Effects of a heat shock protein inhibitor KNK437 on heat sensitivity and heat tolerance in human squamous cell carcinoma cell lines differing in p53 status

Purpose: The effects of a heat shock protein (hsp) inhibitor KNK437 (N‐formyl‐3,4‐methylenedioxy‐benzylidene‐γ‐butyrolactam) were examined on the heat sensitivity and heat tolerance of human cancer cells with special reference to p53 status.

Materials and methods: Human squamous cell carcinoma (SAS) and glioblastoma cell lines (A‐172) transfected with mutant p53 (mp53) or control neo genes were used. KNK437 was added in culture medium at a final concentration of 50, 100 or 300?µM 1?h before heating (42°C). Surviving fractions of cells were measured by use of a clonogenic assay. Effects of KNK437 on the accumulation of heat shock proteins and DNA binding activity of heat shock factor 1 were examined with Western blot analysis and gel mobility‐shift assay, respectively. Heat‐induced apoptotic bodies were detected by Hoechst 33342 staining.

Results: The mp53‐transfected SAS (SAS/mp53) and A‐172 (A‐172/mp53) cells were more resistant to heat than the neomycin (neo)‐transfected SAS (SAS/neo) and A‐172 (A‐172/neo) cells. The constitutive amount of hsp27 was larger in SAS/mp53 than in SAS/neo cells. Clear differences in the constitutive amounts of hsp40, hsp72 and hsp90 were not observed between SAS/mp53 and SAS/neo cells. KNK437 enhanced the heat sensitivity in SAS/mp53 and A‐172/mp53 cells more effectively than in neo control cells. Heat tolerance was suppressed by KNK437 in SAS/mp53 and SAS/neo cells and also in A‐172/mp53 and A‐172/neo cells. Along with suppression of heat tolerance, KNK437 suppressed heat‐induced accumulation of both hsp27 and hsp72. Heat‐induced apoptotic bodies were enhanced by KNK437 in SAS/mp53 and SAS/neo cells.

Conclusion: The results suggest a possible mechanism for the heat sensitivity of SAS cells. Heat sensitivity depends on p53 status regulating the amount of hsp27. Heat tolerance is suppressed by KNK437 through the suppression of heat‐induced accumulations of hsp27 and hsp72 and the induction of p53‐independent apoptosis.     

Induction of radiation resistance by a heat shock protein inhibitor, KNK437, in human glioblastoma cells

PURPOSE: We examined the effects of a heat shock protein (hsp) inhibitor, N-formyl-3, 4-methylenedioxy-gamma-butyrolactam (KNK437), on the radiosensitivity of human glioblastoma cells (A-172). MATERIALS AND METHODS: Effects of KNK437 on radiosensitivity and cell cycle regulation were examined using colony formation assays, flow cytometry analysis and Western blot analysis. KNK437 was added to the culture medium 1 h before X-ray irradiation at 50, 100 or 300 microM final concentration. RESULTS: KNK437 induced the resistance of A-172 cells and human squamous cell carcinoma cells (SAS) to X-rays. Flow cytometry analysis showed that KNK437 alone efficiently induced A-172 cells to enter G2/M phase. Though A-172 cells irradiated with X-rays at 6 Gy showed no clear change in the cell cycle, the irradiated cells were induced to enter G2/M phase when they had been pre-treated with KNK437. By Western blot analysis, p53, 14-3-3sigma and cell division cycle 2 (cdc2) proteins that function in G2 arrest were observed to be persistently accumulated or phosphorylated in KNK437-treated cells, regardless of X-ray irradiation. CONCLUSIONS: These results show that KNK437 causes cells to be resistant to radiation, and that this might be correlated with maintenance of G2 arrest in the cell cycle regulation.     

Induction of radiation resistance by a heat shock protein inhibitor,KNK437, in human glioblastoma cells

Purpose:?We examined the effects of a heat shock protein (hsp) inhibitor, N-formyl-3, 4-methylenedioxy-γ-butyrolactam (KNK437), on the radiosensitivity of human glioblastoma cells (A-172).

