Methylator-induced, mismatch repair-dependent G2 arrest is activated through Chk1 and Chk2

SN1 DNA methylating agents such as the nitrosourea N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) elicit a G2/M checkpoint response via a mismatch repair (MMR) system-dependent mechanism; however, the exact nature of the mechanism governing MNNG-induced G2/M arrest and how MMR mechanistically participates in this process are unknown. Here, we show that MNNG exposure results in activation of the cell cycle checkpoint kinases ATM, Chk1, and Chk2, each of which has been implicated in the triggering of the G2/M checkpoint response. We document that MNNG induces a robust, dose-dependent G2 arrest in MMR and ATM-proficient cells, whereas this response is abrogated in MMR-deficient cells and attenuated in ATM-deficient cells treated with moderate doses of MNNG. Pharmacological and RNA interference approaches indicated that Chk1 and Chk2 are both required components for normal MNNG-induced G2 arrest. MNNG-induced nuclear exclusion of the cell cycle regulatory phosphatase Cdc25C occurred in an MMR-dependent manner and was compromised in cells lacking ATM. Finally, both Chk1 and Chk2 interact with the MMR protein MSH2, and this interaction is enhanced after MNNG exposure, supporting the notion that the MMR system functions as a molecular scaffold at the sites of DNA damage that facilitates activation of these kinases.     

Priming phosphorylation of Chk2 by polo-like kinase 3 (Plk3) mediates its full activation by ATM and a downstream checkpoint in response to DNA damage

The tumor suppressor gene Chk2 encodes a serine/threonine kinase that signals DNA damage to cell cycle checkpoints. In response to ionizing radiation, Chk2 is phosphorylated on threonine 68 (T68) by ataxia-telangiectasia mutated (ATM) protein leading to its activation. We have previously shown that polo-like kinase 3 (Plk3), a protein involved in DNA damage checkpoint and M-phase functions, interacts with and phosphorylates Chk2. When Chk2 was immunoprecipitated from Daudi cells (Plk3-deficient), it had weak kinase activity towards Cdc25C compared with Chk2 derived from T47D cells (Plk3-expressing cells). This activity was restored by addition of recombinant Plk3 in a dose-dependent manner. Plk3 phosphorylates Chk2 at two residues, serine 62 (S62) and serine 73 (S73) in vitro, and this phosphorylation facilitates subsequent phosphorylation of Chk2 on T68 by ATM in response to DNA damage. When the Chk2 mutant construct GFP-Chk2 S73A (serine 73 mutated to alanine) is transfected into cells, it no longer associates with a large complex in vivo, and manifests a significant reduction in kinase activity. It is also inefficiently activated by ATM by phosphorylation at T68 and, in turn, is unable to phosphorylate the Cdc25C peptide 200-256, which contains the inhibitory S216 target phosphorylation residue. As a consequence, tyrosine 15 (Y15) on Cdc2 remains hypophosphorylated, and there is a loss of the G2/M checkpoint. These data describe a functional role for Plk3 in a pathway linking ATM, Plk3, Chk2, Cdc25C and Cdc2 in cellular response to DNA damage.     

Gossypin induces G2/M arrest in human malignant glioma U251 cells by the activation of Chk1/Cdc25C pathway

Gossypin is a flavone that was originally isolated from Hibiscus vitifolius and has traditionally been used for the treatment of diabetes, jaundice, and inflammation. Recently, gossypin was found to have potent anticancer properties; however, its effect on human gliomas still remain unknown. To investigate the potential anticancer effects of gossypin on malignant gliomas and analyze the associated molecular mechanisms, we treated human glioma U251 cells with gossypin. Our study showed that the treatment of U251 cells with gossypin inhibited cell proliferation in a dose- and time-dependent manner and was observed to be minimally toxic to normal human astrocytes. Gossypin's effect on cell cycle distribution was observed, and we found that it induced G2/M-phase arrest in U251 cells. An analysis of cell-cycle regulatory proteins indicated that the arresting effect of gossypin on the cell cycle at G2/M phase was involved in the phosphorylation of cell division cycle 25C (Cdc25C) tyrosine phosphatase via the activation of checkpoint kinase 1 (Chk1). These findings indicate that gossypin is a potential treatment of gliomas because of gossypin's potential to regulate the proliferation of U251 cells via the cell-cycle regulatory proteins Chk1 and Cdc25C.     

