Role of DNA Methylation in Cell Cycle Arrest Induced by Cr (VI) in Two Cell Lines

Hexavalent chromium [Cr(IV)], a well-known industrial waste product and an environmental pollutant, is recognized as a human carcinogen. But its mechanisms of carcinogenicity remain unclear, and recent studies suggest that DNA methylation may play an important role in the carcinogenesis of Cr(IV). The aim of our study was to investigate the effects of Cr(IV) on cell cycle progress, global DNA methylation, and DNA methylation of p16 gene. A human B lymphoblastoid cell line and a human lung cell line A549 were exposed to 5–15 µM potassium dichromate or 1.25–5 µg/cm² lead chromate for 2–24 hours. Cell cycle was arrested at G₁ phase by both compounds in 24 hours exposure group, but global hypomethylation occurred earlier than cell cycle arrest, and the hypomethylation status maintained for more than 20 hours. The mRNA expression of p16 was significantly up-regulated by Cr(IV), especially by potassium dichromate, and the mRNA expression of cyclin-dependent kinases (CDK4 and CDK6) was significantly down-regulated. But protein expression analysis showed very little change of p16 gene. Both qualitative and quantitative results showed that DNA methylation status of p16 remained unchanged. Collectively, our data suggested that global hypomethylation was possibly responsible for Cr(IV) - induced G₁ phase arrest,but DNA methylation might not be related to up-regulation of p16 gene by Cr(IV).     

p16INK4A Participates in a G1 Arrest Checkpoint in Response to DNA Damage

Members of the INK4 protein family specifically inhibit cyclin-dependent kinase 4 (cdk4) and cdk6-mediated phosphorylation of the retinoblastoma susceptibility gene product (Rb). p16^INK4A, a prototypic INK4 protein, has been identified as a tumor suppressor in many human cancers. Inactivation of p16^INK4A in tumors expressing wild-type Rb is thought to be required in order for many malignant cell types to enter S phase efficiently or to escape senescence. Here, we demonstrate another mechanism of tumor suppression by implicating p16^INK4A in a G₁ arrest checkpoint in response to DNA damage. Calu-1 non-small cell lung cancer cells, which retain Rb and lack p53, do not arrest in G₁ following DNA damage. However, engineered expression of p16^INK4A at levels compatible with cell proliferation restores a G₁ arrest checkpoint in response to treatment with γ-irradiation, topoisomerase I and II inhibitors, and cisplatin. A similar checkpoint can be demonstrated in p53^−/− fibroblasts that express p16^INK4A. DNA damage-induced G₁ arrest, which requires the expression of pocket proteins such as Rb, can be abrogated by overexpression of cdk4, kinase-inactive cdk4 variants capable of sequestering p16^INK4A, or a cdk4 variant incapable of binding p16^INK4A. After exposure to DNA-damaging agents, there was no change either in overall levels of p16^INK4A or in amounts of p16^INK4A found in complex with cdks 4 and 6. Nonetheless, p16^INK4A expression is required for the reduction in cdk4- and cdk6-mediated Rb kinase activity observed in response to DNA damage. During tumor progression, loss of p16^INK4A expression may be necessary for cells with wild-type Rb to bypass this G₁ arrest checkpoint and attain a fully transformed phenotype.     

Resistance to Bleomycin in Cancer Cell Lines Is Characterized by Prolonged Doubling Time,Reduced DNA Damage and Evasion of G2/M Arrest and Apoptosis

Background

To establish, characterize and elucidate potential mechanisms of acquired bleomycin (BLM) resistance using human cancer cell lines. Seven BLM-resistant cell lines were established by exposure to escalating BLM concentrations over a period of 16-24 months. IC₅₀ values and cell doubling times were quantified using a real time cytotoxicity assay. COMET and γ-H2AX assays, cell cycle analysis, and apoptosis assessment further investigated the mechanisms of BLM resistance in these cell lines.

