The role of G2-block abrogation,DNA double-strand break repair and apoptosis in the radiosensitization of melanoma and squamous cell carcinoma cell lines by pentoxifylline

Purpose : To examine the role of G2-block abrogation, DNA repair inhibition and apoptosis in the enhancement of radiotoxicity by pentoxifylline. Materials and methods : The influence of pentoxifylline on radiotoxicity was assessed by colony assay in TP53 wild-type Be11 and mutant MeWo melanoma, and in TP53 wild-type 4197 and mutant 4451 squamous cell carcinoma (SCC) cell lines. G2-block abrogation was assessed by flow cytometry. Induction of DNA damage and repair was measured over a dose range of 0-100Gy by constant field gel electrophoresis (CFGE). The Annexin-V binding assay was used to identify apoptotic cells. Results : Pentoxifylline, when combined with irradiation, significantly increased radiotoxicity in the TP53 mutant MeWo and 4451 cell lines by radiotoxicity enhancement factors of 3 and 14.5 respectively. No radiosensitization was seen in the TP53 wild-type Be11 and 4197 cells. When the drug was added after irradiation at the time of maximum G2-block expression, no radiosensitization was seen in any of the four cell lines. CFGE analyses showed that pentoxifylline effectively suppressed DNA double-strand break (DSB) repair in all four cell lines, as indicated by 20 h repair inhibition factors of 1.4-2.4. Pentoxifylline did not increase apoptosis in any of the four cell lines. Conclusion : These data suggest that radiosensitization by pentoxifylline is not a consequence of G2-block abrogation alone, but that inhibition of DSB repair plays a role in certain cell types.     

The role of G2-block abrogation, DNA double-strand break repair and apoptosis in the radiosensitization of melanoma and squamous cell carcinoma cell lines by pentoxifylline

PURPOSE: To examine the role of G2-block abrogation, DNA repair inhibition and apoptosis in the enhancement of radiotoxicity by pentoxifylline. MATERIALS AND METHODS: The influence of pentoxifylline on radiotoxicity was assessed by colony assay in TP53 wild-type Bell and mutant MeWo melanoma, and in TP53 wild-type 4197 and mutant 4451 squamous cell carcinoma (SCC) cell lines. G2-block abrogation was assessed by flow cytometry. Induction of DNA damage and repair was measured over a dose range of 0-100 Gy by constant field gel electrophoresis (CFGE). The Annexin-V binding assay was used to identify apoptotic cells. RESULTS: Pentoxifylline, when combined with irradiation, significantly increased radiotoxicity in the TP53 mutant MeWo and 4451 cell lines by radiotoxicity enhancement factors of 3 and 14.5 respectively. No radiosensitization was seen in the TP53 wild-type Be11 and 4197 cells. When the drug was added after irradiation at the time of maximum G2-block expression, no radiosensitization was seen in any of the four cell lines. CFGE analyses showed that pentoxifylline effectively suppressed DNA double-strand break (DSB) repair in all four cell lines, as indicated by 20 h repair inhibition factors of 1.4-2.4. Pentoxifylline did not increase apoptosis in any of the four cell lines. CONCLUSION: These data suggest that radiosensitization by pentoxifylline is not a consequence of G2-block abrogation alone, but that inhibition of DSB repair plays a role in certain cell types.     

Radiosensitization and DNA repair inhibition by pentoxifylline in NIH3T3 p53 transfectants

PURPOSE: To examine the role of p53 mutations in the modulation of DNA repair and radiotoxicity by pentoxifylline. MATERIALS AND METHODS: NIH3T3 murine cells transfected with mutant p53 constructs were examined for the influence of pentoxifylline on radiotoxicity to Co(60) gamma-irradiation by colony assay. DNA repair (0-100 Gy) was measured by constant-field gel electrophoresis. Apoptosis was assessed by flow cytometry with the annexin-V-binding assay. RESULTS: In the two p53 hot-spot mutant cell lines p53-S269R and p53- + 15, the SF(10) radiotoxicity enhancement factors induced by the pentoxifylline were 8.0 and 9.7, respectively. In the p53 deletion mutant p53-DeltaA cell line, the radiotoxicity enhancement factor was 2.6. No radiosensitization was obtained in the untransfected p53 wild-type cell line U-Wt and in the transfected p53 double-wild-type p53-Wt cell line. When pentoxifylline was added after irradiation at the time of maximum G2 block expression, no radiosensitization was observed in any of the five cell lines. Constant-field gel electrophoresis analyses after 20 h of repair showed that pentoxifylline suppresses DNA double-strand break repair in all p53 mutant cell lines, as indicated by repair inhibition factors of 2.0-2.3. No repair suppression was found in the p53 wild-type cell lines. CONCLUSIONS: p53 mutations are a general requirement for radiosensitization by pentoxifylline and the level of radiosensitization depends upon the location of the p53 mutation.     