Recovery from DNA damage checkpoint arrest by PP1-mediated inhibition of Chk1

The G2 DNA damage checkpoint delays mitotic entry via the upregulation of Wee1 kinase and the downregulation of Cdc25 phosphatase by Chk1 kinase, and resultant inhibitory phosphorylation of Cdc2. While checkpoint activation is well understood, little is known about how the checkpoint is switched off to allow cell cycle re-entry. To identify proteins required for checkpoint release, we screened for genes in Schizosaccharomyces pombe that, when overexpressed, result in precocious mitotic entry in the presence of DNA damage. We show that overexpression of the type I protein phosphatase Dis2 sensitises S. pombe cells to DNA damage, causing aberrant mitoses. Dis2 abrogates Chk1 phosphorylation and activation in vivo, and dephosphorylates Chk1 and a phospho-S345 Chk1 peptide in vitro. dis2Delta cells have a prolonged chk1-dependent arrest and a compromised ability to downregulate Chk1 activity for checkpoint release. These effects are specific for the DNA damage checkpoint, because Dis2 has no effect on the chk1-independent response to stalled replication forks. We propose that inactivation of Chk1 by Dis2 allows mitotic entry following repair of DNA damage in the G2-phase.     

The radioresistance to killing of A1-5 cells derives from activation of the Chk1 pathway

Checkpoints respond to DNA damage by arresting the cell cycle to provide time for facilitating repair. In mammalian cells, the G(2) checkpoint prevents the Cdc25C phosphatase from removing inhibitory phosphate groups from the mitosis-promoting kinase Cdc2. Both Chk1 and Chk2, the checkpoint kinases, can phosphorylate Cdc25C and inactivate its in vitro phosphatase activity. Therefore, both Chk1 and Chk2 are thought to regulate the activation of the G(2) checkpoint. Here we report that A1-5, a transformed rat embryo fibroblast cell line, shows much more radioresistance associated with a much stronger G(2) arrest response when compared with its counterpart, B4, although A1-5 and B4 cells have a similar capacity for nonhomologous end-joining DNA repair. These phenotypes of A1-5 cells are accompanied by a higher Chk1 expression and a higher phosphorylation of Cdc2. On the other hand, Chk2 expression increases slightly following radiation; however, it has no difference between A1-5 and B4 cells. Caffeine or UCN-01 abolishes the extreme radioresistance with the strong G(2) arrest and at the same time reduces the phosphorylation of Cdc2 in A1-5 cells. In addition, Chk1 but not Chk2 antisense oligonucleotide sensitizes A1-5 cells to radiation-induced killing and reduces the G(2) arrest of the cells. Taken together these results suggest that the Chk1/Cdc25C/Cdc2 pathway is the major player for the radioresistance with G(2) arrest in A1-5 cells.     

Regulation of Human Cdc25A Stability by Serine 75 Phosphorylation Is Not Sufficient to Activate a S-phase Checkpoint

Degradation of Cdc25A phosphatase is an ubiquitous feature of stress. There are some discrepancies in the reported roles for different phosphorylation sites in the regulation of Cdc25A stability. Using a panel of doxycycline-inducible phosphorylation mutants we show that the stability of human Cdc25A protein is dependent upon phosphorylation at S75. In non-stressed conditions and in non-mitotic cells, Cdc25A is unstable and its stability is regulated in a Chk1-dependent manner. During mitosis, Cdc25A becomes stable and does not undergo degradation after DNA damage. We further show that Chk1 kinase regulates Cdc25A stability after UV irradiation. Similar to Chk1 kinase, p38 MAPK controls Cdc25A protein level after osmotic stress. Using phospho-specific antibodies, we find that both kinases can phosphorylate S75 and S123 in vitro. Inactivation of either Chk1 after UV-irradiation or p38 MAPK after osmotic stress prevents activation of a S phase checkpoint and S75 and S123 phosphorylation. However, introduction of stable Cdc25A (S75A or S75/123A) proteins is not sufficient to overcome this checkpoint. We propose that regulation of human Cdc25A stability by its phosphorylation at S75 may contribute to S phase checkpoint activation only in cooperation with other regulatory mechanisms.     