Results

Compared with parental cell lines, real time cytotoxicity assays revealed 7 to 49 fold increases in IC₅₀ and a mean doubling time increase of 147 % (range 64 %-352%) in BLM-resistant sub-clones (p<0.05 for both). Higher maintenance BLM concentrations were associated with higher IC₅₀ and increased doubling times (p<0.05). Significantly reduced DNA damage (COMET and γ-H2AX assays), G2/M arrest, and apoptosis (p<0.05 for each set of comparison) following high-dose acute BLM exposure was observed in resistant sub-clones, compared with their BLM-sensitive parental counterparts. Three weeks of BLM-free culturing resulted in a partial return to BLM sensitivity in 3/7 BLM-resistant sub-clones (p<0.05).

Conclusion

Bleomycin resistance may be associated with reduced DNA damage after bleomycin exposure, resulting in reduced G2/M arrest, and reduced apoptosis.     

DNA Damage Triggers p21WAF1-dependent Emi1 Down-Regulation That Maintains G2 Arrest

Several regulatory proteins control cell cycle progression. These include Emi1, an anaphase-promoting complex (APC) inhibitor whose destruction controls progression through mitosis to G1, and p21^WAF1, a cyclin-dependent kinase (CDK) inhibitor activated by DNA damage. We have analyzed the role of p21^WAF1 in G2-M phase checkpoint control and in prevention of polyploidy after DNA damage. After DNA damage, p21^+/+ cells stably arrest in G2, whereas p21^−/− cells ultimately progress into mitosis. We report that p21 down-regulates Emi1 in cells arrested in G2 by DNA damage. This down-regulation contributes to APC activation and results in the degradation of key mitotic proteins including cyclins A2 and B1 in p21^+/+ cells. Inactivation of APC in irradiated p21^+/+ cells can overcome the G2 arrest. siRNA-mediated Emi1 down-regulation prevents irradiated p21^−/− cells from entering mitosis, whereas concomitant down-regulation of APC activity counteracts this effect. Our results demonstrate that Emi1 down-regulation and APC activation leads to stable p21-dependent G2 arrest after DNA damage. This is the first demonstration that Emi1 regulation plays a role in the G2 DNA damage checkpoint. Further, our work identifies a new p21-dependent mechanism to maintain G2 arrest after DNA damage.     

Induction of G1 Cell Cycle Arrest in Human Glioma Cells by Salinomycin Through Triggering ROS-Mediated DNA Damage In Vitro and In Vivo

Chemotherapy has always been one of the most effective ways in combating human glioma. However, the high metastatic potential and resistance toward standard chemotherapy severely hindered the chemotherapy outcomes. Hence, searching effective chemotherapy drugs and clarifying its mechanism are of great significance. Salinomycin an antibiotic shows novel anticancer potential against several human tumors, including human glioma, but its mechanism against human glioma cells has not been fully elucidated. In the present study, we demonstrated that salinomycin treatment time- and dose-dependently inhibited U251 and U87 cells growth. Mechanically, salinomycin-induced cell growth inhibition against human glioma was mainly achieved by induction of G1-phase arrest via triggering reactive oxide species (ROS)-mediated DNA damage, as convinced by the activation of histone, p53, p21 and p27. Furthermore, inhibition of ROS accumulation effectively attenuated salinomycin-induced DNA damage and G1 cell cycle arrest, and eventually reversed salinomycin-induced cytotoxicity. Importantly, salinomycin treatment also significantly inhibited the U251 tumor xenograft growth in vivo through triggering DNA damage-mediated cell cycle arrest with involvement of inhibiting cell proliferation and angiogenesis. The results above validated the potential of salinomycin-based chemotherapy against human glioma.     

