The DNA damage response kinases DNA-dependent protein kinase (DNA-PK) and ataxia telangiectasia mutated (ATM) Are stimulated by bulky adduct-containing DNA

A variety of environmental, carcinogenic, and chemotherapeutic agents form bulky lesions on DNA that activate DNA damage checkpoint signaling pathways in human cells. To identify the mechanisms by which bulky DNA adducts induce damage signaling, we developed an in vitro assay using mammalian cell nuclear extract and plasmid DNA containing bulky adducts formed by N-acetoxy-2-acetylaminofluorene or benzo(a)pyrene diol epoxide. Using this cell-free system together with a variety of pharmacological, genetic, and biochemical approaches, we identified the DNA damage response kinases DNA-dependent protein kinase (DNA-PK) and ataxia telangiectasia mutated (ATM) as bulky DNA damage-stimulated kinases that phosphorylate physiologically important residues on the checkpoint proteins p53, Chk1, and RPA. Consistent with these results, purified DNA-PK and ATM were directly stimulated by bulky adduct-containing DNA and preferentially associated with damaged DNA in vitro. Because the DNA damage response kinase ATM and Rad3-related (ATR) is also stimulated by bulky DNA adducts, we conclude that a common biochemical mechanism exists for activation of DNA-PK, ATM, and ATR by bulky adduct-containing DNA.     

Tipin-Replication Protein A Interaction Mediates Chk1 Phosphorylation by ATR in Response to Genotoxic Stress

Mammalian Timeless is a multifunctional protein that performs essential roles in the circadian clock, chromosome cohesion, DNA replication fork protection, and DNA replication/DNA damage checkpoint pathways. The human Timeless exists in a tight complex with a smaller protein called Tipin (Timeless-interacting protein). Here we investigated the mechanism by which the Timeless-Tipin complex functions as a mediator in the ATR-Chk1 DNA damage checkpoint pathway. We find that the Timeless-Tipin complex specifically mediates Chk1 phosphorylation by ATR in response to DNA damage and replication stress through interaction of Tipin with the 34-kDa subunit of replication protein A (RPA). The Tipin-RPA interaction stabilizes Timeless-Tipin and Tipin-Claspin complexes on RPA-coated ssDNA and in doing so promotes Claspin-mediated phosphorylation of Chk1 by ATR. Our results therefore indicate that RPA-covered ssDNA not only supports recruitment and activation of ATR but also, through Tipin and Claspin, it plays an important role in the action of ATR on its critical downstream target Chk1.     

Requirement of the Mre11 complex and exonuclease 1 for activation of the Mec1 signaling pathway

The large protein kinases, ataxia-telangiectasia mutated (ATM) and ATM-Rad3-related (ATR), orchestrate DNA damage checkpoint pathways. In budding yeast, ATM and ATR homologs are encoded by TEL1 and MEC1, respectively. The Mre11 complex consists of two highly related proteins, Mre11 and Rad50, and a third protein, Xrs2 in budding yeast or Nbs1 in mammals. The Mre11 complex controls the ATM/Tel1 signaling pathway in response to double-strand break (DSB) induction. We show here that the Mre11 complex functions together with exonuclease 1 (Exo1) in activation of the Mec1 signaling pathway after DNA damage and replication block. Mec1 controls the checkpoint responses following UV irradiation as well as DSB induction. Correspondingly, the Mre11 complex and Exo1 play an overlapping role in activation of DSB- and UV-induced checkpoints. The Mre11 complex and Exo1 collaborate in producing long single-stranded DNA (ssDNA) tails at DSB ends and promote Mec1 association with the DSBs. The Ddc1-Mec3-Rad17 complex associates with sites of DNA damage and modulates the Mec1 signaling pathway. However, Ddc1 association with DSBs does not require the function of the Mre11 complex and Exo1. Mec1 controls checkpoint responses to stalled DNA replication as well. Accordingly, the Mre11 complex and Exo1 contribute to activation of the replication checkpoint pathway. Our results provide a model in which the Mre11 complex and Exo1 cooperate in generating long ssDNA tracts and thereby facilitate Mec1 association with sites of DNA damage or replication block.     

