Loss of CCDC6 affects cell cycle through impaired intra-S-phase checkpoint control

In most cancers harboring Ccdc6 gene rearrangements, like papillary thyroid tumors or myeloproliferative disorders, the product of the normal allele is supposed to be functionally impaired or absent. To address the consequence of the loss of CCDC6 expression, we applied lentiviral shRNA in several cell lines. Loss of CCDC6 resulted in increased cell death with clear shortening of the S phase transition of the cell cycle. Upon exposure to etoposide, the cells lacking CCDC6 did not achieve S-phase accumulation. In the absence of CCDC6 and in the presence of genotoxic stress, like etoposide treatment or UV irradiation, increased accumulation of DNA damage was observed, as indicated by a significant increase of pH2Ax Ser139. 14-3-3σ, a major cell cycle regulator, was down-regulated in CCDC6 lacking cells, regardless of genotoxic stress. Interestingly, in the absence of CCDC6, the well-known genotoxic stress-induced cytoplasmic sequestration of the S-phase checkpoint CDC25C phosphatase did not occur. These observations suggest that CCDC6 plays a key role in cell cycle control, maintenance of genomic stability and cell survival and provide a rational of how disruption of CCDC6 normal function contributes to malignancy.     

Critical role of monoubiquitination of histone H2AX protein in histone H2AX phosphorylation and DNA damage response

DNA damage response is an important surveillance mechanism used to maintain the integrity of the human genome in response to genotoxic stress. Histone variant H2AX is a critical sensor that undergoes phosphorylation at serine 139 upon genotoxic stress, which provides a docking site to recruit the mediator of DNA damage checkpoint protein 1 (MDC1) and DNA repair protein complex to sites of DNA breaks for DNA repair. Here, we show that monoubiquitination of H2AX is induced upon DNA double strand breaks and plays a critical role in H2AX Ser-139 phosphorylation (γ-H2AX), in turn facilitating the recruitment of MDC1 to DNA damage foci. Mechanistically, we show that monoubiquitination of H2AX induced by RING finger protein 2 (RNF2) is required for the recruitment of active ataxia telangiectasia mutated to DNA damage foci, thus affecting the formation of γ-H2AX. Importantly, a defect in monoubiquitination of H2AX profoundly enhances ionizing radiation sensitivity. Our study therefore suggests that monoubiquitination of H2AX is an important step for DNA damage response and may have important clinical implications for the treatment of cancers.     

TIPRL Inhibits Protein Phosphatase 4 Activity and Promotes H2AX Phosphorylation in the DNA Damage Response

Despite advances in our understanding of protein kinase regulation in the DNA damage response, the mechanism that controls protein phosphatase activity in this pathway is unclear. Unlike kinases, the activity and specificity of serine/threonine phosphatases is governed largely by their associated proteins. Here we show that Tip41-like protein (TIPRL), an evolutionarily conserved binding protein for PP2A-family phosphatases, is a negative regulator of protein phosphatase 4 (PP4). Knockdown of TIPRL resulted in increased PP4 phosphatase activity and formation of the active PP4-C/PP4R2 complex known to dephosphorylate γ-H2AX. Thus, overexpression of TIPRL promotes phosphorylation of H2AX, and increases γ-H2AX positive foci in response to DNA damage, whereas knockdown of TIPRL inhibits γ-H2AX phosphorylation. In correlation with γ-H2AX levels, we found that TIPRL overexpression promotes cell death in response to genotoxic stress, and knockdown of TIPRL protects cells from genotoxic agents. Taken together, these data demonstrate that TIPRL inhibits PP4 activity to allow for H2AX phosphorylation and the subsequent DNA damage response.     