Materials and methods:?Effects of KNK437 on radiosensitivity and cell cycle regulation were examined using colony formation assays, flow cytometry analysis and Western blot analysis. KNK437 was added to the culture medium 1 h before X-ray irradiation at 50, 100 or 300 μM final concentration.

Results:?KNK437 induced the resistance of A-172 cells and human squamous cell carcinoma cells (SAS) to X-rays. Flow cytometry analysis showed that KNK437 alone efficiently induced A-172 cells to enter G₂/M phase. Though A-172 cells irradiated with X-rays at 6 Gy showed no clear change in the cell cycle, the irradiated cells were induced to enter G₂/M phase when they had been pre-treated with KNK437. By Western blot analysis, p53, 14-3-3σ and cell division cycle 2 (cdc2) proteins that function in G₂ arrest were observed to be persistently accumulated or phosphorylated in KNK437-treated cells, regardless of X-ray irradiation.

Conclusions:?These results show that KNK437 causes cells to be resistant to radiation, and that this might be correlated with maintenance of G₂ arrest in the cell cycle regulation.     

WAF1 accumulation by carbon-ion beam and alpha-particle irradiation in human glioblastoma cultured cells

PURPOSE: There have been no reports about the effects of heavy-ion beams on the expression of the WAF1 gene, although ionizing radiation such as y-rays and X-rays is well known to induce WAF1 (p21/CIP1/sdi1) gene expression in a p53-dependent manner. In the present study, it was examined whether WAF1 accumulation was induced after carbon-ion (C-) beam or alpha-particle irradiation in four glioblastoma cell lines. MATERIALS AND METHODS: A colony assay for radiosensitivity and Western blot analysis of WAF1 were applied to two human glioblastoma cell lines, A-172 bearing wild-type p53 (wtp53) and T98G bearing mutated p53 (mp53). A-172/neo and A-172/mp53 were transfected with a control vector (containing only a neo selection marker) and a mp53 expression vector respectively. RESULTS: The amount of WAF1 increased markedly after X-ray irradiation in A-172 and A-172/neo cells but not in T98G and A-172/mp53 cells. The level of WAF1 reached a plateau at 3-10 h after X-ray irradiation at 5 Gy in A-172 and A-172/neo cells. Likewise, the levels of WAF1 in A-172 and A-172/neo cells reached a plateau at 3-10 h and 6-24 h after C-beam (3.0 Gy) and alpha-particle (4.5 Gy) irradiation respectively. The amount of WAF1 increased markedly in a dose-dependent manner 10 h after X-ray, C-beam or alpha-particle irradiation in A-172 and A-172/neo cells but not in T98G or A-172/mp53 cells. In addition, cell survival assay showed that these cell lines were most sensitive to C-beams, less sensitive to alpha-particles and least sensitive to X-rays at 10% survival. There was no difference in sensitivity among these cell lines against C-beam and alpha-particle irradiation whereas wtp53 cells (A-172 and A-172/neo) were more sensitive to X-rays than mp53 cells (A-172/mp53 and T98G). CONCLUSIONS: These results indicate that C-beams and alpha-particles induce p53-dependent WAF1 accumulation as well as is the case with X-rays, suggesting that WAF1 protein accumulation may not contribute to cell killing.     

WAF1 accumulation by carbon-ion beam and alpha-particle irradiation in human glioblastoma cultured cells