Radiosensitization and DNA repair inhibition by pentoxifylline in NIH3T3 p53 transfectants

Purpose : To examine the role of p53 mutations in the modulation of DNA repair and radiotoxicity by pentoxifylline. Materials and methods : NIH3T3 murine cells transfected with mutant p53 constructs were examined for the influence of pentoxifylline on radiotoxicity to Co 60 γ-irradiation by colony assay. DNA repair (0-100 Gy) was measured by constant-field gel electrophoresis. Apoptosis was assessed by flow cytometry with the annexin-V-binding assay. Results : In the two p53 hot-spot mutant cell lines p53-S269R and p53- + 15, the SF 10 radiotoxicity enhancement factors induced by the pentoxifylline were 8.0 and 9.7, respectively. In the p53 deletion mutant p53- ΔA cell line, the radiotoxicity enhancement factor was 2.6. No radiosensitization was obtained in the untransfected p53 wild-type cell line U-Wt and in the transfected p53 double-wild-type p53-Wt cell line. When pentoxifylline was added after irradiation at the time of maximum G2 block expression, no radiosensitization was observed in any of the five cell lines. Constant-field gel electrophoresis analyses after 20 h of repair showed that pentoxifylline suppresses DNA double-strand break repair in all p53 mutant cell lines, as indicated by repair inhibition factors of 2.0-2.3. No repair suppression was found in the p53 wild-type cell lines. Conclusions : p53 mutations are a general requirement for radiosensitization by pentoxifylline and the level of radiosensitization depends upon the location of the p53 mutation.     

Cell cycle checkpoint evasion and protracted cell cycle arrest in X-irradiated small-cell lung carcinoma cells.

PURPOSE: To determine the longevity and dose-dependence of acute X-irradiation-induced cell cycle perturbations in a panel of seven small-cell lung carcinoma (SCLC) cell lines (COR-L32B, COR-L51B, COR-L88B, COR-L96C, COR-L103, COR-L266B, COR-L279), assessed for TP53 tumour suppressor gene status and showing characteristically long population doubling periods. MATERIALS AND METHODS: Cell lines were screened for abnormalities in TP53. Cell cycle arrest and nuclear fragmentation were determined by flow cytometry under culture conditions that minimized the propensity of SCLC cells to form multicellular aggregates. A faster growing SCLC cell line (NCI-H69) and two breast tumour cell lines were used as controls. RESULTS: NCI-H69 and five of the COR-SCLC cell lines showed clear evidence of TP53 abnormalities and the cycle arrest responses of the breast tumour cell lines established the effects of TP53 mutation on G1/S checkpoint loss. All SCLC lines, at 24 h after low dose irradiation, showed abrogation of the G1/S checkpoint together with a range of expression of a protracted G2/M delay. G2/M delay progressed in all panel cell lines up to 48 h post-irradiation while NCI-H69 showed significant recovery for the dose range 75-600cGy. Only NCI-H69 and one panel line showed dose-dependent progression to complete nuclear DNA fragmentation. CONCLUSIONS: The culture method permits the measurement of cell cycle effects that reflect the TP53 status of SCLC cells. G1/S checkpoint failure, long-term radiation-induced G2 arrest, highly muted apoptotic responses and delayed recovery appear to be typical responses of the recently derived COR-SCLC lines. The results imply that low levels of unrepaired DNA damage, induced at clinically relevant doses, can persist for days in SCLC cells with long cell cycle traverse times, and can remain capable of checkpoint activation with implications for S phase-targeted therapies.     