Enhanced H2AX Phosphorylation,DNA Replication Fork Arrest,and Cell Death in the Absence of Chk1

H2AX phosphorylation at serine 139 (γH2AX) is a sensitive indicator of both DNA damage and DNA replication stress. Here we show that γH2AX formation is greatly enhanced in response to replication inhibitors but not ionizing radiation in HCT116 or SW480 cells depleted of Chk1. Although H2AX phosphorylation precedes the induction of apoptosis in such cells, our results suggest that cells containing γH2AX are not committed to death. γH2AX foci in these cells largely colocalize with RPA foci and their formation is dependent upon the essential replication helicase cofactor Cdc45, suggesting that H2AX phosphorylation occurs at sites of stalled forks. However Chk1-depleted cells released from replication inhibitors retain γH2AX foci and do not appear to resume replicative DNA synthesis. BrdU incorporation only occurs in a minority of Chk1-depleted cells containing γH2AX foci after release from thymidine arrest and, in cells incorporating BrdU, DNA synthesis does not occur at sites of γH2AX foci. Furthermore activated ATM and Chk2 persist in these cells. We propose that the γH2AX foci in Chk1-depleted cells may represent sites of persistent replication fork damage or abandonment that are unable to resume DNA synthesis but do not play a direct role in the Chk1 suppressed death pathway.     

Protein phosphatase PP6 is required for homology-directed repair of DNA double-strand breaks

DNA double-strand breaks (DSBs) are among the most lethal lesions associated with genome stability which, when destabilized, predisposes organs to cancers. DSBs are primarily fixed either with little fidelity by non-homologous end joining (NHEJ) repair or with high fidelity by homology-directed repair (HDR). The phosphorylated form of H2AX on serine 139 (g-H2AX) is a marker of DSBs. In this study, we explored if the protein phosphatase PP6 is involved in DSB repair by depletion of its expression in human cancer cell lines, and determined PP6 expression in human breast cancer tissues by immunohistochemistry staining. We found that bacterially-produced PP6c (the catalytic subunit of PP6)-containing heterotrimeric combinations exhibit phosphatase activity against g-H2AX in the in vitro phosphatase assays. Depletion of PP6c or PP6R2 led to persistent high levels of g-H2AX after DNA damage and a defective HDR. Chromatin immunoprecipitation assays demonstrated that PP6c was recruited to the region adjacent to the DSB sites. Expression of PP6c, PP6R2, and PP6R3 in human breast tumors was significantly lower than those in benign breast diseases. Taken together, our results suggest that g-H2AX is a physiological substrate of PP6, and PP6 is required for HDR and its expression may harbor a protective role during the development of breast cancer.     

Protein phosphatase PP6 is required for homology-directed repair of DNA double-strand breaks

DNA double-strand breaks (DSBs) are among the most lethal lesions associated with genome stability, which, when destabilized, predisposes organs to cancers. DSBs are primarily fixed either with little fidelity by non-homologous end joining (NHEJ) repair or with high fidelity by homology-directed repair (HDR). The phosphorylated form of H2AX on serine 139 (γ-H2AX) is a marker of DSBs. In this study, we explored if the protein phosphatase PP6 is involved in DSB repair by depletion of its expression in human cancer cell lines, and determined PP6 expression in human breast cancer tissues by immunohistochemistry staining. We found that bacterially produced PP6c (the catalytic subunit of PP6)-containing heterotrimeric combinations exhibit phosphatase activity against γ-H2AX in the in vitro phosphatase assays. Depletion of PP6c or PP6R2 led to persistent high levels of γ-H2AX after DNA damage and a defective HDR. Chromatin immunoprecipitation assays demonstrated that PP6c was recruited to the region adjacent to the DSB sites. Expression of PP6c, PP6R2 and PP6R3 in human breast tumors was significantly lower than those in benign breast diseases. Taken together, our results suggest that γ-H2AX is a physiological substrate of PP6 and PP6 is required for HDR and its expression may harbor a protective role during the development of breast cancer.Key words: protein phosphatase, PP6, γ-H2AX, DNA double-strand break, homology-directed repair     

PP4 is a gamma H2AX phosphatase required for recovery from the DNA damage checkpoint

Phosphorylation of histone H2AX on Ser 139 (γH2AX) is one of the earliest events in the response to DNA double-strand breaks; however, the subsequent removal of γH2AX from chromatin is less understood, despite being a process tightly coordinated with DNA repair. Previous studies in yeast have identified the Pph3 phosphatase (the PP4C orthologue) as important for the dephosphorylation of γH2AX. By contrast, work in human cells attributed this activity to PP2A. Here, we report that PP4 contributes to the dephosphorylation of γH2AX, both at the sites of DNA damage and in undamaged chromatin in human cells, independently of a role in DNA repair. Furthermore, depletion of PP4C results in a prolonged checkpoint arrest, most likely owing to the persistence of mediator of DNA damage checkpoint 1 (MDC1) at the sites of DNA lesions. Taken together, these results indicate that PP4 is an evolutionarily conserved γH2AX phosphatase.     

