Checkpoint Signal Transduction Research Articles

Impact of mitochondrial dysfunction on the antitumor effects of immune cells.

Mitochondrial dysfunction, a hallmark of immune cell failure, affects the antitumor effects of immune cells through metabolic reprogramming, fission, fusion, biogenesis, and immune checkpoint signal transduction of mitochondria. According to researchers, restoring damaged mitochondrial function can enhance the efficacy of immune cells. Nevertheless, the mechanism of mitochondrial dysfunction in immune cells in patients with cancer is unclear. In this review, we recapitulate the impact of mitochondrial dysfunction on the antitumor effects of T cells, natural killer cells, dendritic cells, and tumor-associated macrophage and propose that targeting mitochondria can provide new strategies for antitumor therapy.

The multiple activations in budding yeast S-phase checkpoint are Poisson processes.

Eukaryotic cells activate the S-phase checkpoint signal transduction pathway in response to DNA replication stress. Affected by the noise in biochemical reactions, such activation process demonstrates cell-to-cell variability. Here, through the analysis of microfluidics-integrated time-lapse imaging, we found multiple S-phase checkpoint activations in a certain budding yeast cell cycle. Yeast cells not only varied in their activation moments but also differed in the number of activations within the cell cycle, resulting in a stochastic multiple activation process. By investigating dynamics at the single-cell level, we showed that stochastic waiting times between consecutive activations are exponentially distributed and independent from each other. Finite DNA replication time provides a robust upper time limit to the duration of multiple activations. The mathematical model, together with further experimental evidence from the mutant strain, revealed that the number of activations under different levels of replication stress agreed well with Poisson distribution. Therefore, the activation events of S-phase checkpoint meet the criterion of Poisson process during DNA replication. In sum, the observed Poisson activation process may provide new insights into the complex stochastic dynamics of signal transduction pathways.

Multivariate Gene Expression Analysis Identifies Novel Signatures and Therapeutic Targets for CLL Relapse

Abstract Chronic Lymphocytic Leukemia (CLL) is a hematological malignancy of immature B cells that is characterized by episodes of relapse. CLL relapse is supported by pro-survival factors, such as chemokines, secreted CLL cells of the CLL microenvironment. The CXCL13-CXCR5 axis has been previously shown to contribute to the progression of several malignancies and possibly CLL relapse. CXCR5 is highly expressed by CLL cells and CXCL13 serum levels were found to be significantly higher in CLL patients versus healthy donors. There is a gap in the understanding of the molecular mechanisms following CXCL13-CXCR5 interactions during CLL. The presence of CXCR5, CXCL13, and associated genes were investigated by using a novel weighted gene co-expression network analysis (WGCNA) method as well as examining overrepresentation of upstream regulators and biological functions found in the transcriptomes (24,658 genes) of CLL patients (n = 203). The WGCNA-designated yellow (p = 0.003), brown (p = 0.05), purple (p < 0.001), black (p = 0.006), and salmon (p = 0.001) modules were significantly correlated with relapse. The fourth-largest, yellow co-expression module contained CXCR5 and 1,315 other genes. The biological processes associated with this module included lipid metabolism, protein catabolism, positive regulation of cell cycle arrest, and cell cycle checkpoint signal transduction. Systems pharmacology analysis revealed drugs targeting ATPases, proteasomes, and microtubules, could disrupt CLL relapse signatures, found in the yellow module. Taken together, the relapse associated gene networks have provided new insights on the complex biology of CLL and identified new targets for the treatment CLL relpase.

Response of alternative splice isoforms of OsRad9 gene from Oryza sativa to environmental stress.

Rad9 protein plays an important role in cell-cycle checkpoint signal transduction in human and yeast cells, but knowledge about Rad9 in plants is limited. This study reports that the Rad9 gene of rice can generate the transcript products OsRad9.1 and OsRad9.2 through alternative splicing. OsRad9.1, with all nine exons, is the main cell-cycle checkpoint protein involved in the response of rice to genotoxic stresses (ultraviolet radiation and antibiotic stress), environmental stresses (drought, salt, and heavy metal stress), and auxin stimuli (2,4-D, IAA, and IBA). Meanwhile, transcript isoform OsRad9.2, which lost exon7 and exon8, showed different preferential stimulation effects on these stresses and pollen development duration. These results might indicat that besides the monitoring and repair of DNA damage, Rad9 might involve in the development of pollen.