Regulation of human Cdc25A stability by Serine 75 phosphorylation is not sufficient to activate a S phase checkpoint

Degradation of Cdc25A phosphatase is an ubiquitous feature of stress. There are some discrepancies in the reported roles for different phosphorylation sites in the regulation of Cdc25A stability. Using a panel of doxycycline-inducible phosphorylation mutants we show that the stability of human Cdc25A protein is dependent upon phosphorylation at S75. In non-stressed conditions and in non-mitotic cells, Cdc25A is unstable and its stability is regulated in a Chk1-dependent manner. During mitosis, Cdc25A becomes stable and does not undergo degradation after DNA damage. We further show that Chk1 kinase regulates Cdc25A stability after UV irradiation. Similar to Chk1 kinase, p38 MAPK controls Cdc25A protein level after osmotic stress. Using phospho-specific antibodies, we find that both kinases can phosphorylate S75 and S123 in vitro. Inactivation of either Chk1 after UV-irradiation or p38 MAPK after osmotic stress prevents activation of a S phase checkpoint and S75 and S123 phosphorylation. However, introduction of stable Cdc25A (S75A or S75/123A) proteins is not sufficient to overcome this checkpoint. We propose that regulation of human Cdc25A stability by its phosphorylation at S75 may contribute to S phase checkpoint activation only in cooperation with other regulatory mechanisms.     

Genistein induces G2/M cell cycle arrest and apoptosis of human ovarian cancer cells via activation of DNA damage checkpoint pathways

Genistein is a major isoflavonoid in dietary soybean, commonly consumed in Asia. Genistein exerts inhibitory effects on the proliferation of various cancer cells and plays an important role in cancer prevention. However, the molecular and cellular mechanisms of genistein on human ovarian cancer cells are still little known. We show that exposure of human ovarian cancer HO-8910 cells to genistein induces DNA damage, and triggers G2/M phase arrest and apoptosis. Furthermore, we also found that checkpoint proteins ATM and ATR are phosphorylated and activated in the cells treated with genistein. It is also shown that genistein increases the phosphorylation and activation of Chk1 and Chk2, which results in the phosphorylation and inactivation of phosphatases Cdc25C and Cdc25A, and thereby the phosphorylation and inactivation of Cdc2 which arrests cells in G2/M phase. Moreover, genistein enhances the phosphorylation and activation of p53, while decreases the ratio of Bcl-2/Bax and Bcl-xL/Bax and the level of phosphorylated Akt, which result in cells undergoing apoptosis. These results demonstrate that genistein-activated ATM-Chk2-Cdc25 and ATR-Chk1-Cdc25 DNA damage checkpoint pathways can arrest ovarian cancer cells in G2/M phase, and induce apoptosis while the cellular DNA damage is too serious to be repaired. Thus, the antiproliferative, DNA damage-inducing and pro-apoptotic activities of genistein are probably responsible for its genotoxic effects on human ovarian cancer HO-8910 cells.     