A PP4-phosphatase complex dephosphorylates gamma-H2AX generated during DNA replication

The histone H2A variant H2AX is rapidly phosphorylated in response to DNA double-stranded breaks to produce gamma-H2AX. gamma-H2AX stabilizes cell-cycle checkpoint proteins and DNA repair factors at the break site. We previously found that the protein phosphatase PP2A is required to resolve gamma-H2AX foci and complete DNA repair after exogenous DNA damage. Here we describe a three-protein PP4 phosphatase complex in mammalian cells, containing PP4C, PP4R2, and PP4R3beta, that specifically dephosphorylates ATR-mediated gamma-H2AX generated during DNA replication. PP4 efficiently dephosphorylates gamma-H2AX within mononucleosomes in vitro and does not directly alter ATR or checkpoint kinase activity, suggesting that PP4 acts directly on gamma-H2AX in cells. When the PP4 complex is silenced, repair of DNA replication-mediated breaks is inefficient, and cells are hypersensitive to DNA replication inhibitors, but not radiomimetic drugs. Therefore, gamma-H2AX elimination at DNA damage foci is required for DNA damage repair, but accomplishing this task involves distinct phosphatases with potentially overlapping roles.     

Histone H2AX and Fanconi anemia FANCD2 function in the same pathway to maintain chromosome stability

Fanconi anemia (FA) is a chromosome fragility syndrome characterized by bone marrow failure and cancer susceptibility. The central FA protein FANCD2 is known to relocate to chromatin upon DNA damage in a poorly understood process. Here, we have induced subnuclear accumulation of DNA damage to prove that histone H2AX is a novel component of the FA/BRCA pathway in response to stalled replication forks. Analyses of cells from H2AX knockout mice or expressing a nonphosphorylable H2AX (H2AX(S136A/S139A)) indicate that phosphorylated H2AX (gammaH2AX) is required for recruiting FANCD2 to chromatin at stalled replication forks. FANCD2 binding to gammaH2AX is BRCA1-dependent and cells deficient or depleted of H2AX show an FA-like phenotype, including an excess of chromatid-type chromosomal aberrations and hypersensitivity to MMC. This MMC hypersensitivity of H2AX-deficient cells is not further increased by depleting FANCD2, indicating that H2AX and FANCD2 function in the same pathway in response to DNA damage-induced replication blockage. Consequently, histone H2AX is functionally connected to the FA/BRCA pathway to resolve stalled replication forks and prevent chromosome instability.     

RB signaling prevents replication-dependent DNA double-strand breaks following genotoxic insult

Cell cycle checkpoints induced by DNA damage play an integral role in preservation of genomic stability by allowing cells to limit the propagation of deleterious mutations. The retinoblastoma tumor suppressor (RB) is crucial for the maintenance of the DNA damage checkpoint function because it elicits cell cycle arrest in response to a variety of genotoxic stresses. Although sporadic loss of RB is characteristic of most cancers and results in the bypass of the DNA damage checkpoint, the consequence of RB loss upon chemotherapeutic responsiveness has been largely uninvestigated. Here, we employed a conditional knockout approach to ablate RB in adult fibroblasts. This system enabled us to examine the DNA damage response of adult cells following acute RB deletion. Using this system, we demonstrated that loss of RB disrupted the DNA damage checkpoint elicited by either cisplatin or camptothecin exposure. Strikingly, this bypass was not associated with enhanced repair, but rather the accumulation of phosphorylated H2AX (γH2AX) foci, which indicate DNA double-strand breaks. The formation of γH2AX foci was due to ongoing replication following chemotherapeutic treatment in the RB-deficient cells. Additionally, peak γH2AX accumulation occurred in S-phase cells undergoing DNA replication in the presence of damage, and these γH2AX foci co-localized with replication foci. These results demonstrate that acute RB loss abrogates DNA damage-induced cell cycle arrest to induce γH2AX foci formation. Thus, secondary genetic lesions induced by RB loss have implications for the chemotherapeutic response and the development of genetic instability.     