Cell cycle checkpoint evasion and protracted cell cycle arrest in X-irradiated small-cell lung carcinoma cells

Purpose: To determine the longevity and dose-dependence of acute X-irradiation-induced cell cycle perturbations in a panel of seven small-cell lung carcinoma (SCLC) cell lines (CORL32B, COR-L51B, COR-L88B, COR-L96C, COR-L103, CORL266B, COR-L279), assessed for TP53 tumour suppressor gene status and showing characteristically long population doubling periods. Materials and methods: Cell lines were screened for abnormalities in TP53. Cell cycle arrest and nuclear fragmentation were determined by flow cytometry under culture conditions that minimized the propensity of SCLC cells to form multicellular aggregates. A faster growing SCLC cell line (NCI-H69) and two breast tumour cell lines were used as controls. Results: NCI-H69 and five of the COR-SCLC cell lines showed clear evidence of TP53 abnormalities and the cycle arrest responses of the breast tumour cell lines established the effects of TP53 mutation on G1/S checkpoint loss. All SCLC lines, at 24h after low dose irradiation, showed abrogation of the G1/S checkpoint together with a range of expression of a protracted G2/M delay. G2/M delay progressed in all panel cell lines up to 48h post-irradiation while NCI-H69 showed significant recovery for the dose range 75-600cGy. Only NCI-H69 and one panel line showed dose-dependent progression to complete nuclear DNA fragmentation. Conclusions: The culture method permits the measurement of cell cycle effects that reflect the TP53 status of SCLC cells. G1/S checkpoint failure, long-term radiation-induced G2 arrest, highly muted apoptotic responses and delayed recovery appear to be typical responses of the recently derived COR-SCLC lines. The results imply that low levels of unrepaired DNA damage, induced at clinically relevant doses, can persist for days in SCLC cells with long cell cycle traverse times, and can remain capable of checkpoint activation with implications for S phase-targeted therapies.     

外源性野生型p53基因对不同p53功能状态的人肺腺癌细胞株的放射增敏作用

目的 观察外源性野生型p53基因(wtp53)对人肺腺癌细胞株的放射增敏作用,比较不同p53基因状态对照射的影响。 方法 免疫组织化学法、聚合酶链反应-单链构象多态性分析(PCR-SSCP法)筛选p53基因状态不同的两种人肺腺癌细胞系A549及GLC-82,用腺病毒介导wtp53 (Ad-p53)转染后分别给予0、2和4 Gy照射,测定集落形成率,流式细胞仪检测细胞周期分布和凋亡。结果 A549细胞的p53基因正常,而GLC-82细胞的p53基因第7外显子突变,转染后wtp53在两种细胞内均成功表达。Ad-p53对A549及GLC-82细胞抑制率分别为55%和88%,对GLC-82抑制作用较强(P<0.01)。转染Ad-p53后照射,两种细胞集落形成率较对照组明显下降(P<0.001)。流式细胞仪分析Ad-p53使G₁期细胞比例增加和凋亡指数增高,Ad-p53＋照射组最为明显(P<0.001)。结论 Ad-wtp53可以抑制人肺腺癌细胞株的生长,增加其放射敏感性,其放射增敏作用并不依赖于细胞内源性p53基因的状态。     