DNA damage regulates Chk2 association with chromatin

DNA damage triggers cellular signaling pathways that control the cell cycle and DNA repair. Chk2 is a critical mediator of diverse responses to DNA damage. Chk2 transmits signals from upstream phosphatidylinositol 3'-kinase-like kinases to effector substrates including p53, Brca1, Cdc25A, and Cdc25C. Using chromatin fractionation as well as immunostaining combined with detergent pre-extraction, we have found that a small pool of Chk2 is associated with chromatin prior to DNA damage. Recovery of chromatin-bound Chk2 is reduced in an ATM-dependent manner by exposure to ionizing radiation. Camptothecin and adriamycin also reduce the amount of chromatin-associated Chk2. The Thr(68)-phosphorylated forms of Chk2 induced by DNA damage are found in soluble fractions, but not in the chromatin-enriched fraction. Functional serine/threonine glutamine cluster domain, forkhead-associated domain, and kinase activity are all required for efficient reduction of chromatin-bound Chk2 in response to DNA damage. Artificial induction of Chk2 oligomerization concomitant with exposure to low dose ionizing radiation reduces chromatin-bound Chk2. When Chk2 is incubated with chromatin-enriched fractions in vitro in the presence of ATP, hyperphosphorylated forms of Chk2 bind more weakly to chromatin than hypophosphorylated forms. Taken together, our data suggest that DNA damage induces activation of chromatin-bound Chk2 by a chromatin-derived signal, and that this results in dissociation of activated Chk2 from chromatin, facilitating further signal amplification and transmission to soluble substrates.     

Antagonism of Chk1 signaling in the G2 DNA damage checkpoint by dominant alleles of Cdr1

Activation of the Chk1 protein kinase by DNA damage enforces a checkpoint that maintains Cdc2 in its inactive, tyrosine-15 (Y15) phosphorylated state. Chk1 downregulates the Cdc25 phosphatases and concomitantly upregulates the Wee1 kinases that control the phosphorylation of Cdc2. Overproduction of Chk1 causes G(2) arrest/delay independently of DNA damage and upstream checkpoint genes. We utilized this to screen fission yeast for mutations that alter sensitivity to Chk1 signaling. We describe three dominant-negative alleles of cdr1, which render cells supersensitive to Chk1 levels, and suppress the checkpoint defects of chk1Delta cells. Cdr1 encodes a protein kinase previously identified as a negative regulator of Wee1 activity in response to limited nutrition, but Cdr1 has not previously been linked to checkpoint signaling. Overproduction of Cdr1 promotes checkpoint defects and exacerbates the defective response to DNA damage of cells lacking Chk1. We conclude that regulation of Wee1 by Cdr1 and possibly by related kinases is an important antagonist of Chk1 signaling and represents a novel negative regulation of cell cycle arrest promoted by this checkpoint.     

Mitotic DNA damage response: Polo-like Kinase-1 is dephosphorylated through ATM-Chk1 pathway

DNA damage during the cell division cycle can activate ATM/ATR and their downstream kinases that are involved in the checkpoint pathway, and cell growth is halted until damage is repaired. As a result of DNA damage induced in mitotic cells by doxorubicin treatment, cells accumulate in a G2-like phase, not in mitosis. Under these conditions, two mitosis-specific kinases, Cdk1 and Plk1, are inhibited by inhibitory phosphorylation and dephosphorylation, respectively. G2-specific phosphorylation of Cdc25 was increased during incubation after mitotic DNA damage. Inhibition of Plk1 through dephosphorylation was dependent on ATM/Chk1 activity. Depleted expression of ATM and Chk1 was achieved using small hairpin RNA (shRNA) plasmid constructs. In this condition, damaged mitotic cells did not accumulated in a G2-like stage, and entered into G1 phase without delay. Protein phosphatase 2A was responsible for dephosphorylation of mitotic Plk1 in response to DNA damage. In knockdown of PP2A catalytic subunits, Plk1 was not dephosphorylated, but rather degraded in response to DNA damage, and cells did not accumulate in G2-like phase. The effect of ATM/Chk1 inhibition was counteracted by overexpression of PP2A, indicated that PP2A may function as a downstream target of ATM/Chk1 at a mitotic DNA damage checkpoint, or may have a dominant effect on ATM/Chk1 function at this checkpoint. Finally, we have shown that negative regulation of Plk1 by dephosphorylation is important to cell accumulation in G2-like phase at the mitotic DNA damage checkpoint, and that this ATM/Chk1/PP2A pathway independent on p53 is a novel mechanism of cellular response to mitotic DNA damage.     