Protein Phosphatase 6 Interacts with the DNA-Dependent Protein Kinase Catalytic Subunit and Dephosphorylates γ-H2AX

The catalytic subunit of the DNA-dependent protein kinase (DNA-PKcs) plays a major role in the repair of DNA double-strand breaks (DSBs) by nonhomologous end joining (NHEJ). We have previously shown that DNA-PKcs is autophosphorylated in response to ionizing radiation (IR) and that dephosphorylation by a protein phosphatase 2A (PP2A)-like protein phosphatase (PP2A, PP4, or PP6) regulates the protein kinase activity of DNA-PKcs. Here we report that DNA-PKcs interacts with the catalytic subunits of PP6 (PP6c) and PP2A (PP2Ac), as well as with the PP6 regulatory subunits PP6R1, PP6R2, and PP6R3. Consistent with a role in the DNA damage response, silencing of PP6c by small interfering RNA (siRNA) induced sensitivity to IR and delayed release from the G₂/M checkpoint. Furthermore, siRNA silencing of either PP6c or PP6R1 led to sustained phosphorylation of histone H2AX on serine 139 (γ-H2AX) after IR. In contrast, silencing of PP6c did not affect the autophosphorylation of DNA-PKcs on serine 2056 or that of the ataxia-telangiectasia mutated (ATM) protein on serine 1981. We propose that a novel function of DNA-PKcs is to recruit PP6 to sites of DNA damage and that PP6 contributes to the dephosphorylation of γ-H2AX, the dissolution of IR-induced foci, and release from the G₂/M checkpoint in vivo.DNA double-strand breaks (DSBs) are the most cytotoxic form of DNA damage. In human cells there are two main pathways for the repair of DSBs, namely, nonhomologous end joining (NHEJ) and homologous recombination (HR) (reviewed in reference 26). In the initial phase of NHEJ, DSBs are detected by the Ku70/80 heterodimer, which leads to recruitment of the DNA-dependent protein kinase catalytic subunit (DNA-PKcs) and stimulation of its serine/threonine protein kinase activity. Upon autophosphorylation, DNA-PKcs undergoes a conformational change and dissociates from the DSB (25), providing other DNA repair proteins with access to the damage site (reviewed in reference 33). Another physiological substrate of DNA-PK is a histone H2A variant, H2AX. DNA-PKcs and the related protein kinase ATM (ataxia-telangiectasia mutated) both contribute to DNA damage-induced phosphorylation of H2AX on serine 139 to form γ-H2AX (51), which acts as a recruitment platform for MDC1, 53BP1, and other proteins involved in the DNA damage response and cell cycle checkpoint activation (7, 52).While the effects of phosphorylation on the repair process have been well documented, comparatively little is known about the role of serine/threonine phosphoprotein phosphatases (PPPs) in the DNA damage response. Within the PPP family, the catalytic subunits of PP2A (PP2Ac), PP4 (PP4c), and PP6 (PP6c) are most closely related and form a subgroup referred to as the PP2A-like protein phosphatases (reviewed in reference 40). In vitro, the PP2A-like enzymes display similar sensitivities to small-molecule inhibitors such as okadaic acid and microcystin (27, 45, 53). The specificity of PP2Ac, PP4c, and PP6c function in vivo is derived from a group of regulatory subunits that, with the exception of α4/TAP42 and TIP41, are unique to each enzyme (12, 13, 27, 45, 49). PP2Ac associates with a scaffolding A-α or A-β subunit and additional B-type subunits, while four direct binding partners and several other complex partners unique to PP4c have been characterized (12). The Saccharomyces cerevisiae homologue of PP6c, known as Sit4, interacts with three related proteins: the Sit4-associated proteins SAP155, SAP185, and SAP190, each of which contains a conserved domain known as the SAPs domain (32, 50). The SAPs domain is present in three human orthologues designated PP6R1, PP6R2, and PP6R3, which are therefore considered PP6c regulatory subunits, and each has been shown to bind independently to PP6c (48). More recently, three ankyrin repeat-containing proteins (ARS-A, ARS-B, and ARS-C) were identified as PP6R1 binding partners. One of these, ARS-A, has been shown to dock all three SAPs domain proteins (50), suggesting that, like PP2Ac, PP6c forms stable heterotrimers in vivo and that together these subunits define PP6 function.We have previously shown that inhibition of PP2A-like protein phosphatase activity by okadaic acid increases the phosphorylation status of DNA-PKcs and decreases its protein kinase activity (20), thus implicating PP2A-like phosphatases in the regulation of DNA-PK activity in vivo. More recently, both PP4 and PP2A have been shown to play roles in the DNA damage response by dephosphorylating γ-H2AX (14, 15, 28, 42). However, the potential role of PP6 in γ-H2AX dephosphorylation has not been addressed.Here we show that DNA-PKcs interacts with PP2Ac and PP6c, as well as with the PP6c regulatory subunits, PP6R1, PP6R2, and PP6R3. Depletion of PP6c by small interfering RNA (siRNA) induces sensitivity to ionizing radiation (IR) and delayed release from the G₂/M checkpoint. Furthermore, siRNA silencing of either PP6c or PP6R1 leads to sustained phosphorylation of γ-H2AX after DNA damage. Together, our studies reveal that a novel and previously unrecognized function of DNA-PKcs may be to recruit PP6 to sites of DNA damage and that PP6 regulates the phosphorylation status of γ-H2AX, the dissolution of IR-induced foci, and release from the G₂/M checkpoint.     