Maintenance of replication forks and the S-phase checkpoint by Cdc18p and Orp1p

S-phase and DNA damage checkpoint controls block the onset of mitosis when DNA is damaged or DNA replication is incomplete. It has been proposed that damaged or incompletely replicated DNA generates structures that are sensed by the checkpoint control pathway, although little is known about the structures and mechanisms involved. Here, we show that the DNA replication initiation proteins Orp1p and Cdc18p are required to induce and maintain the S-phase checkpoint in Schizosaccharomyces pombe. The presence of DNA replication structures correlates with activation of the Cds1p checkpoint protein kinase and the S-phase checkpoint pathway. By contrast, induction of the DNA damage pathway is not dependent on Orp1p or Cdc18p. We propose that the presence of unresolved replication forks, together with Orp1p and Cdc18p, are necessary to activate the Cds1p-dependent S-phase checkpoint.     

Checkpoint arrest signaling in response to UV damage is independent of nucleotide excision repair in Saccharomyces cerevisiae

The recognition of DNA double-stranded breaks or single-stranded DNA gaps as a precondition for cell cycle checkpoint arrest has been well established. However, how bulky base damage such as UV-induced pyrimidine dimers elicits a checkpoint response has remained elusive. Nucleotide excision repair represents the main pathway for UV dimer removal that results in strand interruptions. However, we demonstrate here that Rad53p hyperphosphorylation, an early event of checkpoint signaling in Saccharomyces cerevisiae, is independent of nucleotide excision repair (NER), even if replication as a source of secondary DNA damage is excluded. Thus, our data hint at primary base damage or at UV damage (primary or secondary) that does not need to be processed by NER as the relevant substrate of damage-sensing checkpoint proteins.     

RHINO forms a stoichiometric complex with the 9-1-1 checkpoint clamp and mediates ATR-Chk1 signaling

The ATR-Chk1 signaling pathway mediates cellular responses to DNA damage and replication stress and is composed of a number of core factors that are conserved throughout eukaryotic organisms. However, humans and other higher eukaryotic species possess additional factors that are implicated in the regulation of this signaling network but that have not been extensively studied. Here we show that RHINO (for Rad9, Rad1, Hus1 interacting nuclear orphan) forms complexes with both the 9-1-1 checkpoint clamp and TopBP1 in human cells even in the absence of treatments with DNA damaging agents via direct interactions with the Rad9 and Rad1 subunits of the 9-1-1 checkpoint clamp and with the ATR kinase activator TopBP1. The interaction of RHINO with 9-1-1 was of sufficient affinity to allow for the purification of a stable heterotetrameric RHINO-Rad9-Hus1-Rad1 complex in vitro. In human cells, a portion of RHINO localizes to chromatin in the absence of DNA damage, and this association is enriched following UV irradiation. Furthermore, we find that the tethering of a Lac Repressor (LacR)-RHINO fusion protein to LacO repeats in chromatin of mammalian cells induces Chk1 phosphorylation in a Rad9- and Claspin-dependent manner. Lastly, the loss of RHINO partially abrogates ATR-Chk1 signaling following UV irradiation without impacting the interaction of the 9-1-1 clamp with TopBP1 or the loading of 9-1-1 onto chromatin. We conclude that RHINO is a bona fide regulator of ATR-Chk1 signaling in mammalian cells.     

Distinct modes of ATR activation after replication stress and DNA double-strand breaks in Caenorhabditis elegans

ATM and ATR are key components of the DNA damage checkpoint. ATR primarily responds to UV damage and replication stress, yet may also function with ATM in the checkpoint response to DNA double-strand breaks (DSBs), although this is less clear. Here, we show that atl-1 (Caenorhabditis elegans ATR) and rad-5/clk-2 prevent mitotic catastrophe, function in the S-phase checkpoint and also cooperate with atm-1 in the checkpoint response to DSBs after ionizing radiation (IR) to induce cell cycle arrest or apoptosis via the cep-1(p53)/egl-1 pathway. ATL-1 is recruited to stalled replication forks by RPA-1 and functions upstream of rad-5/clk-2 in the S-phase checkpoint. In contrast, mre-11 and atm-1 are dispensable for ATL-1 recruitment to stalled replication forks. However, mre-11 is required for RPA-1 association and ATL-1 recruitment to DSBs. Thus, DNA processing controlled by mre-11 is important for ATL-1 activation at DSBs but not following replication fork stalling. We propose that atl-1 and rad-5/clk-2 respond to single-stranded DNA generated by replication stress and function with atm-1 following DSB resection.     