Abstract 2119: DDB2 and XPC influence ATR and ATM recruitment and regulate DNA damage response upon UV irradiation

Abstract DNA damage response (DDR) pathways control the activation of DNA repair mechanisms, the activation and eventual release of cell cycle checkpoints to prevent replication of damaged DNA, and apoptosis as a last resort. These processes suggest the coordination of numerous proteins required to preserve genomic integrity. ATR and ATM kinases are central to checkpoint activation in response to DNA damage and replication stress. Activated ATR and ATM phosphorylate several proteins involved in DNA repair and cell cycle arrest. The nature of the signal, which activates ATR and ATM in response to UV damage, is not clear. Here, we showed that DDB2 and XPC, two early damage recognition factors, promote ATR and ATM recruitment and phosphorylation. ATR and ATM localize to the damage site and physically interact with XPC and DDB2. ATR and ATM recruitment and their phosphorylation are affected in cells defective in DDB2 and XPC function. In contrast, ATR- and ATM-deficiency do not regulate DDB2 and XPC recruitment to the damage site. Consequently, phosphorylation of ATR and ATM substrates Chk1, Chk2, H2AX, and BRCA1 was significantly reduced or abrogated in mutated cells, indicating that defective DDB2 and XPC function impair checkpoint signal transduction cascade in response to UV damage. Furthermore, DDB2 and XPC also regulate BRCA1 and Rad51 recruitment to the damage site, implicating their role in homologous recombination-mediated DNA repair pathway. Collectively, these data showed that ATR and ATM are present in the preincision complex with XPC, and influence DNA repair and checkpoint signaling pathways. In support of this, we revealed that depletion of ATR and ATM influence NER efficiency. These results are consistent with a model in which DDB2 and XPC cross-talk with ATR and ATM during maintenance of genomic integrity. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 2119. doi:1538-7445.AM2012-2119

Using the S. cerevisiae Stn1 telomere capping protein to dissect downstream responses of the S phase checkpoint

In the budding yeast S. cerevisiae, Stn1 is an essential protein that caps chromosome ends, and facilitates telomere replication. Previous work in our lab has shown that increasing the levels of Stn1 makes cells extremely sensitive to the replication inhibitors hydroxyurea (HU) and methyl‐methane sulfonate (MMS). Remarkably, this sensitivity corresponds with overproduced Stn1 abrogating most aspects of the S phase checkpoint, including destabilization of replication forks, de‐repression of late replication origins, and causing cells to arrest with elongated mitotic spindles. The Rad53 checkpoint kinase is activated normally in Stn1 overproducing cells, indicating Stn1 is impacting checkpoint responses downstream of the checkpoint signal transduction pathway. These observations indicate that Stn1 overproduction provides a unique reagent to probe downstream aspects of Rad53 function, and we are therefore analyzing the mechanism and genetic requirements by which Stn1 shuts down execution of the S phase checkpoint pathway. This work was funded in part by the NSF, grant number 1024792 awarded to Connie Nugent.

Dpb11 coordinates Mec1 kinase activation with cell cycle-regulated Rad9 recruitment

Eukaryotic cells respond to DNA damage by activating checkpoint signalling pathways. Checkpoint signals are transduced by a protein kinase cascade that also requires non-kinase mediator proteins. One such mediator is the Saccharomyces cerevisiae Dpb11 protein, which binds to and activates the apical checkpoint kinase, Mec1. Here, we show that a ternary complex of Dpb11, Mec1 and another key mediator protein Rad9 is required for efficient Rad9 phosphorylation by Mec1 in vitro, and for checkpoint activation in vivo. Phosphorylation of Rad9 by cyclin-dependent kinase (CDK) on two key residues generates a binding site for tandem BRCT repeats of Dpb11, and is thereby required for Rad9 recruitment into the ternary complex. Checkpoint signalling via Dpb11, therefore, does not efficiently occur during G1 phase when CDK is inactive. Thus, Dpb11 coordinates checkpoint signal transduction both temporally and spatially, ensuring the initiator kinase is specifically activated in proximity of one of its critical substrates.