Purpose : There have been no reports about the effects of heavy-ion beams on the expression of the WAF1 gene, although ionizing radiation such as gamma-rays and X-rays is well known to induce WAF1 (p21/CIP1/sdi1) gene expression in a p53 -dependent manner. In the present study, it was examined whether WAF1 accumulation was induced after carbon-ion (C-) beam or alpha-particle irradiation in four glioblastoma cell lines. Materials and methods : A colony assay for radiosensitivity and Western blot analysis of WAF1 were applied to two human glioblastoma cell lines, A-172 bearing wild-type p53 (wt p53) and T98G bearing mutated p53 (m p53) . A-172/neo and A-172/mp53 were transfected with a control vector (containing only a neo selection marker) and a m p53 expression vector respectively. Results : The amount of WAF1 increased markedly after X-ray irradiation in A-172 and A-172/neo cells but not in T98G and A-172/mp53 cells. The level of WAF1 reached a plateau at 3-10 h after X-ray irradiation at 5 Gy in A-172 and A-172/neo cells. Likewise, the levels of WAF1 in A-172 and A-172/neo cells reached a plateau at 3-10 h and 6-24 h after C-beam (3.0Gy) and alpha-particle (4.5 Gy) irradiation respectively. The amount of WAF1 increased markedly in a dose-dependent manner 10 h after X-ray, C-beam or alpha-particle irradiation in A-172 and A172/neo cells but not in T98G or A-172/mp53 cells. In addition, cell survival assay showed that these cell lines were most sensitive to C-beams, less sensitive to alpha-particles and least sensitive to X-rays at 10% survival. There was no difference in sensitivity among these cell lines against C-beam and alpha-particle irradiation whereas wt p53 cells (A-172 and A-172/neo) were more sensitive to X-rays than m p53 cells (A-172/mp53 and T98G). Conclusions : These results indicate that C-beams and alpha-particles induce p53 -dependent WAF1 accumulation as well as is the case with X-rays, suggesting that WAF1 protein accumulation may not contribute to cell killing.     

p53-dependent thermal enhancement of cellular sensitivity in human squamous cell carcinomas in relation to LET.

PURPOSE: To investigate the dependence on p53 gene status of the thermal enhancement of cellular sensitivity against different levels of linear energy transfer (LET) from X-rays or carbon-ion (C-) beams. MATERIALS AND METHODS: Two kinds of human squamous cell carcinoma cell lines were used with an identical genotype except for the p53 gene. SAS/mp53 cells were established by transfection with mutated p53 (mp53) gene to SAS cells having functional wild-type p53 (wtp53). As the control, a neo vector was transfected to the SAS cells (SAS/neo cells). Both cells were exposed to X-rays or accelerated C-beams (30-150 KeV microm(-1)) followed by heating at 44 degrees C. Cellular sensitivity was determined by colony-forming activity. Induction of apoptosis was analysed by Hoechst 33342 staining of apoptotic bodies and agarose-gel electrophoresis for the formation of DNA ladders. RESULTS: It was found that (1) there was no significant difference in cellular sensitivity between SAS/neo and SAS/mp53 cells to LET radiation of >30 KeV microm(-1), although the radiosensitivity of SAS/neo cells to X-rays was higher (1.2-fold) than that of SAS/mp53 cells; (2) there was an interactive thermal enhancement of radiosensitivity below an LET of 70 KeV microm(-1) in SAS/neo cells, although only additive thermal enhancement was observed in SAS/mp53 cells through all LET levels examined; (3) low-LET radiation induced apoptosis only in SAS/neo cells; (4) high-LET radiation at an isosurvival dose-induced apoptosis of SAS/neo cells at a higher frequency compared with that with low-LET radiation; (5) high-LET radiation-induced p53-independent apoptosis in SAS/mp53 cells; and (6) thermal enhancement of cellular sensitivity to X-rays was due to induction of p53-dependent apoptosis. CONCLUSIONS: The findings suggest that thermal enhancement of radiosensitivity may result from p53-dependent apoptosis induced by inhibition of p53-dependent cell survival system(s) through either regulation of the cell cycle or induction of DNA repair. It is also suggested that the analysis of p53 gene status of cancer cells may predict response to combined therapies with low-LET radiation and hyperthermia.     

