Synthesis and properties of fluorescent derivatives of atractyloside as potential probes of the mitochondrial ADP/ATP carrier protein

The chemical synthesis of fluorescent derivatives of atractyloside (ATR), an inhibitor of the mitochondrial ADP/ATP carrier protein, is described. These derivatives are the following: 6′-O-dansyl ATR, 6′-O-dansyl-aminobutyryl ATR, and 6′-O-naphthoyl ATR. The spectral properties of these analogs were analyzed, and their biological features were compared to those of ATR. The fluorescence emission of the dansyl ATR derivatives was increased in organic solvents and that of naphthoyl ATR was decreased; for both analogs, solubilization in organic solvents resulted in a blue shift of the emission peak. The fluorescent dansyl and naphthoyl ATR derivatives were specifically recognized by the mitochondrial ADP/ATP carrier protein. Because of their spectral properties and their biochemical reactivities, the fluorescent analogs of ATR can be considered as potential probes to investigate the topography of the ADP/ATP carrier in the mitochondrial membrane and to monitor conformational changes of the ADP/ATP carrier protein associated with transport.     

UV-induced ataxia-telangiectasia-mutated and Rad3-related (ATR) activation requires replication stress

Ataxia-telangiectasia-mutated and Rad3-related (ATR) plays an essential role in the maintenance of genome integrity and cell viability. The kinase is activated in response to DNA damage and initiates a checkpoint signaling cascade by phosphorylating a number of downstream substrates including Chk1. Unlike ataxia-telangiectasia-mutated (ATM), which appears to be mainly activated by DNA double-strand breaks, ATR can be activated by a variety of DNA damaging agents. However, it is still unclear what triggers ATR activation in response to such diverse DNA lesions. One model proposes that ATR can directly recognize DNA lesions, while other recent data suggest that ATR is activated by a common single-stranded DNA (ssDNA) intermediate generated during DNA repair. In this study, we show that UV lesions do not directly activate ATR in vivo. In addition, ssDNA lesions created during the repair of UV damage are also not sufficient to activate the ATR-dependent pathway. ATR activation is only observed in replicating cells indicating that replication stress is required to trigger the ATR-mediated checkpoint cascade in response to UV irradiation. Interestingly, H2AX appears to be required for the accumulation of ATR at stalled replication forks. Together our data suggest that ssDNA at arrested replication forks recruits ATR and initiates ATR-mediated phosphorylation of H2AX and Chk1. Phosphorylated H2AX might further facilitate ATR activation by stabilizing ATR at the sites of arrested replication forks.     

ATR autophosphorylation as a molecular switch for checkpoint activation

The ataxia telangiectasia-mutated and Rad3-related (ATR) kinase is a master checkpoint regulator safeguarding the genome. Upon DNA damage, the ATR-ATRIP complex is recruited to sites of DNA damage by RPA-coated single-stranded DNA and activated by an elusive process. Here, we show that ATR is transformed into a hyperphosphorylated state after DNA damage, and that a single autophosphorylation event at Thr 1989 is crucial for ATR activation. Phosphorylation of Thr 1989 relies on RPA, ATRIP, and ATR kinase activity, but unexpectedly not on the ATR stimulator TopBP1. Recruitment of ATR-ATRIP to RPA-ssDNA leads to congregation of ATR-ATRIP complexes and promotes Thr 1989 phosphorylation in trans. Phosphorylated Thr 1989 is directly recognized by TopBP1 via the BRCT domains 7 and 8, enabling TopBP1 to engage ATR-ATRIP, to stimulate the ATR kinase, and to facilitate ATR substrate recognition. Thus, ATR autophosphorylation on RPA-ssDNA is a molecular switch to launch robust checkpoint response.     

hMSH2 recruits ATR to DNA damage sites for activation during DNA damage-induced apoptosis