Human exonuclease 1 connects nucleotide excision repair (NER) processing with checkpoint activation in response to UV irradiation

UV light induces DNA lesions, which are removed by nucleotide excision repair (NER). Exonuclease 1 (EXO1) is highly conserved from yeast to human and is implicated in numerous DNA metabolic pathways, including repair, recombination, replication, and telomere maintenance. Here we show that hEXO1 is involved in the cellular response to UV irradiation in human cells. After local UV irradiation, fluorescent-tagged hEXO1 localizes, together with NER factors, at the sites of damage in nonreplicating cells. hEXO1 accumulation requires XPF-dependent processing of UV-induced lesions and is enhanced by inhibition of DNA repair synthesis. In nonreplicating cells, depletion of hEXO1 reduces unscheduled DNA synthesis after UV irradiation, prevents ubiquitylation of histone H2A, and impairs activation of the checkpoint signal transduction cascade in response to UV damage. These findings reveal a key role for hEXO1 in the UV-induced DNA damage response linking NER to checkpoint activation in human cells.

Telomeres avoid end detection by severing the checkpoint signal transduction pathway

Telomeres protect the normal ends of chromosomes from being recognized as deleterious DNA double-strand breaks. Recent studies have uncovered an apparent paradox: although DNA repair is prevented, several proteins involved in DNA damage processing and checkpoint responses are recruited to telomeres in every cell cycle and are required for end protection. It is currently not understood how telomeres prevent DNA damage responses from causing permanent cell cycle arrest. Here we show that fission yeast (Schizosaccharomyces pombe) cells lacking Taz1, an orthologue of human TRF1 and TRF2 (ref. 2), recruit DNA repair proteins (Rad22(RAD52) and Rhp51(RAD51), where the superscript indicates the human orthologue) and checkpoint sensors (RPA, Rad9, Rad26(ATRIP) and Cut5/Rad4(TOPBP1)) to telomeres. Despite this, telomeres fail to accumulate the checkpoint mediator Crb2(53BP1) and, consequently, do not activate Chk1-dependent cell cycle arrest. Artificially recruiting Crb2(53BP1) to taz1Δ telomeres results in a full checkpoint response and cell cycle arrest. Stable association of Crb2(53BP1) to DNA double-strand breaks requires two independent histone modifications: H4 dimethylation at lysine 20 (H4K20me2) and H2A carboxy-terminal phosphorylation (γH2A). Whereas γH2A can be readily detected, telomeres lack H4K20me2, in contrast to internal chromosome locations. Blocking checkpoint signal transduction at telomeres requires Pot1 and Ccq1, and loss of either Pot1 or Ccq1 from telomeres leads to Crb2(53BP1) foci formation, Chk1 activation and cell cycle arrest. Thus, telomeres constitute a chromatin-privileged region of the chromosomes that lack essential epigenetic markers for DNA damage response amplification and cell cycle arrest. Because the protein kinases ATM and ATR must associate with telomeres in each S phase to recruit telomerase, exclusion of Crb2(53BP1) has a critical role in preventing telomeres from triggering cell cycle arrest.

Interference of Chkl/2 by RNA Regulates G2/M Arrest and Expressions of Cell Cycle Related Proteins Induced by Diallyl Disulfide*

Chk1 and Chk2 play major role in cell cycle checkpoint signaling pathway, which are mainly involved in G2/M cell cycle checkpoint signal transduction. Firstly, the siRNA targeting at Chk1 or Chk2 gene was transfected into human gastric cancer BGC823 cells for 24 h before 15 mg/L DADS was added Then, the mRNA and protein expression of Chk1 or Chk2 was detected by Real-time PCR and Western-blot respectively Cell cycle rates and expressions of CDC25C and cyclinB1 were determined by FCM and Western blot respectively. The results showed that the Chk1 or Chk2 expression was inhibited in Chk1 or Chk2 siRNA-transfected group, in which the Chk1 or Chk2 expression at mRNA level was reduced 84.7% and 69.0% respectively and the protein expression of Chk1 or Chk2 was reduced 73.4% and 78.5% respectively as compared with that in empty control group (P 0.05). Western blot showed that although DADS decreased expression of CDC25C and cyclinB1 in untransfected cells, inhibition of expression of CDC25C and cyclinB1 treated by DADS was blocked by Chk1 gene silence (P < 0.05). On the contrary.. Chk2 gene silence can not do so. These results suggest Chk1 gene silence could abrogate G2/M arrest induced by DADS in BGC823 cell line, and Chk1/CDC25C/cyclinB1 pathway was involved at the G2/M arrest induced by DADS