照射后不同p53基因状态胃癌细胞的G1期阻滞和凋亡

目的　评价抑癌基因ｐ５３（ 野生型ｐ５３） 对照射后人胃癌细胞系（ＢＧＣ８２３） 的Ｇ１ 期阻滞和凋亡的控制作用。方法　３ 种具有不同ｐ５３ 状态的人胃癌细胞系,即转染人野生型ｐ５３ 基因的ＢＧＣ８２３ｗｔｐ５３ 细胞、转染人突变型ｐ５３ 基因的ＢＧＣ８２３ｍｕｔｐ５３ 细胞和转染无ｐ５３ 基因的空载质粒的ＢＧＣ８２３ｖｅｃｔ 细胞,用流式细胞计分析细胞,４Ｇｙ 照射后０、８ 和２４ 小时后各细胞时相分布和凋亡的反应。结果　照射４Ｇｙ 后８ 小时和２４ 小时后的ＢＧＣ８２３ｗｔｐ５３ 细胞出现强烈的Ｇ１ 期阻滞（分别占原细胞总数的６７－９％ 和６１－１ ％） ,而ＢＧＣ８２３ｍｕｔｐ５３ 、ＢＧＣ８２３ｖｅｃｔ 细胞几乎没有Ｇ１ 期阻滞;照射４Ｇｙ 后８ 小时和２４ 小时后的ＢＧＣ８２３ｗｔｐ５３ 细胞出现明显的预示凋亡的亚Ｇ１ 峰,凋亡细胞比例分别达１３－０ ％ 和１５－３ ％ ;而ＢＧＣ８２３ｍｕｔｐ５３ 和ＢＧＣ８２３ｖｅｃｔ 细胞几乎没有出现亚Ｇ１ 峰和凋亡细胞比例都为零。结论　野生型ｐ５３ 基因具有促进照射后肿瘤细胞的Ｇ１ 期阻滞和凋亡作用,而ｐ５３ 变异和缺失则减低了肿瘤细胞对放射线的反应。     

p53 status,cellular recovery and cell cycle arrest as prognosticators of in vitro radiosensitivity in human pancreatic adenocarcinoma cell lines

Purpose: To investigate the factors contributing to the in vitro radiosensitivity of four human pancreatic adenocarcinoma cell lines differing in p53 status, and the basis for the lack of post-irradiation G1 arrest in the two cell lines that have retained a wild-type p53 allele. Materials and methods: Cells were X-irradiated and the parameters related to radiosensitivity, as well as the modulation of gene products linked to regulation of cell cycle transit (p53, p21/WAF1/CIP1, pRb) or DNA replication and repair (DNA topoisomerase I and II), were determined. Results: Both cell lines expressing either mutant (mt) R248W or R273H p53 proteins were more radioresistant. All the cell lines arrested in G2. None of the cell lines arrested in G1 and this was linked to the inability to upregulate p21/WAF1/CIP1. There were no correlations between p53 status and the magnitude or time of maximum G2 arrest. However, there was a negative correlation between a protracted arrest in G2 and the ability to recover from potentially lethal damage (PLD). Conclusions: Variation in radiosensitivity is related to p53 status, but the survival advantage conferred by having mutant p53 status is not readily explained neither by recovery from PLD nor by cell cycle arrest kinetics. There is no p53-independent pathway for the recruitment of p21 in these cell lines following irradiation.     

p53 status, cellular recovery and cell cycle arrest as prognosticators of in vitro radiosensitivity in human pancreatic adenocarcinoma cell lines

PURPOSE: To investigate the factors contributing to the in vitro radiosensitivity of four human pancreatic adenocarcinoma cell lines differing in p53 status, and the basis for the lack of post-irradiation G1 arrest in the two cell lines that have retained a wild-type p53 allele. MATERIALS AND METHODS: Cells were X-irradiated and the parameters related to radiosensitivity, as well as the modulation of gene products linked to regulation of cell cycle transit (p53, p21/WAF1/CIP1, pRb) or DNA replication and repair (DNA topoisomerase I and II), were determined. RESULTS: Both cell lines expressing either mutant (mt) R248W or R273H p53 proteins were more radioresistant. All the cell lines arrested in G2. None of the cell lines arrested in G1 and this was linked to the inability to upregulate p21/WAF1/CIP1. There were no correlations between p53 status and the magnitude or time of maximum G2 arrest. However, there was a negative correlation between a protracted arrest in G2 and the ability to recover from potentially lethal damage (PLD). CONCLUSIONS: Variation in radiosensitivity is related to p53 status, but the survival advantage conferred by having mutant p53 status is not readily explained neither by recovery from PLD nor by cell cycle arrest kinetics. There is no p53-independent pathway for the recruitment of p21 in these cell lines following irradiation.     