Widdrol activates DNA damage checkpoint through the signaling Chk2–p53–Cdc25A–p21–MCM4 pathway in HT29 cells

Widdrol is an odorant compound isolated from Juniperus chinensis. We previously reported that widdrol induces Gap 1 (G1) phase cell cycle arrest and leads to apoptosis in human colon adenocarcinoma HT29 cells. It was also reported that this cell cycle arrest is associated with the induction of checkpoint kinase 2 (Chk2), p53 phosphorylation and cyclin dependent kinase (Cdk) inhibitor p21 expression. In this paper, we investigated the molecular mechanisms of widdrol on the activation of G1 DNA damage checkpoint at early phase when DNA damages occurred in HT29 cells. First of all, we examined that widdrol breaks DNA directly or not. As the results of DNA electrophoresis and formation of phosphorylated histone H2AX (γH2AX) foci in HT29 cells, widdrol generates DNA double-strand breaks directly within 0.5?h both in vitro and in vivo. Based on this result, the change of proteins related in checkpoint pathway was examined over a time course of 0.5-24?h. Treatment of HT29 cells with widdrol elicits the following: (1) phosphorylation of Chk2 and p53, (2) reduction of cell division cycle 25A (Cdc25A) expression, (3) increase of Cdk inhibitor p21 expression, and (4) decrease of the levels of Cdk2 and cyclin E expression in a time-dependent manner. Moreover, only the expression level of mini-chromosome maintenance 4 (MCM4) protein, a subunit of the eukaryotic DNA replicative helicase, is rapidly down-regulated in HT29 cells treated with widdrol over the same time course, but those of the other MCM proteins are unchanged. Overall, our results indicated that widdrol breaks DNA directly in HT29 cells, and this DNA damage results in checkpoint activation via Chk2-p53-Cdc25A-p21-MCM4 pathway and finally cells go to G1-phase cell cycle arrest and apoptosis.     

Stopped for Repairs: A New Role for Nutrient Sensing Pathways

In order to prevent division of damaged chromosomes, cells activate a checkpoint to inhibit mitotic progression in order to repair the damaged DNA. Upon detection of DNA damage two downstream checkpoint kinases, Chk1 and Rad53, are activated by the sensor kinase, Mec1, to block the metaphase to anaphase transition and mitotic exit, respectively. Recent data from studies with budding yeast suggested that the DNA damage checkpoint also enlists the cAMP dependent protein kinase (PKA) pathway, which is an integral part of the nutrient sensing mechanism in budding yeast, to inhibit mitosis in response to DNA damage. Genetic and biochemical evidence suggested that the PKA pathway contributes to the inhibition of mitotic progression by mediating the phosphorylation of the APC specificity factor Cdc20. Phosphorylation of Cdc20 assists the activity of the checkpoint pathways in the inhibition of the degradation of mitotic inhibitors securin, Pds1, and the B type cyclin, Clb2, in order to block anaphase and mitotic exit. Cdc20 was phosphorylated following DNA damage in a PKA and Mec1 dependent manner, suggesting PKA activation is dependent on Mec1. Here we discuss possible mechanisms for how PKA activity could be regulated in response to DNA damage and we will also address the implication of these results in evaluating current cancer treatments.     

A human homologue of the checkpoint kinase Cds1 directly inhibits Cdc25 phosphatase