Pterostilbene Simultaneously Induced G0/G1-Phase Arrest and MAPK-Mediated Mitochondrial-Derived Apoptosis in Human Acute Myeloid Leukemia Cell Lines

Background

Pterostilbene (PTER) is a dimethylated analog of the phenolic phytoalexin, resveratrol, with higher anticancer activity in various tumors. Herein, the molecular mechanisms by which PTER exerts its anticancer effects against acute myeloid leukemia (AML) cells were investigated.

Methodology and Principal Findings

Results showed that PTER suppressed cell proliferation in various AML cell lines. PTER-induced G0/G1-phase arrest occurred when expressions of cyclin D3 and cyclin-dependent kinase (CDK)2/6 were inhibited. PTER-induced cell apoptosis occurred through activation of caspases-8-9/-3, and a mitochondrial membrane permeabilization (MMP)-dependent pathway. Moreover, treatment of HL-60 cells with PTER induced sustained activation of extracellular signal-regulated kinase (ERK)1/2 and c-Jun N-terminal kinase (JNK)1/2, and inhibition of both MAPKs by their specific inhibitors significantly abolished the PTER-induced activation of caspases-8/-9/-3. Of note, PTER-induced cell growth inhibition was only partially reversed by the caspase-3-specific inhibitor, Z-DEVE-FMK, suggesting that this compound may also act through a caspase-independent pathway. Interestingly, we also found that PTER promoted disruption of lysosomal membrane permeabilization (LMP) and release of activated cathepsin B.

Conclusion

Taken together, our results suggest that PTER induced HL-60 cell death via MAPKs-mediated mitochondria apoptosis pathway and loss of LMP might be another cause for cell apoptosis induced by PTER.     

A Novel Replication Arrest Pathway in Response to DNA Damage

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

Plk1 Inhibition Causes Post-Mitotic DNA Damage and Senescence in a Range of Human Tumor Cell Lines

Plk1 is a checkpoint protein whose role spans all of mitosis and includes DNA repair, and is highly conserved in eukaryotes from yeast to man. Consistent with this wide array of functions for Plk1, the cellular consequences of Plk1 disruption are diverse, spanning delays in mitotic entry, mitotic spindle abnormalities, and transient mitotic arrest leading to mitotic slippage and failures in cytokinesis. In this work, we present the in vitro and in vivo consequences of Plk1 inhibition in cancer cells using potent, selective small-molecule Plk1 inhibitors and Plk1 genetic knock-down approaches. We demonstrate for the first time that cellular senescence is the predominant outcome of Plk1 inhibition in some cancer cell lines, whereas in other cancer cell lines the dominant outcome appears to be apoptosis, as has been reported in the literature. We also demonstrate strong induction of DNA double-strand breaks in all six lines examined (as assayed by γH2AX), which occurs either during mitotic arrest or mitotic-exit, and may be linked to the downstream induction of senescence. Taken together, our findings expand the view of Plk1 inhibition, demonstrating the occurrence of a non-apoptotic outcome in some settings. Our findings are also consistent with the possibility that mitotic arrest observed as a result of Plk1 inhibition is at least partially due to the presence of unrepaired double-strand breaks in mitosis. These novel findings may lead to alternative strategies for the development of novel therapeutic agents targeting Plk1, in the selection of biomarkers, patient populations, combination partners and dosing regimens.     

Role of ATM and the Damage Response Mediator Proteins 53BP1 and MDC1 in the Maintenance of G2/M Checkpoint Arrest