Preferential radiosensitization in p53-mutated human tumour cell lines by pentoxifylline-mediated disruption of the G2/M checkpoint control

Purpose : There is evidence that the duration of the G2/M delay following irradiation is correlated with cell survival. We studied the radiosensitizing potential of pentoxifylline (PTX) and the PTX-mediated modulation of cell-cycle progression dependent on the p53 status of various human tumour cell lines. Materials and methods : The cellular radiosensitivity of human MCF-7 (wild-type p53) and HT-29 (p53-defective) tumour cells, which were exposed to PTX (2 mM) immediately after γ-irradiation was determined by colony forming assay. The influence on cell cycle progression after irradiation (6 Gy) was assessed by flow cytometric analysis using p53 wild-type MCF-7 and HPR600 cells, and p53-defective HT-29 and WiDr cells. Results : Clonogenic survival assays up to 8 Gy demonstrated that p53-defective HT-29 cells (sensitizer enhancement ratio [SER]=1.54) were sensitized by PTX (2 mM) to a significantly higher degree than p53 wild-type MCF-7 (SER=1.14) cells. Exposure of irradiated (6 Gy) cells to PTX (2 mM) resulted in abrogation of the radiation-induced G2/M arrest in the p53-defective HT-29 and WiDr cells, whereas the p53 wild-type-expressing MCF-7 and HPR600 cells showed less significant impairment of the G2/M checkpoint. In HT-29 cells, the rate of transition into mitosis was even higher than in the sham-treated control cells. G2/M abrogation was accompanied by an increase of apoptosis only in HPR600 cells. Conclusions : Since PTX was less effective in cells expressing intact p53, the application of PTX suggests a promising strategy of pharmacological disruption of the G2/M checkpoint control by which preferentially radiation-resistant tumours with defective p53 function might be rendered more sensitive to ionizing radiation.     

Preferential radiosensitization in p53-mutated human tumour cell lines by pentoxifylline-mediated disruption of the G2/M checkpoint control

PURPOSE: There is evidence that the duration of the G2/M delay following irradiation is correlated with cell survival. We studied the radiosensitizing potential of pentoxifylline (PTX) and the PTX-mediated modulation of cell-cycle progression dependent on the p53 status of various human tumour cell lines. MATERIALS AND METHODS: The cellular radiosensitivity of human MCF-7 (wild-type p53) and HT-29 (p53-defective) tumour cells, which were exposed to PTX (2 mM) immediately after gamma-irradiation was determined by colony forming assay. The influence on cell cycle progression after irradiation (6 Gy) was assessed by flow cytometric analysis using p53 wild-type MCF-7 and HPR600 cells, and p53-defective HT-29 and WiDr cells. RESULTS: Clonogenic survival assays up to 8 Gy demonstrated that p53-defective HT-29 cells (sensitizer enhancement ratio [SER]=1.54) were sensitized by PTX (2 mM) to a significantly higher degree than p53 wild-type MCF-7 (SER=1.14) cells. Exposure of irradiated (6 Gy) cells to PTX (2 mM) resulted in abrogation of the radiation-induced G2/M arrest in the p53-defective HT-29 and WiDr cells, whereas the p53 wild-type-expressing MCF-7 and HPR600 cells showed less significant impairment of the G2/M checkpoint. In HT-29 cells, the rate of transition into mitosis was even higher than in the sham-treated control cells. G2/M abrogation was accompanied by an increase of apoptosis only in HPR600 cells. CONCLUSIONS: Since PTX was less effective in cells expressing intact p53, the application of PTX suggests a promising strategy of pharmacological disruption of the G2/M checkpoint control by which preferentially radiation-resistant tumours with defective p53 function might be rendered more sensitive to ionizing radiation.     

Cytoprotection by WR-1065, the active form of amifostine, is independent of p53 status in human malignant glioma cell lines