Background: In human cells, the mitosis-inducing kinase Cdc2 is inhibited by phosphorylation on Thr14 and Tyr15. Disruption of these phosphorylation sites abrogates checkpoint-mediated regulation of Cdc2 and renders cells highly sensitive to agents that damage DNA. Phosphorylation of these sites is controlled by the opposing activities of the Wee1/Myt1 kinases and the Cdc25 phosphatase. The regulation of these enzymes is therefore likely to be crucial for the operation of the G2–M DNA-damage checkpoint.Results: Here, we show that the activity of Cdc25 decreased following exposure to ionizing radiation. The irradiation-induced decrease in Cdc25 activity was suppressed by wortmannin, an inhibitor of phosphatidylinositol (PI) 3-kinases, and was dependent on the function of the gene that is mutated in ataxia telangiectasia. We also identified two human kinases that phosphorylate and inactivate Cdc25 in vitro. One is the previously characterized Chk1 kinase. The second is novel and is homologous to the Cds1/Rad53 family of checkpoint kinases in yeast. Human Cds1 was found to be activated in response to DNA damage.Conclusions: These results suggest that, in human cells, the DNA-damage checkpoint involves direct inactivation of Cdc25 catalyzed by Cds1 and/or Chk1.     

Human herpesvirus 6 suppresses T cell proliferation through induction of cell cycle arrest in infected cells in the G2/M phase

Human herpesvirus 6 (HHV-6) is an important immunosuppressive and immunomodulatory virus that primarily infects immune cells and strongly suppresses the proliferation of infected cells. However, the mechanisms responsible for the regulation and suppression mediated by HHV-6 are still unknown. In this study, we examined the ability of HHV-6A to manipulate cell cycle progression in infected cells and explored the potential molecular mechanisms. We demonstrated that infection with HHV-6A imposed a growth-inhibitory effect on HSB-2 cells by inducing cell cycle arrest at the G(2)/M phase. We then showed that the activity of the Cdc2-cyclin B1 complex was significantly decreased in HHV-6A-infected HSB-2 cells. Furthermore, we found that inactivation of Cdc2-cyclin B1 in HHV-6A-infected cells occurred through the inhibitory Tyr15 phosphorylation resulting from elevated Wee1 expression and inactivated Cdc25C. The reduction of Cdc2-cyclin B1 activity in HHV-6-infected cells was also partly due to the increased expression of the cell cycle-regulatory molecule p21 in a p53-dependent manner. In addition, HHV-6A infection activated the DNA damage checkpoint kinases Chk2 and Chk1. Our data suggest that HHV-6A infection induces G(2)/M arrest in infected T cells via various molecular regulatory mechanisms. These results further demonstrate the potential mechanisms involved in immune suppression and modulation mediated by HHV-6 infection, and they provide new insights relevant to the development of novel vaccines and immunotherapeutic approaches.     

Cytoplasmic occurrence of the Chk1/Cdc25 pathway and regulation of Chk1 in Xenopus oocytes

Chk1, a nuclear DNA damage/replication G2 checkpoint kinase, phosphorylates Cdc25 and causes its nuclear exclusion in yeast and mammalian cells, thereby arresting the cell at the G2 phase until DNA repair/replication is completed. Chk1 is also involved, at least in part, in the natural G2 arrest of immature Xenopus oocytes, but it is unknown how Chk1 inhibits Cdc25 function and undergoes regulation during oocyte maturation. By using enucleated oocytes, we show here that Chk1 inhibits Cdc25 function in the cytoplasm of G2-arrested oocytes and that Cdc25 is activated exclusively in the cytoplasm of maturing oocytes. Moreover, we show that Chk1 activity is not appreciably altered during maturation, being maintained at basal levels, and that C-terminal truncation mutants of Chk1 have very high kinase activities, strong abilities to inhibit maturation, and altered subcellular localization in oocytes. These results, together with other results, suggest that the Chk1/Cdc25 pathway is involved cytoplasmically in G2 arrest of Xenopus oocytes, but moderately and independent of the G2 checkpoint, and that the C-terminal region of Chk1 negatively regulates its kinase activity and also determines its subcellular localization. Based on these results, we discuss the possibility that Chk1 (with the basal activity) may function as an ordinary regulator of Cdc25 in oocytes (and in other cell types) and that Chk1 might be hyperactivated in response to the G2 checkpoint via its dramatic conformational change.     