ATM-dependent initiation of the radiation-induced G₂/M checkpoint arrest is well established. Recent results have shown that the majority of DNA double-strand breaks (DSBs) in G₂ phase are repaired by DNA nonhomologous end joining (NHEJ), while ∼15% of DSBs are slowly repaired by homologous recombination. Here, we evaluate how the G₂/M checkpoint is maintained in irradiated G₂ cells, in light of our current understanding of G₂ phase DSB repair. We show that ATM-dependent resection at a subset of DSBs leads to ATR-dependent Chk1 activation. ATR-Seckel syndrome cells, which fail to efficiently activate Chk1, and small interfering RNA (siRNA) Chk1-treated cells show premature mitotic entry. Thus, Chk1 significantly contributes to maintaining checkpoint arrest. Second, sustained ATM signaling to Chk2 contributes, particularly when NHEJ is impaired by XLF deficiency. We also show that cells lacking the mediator proteins 53BP1 and MDC1 initially arrest following radiation doses greater than 3 Gy but are subsequently released prematurely. Thus, 53BP1^−/− and MDC1^−/− cells manifest a checkpoint defect at high doses. This failure to maintain arrest is due to diminished Chk1 activation and a decreased ability to sustain ATM-Chk2 signaling. The combined repair and checkpoint defects conferred by 53BP1 and MDC1 deficiency act synergistically to enhance chromosome breakage.DNA double-strand breaks (DSBs) activate the DNA damage response (DDR), a coordinated process that functions to enhance survival and maintain genomic stability. The DDR includes pathways of DSB repair and a signal transduction response that activates apoptosis and cell cycle checkpoint arrest and influences DSB repair (15). DNA nonhomologous end joining (NHEJ) and homologous recombination (HR) represent the major DSB repair mechanisms, NHEJ being the major mechanism in G₀/G₁, while both processes function in G₂ (9, 32). Ataxia telangiectasia mutated (ATM) and ATM- and Rad3-related (ATR) are related phosphoinositol 3-kinase-like kinases (PIKKs) that regulate the DNA damage signaling response. ATM is activated by DSBs, while ATR is activated at single-strand (ss) regions of DNA via a process that involves ATRIP-replication protein A (RPA)-ssDNA association. Ionizing radiation (IR) induces DSBs, base damage, and ss nicks. Since neither base damage nor ss nicks activate ATR, IR-induced signaling in the G₁ and G₂ phases is predominantly ATM dependent (3, 29). In S phase, ATR can be activated by both endogenous and exogenously induced lesions following replication fork stalling/collapse (8).Recent work has shown that in G₂ phase, DSBs can undergo resection via an ATM-dependent process generating ssDNA regions that can activate ATR following RPA association (11). ATR activation at resected DSBs is coupled to loss of ATM activation (11). Although ATM and ATR share overlapping substrates, there is specificity in their signaling to the transducer kinases; ATM uniquely phosphorylates Chk2, while ATR phosphorylates Chk1. Phosphorylation of either Chk1 or Chk2 causes their activation. Critical targets of Chk1/Chk2 are the Cdc25 phosphatases, which regulate the cyclin-dependent kinases (Cdks), including Cdk1, the regulator of mitotic entry (18). Collectively, these studies suggest that two components of ATM-dependent signaling to the G₂/M checkpoint machinery can occur: ATM-Chk2 signaling at unresected DSBs and ATM-ATR-Chk1 signaling at resected DSBs.Although much is known about the mechanism leading to G₂/M checkpoint activation, few studies have addressed how arrest is maintained and how release