PURPOSE: This study tests the hypothesis that p53 status, i.e. wild type versus mutant form, is a determinant in radiation protection of human glioma cells by WR-1065, the active thiol form of amifostine (WR-2721). MATERIALS AND METHODS: The cytoprotective effectiveness of WR-1065 when present during irradiation was investigated using four well-characterized human glioma cell lines. The p53 positive lines were U87 and D54, and the mutant p53 lines were U251 (mutant at codon 273; CGT/CAT; Arg/His) and A172 (mutant at codon 242; TGC/TTC; Cys/Phe). Treatment conditions included exposure of cells to a range of doses (0-10Gy) alone or in combination with 4mM of WR-1065 added 30min prior to irradiation. Resultant survival curves were obtained using a clonogenic assay and protection factors, the ratio of terminal slopes +/- WR-1065, were determined for each glioma cell line. RESULTS: The Do values of wild-type U87 and D54 were 1.62 and 1.89Gy while those of p53 mutants U251 and A172 were 1.64 and 1.68 Gy, respectively. Protection factors were determined to be 2.4 and 1.9 for U87 and D54, and 2.6 and 2.8 for U251 and A172, respectively. CONCLUSIONS: The p53 status of the four human glioma cell lines tested was not a predictor for either their relative sensitivity to ionizing radiation or ability to be protected by WR-1065. It is concluded that cytoprotection exhibited by cells exposed to WR-1065 during irradiation is independent of their p53 status.     

Cytoprotection by WR-1065, the active form of amifostine,is independent of p53 status in human malignant glioma cell lines

Purpose : This study tests the hypothesis that p53 status, i.e. wild type versus mutant form, is a determinant in radiation protection of human glioma cells by WR-1065, the active thiol form of amifostine (WR-2721). Materials and methods : The cytoprotective effectiveness of WR-1065 when present during irradiation was investigated using four well-characterized human glioma cell lines. The p53 positive lines were U87 and D54, and the mutant p53 lines were U251 (mutant at codon 273; CGT/CAT; Arg/His) and A172 (mutant at codon 242; TGC/TTC; Cys/Phe). Treatment conditions included exposure of cells to a range of doses (0–10Gy) alone or in combination with 4 mM of WR-1065 added 30min prior to irradiation. Resultant survival curves were obtained using a clonogenic assay and protection factors, the ratio of terminal slopes +/- WR-1065, were determined for each glioma cell line. Results : The D 0 values of wild-type U87 and D54 were 1.62 and 1.89 Gy while those of p53 mutants U251 and A172 were 1.64 and 1.68 Gy, respectively. Protection factors were determined to be 2.4 and 1.9 for U87 and D54, and 2.6 and 2.8 for U251 and A172, respectively. Conclusions : The p53 status of the four human glioma cell lines tested was not a predictor for either their relative sensitivity to ionizing radiation or ability to be protected by WR-1065. It is concluded that cytoprotection exhibited by cells exposed to WR-1065 during irradiation is independent of their p53 status.     

Gamma irradiation of human leukaemic cells HL-60 and MOLT-4 induces decrease in Mcl-1 and Bid, release of cytochrome c, and activation of caspase-8 and caspase-9

PURPOSE: Apoptosis is significantly controlled by proteins of Bcl-2 (B-cell lymphoma 2) family promoting cell death or maintaining cell survival. We selected two representatives of Bcl-2 family (anti-apoptotic Mcl-1 - myeloid cell line-1 and pro-apoptotic Bid - Bcl-2 homology domain 3 interacting death agonist), cytochrome c (cyt-c), and two initial caspases (-8 and -9) to evaluate their function in ionizing radiation (IR)-induced apoptosis in human leukaemic cell lines diverging in p53 (TP53 tumor suppressor gene) status. MATERIALS AND METHODS: A total of 30 microg of proteins of whole-cell lysates or 10 microg of mitochondrial protein fractions were electrophoretically separated and analyzed by Western-blotting. RESULTS: Here we show that in both HL-60 (p53 null) and MOLT-4 (p53 wild type) leukaemic cells the amount of Mcl-1 initially increased after irradiation by sublethal but not by lethal dose and later (when apoptosis occurred) it decreased in a dose-dependent manner. Caspase-8 was cleaved and afterwards the amount of Bid decreased as it was truncated. We also found cyt-c release from the inner mitochondrial membrane space into cytoplasm to be dose-dependent and it was followed by induction of apoptosis. In the p53-null cells caspase-8 was activated prior caspase-9, whereas the cells harboring p53 exhibited a simultaneous activation of both initial caspases. CONCLUSION: IR induced a decrease in Mcl-1, activation of Bid, caspase-8, and -9, and release of cyt-c. Presented data indicate that both extrinsic and intrinsic apoptosis signalling pathways were activated in HL-60 and MOLT-4 cells upon exposure to IR regardless to the p53 status.     