Protein phosphatase Pph3 and its regulatory subunit Psy2 regulate Rad53 dephosphorylation and cell morphogenesis during recovery from DNA damage in Candida albicans

The ability of the pathogenic fungus Candida albicans to switch cellular morphologies is important for infection and virulence. Recent studies have revealed that C. albicans yeast cells can switch to filamentous growth under genotoxic stress in a manner dependent on the DNA replication/damage checkpoint. Here, we have investigated the functions of Pph3 (orf19.4378) and Psy2 (orf19.3685), whose orthologues in Saccharomyces cerevisiae mediate the dephosphorylation of the DNA damage checkpoint kinase Rad53 and the histone variant H2AX during recovery from DNA damage. Deleting PPH3 or PSY2 causes hypersensitivity to DNA-damaging agents, including cisplatin, methylmethane sulfonate (MMS), and UV light. In addition, pph3Δ and psy2Δ cells exhibit strong filamentous growth under genotoxic stress. Flow cytometry analysis shows that the mutant cells have lost the ability to adapt to genotoxic stress and remain arrested even after the stress is withdrawn. Furthermore, we show that Pph3 and Psy2 are required for the dephosphorylation of Rad53, but not H2AX, during DNA damage recovery. Taken together, these results show that C. albicans Pph3 and Psy2 have important roles in mediating genotoxin-induced filamentous growth and regulating Rad53 dephosphorylation.     

DNA double-strand breaks and gamma-H2AX signaling in the testis

Within minutes of the induction of DNA double-strand breaks in somatic cells, histone H2AX becomes phosphorylated at serine 139 and forms gamma-H2AX foci at the sites of damage. These foci then play a role in recruiting DNA repair and damage-response factors and changing chromatin structure to accurately repair the damaged DNA. These gamma-H2AX foci appear in response to irradiation and genotoxic stress and during V(D)J recombination and meiotic recombination. Independent of irradiation, gamma-H2AX occurs in all intermediate and B spermatogonia and in preleptotene to zygotene spermatocytes. Type A spermatogonia and round spermatids do not exhibit gamma-H2AX foci but show homogeneous nuclear gamma-H2AX staining, whereas in pachytene spermatocytes gamma-H2AX is only present in the sex vesicle. In response to ionizing radiation, gamma-H2AX foci are generated in spermatogonia, spermatocytes, and round spermatids. In irradiated spermatogonia, gamma-H2AX interacts with p53, which induces spermatogonial apoptosis. These events are independent of the DNA-dependent protein kinase (DNA-PK). Irradiation-independent nuclear gamma-H2AX staining in leptotene spermatocytes demonstrates a function for gamma-H2AX during meiosis. gamma-H2AX staining in intermediate and B spermatogonia, preleptotene spermatocytes, and sex vesicles and round spermatids, however, indicates that the function of H2AX phosphorylation during spermatogenesis is not restricted to the formation of gamma-H2AX foci at DNA double-strand breaks.     