DNA damage response (DDR) activates a complex signaling network that triggers DNA repair, cell cycle arrest, and/or cell death. Depending on the type and severity of DNA lesion, DDR is controlled by "master" regulators including ATM and ATR protein kinases. Cisplatin, a major chemotherapy drug that cross-links DNA, induces ATR-dependent DDR, resulting in apoptosis. However, it is unclear how ATR is activated. To identify the key regulators of ATR, we analyzed the proteins that associate with ATR after cisplatin treatment by blue native-PAGE and co-immunoprecipitation. The mismatch repair protein hMSH2 was found to be a major ATR-binding protein. Functionally, ATR activation and its recruitment to nuclear foci during cisplatin treatment were attenuated, and DNA damage signaling, involving Chk2, p53, and PUMA-α, was suppressed in hMSH2-deficient cells. ATR activation induced by the DNA methylating agent N-methyl-N-nitrosourea was also shown to be hMSH2-dependent. Intriguingly, hMSH2-mediated ATR recruitment and activation appeared independent of replication protein A, Rad17, and the Rad9-Hus1-Rad1 protein complex. Together the results support a hMSH2-dependent pathway of ATR activation and downstream Chk2/p53 signaling.     

Tethering DNA damage checkpoint mediator proteins topoisomerase IIbeta-binding protein 1 (TopBP1) and Claspin to DNA activates ataxia-telangiectasia mutated and RAD3-related (ATR) phosphorylation of checkpoint kinase 1 (Chk1)

The ataxia-telangiectasia mutated and RAD3-related (ATR) kinase initiates DNA damage signaling pathways in human cells after DNA damage such as that induced upon exposure to ultraviolet light by phosphorylating many effector proteins including the checkpoint kinase Chk1. The conventional view of ATR activation involves a universal signal consisting of genomic regions of replication protein A-covered single-stranded DNA. However, there are some indications that the ATR-mediated checkpoint can be activated by other mechanisms. Here, using the well defined Escherichia coli lac repressor/operator system, we have found that directly tethering the ATR activator topoisomerase IIβ-binding protein 1 (TopBP1) to DNA is sufficient to induce ATR phosphorylation of Chk1 in an in vitro system as well as in vivo in mammalian cells. In addition, we find synergistic activation of ATR phosphorylation of Chk1 when the mediator protein Claspin is also tethered to the DNA with TopBP1. Together, these findings indicate that crowding of checkpoint mediator proteins on DNA is sufficient to activate the ATR kinase.     

Cooperative activation of the ATR checkpoint kinase by TopBP1 and damaged DNA

TopBP1, acting in concert with DNA containing bulky base lesions, stimulates ATR kinase activity under physiologically relevant reaction conditions. Here, we analyze the roles of the three components in ATR activation: DNA, base damage and TopBP1. We show that base adducts caused by a potent carcinogen, benzo[a]pyrene diol epoxide (BPDE), constitute a strong signal for TopBP1-dependent ATR kinase activity on Chk1 and p53. We find that the C-terminus of TopBP1 binds preferentially to damaged DNA and is sufficient to mediate damaged DNA-dependent ATR activation in a manner similar to full-length TopBP1. Significantly, we find that stimulation of ATR by BPDE-damaged DNA exhibits strong dependence on the length of DNA, with essentially no stimulation with fragments of 0.2 kb and reaching maximum stimulation with 2 kb fragments. Moreover, TopBP1 shows preferential binding to longer DNA fragments and, in contrast to previous biochemical studies, TopBP1 binding is completely independent of DNA ends. We find that TopBP1 binds to circular and linear DNAs with comparable affinities and that these DNA forms elicit the same level of TopBP1-dependent ATR activation. Taken together, these findings suggest a cooperative activation mechanism for the ATR checkpoint kinase by TopBP1 and damaged DNA.     