coordinates with the status of DSB repair. We examine here the maintenance of checkpoint arrest during the immediate phase of DSB repair. We do not address the issue of checkpoint adaptation, a distinct phenomenon which occurs after prolonged checkpoint arrest (22). Further, we focus on the process maintaining arrest in irradiated G₂-phase cells and do not consider how arrest is maintained in irradiated S-phase cells that progress into G₂ phase. (Previous studies have shown that while G₂/M arrest is ATM dependent at early times post-IR, at later times it becomes ATR dependent as S-phase cells progress into G₂ phase [2, 33].) To focus on mechanisms maintaining ATM-dependent signaling in G₂-phase cells, we use aphidicolin (APH) to prevent S-phase cells from progressing into G₂ during analysis. We, thus, examine checkpoint maintenance in cells irradiated in G₂ phase and do not evaluate arrest regulated by ATR following replication fork stalling. The basis for our work stems from two recent advances. First, we evaluate the impact of ATM-mediated ATR activation in the light of recent findings that resection occurs in G₂ phase (11). Second, we consider the finding that NHEJ represents the major DSB repair mechanism in G₂ and that a 15 to 20% subset of DSBs, representing those that are rejoined with slow kinetics in an ATM-dependent manner, undergo resection and repair by HR (3, 25). Thus, contrary to the notion that HR represents the major DSB repair pathway in G₂ phase, it repairs only 15 to 20% of X- or gamma-ray-induced DSBs and represents the slow component of DSB repair in G₂ phase. Given these findings, several potential models for how checkpoint arrest is maintained in G₂ can be envisaged. A simple model is that the initial signal generated by IR is maintained for a defined time to allow for DSB repair. Such a model appears to explain the kinetics of checkpoint signaling in fission yeast after moderate IR (17). In mammalian cells, the duration of arrest depends on dose and DSB repair capacity (6). Thus, it is possible that the status of ongoing repair is communicated to the checkpoint machinery to coordinate timely release with the process of DSB repair. Here, we consider the impact of resection leading to ATM-ATR-Chk1 signaling versus ATM-Chk2 signaling from nonresected DSBs and how they interplay to maintain rather than initiate checkpoint arrest.Mediator proteins, including 53BP1 and MDC1, assemble at DSBs in an ATM-dependent manner, but their roles in the DDR are unclear. Cells lacking 53BP1 or MDC1 are proficient in checkpoint initiation after moderate IR doses, leading to the suggestion that these proteins are required for amplification of the ATM signal after exposure to low doses but are dispensable after high doses, when a robust signal is generated, even in their absence (7, 16, 28, 31). Despite their apparent subtle role in ATM signaling, cells lacking these mediator proteins display significant genomic instability (19). We thus also examine whether the mediator proteins contribute to the maintenance of checkpoint arrest.We identify two ATM-dependent processes that contribute to the maintenance of checkpoint arrest in G₂-phase cells: (i) ATR-Chk1 activation at resected DSBs and (ii) a process that involves sustained signaling from ATM to Chk2 at unrepaired DSBs. Further, we show that 53BP1 and MDC1 are required for maintaining checkpoint arrest, even following exposure to high radiation doses due to roles in ATR-Chk1 activation and sustained ATM-Chk2 signaling, and that this contributes to their elevated genomic instability.     