DNA damage response links calpain to cellular senescence

Senescence represents an important barrier against cellular transformation. Here we show that CAPNS1 depletion impairs senescence induction both in BJ-ET H-Ras^v12 inducible human fibroblasts upon Ras induction and in HT1080 targeted to senescence by treatment with low doses of doxorubicin. We further show that CAPNS1 depletion is coupled to reduced levels of H2AX phosphorylation, not only in Ras^v12 induced BJ-ET fibroblasts, but also in a number of cellular systems upon genotoxic stress. In particular CAPNS1 depletion affects γ-H2AX appearance or persistence in U2OS osteosarcoma cells 24 hours after MMC addition or UV light exposure; HT1080 upon camptothecin treatment for 4 hours and 48 hours after addition of MMC; MDA-MB-231, 24 hours after UV light exposure and 2 hours after bleomycin addition. Overall this study unveils a novel link between calpain, cellular senescence and DNA damage response.     

Collaborative roles of gammaH2AX and the Rad51 paralog Xrcc3 in homologous recombinational repair

One of the earliest events in the signal transduction cascade that initiates a DNA damage checkpoint is the phosphorylation on serine 139 of histone H2AX (gammaH2AX) at DNA double-strand breaks (DSBs). However, the role of gammaH2AX in DNA repair is poorly understood. To address this question, we generated chicken DT40 cells carrying a serine to alanine mutation at position 139 of H2AX (H2AX(-/S139A)) and examined their DNA repair capacity. H2AX(-/S139A) cells exhibited defective homologous recombinational repair (HR) as manifested by delayed Rad51 focus formation following ionizing radiation (IR) and hypersensitivity to the topoisomerase I inhibitor, camptothecin (CPT), which causes DSBs at replication blockage. Deletion of the Rad51 paralog gene, XRCC3, also delays Rad51 focus formation. To test the interaction of Xrcc3 and gammaH2AX, we disrupted XRCC3 in H2AX(-/S139A) cells. XRCC3(-/-)/H2AX(-/S139A) mutants were not viable, although this synthetic lethality was reversed by inserting a transgene that conditionally expresses wild-type H2AX. Upon repression of the wild-type H2AX transgene, XRCC3(-/-)/H2AX(-/S139A) cells failed to form Rad51 foci and exhibited markedly increased levels of chromosomal aberrations after CPT treatment. These results indicate that H2AX and XRCC3 act in separate arms of a branched pathway to facilitate Rad51 assembly.     

Human RIF1 and protein phosphatase 1 stimulate DNA replication origin licensing but suppress origin activation

The human RIF1 protein controls DNA replication, but the molecular mechanism is largely unknown. Here, we demonstrate that human RIF1 negatively regulates DNA replication by forming a complex with protein phosphatase 1 (PP1) that limits phosphorylation‐mediated activation of the MCM replicative helicase. We identify specific residues on four MCM helicase subunits that show hyperphosphorylation upon RIF1 depletion, with the regulatory N‐terminal domain of MCM4 being particularly strongly affected. In addition to this role in limiting origin activation, we discover an unexpected new role for human RIF1‐PP1 in mediating efficient origin licensing. Specifically, during the G1 phase of the cell cycle, RIF1‐PP1 protects the origin‐binding ORC1 protein from untimely phosphorylation and consequent degradation by the proteasome. Depletion of RIF1 or inhibition of PP1 destabilizes ORC1, thereby reducing origin licensing. Consistent with reduced origin licensing, RIF1‐depleted cells exhibit increased spacing between active origins. Human RIF1 therefore acts as a PP1‐targeting subunit that regulates DNA replication positively by stimulating the origin licensing step, and then negatively by counteracting replication origin activation.     

Replication stress induces micronuclei comprising of aggregated DNA double-strand breaks

Background

Micronuclei (MN) in mammalian cells serve as a reliable biomarker of genomic instability and genotoxic exposure. Elevation of MN is commonly observed in cells bearing intrinsic genomic instability and in normal cells exposed to genotoxic agents. DNA double-strand breaks are marked by phosphorylation of H2AX at serine 139 (γ-H2AX). One subclass of MN contains massive and uniform γ-H2AX signals. This study tested whether this subclass of MN can be induced by replication stress.