The SUMO (Small Ubiquitin-like Modifier) Ligase PIAS3 Primes ATR for Checkpoint Activation

The maintenance of genomic stability relies on the concerted action of DNA repair and DNA damage signaling pathways. The PIAS (protein inhibitor of activated STAT) family of SUMO (small ubiquitin-like modifier) ligases has been implicated in DNA repair, but whether it plays a role in DNA damage signaling is still unclear. Here, we show that the PIAS3 SUMO ligase is important for activation of the ATR (ataxia telangiectasia and Rad3 related)-regulated DNA damage signaling pathway. PIAS3 is the only member of the PIAS family that is indispensable for ATR activation. In response to different types of DNA damage and replication stress, PIAS3 plays multiple roles in ATR activation. In cells treated with camptothecin (CPT), PIAS3 contributes to formation of DNA double-stranded breaks. In UV (ultraviolet light)- or HU (hydroxyurea)-treated cells, PIAS3 is required for efficient ATR autophosphorylation, one of the earliest events during ATR activation. Although PIAS3 is dispensable for ATRIP (ATR-interacting protein) SUMOylation and the ATR-ATRIP interaction, it is required for maintaining the basal kinase activity of ATR prior to DNA damage. In the absence of PIAS3, ATR fails to display normal kinase activity after DNA damage, which accompanies with reduced phosphorylation of ATR substrates. Together, these results suggest that PIAS3 primes ATR for checkpoint activation by sustaining its basal kinase activity, revealing a new function of the PIAS family in DNA damage signaling.     

ATR kinase activity regulates the intranuclear translocation of ATR and RPA following ionizing radiation

Upon damage of DNA in eukaryotic cells, several repair and checkpoint proteins undergo a dramatic intranuclear relocalization, translocating to nuclear foci thought to represent sites of DNA damage and repair. Examples of such proteins include the checkpoint kinase ATR (ATM and Rad3-related) as well as replication protein A (RPA), a single-stranded DNA binding protein required in DNA replication and repair. Here, we used a microscopy-based approach to investigate whether the damage-induced translocation of RPA is an active process regulated by ATR. Our data show that in undamaged cells, ATR and RPA are uniformly distributed in the nucleus or localized to promyelocytic leukemia protein (PML) nuclear bodies. In cells treated with ionizing radiation, both ATR and RPA translocate to punctate, abundant nuclear foci where they continue to colocalize. Surprisingly, an ATR mutant that lacks kinase activity fails to relocalize in response to DNA damage. Furthermore, this kinase-inactive mutant blocks the translocation of RPA in a cell cycle-dependent manner. These observations demonstrate that the kinase activity of ATR is essential for the irradiation-induced release of ATR and RPA from PML bodies and translocation of ATR and RPA to potential sites of DNA damage.     

Dormant origin signaling during unperturbed replication

Mechanisms that limit origin firing are essential as the ˜50,000 origins that replicate the human genome in unperturbed cells are chosen from an excess of ˜500,000 licensed origins. Computational models of the spatiotemporal pattern of replication foci assume that origins fire stochastically with a domino-like progression that places later firing origins near recent fired origins. These stochastic models of origin firing require dormant origin signaling that inhibits origin firing and suppresses licensed origins for passive replication at a distance of ∼7–120 kbp around replication forks. ATR and CHK1 kinase inhibitors increase origin firing and increase origin density in unperturbed cells. Thus, basal ATR and CHK1 kinase-dependent dormant origin signaling inhibits origin firing and there appear to be two thresholds of ATR kinase signaling. A minority of ATR molecules are activated for ATR and CHK1 kinase-dependent dormant origin signaling and this is essential for DNA replication in unperturbed cells. A majority of ATR molecules are activated for ATR and CHK1 kinase-dependent checkpoint signaling in cells treated with DNA damaging agents that target replication forks. Since ATR and CHK1 kinase inhibitors increase origin firing and this is associated with fork stalling and extensive regions of single-stranded DNA, they are DNA damaging agents. Accordingly, the sequence of administration of ATR and CHK1 kinase inhibitors and DNA damaging agents may impact the DNA damage induced by the combination and the efficacy of cell killing by the combination.     