Comparison of the Side Populations in Pretreatment and Postrelapse Neuroblastoma Cell Lines

Cancer stem-like cells have been identified in both primary tumors and in cell lines and seem to have a high degree of inherent resistance to traditional chemotherapeutic agents. Relapsed cancers including neuroblastoma are generally chemotherapy-resistant and carry a very poor prognosis. We investigated the side populations of three pairs of neuroblastoma cell lines derived from single patients at the time of their initial presentation and then at relapse after multimodality therapy. We found that the size of the side populations in the relapsed cell lines was significantly increased compared with its paired pretreatment cell line. In addition, these side population cells showed increased proliferation and were significantly more efficient at forming colonies in soft agar than their prerelapse pair. Gene expression analysis of the stem cell genes NANOG and POU5F1 (Oct3/4) showed increased expression in the unsorted relapsed cell lines compared with pretreatment lines as well as in the side populations of the relapsed versus prerelapse cell line pairs. The increased size, proliferative ability, and colony-forming efficiency of the side populations of the postrelapse cell lines demonstrated in this study suggest that a population of stemlike cells is not being efficiently targeted by conventional therapy and implies that strategies to specifically target the stem cell fraction of neuroblastomas are needed to improve outcomes in this devastating childhood disease.     

Vitamin E Protects DNA from Oxidative Damage in Human Hepatocellular Carcinoma Cell Lines

Expression of multiple drug resistant (MDR) phenotype and over-expression of P-glycoprotein (P-gp) in the human hepatocellular carcinoma (HCC) cell clone P1(0.5), derived from the PLC/PRF/5 cell line (P5), are associated with strong resistance to oxidative stress and a significant (?p<0.01) increase in intracellular vitamin E content as compared with the parental cell line. This study evaluates the role of vitamin E in conferring resistance to drugs and oxidative stress in P1(0.5) cells. Parental drug-sensitive cells, P5, were incubated in α-tocopherol succinate (α-TS, 5?μM for 24?h) enriched medium to increase intracellular vitamin E content to levels comparable to those observed in P1(0.5) cells at basal conditions. Susceptibility to lipid peroxidation and oxidative DNA damage were assessed by measuring the concentration of thiobarbituric-reactive substances (TBARS) and 8-hydroxy-2′-deoxyguanosine (8-OHdG) at basal and after experimental conditions. Cell capacity to form colonies and resistance to doxorubicin were also studied. P5 cells, treated with α-TS, became resistant to ADP-Fe³⁺ and to ionizing radiation-induced lipid peroxidation as P1(0.5) cells. Exposure to ADP-Fe³⁺ or ionizing radiation increased TBARS and the 8-OHdG content in the P5 cells, while vitamin E enrichment abolished these effects. Irradiation doses at 5?cGy increased TBARS and 8-OHdG. They also inhibited cell capacity to form colonies in the untreated P5 cells. Incubation with α-TS fully reverted this effect and significantly (p<0.01) reduced the inhibitory effect of cell proliferation induced by irradiation doses at >500?cGy. Resistance to doxorubicin was not affected by α-TS. These observations demonstrate the role of vitamin E in conferring protection from lipid peroxidation, ionizing radiation and oxidative DNA damage on the human HCC cell line. They also rule out any role of P-gp over-expression as being responsible for these observations in cells with MDR phenotype expression.     

塞来昔布诱导HCT-116结肠癌细胞G2/M阻滞

目的:研究选择性COX-2抑制剂塞来昔布诱导结肠癌细胞株HCT-116细胞周期阻滞的作用及其可能的机制。方法:应用流式细胞仪检测塞来昔布对HCT-116细胞周期的影响,定量PCR检测细胞周期素cyclinB1及COX-2 mRNA表达水平,Western-Blot检测细胞周期素cyclinB1的蛋白水平。结果:塞来昔布诱导HCT-116细胞G2/M阻滞的作用呈剂量依赖性,塞来昔布在mRNA及蛋白水平下调HCT-116细胞的cyclinB1。结论:塞来昔布能在体外抑制HCT-116细胞的增殖,诱导G2/M的阻滞,其作用与下调细胞周期素cyclinB1有关。     

Identification of Proteins Sensitive to Thermal Stress in Human Neuroblastoma and Glioma Cell Lines

Heat-shock is an acute insult to the mammalian proteome. The sudden elevation in temperature has far-reaching effects on protein metabolism, leads to a rapid inhibition of most protein synthesis, and the induction of protein chaperones. Using heat-shock in cells of neuronal (SH-SY5Y) and glial (CCF-STTG1) lineage, in conjunction with detergent extraction and sedimentation followed by LC-MS/MS proteomic approaches, we sought to identify human proteins that lose solubility upon heat-shock. The two cell lines showed largely overlapping profiles of proteins detected by LC-MS/MS. We identified 58 proteins in detergent insoluble fractions as losing solubility in after heat shock; 10 were common between the 2 cell lines. A subset of the proteins identified by LC-MS/MS was validated by immunoblotting of similarly prepared fractions. Ultimately, we were able to definitively identify 3 proteins as putatively metastable neural proteins; FEN1, CDK1, and TDP-43. We also determined that after heat-shock these cells accumulate insoluble polyubiquitin chains largely linked via lysine 48 (K-48) residues. Collectively, this study identifies human neural proteins that lose solubility upon heat-shock. These proteins may represent components of the human proteome that are vulnerable to misfolding in settings of proteostasis stress.