     

Collapse and repair of replication forks in Escherichia coli

Single-strand interruptions in a template DNA are likely to cause collapse of replication forks. We propose a model for the repair of collapsed replication forks in Escherichia coli by the RecBCD recombinational pathway. The model gives reasons for the preferential orientation of Chi sites in the E. coli chromosome and accounts for the hyper-rec phenotype of the strains with increased numbers of single-strand interruptions in their DNA. On the basis of the model we offer schemes for various repeat-mediated recombinational events and discuss a mechanism for quasi-conservative DNA replication explaining the recombinational repair-associated mutagenesis.     

Recombinational repair and restart of damaged replication forks

Genome duplication necessarily involves the replication of imperfect DNA templates and, if left to their own devices, replication complexes regularly run into problems. The details of how cells overcome these replicative 'hiccups' are beginning to emerge, revealing a complex interplay between DNA replication, recombination and repair that ensures faithful passage of the genetic material from one generation to the next.     

Interplay of replication checkpoints and repair proteins at stalled replication forks

DNA replication is an essential process that occurs in all growing cells and needs to be tightly regulated in order to preserve genetic integrity. Eukaryotic cells have developed multiple mechanisms to ensure the fidelity of replication and to coordinate the progression of replication forks. Replication is often impeded by DNA damage or replication blocks, and the resulting stalled replication forks are sensed and protected by specialized surveillance mechanisms called checkpoints. The replication checkpoint plays an essential role in preventing the breakdown of stalled replication forks and the accumulation of DNA structures that enhance recombination and chromosomal rearrangements that ultimately lead to genomic instability and cancer development. In addition, the replication checkpoint is thought to assist and coordinate replication fork restart processes by controlling DNA repair pathways, regulating chromatin structure, promoting the recruitment of proteins to sites of damage, and controlling cell cycle progression. In this review we focus mainly on the results obtained in budding yeast to discuss on the multiple roles of checkpoints in maintaining fork integrity and on the enzymatic activities that cooperate with the checkpoint pathway to promote fork resumption and repair of DNA lesions thereby contributing to genome integrity.     

Compartmentation of deoxypyrimidine nucleotides for nuclear DNA replication in S phase mammalian cells

DNA synthesis in S phase Chinese hamster embryo fibroblast cells in the presence of exogenous 3H-dUrd shows incorporation of the labeled precursor with very little dilution by the large unlabeled intracellular precursor pools. Full mixing would predict a specific activity 10-fold less than that measured. This coupled with the finding that 80% of the radioactivity derived from the exogenous 3H-dUrd appears in the karyoplasts implies a compartmentation where 3H-dUMP and 3H-dTTP derived from exogenous 3H-dUrd do not mix freely with endogenous cytoplasmic pools.     

Bromodeoxyuridine mutagenesis in mammalian cells is stimulated by purine deoxyribonucleosides

The effects of purine deoxyribonucleosides on bromodeoxyurdine (BrdU) mutagenesis in Syrian hamster melanoma cells were determined. Both deoxyguanosine (dG) and deoxyadenosine (dA) were found to stimulate mutagenesis without changing the amount of BrdU in DNA. In addition, the stimulation of mutagenesis by dG and dA was suppressed by the addition of deoxycytidine (dC). These results suggest that BrdU mutagenesis involves the perturbation of dC metabolism, which perturbation is enhanced by dGTP and dATP. The mutagenic activity of dG in the absence of BrdU was tested, as was that of thymidine (dT), which we had shown previously to stimulate BrdU mutageneis. With dG alone, no increase above the spontaneous mutation frequency was detected. However, at extremely high concentration, dT in the absence of BrdU was slightly mutagenic, and the mutagenesis by dT was enhanced by dG and suppressed by dC.     

Multiple roles of replication forks in S phase checkpoints: sensors, effectors and targets

There is mounting evidence that replication defects are the major source of spontaneous genomic instability in the cell and that S phase checkpoints are the principle defense against such instability. In Saccharomyces cerevisiae, S phase checkpoints can be provoked by either depletion of dNTPs or DNA damage. In both cases the checkpoint kinases Mec1 and Rad53 act to suppress late origin firing, stabilize slowed or stalled replication forks and prevent S phase progression until conditions are appropriate for the resumption of DNA replication. The present review highlights recent work emphasizing the central importance of replication forks, not just as targets, but also as sensors and primary effectors of checkpoint responses, and identifies the roles played by specific fork-associated factors in these processes.     

Changes in the rate of DNA replication fork movement during S phase in mammalian cells.

DNA fiber autoradiography was used to measure the rate of replication fork movement and the size of replication units as a function of time during the S phase of synchronized Chinese hamster ovary cells. The rate of fork movement increased by about threefold from early S to later S phase, with the most dramatic change occurring in the first hour of S phase. On the other hand, the size of replication units did not vary significantly during S phase.     

A model for replication repair in mammalian cells.

A model for replication repair based on the process of branch migration explains the transient production of doubly substituted DNA within the first generation of incubation in bromodeoxyuridine and the appearance of four-pronged replication forks.     