Herpes Simplex Virus Type 1 Single Strand DNA Binding Protein and Helicase/Primase Complex Disable Cellular ATR Signaling

Herpes Simplex Virus type 1 (HSV-1) has evolved to disable the cellular DNA damage response kinase, ATR. We have previously shown that HSV-1-infected cells are unable to phosphorylate the ATR substrate Chk1, even under conditions in which replication forks are stalled. Here we report that the HSV-1 single stranded DNA binding protein (ICP8), and the helicase/primase complex (UL8/UL5/UL52) form a nuclear complex in transfected cells that is necessary and sufficient to disable ATR signaling. This complex localizes to sites of DNA damage and colocalizes with ATR/ATRIP and RPA, but under these conditions, the Rad9-Rad1-Hus1 checkpoint clamp (9-1-1) do not. ATR is generally activated by substrates that contain ssDNA adjacent to dsDNA, and previous work from our laboratory has shown that ICP8 and helicase/primase also recognize this substrate. We suggest that these four viral proteins prevent ATR activation by binding to the DNA substrate and obstructing loading of the 9-1-1 checkpoint clamp. Exclusion of 9-1-1 prevents recruitment of TopBP1, the ATR kinase activator, and thus effectively disables ATR signaling. These data provide the first example of viral DNA replication proteins obscuring access to a DNA substrate that would normally trigger a DNA damage response and checkpoint signaling. This unusual mechanism used by HSV suggests that it may be possible to inhibit ATR signaling by preventing recruitment of the 9-1-1 clamp and TopBP1.     

DNA structure-specific priming of ATR activation by DNA-PKcs

Three phosphatidylinositol-3-kinase–related protein kinases implement cellular responses to DNA damage. DNA-dependent protein kinase catalytic subunit (DNA-PKcs) and ataxia-telangiectasia mutated respond primarily to DNA double-strand breaks (DSBs). Ataxia-telangiectasia and RAD3-related (ATR) signals the accumulation of replication protein A (RPA)–covered single-stranded DNA (ssDNA), which is caused by replication obstacles. Stalled replication intermediates can further degenerate and yield replication-associated DSBs. In this paper, we show that the juxtaposition of a double-stranded DNA end and a short ssDNA gap triggered robust activation of endogenous ATR and Chk1 in human cell-free extracts. This DNA damage signal depended on DNA-PKcs and ATR, which congregated onto gapped linear duplex DNA. DNA-PKcs primed ATR/Chk1 activation through DNA structure-specific phosphorylation of RPA32 and TopBP1. The synergistic activation of DNA-PKcs and ATR suggests that the two kinases combine to mount a prompt and specific response to replication-born DSBs.     

ATR: an essential regulator of genome integrity

Genome maintenance is a constant concern for cells, and a coordinated response to DNA damage is required to maintain cellular viability and prevent disease. The ataxia-telangiectasia mutated (ATM) and ATM and RAD3-related (ATR) protein kinases act as master regulators of the DNA-damage response by signalling to control cell-cycle transitions, DNA replication, DNA repair and apoptosis. Recent studies have provided new insights into the mechanisms that control ATR activation, have helped to explain the overlapping but non-redundant activities of ATR and ATM in DNA-damage signalling, and have clarified the crucial functions of ATR in maintaining genome integrity.     