Genotype-dependent radiosensitivity: clonogenic survival, apoptosis and cell-cycle redistribution

PURPOSE: We describe variations of three radiation-induced endpoints on the basis of cell genotype: Clonogenic survival, expression of apoptosis and cell-cycle redistribution. METHODS: Clonogenic survival, apoptosis and cell-cycle redistribution are measured in multiple cell lines after exposure to radiation between 2 and 16 Gy. Cell lines varied in clonogenic radiosensitivity and expression of specific genes. RESULTS: Clonal radiosensitivity is genotype-dependent, associating with four specific genes: A mutated form of Ataxia telangiectasia mutated (mutATM); with two forms of TP53, the gene that is template for tumor protein p53, wildtype TP53 (wtTP53) and mutated TP53 (mutTP53); and an unidentified gene in radioresistant glioblastoma cells. Apoptosis is also genotype-dependent showing elevated levels in cells that express mutATM and abrogated 14-3-3sigma (an isoform of the 14-3-3 gene) but less variation for different forms of TP53. Cell-cycle redistribution varied in mutATM cells. Kinetics of apoptosis are biphasic for both time and dose; cell lines did not express apoptosis at doses below 5 Gy or times before 24 hours. Kinetics of cell-cycle redistribution changed dynamically in the first 24 hours but showed little change after that time. CONCLUSIONS: Clonogenic survival, radiation-induced apoptosis and radiation-induced redistribution in the cell-cycle vary with cell genotype, but not the same genotypes. There is temporal, not quantitative, correlation between apoptosis and clonal radiosensitivity with apoptosis suppressed by lower, less toxic doses of radiation (<5 Gy) but enabled after larger, more toxic doses. Kinetic patterns for apoptosis and redistribution show a common change at approximately 24 hours.     

Radiation-induced apoptosis in human non-small-cell lung cancer cell lines is secondary to cell-cycle progression beyond the G2-phase checkpoint

PURPOSE: To characterize the relationship between cell-cycle progression and radiation-induced apoptosis in NSCLC cell lines with different p53 status. MATERIALS AND METHODS: Cell lines with functional (H460, A549) and non-functional p53 (H661 and H520) were irradiated with 20 Gy. Multiparameter flow-cytometry was used to follow the progression of synchronized cells through the cell cycle after irradiation. RESULTS: Delayed apoptosis was observed after cell-cycle progression beyond the G2 block, either in the late G2/M-phase of the same cell cycle being irradiated (H661, H520) or in the G1-phase of the subsequent cell cycle (H460, A549). The apoptotic fraction in H661 and H520 was 60-80% at 144h after irradiation, higher than in A549 and H460 (5 and 35%, respectively). As an alternative to apoptosis in cells cycling beyond the G2 restriction point, hyperploid cells were generated by all cell lines. Inhibition of cell-cycle progression through the G2/M-phase efficiently reduced the induction of late apoptosis. After irradiation in S-phase, 50-60% of cells with functional p53 remained arrested at the G2 restriction point until 144 h post-irradiation, while only 20% of the H661 or H520 did so. CONCLUSIONS: These data characterize radiation-induced apoptosis in NSCLC cell lines as a removal pathway of clonogenically inactivated cells secondary to cell-cycle progression beyond G2/M, and is unlikely to be a critical factor for cellular radiation sensitivity.     

Radiosensitivity and TP53, EGFR Amplification and LOH10 Analysis of Primary Glioma Cell Cultures