RAD51 is involved in repair of damage associated with DNA replication in mammalian cells

The RAD51 protein, a eukaryotic homologue of the Escherichia coli RecA protein, plays an important role in the repair of DNA double-strand breaks (DSBs) by homologous recombination (HR) in mammalian cells. Recent findings suggest that HR may be important in repair following replication arrest in mammalian cells. Here, we have investigated the role of RAD51 in the repair of different types of damage induced during DNA replication with etoposide, hydroxyurea or thymidine. We show that etoposide induces DSBs at newly replicated DNA more frequently than gamma-rays, and that these DSBs are different from those induced by hydroxyurea. No DSB was found following treatment with thymidine. Although these compounds appear to induce different DNA lesions during DNA replication, we show that a cell line overexpressing RAD51 is resistant to all of them, indicating that RAD51 is involved in repair of a wide range of DNA lesions during DNA replication. We observe fewer etoposide-induced DSBs in RAD51-overexpressing cells and that HR repair of etoposide-induced DSBs is faster. Finally, we show that induced long-tract HR in the hprt gene is suppressed in RAD51-overexpressing cells, although global HR appears not to be suppressed. This suggests that overexpression of RAD51 prevents long-tract HR occurring during DNA replication. We discuss our results in light of recent models suggested for HR at stalled replication forks.     

Mrc1 and Tof1 regulate DNA replication forks in different ways during normal S phase

The Mrc1 and Tof1 proteins are conserved throughout evolution, and in budding yeast they are known to associate with the MCM helicase and regulate the progression of DNA replication forks. Previous work has shown that Mrc1 is important for the activation of checkpoint kinases in responses to defects in S phase, but both Mrc1 and Tof1 also regulate the normal process of chromosome replication. Here, we show that these two important factors control the normal progression of DNA replication forks in distinct ways. The rate of progression of DNA replication forks is greatly reduced in the absence of Mrc1 but much less affected by loss of Tof1. In contrast, Tof1 is critical for DNA replication forks to pause at diverse chromosomal sites where nonnucleosomal proteins bind very tightly to DNA, and this role is not shared with Mrc1.     

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.     

Error-prone repair of stalled replication forks drives mutagenesis and loss of heterozygosity in haploinsufficient BRCA1 cells

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BRCA2-dependent homologous recombination is required for repair of Arsenite-induced replication lesions in mammalian cells

Arsenic exposure constitutes one of the most widespread environmental carcinogens, and is associated with increased risk of many different types of cancers. Here we report that arsenite (As[III]) can induce both replication-dependent DNA double-strand breaks (DSB) and homologous recombination (HR) at doses as low as 5 µM (0.65 mg/l), which are within the typical doses often found in drinking water in contaminated areas. We show that the production of DSBs is dependent on active replication and is likely to be the result of conversion of a DNA single-strand break (SSB) into a toxic DSB when encountered by a replication fork. We demonstrate that HR is required for the repair of these breaks and show that a functional HR pathway protects against As[III]-induced cytotoxicity. In addition, BRCA2-deficient cells are sensitive to As[III] and we suggest that As[III] could be exploited as a therapy for HR-deficient tumours such as BRCA1 and BRCA2 mutated breast and ovarian cancers.     

Dynamics of human replication factors in the elongation phase of DNA replication

In eukaryotic cells, DNA replication is carried out by coordinated actions of many proteins, including DNA polymerase δ (pol δ), replication factor C (RFC), proliferating cell nuclear antigen (PCNA) and replication protein A. Here we describe dynamic properties of these proteins in the elongation step on a single-stranded M13 template, providing evidence that pol δ has a distributive nature over the 7 kb of the M13 template, repeating a frequent dissociation–association cycle at growing 3′-hydroxyl ends. Some PCNA could remain at the primer terminus during this cycle, while the remainder slides out of the primer terminus or is unloaded once pol δ has dissociated. RFC remains around the primer terminus through the elongation phase, and could probably hold PCNA from which pol δ has detached, or reload PCNA from solution to restart DNA synthesis. Furthermore, we suggest that a subunit of pol δ, POLD3, plays a crucial role in the efficient recycling of PCNA during dissociation–association cycles of pol δ. Based on these observations, we propose a model for dynamic processes in elongation complexes.     

Cyclin-dependent kinases and S phase control in mammalian cells

Mammalian DNA replication is an elegantly choreographed process in which multiple components are assembled at the origins to form the prereplication complex. Formation and activation of the prereplication complex requires coordinate actions of G1and S phase cyclin-dependent kinases. Cyclin E-CDK2 and cyclin A-CDK2, together with DBF4-CDC7, phosphorylate several components of the prereplication complex and replication machinery. In this review, we summarize the current understanding of the mechanism of initiation of DNA replication in mammalian cells. The roles of cyclin A/E-CDK2 complexes in driving replication, their relationship with other regulators of S phase, and their role in keeping replication to only once per cell cycle will be discussed. In addition, an important issue is the checks and balances that prevent inappropriate DNA replication, and how a breakdown in these checkpoints can lead to genomic instability and cancer. A critical mediator of these checkpoints, ATM, signals through a comprehensive network of proteins leading to CDK2 inhibition thus preventing DNA synthesis. This will be reviewed in addition to other mechanisms involved in the intra-S phase DNA damage checkpoint.