Xenopus ATR is a replication-dependent chromatin-binding protein required for the DNA replication checkpoint

BACKGROUND: The DNA replication checkpoint ensures that mitosis is not initiated before DNA synthesis is completed. Recent studies using Xenopus extracts have demonstrated that activation of the replication checkpoint and phosphorylation of the Chk1 kinase are dependent on RNA primer synthesis by DNA polymerase alpha, and it has been suggested that the ATR kinase-so-called because it is related to the product of the gene that is mutated in ataxia telangiectasia (ATM) and to Rad3 kinase-may be an upstream component of this response. It has been difficult to test this hypothesis as an ATR-deficient system suitable for biochemical studies has not been available. RESULTS: We have cloned the Xenopus laevis homolog of ATR (XATR) and studied the function of the protein in Xenopus egg extracts. Using a chromatin-binding assay, we found that ATR associates with chromatin after initiation of replication, dissociates from chromatin upon completion of replication, and accumulates in the presence of aphidicolin, an inhibitor of DNA replication. Its association with chromatin was inhibited by treatment with actinomycin D, an inhibitor of RNA primase. There was an early rise in the activity of Cdc2-cyclin B in egg extracts depleted of ATR both in the presence or absence of aphidicolin. In addition, the premature mitosis observed upon depletion of ATR was accompanied by the loss of Chk1 phosphorylation. CONCLUSIONS: ATR is a replication-dependent chromatin-binding protein, and its association with chromatin is dependent on RNA synthesis by DNA polymerase alpha. Depletion of ATR leads to premature mitosis in the presence and absence of aphidicolin, indicating that ATR is required for the DNA replication checkpoint.     

Phosphorylation of the BRCA1 C Terminus (BRCT) Repeat Inhibitor of hTERT (BRIT1) Protein Coordinates TopBP1 Protein Recruitment and Amplifies Ataxia Telangiectasia-mutated and Rad3-related (ATR) Signaling

The ataxia telangiectasia-mutated and Rad3-related (ATR) kinase functions as a central node in the DNA damage response signaling network. The mechanisms by which ATR activity is amplified and/or maintained are not understood. Here we demonstrate that BRIT1/microcephalin (MCPH1), a human disease-related protein, is dispensable for the initiation but essential for the amplification of ATR signaling. BRIT1 interacts with and recruits topoisomerase-binding protein 1 (TopBP1), a key activator of ATR signaling, to the sites of DNA damage. Notably, replication stress-induced ataxia telangiectasia-mutated or ATR-dependent BRIT1 phosphorylation at Ser-322 facilitates efficient TopBP1 recruitment. These results reveal a mechanism that ensures the continuation of ATR-initiated DNA damage signaling. Our study uncovers a previously unknown regulatory axis of ATR signaling in maintaining genomic integrity, which may provide mechanistic insights into the perturbation of ATR signaling in human diseases such as neurodevelopmental defects and cancer.     

Senescence of human fibroblasts after psoralen photoactivation is mediated by ATR kinase and persistent DNA damage foci at telomeres

Cellular senescence is a phenotype that is likely linked with aging. Recent concepts view different forms of senescence as permanently maintained DNA damage responses partially characterized by the presence of senescence-associated DNA damage foci at dysfunctional telomeres. Irradiation of primary human dermal fibroblasts with the photosensitizer 8-methoxypsoralen and ultraviolet A radiation (PUVA) induces senescence. In the present study, we demonstrate that senescence after PUVA depends on DNA interstrand cross-link (ICL) formation that activates ATR kinase. ATR is necessary for the manifestation and maintenance of the senescent phenotype, because depletion of ATR expression before PUVA prevents induction of senescence, and reduction of ATR expression in PUVA-senesced fibroblasts releases cells from growth arrest. We find an ATR-dependent phosphorylation of the histone H2AX (gamma-H2AX). After PUVA, ATR and gamma-H2AX colocalize in multiple nuclear foci. After several days, only few predominantly telomere-localized foci persist and telomeric DNA can be coimmunoprecipitated with ATR from PUVA-senesced fibroblasts. We thus identify ATR as a novel mediator of telomere-dependent senescence in response to ICL induced by photoactivated psoralens.     

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.     