AIM: Determination of in-vitro radiosensitivity and genetic alterations of cell cultures derived from human glioma biopsy tissue and established glioma cell lines. MATERIAL AND METHODS: Fresh brain tumor specimens of six patients were processed to early passage cell cultures. In addition the cell lines D 384 and Gli 6 were used. Cell cultures were irradiated with doses from 2 to 10 Gy. Following irradiation, cell survival was determined by clonogenic assay and survival curves were generated. The surviving fractions after 2 Gy (SF2) and 4 Gy (SF4) were used as radiosensitivity parameters. Genetic analysis included determination of the mutational and loss of heterozygosity (LOH) status of TP 53 (exons 5-8), the LOH 10- and epidermal growth factor receptor gene (EGFR) amplification status. RESULTS: The SF2 and SF4 values ranged from 0.54 to 0.88 (mean: 0.70) and from 0.13 to 0.52 (mean: 0.32), respectively. Genetic alterations were found in the Gli 6 cell line and in two primary cell cultures. The genetic profile of Gli 6 showed LOH but no TP 53 mutation, complete LOH 10 and no EGFR amplification. The VU 15 cell culture showed TP 53 mutation but no LOH 10 or EGFR amplification, while VU 24 showed incomplete LOH 10, EGFR amplification and no TP 53 mutation. In the other four cell cultures and D 384 cell line no genetic alterations were diagnosed. Histopathological classification of glioblastoma multiforme and/or genetic alterations resulted in lower radiosensitivity. CONCLUSION: In this small series of early passage glioma cell cultures low radiosensitivity and alterations in cell regulatory genes were seen. Further testing of biological behavior in larger series of patient-derived material is ongoing.     

Radiation-induced apoptosis in human non-small-cell lung cancer cell lines is secondary to cell-cycle progression beyond the G2-phase checkpoint

Purpose : To characterize the relationship between cell-cycle progression and radiation-induced apoptosis in NSCLC cell lines with different p53 status. Materials and methods : Cell lines with functional (H460, A549) and non-functional p53 (H661 and H520) were irradiated with 20 Gy. Multiparameter flow-cytometry was used to follow the progression of synchronized cells through the cell cycle after irradiation. Results : Delayed apoptosis was observed after cell-cycle progression beyond the G2 block, either in the late G2/M-phase of the same cell cycle being irradiated (H661, H520) or in the G1-phase of the subsequent cell cycle (H460, A549). The apoptotic fraction in H661 and H520 was 60-80% at 144 h after irradiation, higher than in A549 and H460 (5 and 35%, respectively). As an alternative to apoptosis in cells cycling beyond the G2 restriction point, hyperploid cells were generated by all cell lines. Inhibition of cell-cycle progression through the G2/M-phase efficiently reduced the induction of late apoptosis. After irradiation in S-phase, 50-60% of cells with functional p53 remained arrested at the G2 restriction point until 144 h post-irradiation, while only 20% of the H661 or H520 did so. Conclusions : These data characterize radiation-induced apoptosis in NSCLC cell lines as a removal pathway of clonogenically inactivated cells secondary to cell-cycle progression beyond G2/M, and is unlikely to be a critical factor for cellular radiation sensitivity.     

Effects of Serum Starvation on Radiosensitivity,Proliferation and Apoptosis in Four Human Tumor Cell Lines with Different p53 Status

PURPOSE: The effects of serum starvation on radiation sensitivity, cell proliferation and apoptosis were investigated with particular consideration of the p53 status. MATERIAL AND METHODS: Four human tumor cell lines, Be11 (melanoma, p53 wild-type), MeWo (melanoma, p53 mutant), 4197 (squamous cell carcinoma, p53 wild-type) and 4451 (squamous cell carcinoma, p53 mutant), were used. After the cells had been incubated in starvation medium (0.5% FCS) for 1-6 days, changes in cell cycle distribution, induction of apoptosis and necrosis, and changes in radiation sensitivity were assessed by two-parameter flow cytometric measurements of DNA-dye-exclusion/Annexin V binding, and a conventional colony assay, respectively. RESULTS: p53 wild-type cell lines showed a decrease in the BrdU labeling index and an increase in the apoptotic cell frequency in starvation medium. p53 mutant cell lines showed a decrease in the BrdU labeling index but no evidence of apoptosis. These cells went into necrosis instead. The radiation sensitivity was increased in 4451 and slightly decreased in Be11 and 4197 in starvation medium. CONCLUSION: These data suggest a functional involvement of p53 in starvation-induced G1-block and apoptosis in tumor cells. Altered radiosensitivity after culture in starvation medium seemed to be explained at least in part by the starvation-induced G1-block. The frequency of starvation-induced apoptosis or necrosis was not correlated with radiation sensitivity.