Localization of checkpoint and repair proteins in eukaryotes

In eukaryotes, the cellular response to DNA damage depends on the type of DNA structure being recognized by the checkpoint and repair machinery. DNA ends and single-stranded DNA are hallmarks of double-strand breaks and replication stress. These two structures are recognized by distinct sets of proteins, which are reorganized into a focal assembly at the lesion. Moreover, the composition of these foci is coordinated with cell cycle progression, reflecting the favoring of end-joining in the G1 phase and homologous recombination in S and G2. The assembly of proteins at sites of DNA damage is largely controlled by a network of protein-protein interactions, with the Mre11 complex initiating assembly at DNA ends and replication protein A directing recruitment to single-stranded DNA. This review summarizes current knowledge on the cellular organization of DSB repair and checkpoint proteins focusing on budding yeast and mammalian cells.     

A Novel Replication Arrest Pathway in Response to DNA Damage

DNA damage has been shown to regulate DNA replication both by inhibition of origin utilization, and by slowing of replication progression. We have recently reported another mechanism by which DNA damage affects replication, in which the presence of damaged DNA inhibits, in trans, the initiation of chromosomal replication. This inhibition occurs by blocking the association of the processivity clamp PCNA with undamaged chromatin. This inhibitory activity is not due to sequestration of replication factors by the damaged DNA, rather, it acts through generation of a diffusible inhibitor of PCNA loading. The activation of this pathway is independent of canonical checkpoint signaling, and, in fact, results in activation of the checkpoint. This novel pathway may therefore represent an amplification step to stop cell cycle progression in response to lower levels of DNA damage.     

A novel replication arrest pathway in response to DNA damage

DNA damage has been shown to regulate DNA replication both by inhibition of origin utilization, and by slowing of replication progression. We have recently reported another mechanism by which DNA damage affects replication, in which the presence of damaged DNA inhibits, in trans, the initiation of chromosomal replication. This inhibition occurs by blocking the association of the processivity clamp PCNA with undamaged chromatin. This inhibitory activity is not due to sequestration of replication factors by the damaged DNA, rather, it acts through generation of a diffusible inhibitor of PCNA loading. The activation of this pathway is independent of canonical checkpoint signaling, and, in fact, results in activation of the checkpoint. This novel pathway may therefore represent an amplification step to stop cell cycle progression in response to lower levels of DNA damage.     

RHINO forms a stoichiometric complex with the 9-1-1 checkpoint clamp and mediates ATR-Chk1 signaling

The ATR-Chk1 signaling pathway mediates cellular responses to DNA damage and replication stress and is composed of a number of core factors that are conserved throughout eukaryotic organisms. However, humans and other higher eukaryotic species possess additional factors that are implicated in the regulation of this signaling network but that have not been extensively studied. Here we show that RHINO (for Rad9, Rad1, Hus1 interacting nuclear orphan) forms complexes with both the 9-1-1 checkpoint clamp and TopBP1 in human cells even in the absence of treatments with DNA damaging agents via direct interactions with the Rad9 and Rad1 subunits of the 9-1-1 checkpoint clamp and with the ATR kinase activator TopBP1. The interaction of RHINO with 9-1-1 was of sufficient affinity to allow for the purification of a stable heterotetrameric RHINO-Rad9-Hus1-Rad1 complex in vitro. In human cells, a portion of RHINO localizes to chromatin in the absence of DNA damage, and this association is enriched following UV irradiation. Furthermore, we find that the tethering of a Lac Repressor (LacR)-RHINO fusion protein to LacO repeats in chromatin of mammalian cells induces Chk1 phosphorylation in a Rad9- and Claspin-dependent manner. Lastly, the loss of RHINO partially abrogates ATR-Chk1 signaling following UV irradiation without impacting the interaction of the 9-1-1 clamp with TopBP1 or the loading of 9-1-1 onto chromatin. We conclude that RHINO is a bona fide regulator of ATR-Chk1 signaling in mammalian cells.     