Quaternary structure of ATR and effects of ATRIP and replication protein A on its DNA binding and kinase activities

ATR is an essential protein that functions as a damage sensor and a proximal kinase in the DNA damage checkpoint response in mammalian cells. It is a member of the phosphoinositide 3-kinase-like kinase (PIKK) family, which includes ATM, ATR, and DNA-dependent protein kinase. Recently, it was found that ATM is an oligomeric protein that is converted to an active monomeric form by phosphorylation in trans upon DNA damage, and this raised the possibility that other members of the PIKK family may be regulated in a similar manner. Here we show that ATR is a monomeric protein associated with a smaller protein called ATRIP with moderate affinity. The ATR protein by itself or in the form of the ATR-ATRIP heterodimer binds to naked or replication protein A (RPA)-covered DNAs with comparable affinities. However, the phosphorylation of RPA by ATR is dependent on single-stranded DNA and is stimulated by ATRIP. These findings suggest that the regulation and mechanism of action of ATR are fundamentally different from those of the other PIKK proteins.     

ATRIP oligomerization is required for ATR-dependent checkpoint signaling

The ATM and ATR kinases signal cell cycle checkpoint responses to DNA damage. Inactive ATM is an oligomer that is disrupted to form active monomers in response to ionizing radiation. We examined whether ATR is activated by a similar mechanism. We found that the ATRIP subunit of the ATR kinase and ATR itself exist as homooligomers in cells. We did not detect regulation of ATR or ATRIP oligomerization after DNA damage. The predicted coiled-coil domain of ATRIP is essential for ATRIP oligomerization, stable ATR binding, and accumulation of ATRIP at DNA lesions. Additionally, the ATRIP coiled-coil is also required for ATRIP to support ATR-dependent checkpoint signaling to Chk1. Replacing the ATRIP coiled-coil domain with a heterologous dimerization domain restored stable binding to ATR and localization to damage-induced intranuclear foci. Thus, the ATR-ATRIP complex exists in higher order oligomeric states within cells and ATRIP oligomerization is essential for its function.     

Regulation of DNA replication by ATR: signaling in response to DNA intermediates

The nuclear protein kinase ATR controls S-phase progression in response to DNA damage and replication fork stalling, including damage caused by ultraviolet irradiation, hyperoxia, and replication inhibitors like aphidicolin and hydroxyurea. ATR activation and substrate specificity require the presence of adapter and mediator molecules, ultimately resulting in the downstream inhibition of the S-phase kinases that function to initiate DNA replication at origins of replication. The data reviewed strongly support the hypothesis that ATR is activated in response to persistent RPA-bound single-stranded DNA, a common intermediate of unstressed and damaged DNA replication and metabolism.     

Claspin operates downstream of TopBP1 to direct ATR signaling towards Chk1 activation

TopBP1 and Claspin are adaptor proteins that facilitate phosphorylation of Chk1 by the ATR kinase in response to genotoxic stress. Despite their established requirement for Chk1 activation, the exact way in which TopBP1 and Claspin control Chk1 phosphorylation remains unclear. We show that TopBP1 tightly colocalizes with ATR in distinct nuclear subcompartments generated by DNA damage. Although depletion of TopBP1 by RNA interference (RNAi) strongly impaired phosphorylation of multiple ATR targets, including Chk1, Nbs1, Smc1, and H2AX, it did not interfere with ATR assembly at the sites of DNA damage. These findings challenge the current concept of ATR activation by recruitment to damaged DNA. In contrast, Claspin, like Chk1, remained distributed throughout the nucleus both before and after DNA damage. Consistently, the RNAi-mediated ablation of Claspin selectively abrogated ATR's ability to phosphorylate Chk1 but not other ATR targets. In addition, downregulation of Claspin mimicked Chk1 inactivation by inducing spontaneous DNA damage. Finally, we show that TopBP1 is required for the DNA damage-induced interaction between Claspin and Chk1. Together, these results suggest that while TopBP1 is a general regulator of ATR, Claspin operates downstream of TopBP1 to selectively regulate the Chk1-controlled branch of the genotoxic stress response.