八氯腺苷诱导SH-SY5Y和SK-N-SH细胞G2/M期阻滞的分子机制不同

为探索八氯腺苷的抗肿瘤作用机制,以神经母细胞瘤SH-SY5Y和SK-N-SH细胞为对象,采用四唑盐比色实验（MTT法）证明,八氯腺苷具有明显的抑制肿瘤细胞增殖的作用,这种抑制作用呈剂量-时间依赖性.流式细胞分析显示,10 μmol/L八氯腺苷作用48 h后可导致靶细胞生长停滞于G ^₂/M期;SH-SY5Y细胞发生明显细胞凋亡,但SK-N-SH细胞却未见凋亡.Hoechst 33342染色显示,SK-N-SH细胞发生了核分裂异常.蛋白质免疫印迹分析证明,10 μmol/L 八氯腺苷处理SH SY5Y 48～72 h后,G^₂检验点调节蛋白ATM、Chk1、Cdc25C和Cdc2磷酸化形式明显上调,同时伴有caspase-3的激活,提示SH-SY5Y细胞发生了G^₂检验点通路和细胞凋亡途径的激活.与SH-SY5Y细胞不同,在SK-N-SH细胞中,八氯腺苷处理24～96 h时,磷酸化ATM、磷酸化Chk1/Chk2、磷酸化Cdc25C以及磷酸化Cdc2的水平呈现逐渐降低的趋势.结果提示,SK-N-SH细胞在八氯腺苷处理后发生了G^₂检验点失败.蛋白质免疫印迹分析还显示,八氯腺苷可诱导p53在SH-SY5Y细胞的表达,但却不能影响SK—N-SH细胞的p53组成性表达水平.p21在SK-N-SH的组成性表达随八氯腺苷处理时间延长而逐渐减少,但在处理前后的SH-SY5Y细胞均未检测到p21蛋白的表达.上述实验结果提示,八氯腺苷抑制两种细胞增殖的机制不同：在SH-SY5Y细胞,八氯腺苷可激活ATM-Chk-Cdc25C-Cdc2/cyclin途径和凋亡通路,使细胞发生G_²/M期阻滞和细胞凋亡;在SK-N-SH细胞,八氯腺苷诱导G^₂检验点失败,导致细胞阻滞在有丝分裂期,并发生有丝分裂异常.2种不同的细胞命运可能还与p53和p21表达不同有关.     

The Chk1-mediated S-phase checkpoint targets initiation factor Cdc45 via a Cdc25A/Cdk2-independent mechanism

DNA damage induced by the carcinogen benzo[a]pyrene dihydrodiol epoxide (BPDE) induces a Chk1-dependent S-phase checkpoint. Here, we have investigated the molecular basis of BPDE-induced S-phase arrest. Chk1-dependent inhibition of DNA synthesis in BPDE-treated cells occurred without detectable changes in Cdc25A levels, Cdk2 activity, or Cdc7/Dbf4 interaction. Overexpression studies showed that Cdc25A, cyclin A/Cdk2, and Cdc7/Dbf4 were not rate-limiting for DNA synthesis when the BPDE-induced S-phase checkpoint was active. To investigate other potential targets of the S-phase checkpoint, we tested the effects of BPDE on the chromatin association of DNA replication factors. The levels of chromatin-associated Cdc45 (but not soluble Cdc45) were reduced concomitantly with BPDE-induced Chk1 activation and inhibition of DNA synthesis. The chromatin association of Mcm7, Mcm10, and proliferating cell nuclear antigen was unaffected by BPDE treatment. However, the association between Mcm7 and Cdc45 in the chromatin fraction was inhibited in BPDE-treated cells. Chromatin immunoprecipitation analyses demonstrated reduced association of Cdc45 with the beta-globin origin of replication in BPDE-treated cells. The inhibitory effects of BPDE on DNA synthesis, Cdc45/Mcm7 associations, and interactions between Cdc45 and the beta-globin locus were abrogated by the Chk1 inhibitor UCN-01. Taken together, our results show that the association between Cdc45 and Mcm7 at origins of replication is negatively regulated by Chk1 in a Cdk2-independent manner. Therefore, Cdc45 is likely to be an important target of the Chk1-mediated S-phase checkpoint.