NAR Breakthrough Article: Pre-activation of the genome integrity checkpoint increases DNA damage tolerance

The genome integrity checkpoint is a conserved signaling pathway that is regulated in yeast by the Mec1 (homologous to human ATR) and Rad53 (homologous to human Chk1) kinases. The pathway coordinates a multifaceted response that allows cells to cope with DNA damage and DNA replication stress. The full activation of the checkpoint blocks origin firing, stabilizes replication forks, activates DNA repair proteins and may lead to senescence or apoptosisin higher eukaryotes. We have recently demonstrated that endogenous replication stress can activate the genome integrity checkpoint in budding yeast at a low level that does not go so far as to interfere with cell cycle progression, but it does activate DNA damage-inducible proteins. Here we demonstrate that the low level pre-activation of the checkpoint, either by endogenous replication stress or by the nucleotide-depleting drug hydroxyurea, can increase damage tolerance to multiple DNA-damaging agents. These results may provide new strategies for using the checkpoint to protect normal cells from genotoxic stress.     

Claspin: Timing the Cell Cycle Arrest When the Genome is Damaged

DNA damage checkpoints maintain genomic integrity by delaying cell cycle progression in response to genotoxic stress and stalled replication forks. One central pathway in the checkpoint response is the ATR-Chk1 pathway, in which, upon DNA damage, ATR phosphorylates and activates the effector kinase Chk1. This process depends on the adaptor protein Claspin that bridges ATR and Chk1. Once the damage is repaired, this pathway must somehow be switched off to allow the cell to continue the cell division process, an event known as checkpoint recovery. Polo-like kinase 1 (Plk1) plays a central role during checkpoint recovery. Interestingly, the Xenopus homologue of Plk1, Plx1, is able to bind and phosphorylate Claspin, releasing it from DNA and thereby contributing to Chk1 inactivation. Moreover, it was recently demonstrated that Claspin levels are controlled by proteasomal degradation, and this is regulated by Plk1. Importantly, Plk1-mediated proteosomal degradation of Claspin appears to be essential for checkpoint recovery. Here we review these recent findings and discuss the mechanisms of checkpoint regulation by Claspin.     

DNA replication is required for the checkpoint response to damaged DNA in Xenopus egg extracts

Alkylating agents, such as methyl methanesulfonate (MMS), damage DNA and activate the DNA damage checkpoint. Although many of the checkpoint proteins that transduce damage signals have been identified and characterized, the mechanism that senses the damage and activates the checkpoint is not yet understood. To address this issue for alkylation damage, we have reconstituted the checkpoint response to MMS in Xenopus egg extracts. Using four different indicators for checkpoint activation (delay on entrance into mitosis, slowing of DNA replication, phosphorylation of the Chk1 protein, and physical association of the Rad17 checkpoint protein with damaged DNA), we report that MMS-induced checkpoint activation is dependent upon entrance into S phase. Additionally, we show that the replication of damaged double-stranded DNA, and not replication of damaged single-stranded DNA, is the molecular event that activates the checkpoint. Therefore, these data provide direct evidence that replication forks are an obligate intermediate in the activation of the DNA damage checkpoint.     

DNA structure-induced recruitment and activation of the Fanconi anemia pathway protein FANCD2

The Fanconi anemia (FA) pathway proteins are thought to be involved in the repair of irregular DNA structures including those encountered by the moving replication fork. However, the nature of the DNA structures that recruit and activate the FA proteins is not known. Because FA proteins function within an extended network of proteins, some of which are still unknown, we recently established cell-free assays in Xenopus laevis egg extracts to deconstruct the FA pathway in a fully replication-competent context. Here we show that the central FA pathway protein, xFANCD2, is monoubiquitinated (xFANCD2-L) rapidly in the presence of linear and branched double-stranded DNA (dsDNA) structures but not single-stranded or Y-shaped DNA. xFANCD2-L associates with dsDNA structures in an FA core complex-dependent manner but independently of xATRIP, the regulatory subunit of xATR. Formation of xFANCD2-L is also triggered in response to circular dsDNA, suggesting that dsDNA ends are not required to trigger monoubiquitination of FANCD2. The induction of xFANCD2-L in response to circular dsDNA is replication and checkpoint independent. Our results provide new evidence that the FA pathway discriminates among DNA structures and demonstrate that triggering the FA pathway can be uncoupled from DNA replication and ATRIP-dependent activation.     