Antitumor activity of an allosteric inhibitor of centromere-associated protein-E

Centromere-associated protein-E (CENP-E) is a kinetochore-associated mitotic kinesin that is thought to function as the key receptor responsible for mitotic checkpoint signal transduction after interaction with spindle microtubules. We have identified GSK923295, an allosteric inhibitor of CENP-E kinesin motor ATPase activity, and mapped the inhibitor binding site to a region similar to that bound by loop-5 inhibitors of the kinesin KSP/Eg5. Unlike these KSP inhibitors, which block release of ADP and destabilize motor-microtubule interaction, GSK923295 inhibited release of inorganic phosphate and stabilized CENP-E motor domain interaction with microtubules. Inhibition of CENP-E motor activity in cultured cells and tumor xenografts caused failure of metaphase chromosome alignment and induced mitotic arrest, indicating that tight binding of CENP-E to microtubules is insufficient to satisfy the mitotic checkpoint. Consistent with genetic studies in mice suggesting that decreased CENP-E function can have a tumor-suppressive effect, inhibition of CENP-E induced tumor cell apoptosis and tumor regression.

Csm3, Tof1, and Mrc1 Form a Heterotrimeric Mediator Complex That Associates with DNA Replication Forks

Mrc1 (mediator of replication checkpoint), Tof1 (topoisomerase I interacting factor), and Csm3 (chromosome segregation in meiosis) are checkpoint-mediator proteins that function during DNA replication and activate the effector kinase Rad53. We reported previously that Mrc1 and Tof1 are constituents of the replication machinery and that both proteins are required for the proper arrest and stabilization of replication forks in the presence of hydroxyurea. In our current study, we show that Csm3 is a component of moving replication forks and that both Tof1 and Csm3 are specifically required for the association of Mrc1 with these structures. In contrast, the deletion of mrc1 did not affect the association of Tof1 and Csm3 with the replication fork complex. In agreement with previous observations in yeast cells, the results of a baculovirus coexpression system showed that these three proteins interact directly with each other to form a mediator complex in the absence of replication forks.

Regulation of Cdc45 in the cell cycle and after DNA damage

The Cdc (cell division cycle) 45 protein has a central role in the regulation of the initiation and elongation stages of eukaryotic chromosomal DNA replication. In addition, it is the main target for a Chk1 (checkpoint kinase 1)-dependent Cdc25/CDK2 (cyclin-dependent kinase 2)-independent DNA damage checkpoint signal transduction pathway following low doses of BPDE (benzo[a]pyrene dihydrodiol epoxide) treatment, which causes DNA damage similar to UV-induced adducts. Cdc45 interacts physically and functionally with the putative eukaryotic replicative DNA helicase, the MCM (mini-chromosome maintenance) complex, and forms a helicase active 'supercomplex', the CMG [Cdc45-MCM2-7-GINS (go-ichi-ni-san)] complex. These known protein-protein interactions, as well as unknown interactions and post-translational modifications, may be important for the regulation of Cdc45 and the initiation of DNA replication following DNA damage. Future studies will help to elucidate the molecular basis of this newly identified S-phase checkpoint pathway which has Cdc45 as a target.

Down-regulation of Chk1/Chk2 gene expression increases apoptosis in irradiated HeLa cells and its mechanism

To explore the increasing effect of blocking Chk1 and /or Chk2 gene by Chk1 or Chk2-specific antisense oligodeoxynucleotides (AsODN) on apoptosis in HeLa cell line after irradiation and its mechanism of action. Asynchronized HeLa cells were exposed to (60)Co-irradiation at different dosage to activate G(2)/M checkpoint arrest. The cell cycle profiles were observed in HeLa cells after irradiation at a range of various doses and different time points by flow cytometry. In the experimental groups, Chk1/2 sODN and AsODN alone or in combination were transfected into HeLa cells, and the cells were exposed to (60)Co-irradiation at 24 h after transfection. The changes of Chk1/2 protein expression were assayed by Western blot and confocal laser scanning microscopy (Confocal), and the cell cycles, apoptosis rates and cell cycle specific apoptosis were detected by annexin V-PI labeling and flow cytometry. Apoptotic response was significantly increased in the Hela cells after G(2)/M arrest and was inversed to activation of G(2)/M checkpoint. Either Chk1 or Chk2-specific AsODN consistently enhanced DNA damage-induced apoptosis by 90% approximately 120%, compared to corresponding sODN control (P < 0.05). Unexpectedly, combined use of Chk1- and Chk2-specific AsODN did not produce synergistic effect as compared to treatment with Chk1- or Chk2-specific AsODN alone (P > 0.05). While irradiated HeLa cells underwent apoptosis preferentially in G(1)-phase, apoptosis occurred in either of G(1)-, S- or G(2)/M -phase in the presence of Chk1 and/or Chk2 AsODN. The radioresistance is mainly induced by activating the cell cycle checkpoint signal transduction pathway after irradiation, and abrogating of the key effector Chk1 and Chk2 may increase the apoptotic sensitivity to irradiation due to changes of the pattern of cell cycle specific apoptosis.