Principal Findings

We observed that a large proportion of MN, from 20% to nearly 50%, showed uniform staining by antibodies against γ-H2AX, a marker of DNA double-strand breaks (DSBs). Such micronuclei were designated as MN-γ–H2AX (+). We showed that such MN can be induced by chemicals that are known to cause DNA replication stress and S phase arrest. Hydroxyurea, aphidicolin and thymidine could all significantly induce MN-γ–H2AX (+), which were formed during S phase and appeared to be derived from aggregation of DSBs. MN-γ–H2AX (−), MN that were devoid of uniform γ-H2AX signals, were induced to a lesser extent in terms of fold change. Paclitaxel, which inhibits the disassembly of microtubules, only induced MN-γ–H2AX (−). The frequency of MN-γ–H2AX (+), but not that of MN-γ–H2AX (−), was also significantly increased in cells that experience S phase prolongation due to depletion of cell cycle regulator CUL4B. Depletion of replication protein A1 (RPA1) by RNA interference resulted in an elevation of both MN-γ–H2AX (+) and MN-γ–H2AX (−).

Conclusions/Significance

A subclass of MN, MN-γ–H2AX (+), can be preferentially induced by replication stress. Classification of MN according to their γ-H2AX status may provide a more refined evaluation of intrinsic genomic instabilities and the various environmental genotoxicants.     

Effects of hydroxyurea and aphidicolin on phosphorylation of ataxia telangiectasia mutated on Ser 1981 and histone H2AX on Ser 139 in relation to cell cycle phase and induction of apoptosis.

BACKGROUND: DNA replication stress often induces DNA damage. The antitumor drug hydroxyurea (HU), a potent inhibitor of ribonucleotide reductase that halts DNA replication through its effects on cellular deoxynucleotide pools, was shown to damage DNA inducing double-strand breaks (DSBs). Aphidicolin (APH), an inhibitor of alpha-like DNA polymerases, was also reported to cause DNA damage, but the evidence for induction of DSBs by APH is not straightforward. Histone H2AX is phosphorylated on Ser 139 in response to DSBs and one of the protein kinases that phosphorylate H2AX is ataxia telangiectasia mutated (ATM); activation of ATM is through its phosphorylation of Ser 1981. The present study was undertaken to reveal whether H2AX is phosphorylated in cells exposed to HU or APH and whether its phosphorylation is mediated by ATM. MATERIALS AND METHODS: HL-60 cells were treated in cultures with 0.1-5.0 mM HU or 1-4 muM APH for up to 5 h. Activation of ATM and H2AX phosphorylation was detected immunocytochemically using Ab specific to Ser1981-ATM or Ser 139-H2AX epitopes, respectively, concurrent with measurement of cellular DNA content. RESULTS: While exposure of cells to HU led to H2AX phosphorylation selectively during S phase and the cells progressing through the early portion of S (DI = 1.1-1.4) were more affected than late-S phase (DI = 1.6-1.9) cells, ATM was not activated by HU. In fact, the level of constitutive ("programmed") ATM phosphorylation was distinctly suppressed, in all phases of the cell cycle, at 0.1-5.0 mM HU. Cells' exposure to APH also resulted in H2AX phosphorylation at Ser139 with no evidence of ATM activation, and as in the case of HU, the early-S cells were more affected than the late-S phase cells. The rise in frequency of apoptotic cells became apparent after 2 h of exposure to HU or APH, and all apoptotic cells had markedly elevated levels of both H2AX-Ser139 and ATM-Ser1981 phosphorylation. CONCLUSIONS: The lack of correlation between H2AX phosphorylation and ATM activation indicates that protein kinase(s) other than ATM (ATR and/or DNA-dependent protein kinase) are activated by DSBs induced by replication stress. Interestingly, HU inhibits the constitutive ("programmed") level of ATM phosphorylation in untreated cells. However, DNA fragmentation during apoptosis activates ATM and dramatically increases level of H2AX phosphorylation.