The basic cleft of RPA70N binds multiple checkpoint proteins, including RAD9, to regulate ATR signaling

ATR kinase activation requires the recruitment of the ATR-ATRIP and RAD9-HUS1-RAD1 (9-1-1) checkpoint complexes to sites of DNA damage or replication stress. Replication protein A (RPA) bound to single-stranded DNA is at least part of the molecular recognition element that recruits these checkpoint complexes. We have found that the basic cleft of the RPA70 N-terminal oligonucleotide-oligosaccharide fold (OB-fold) domain is a key determinant of checkpoint activation. This protein-protein interaction surface is able to bind several checkpoint proteins, including ATRIP, RAD9, and MRE11. RAD9 binding to RPA is mediated by an acidic peptide within the C-terminal RAD9 tail that has sequence similarity to the primary RPA-binding surface in the checkpoint recruitment domain (CRD) of ATRIP. Mutation of the RAD9 CRD impairs its localization to sites of DNA damage or replication stress without perturbing its ability to form the 9-1-1 complex or bind the ATR activator TopBP1. Disruption of the RAD9-RPA interaction also impairs ATR signaling to CHK1 and causes hypersensitivity to both DNA damage and replication stress. Thus, the basic cleft of the RPA70 N-terminal OB-fold domain binds multiple checkpoint proteins, including RAD9, to promote ATR signaling.     

DNA polymerase stabilization at stalled replication forks requires Mec1 and the RecQ helicase Sgs1

To ensure proper replication and segregation of the genome, eukaryotic cells have evolved surveillance systems that monitor and react to impaired replication fork progression. In budding yeast, the intra-S phase checkpoint responds to stalled replication forks by downregulating late-firing origins, preventing spindle elongation and allowing efficient resumption of DNA synthesis after recovery from stress. Mutations in this pathway lead to high levels of genomic instability, particularly in the presence of DNA damage. Here we demonstrate by chromatin immunoprecipitation that when yeast replication forks stall due to hydroxyurea (HU) treatment, DNA polymerases alpha and epsilon are stabilized for 40-60 min. This requires the activities of Sgs1, a member of the RecQ family of DNA helicases, and the ATM-related kinase Mec1, but not Rad53 activation. A model is proposed whereby Sgs1 helicase resolves aberrantly paired structures at stalled forks to maintain single-stranded DNA that allows RP-A and Mec1 to promote DNA polymerase association.     

Strand-specific binding of RPA and XPA to damaged duplex DNA

The nucleotide excision repair (NER) pathway is a major pathway used to repair bulky adduct DNA damage. Two proteins, xeroderma pigmentosum group A protein (XPA) and replication protein A (RPA), have been implicated in the role of DNA damage recognition in the NER pathway. The particular manner in which these two damage recognition proteins align themselves with respect to a damaged DNA site was assessed using photoreactive base analogues within specific DNA substrates to allow site-specific cross-linking of the damage recognition proteins. Results of these studies demonstrate that both RPA and XPA are in close proximity to the adduct as measured by cross-linking of each protein directly to the platinum moiety. Additional studies demonstrate that XPA contacts both the damaged and undamaged strands of the duplex DNA. Direct evidence is presented demonstrating preferential binding of RPA to the undamaged strand of a duplex damaged DNA molecule.     

Turning the Replication Checkpoint On and Off

The replication checkpoint monitors the progress of DNA replication forks during S phase, and delays the firing of later replication origins when active replication forks are stalled due to collisions with damaged or abnormally structured DNA. Key components of the replication checkpoint pathway are the apical protein kinase, ATR, and its downstream target kinase, Chk1. Defects in either ATR or Chk1 function result in loss of DNA replication fidelity and cell viability, even in the absence of extrinsic genotoxic stress. Moreover, several clinically important antitumor agents, such as the camptothecins (CPTs), exert their antitumor effects by interfering with DNA replication, and hence the therapeutic response to these drugs is intimately related to signaling through the replication checkpoint. A recent report from this laboratory adds a new facet to the regulatory mechanisms that control the function and duration of checkpoint signaling through the ATR-Chk1 pathway. The results indicate that replication stress induced by a variety of agents, including CPT and deep hypoxia, triggers the ubiquitin-dependent degradation of the checkpoint kinase Chk1 in both normal and transformed human cells. This review provides an overview of the study’s major findings, together with their implications for both replication checkpoint function and tumor responsiveness to CPT and related anticancer drugs.