Regulation of the Rad53 protein kinase in signal amplification by oligomer assembly and disassembly

Rad53, the ortholog of mammalian Chk2, is a major DNA damage checkpoint effector kinase in Saccharomyces cerevisiae. Despite extensive studies on the genetic requirements for Rad53 activation and its linkage downstream to checkpoint responses, the mechanism of Rad53 activation is not completely understood. Rad53-dependent signal amplification is thought to be a primary force that accelerates checkpoint signal transduction processes in response to DNA damage. Rad53 forms oligomers upon DNA damage in vivo. It is not clear how oligomer formation affects Rad53 activation and what is the mechanism of Rad53 oligomerization. Here, we monitor Rad53 oligomer assembly and disassembly in vitro. These processes are ATP-dependent and are regulated through phosphorylation. Mutations in FHA or SCD domains of RAD53 compromise intermolecular autophosphorylation activity and these domains are indispensable for Rad53 oligomerization. The mediator Rad9 is not necessary for Rad53 oligomerization. Rad53 kinase activity is required for disassembly of Rad53 oligomers in vivo after DNA damage. Moreover, induced oligomerization of Rad53 efficiently activates Rad53 in the absence of Mec1 in vivo. The results support the conclusions that Rad53/Chk2 homo-oligomerization is an evolutionarily conserved mechanism that drives Rad53/Chk2 activation and promotes signal amplification in DNA damage responses.

Mps1 Phosphorylates Borealin to Control Aurora B Activity and Chromosome Alignment

Maintenance of chromosomal stability relies on coordination between various processes that are critical for proper chromosome segregation in mitosis. Here we show that monopolar spindle 1 (Mps1) kinase, which is essential for the mitotic checkpoint, also controls correction of improper chromosome attachments. We report that Borealin/DasraB, a member of the complex that regulates the Aurora B kinase, is directly phosphorylated by Mps1 on residues that are crucial for Aurora B activity and chromosome alignment. As a result, cells lacking Mps1 kinase activity fail to efficiently align chromosomes due to impaired Aurora B function at centromeres, leaving improper attachments uncorrected. Strikingly, Borealin/DasraB bearing phosphomimetic mutations restores Aurora B activity and alignment in Mps1-depleted cells. Mps1 thus coordinates attachment error correction and checkpoint signaling, two crucial responses to unproductive chromosome attachments.

Cell cycle checkpoints: the role and evaluation for early diagnosis of senescence, cardiovascular, cancer, and neurodegenerative diseases

Maintenance of genomic integrity is critical for prevention of a wide variety of adverse cellular effects including apoptosis, cellular senescence, and malignant cell transformation. Under stress conditions and even during an unperturbed cell cycle, checkpoint proteins play the key role in genome maintenance by and mediating cellular response to DNA damage, and represent an essential part of the "cellular stress response proteome". Intact checkpoint signal transduction cascades check the presence of genome damage, trigger cell cycle arrest, and forward the information to the protein core of cell cycle machinery, replication apparatus, repair, and/or apoptotic protein cores. Genetic checkpoint defects lead to syndromes that demonstrate chromosomal instability, increased sensitivity to genotoxic stress, tissue degeneration, developmental retardation, premature aging, and cancer predisposition that is most extensively studied for the ATM-checkpoint mutated in Ataxia telangiectasia. Tissue specific epigenetic control over the function of cell cycle checkpoints can be, further, misregulated by aberrant DNA methylation status. The consequent checkpoint dysregulation may result in tissue specific degenerative processes such as degeneration and calcification of heart aortic valves, diabetic cardiomyopathy, hyperhomocysteinemic cerebrovascular, peripheral vascular and coronary heart diseases, neurodegenerative disorders (Alzheimer and Parkinson diseases, amyotrophic lateral sclerosis, glaucoma), and accelerated aging frequently accompanied with cancer. This review focuses on the checkpoints shown to be crucial for unperturbed cell cycle regulation, dysregulation of which might be considered as a potential molecular marker for early diagnosis of and therapy efficiency in neurodegenerative, cardiovascular and cancer diseases. An application of the most potent detection technologies such as "Disease Proteomics and Transcriptomics" also considered here, allows a most specific selection of diagnostic markers.

Different requirements for the association of ATR–ATRIP and 9-1-1 to the stalled replication forks

DNA replication checkpoint, a surveillance mechanism for S-phase progression, plays a crucial role for the maintenance of genome integrity. A variety of factors have been characterized to be involved in the checkpoint signal transduction. Rpa, a single strand DNA binding protein, was found to be responsible for forming a structure that is recognized by checkpoint sensors and then emits the initial signal for the activation of DNA damage checkpoint. Here we use a mutant of rpa1 gene, rfa1-t11, that has defects in recruiting checkpoint sensor proteins to the site of double strand break, to examine the mutant's effects on the activation of DNA replication checkpoint. We found that the mutant cells activated DNA replication checkpoint normally and showed no defects in recruiting ATR–ATRIP, a major sensor complex that is essential for DNA replication/damage checkpoint, to the site of stalled forks. In contrast, the mutant was defective in recruiting 9-1-1 complex, another sensor complex that functions in DNA damage checkpoint signal transduction, to the stalled forks. Moreover we found that sensitivity for HU obviously appeared in rfa1-t11 mutant when Mrc1 was deleted, while deletion of Rad9, an adaptor specific for damage checkpoint, had subtle effect. These data strongly suggest that rfa1-t11 mutant was mainly defective for activating DNA damage checkpoint and molecular requirement for the recruitment of ATR–ATRIP and 9-1-1 to the stressed forks may be different.

Meiotic spindle, spindle checkpoint and embryonic aneuploidy

In mitosis, a spindle checkpoint plays important roles at the metaphase-anaphase transition to ensure the formation of a bipolar spindle, the completion of connecting chromosomes to microtubules and the alignment of all chromosomes at the spindle equator before initiation of anaphase. Components of the spindle checkpoint were first identified through genetic screens in budding yeast and some checkpoint proteins later were found in a wide range of cells from yeast to human. However, the presence and function of the spindle checkpoint in mammalian meiosis, especially female meiosis, have long been disputed but evidence is now accumulating to support the existence. Recent studies indicate that a spindle checkpoint system participates in the regulation of mammalian female meiosis and prevention of embryonic aneuploidy. Here we review recent progress on checkpoint studies in both mitosis and meiosis, toward an understanding of the checkpoint signal transduction pathway and its role in preventing chromosome abnormalities during meiosis. Furthermore, the causes of embryonic aneuploidies and diagnosis are discussed.

Activation of Ataxia Telangiectasia-mutated DNA Damage Checkpoint Signal Transduction Elicited by Herpes Simplex Virus Infection

Eukaryotic cells are equipped with machinery to monitor and repair damaged DNA. Herpes simplex virus (HSV) DNA replication occurs at discrete sites in nuclei, the replication compartment, where viral replication proteins cluster and synthesize a large amount of viral DNA. In the present study, HSV infection was found to elicit a cellular DNA damage response, with activation of the ataxia-telangiectasia-mutated (ATM) signal transduction pathway, as observed by autophosphorylation of ATM and phosphorylation of multiple downstream targets including Nbs1, Chk2, and p53, while infection with a UV-inactivated virus or with a replication-defective virus did not. Activated ATM and the DNA damage sensor MRN complex composed of Mre11, Rad50, and Nbs1 were recruited and retained at sites of viral DNA replication, probably recognizing newly synthesized viral DNAs as abnormal DNA structures. These events were not observed in ATM-deficient cells, indicating ATM dependence. In Nbs1-deficient cells, HSV infection induced an ATM DNA damage response that was delayed, suggesting a functional MRN complex requirement for efficient ATM activation. However, ATM silencing had no effect on viral replication in 293T cells. Our data open up an interesting question of how the virus is able to complete its replication, although host cells activate ATM checkpoint signaling in response to the HSV infection.