Attenuation of chronic thermotolerance by KNK437, a benzylidene lactam compound, enhances thermal radiosensitization in mild temperature hyperthermia combined with low dose-rate irradiation

PURPOSE: We investigated whether the attenuation of chronic thermotolerance by KNK437, a heat shock protein inhibitor, can modify the effect of thermal radiosensitization in mild temperature hyperthermia (MTH) combined with low dose-rate irradiation (LDRI). MATERIALS AND METHODS: The human lung adenocarcinoma cell line A549 was simultaneously exposed to LDRI with MTH at 41 degrees C and KNK437 at a dose of 100 microM. Cell survival was estimated by a clonogenic assay. Cell cycle change during treatment was analyzed by flow cytometry. Expression levels of the heat shock proteins hsp72, hsp27 and heat shock factor 1 (HSF-1) were measured by Western blotting. RESULTS: KNK437 inhibited the expression of inducible hsp72 and hsp27, but produced no change in the mobility shift of HSF-1. The cytotoxicity of LDRI was enhanced by MTH. The survival curve for LDRI + MTH revealed no development of chronic thermotolerance up to 48 h. Simultaneous LDRI and KNK437 treatment also resulted in enhanced cell killing. The radiosensitizing effect of KNK437 was enhanced by simultaneous exposure of the cells to MTH. Flow cytometry analysis of cell cycle progression demonstrated marked G2 arrest and mild G1 arrest with LDRI alone, but mild G1 arrest with MTH alone, and mild G2-M, S-phase accumulation with KNK437 alone. The marked G2 arrest caused by LDRI was partially suppressed by the addition of MTH, and was also suppressed by KNK437 treatment. CONCLUSIONS: Exposure of A549 cells to KNK437 caused inhibition of hsp72 and hsp27 expression. The addition of KNK437 increased not only thermosensitivity to MTH, but also radiosensitivity to LDRI. KNK437 also enhanced the MTH-induced radiosensitization under these experimental conditions.     

Attenuation of chronic thermotolerance by KNK437, a benzylidene lactam compound,enhances thermal radiosensitization in mild temperature hyperthermia combined with low dose-rate irradiation

Purpose: We investigated whether the attenuation of chronic thermotolerance by KNK437, a heat shock protein inhibitor, can modify the effect of thermal radiosensitization in mild temperature hyperthermia (MTH) combined with low dose-rate irradiation (LDRI).

Materials and methods: The human lung adenocarcinoma cell line A549 was simultaneously exposed to LDRI with MTH at 41°C and KNK437 at a dose of 100 μM. Cell survival was estimated by a clonogenic assay. Cell cycle change during treatment was analyzed by flow cytometry. Expression levels of the heat shock proteins hsp72, hsp27 and heat shock factor 1 (HSF-1) were measured by Western blotting.

Results: KNK437 inhibited the expression of inducible hsp72 and hsp27, but produced no change in the mobility shift of HSF-1. The cytotoxicity of LDRI was enhanced by MTH. The survival curve for LDRI + MTH revealed no development of chronic thermotolerance up to 48 h. Simultaneous LDRI and KNK437 treatment also resulted in enhanced cell killing. The radiosensitizing effect of KNK437 was enhanced by simultaneous exposure of the cells to MTH. Flow cytometry analysis of cell cycle progression demonstrated marked G2 arrest and mild G1 arrest with LDRI alone, but mild G1 arrest with MTH alone, and mild G2-M, S-phase accumulation with KNK437 alone. The marked G2 arrest caused by LDRI was partially suppressed by the addition of MTH, and was also suppressed by KNK437 treatment.

Conclusions: Exposure of A549 cells to KNK437 caused inhibition of hsp72 and hsp27 expression. The addition of KNK437 increased not only thermosensitivity to MTH, but also radiosensitivity to LDRI. KNK437 also enhanced the MTH-induced radiosensitization under these experimental conditions.     

Different inducibility of radiation- or heat-induced p53-dependent apoptosis after acute or chronic irradiation in human cultured squamous cell carcinoma cells

PURPOSE: This study was undertaken to clarify the effects of acute or chronic pre-irradiation on the induction of p53-dependent apoptosis by X-rays or heat shock. MATERIALS AND METHODS: Having an identical genotype except for p53-status, the human cultured squamous cell carcinoma cells (SAS) were transfected with a mutant p53 gene (SAS/mp53) or neo alone (SAS/neo) as a control. After acute X-irradiation (1 Gy min(-1)), chronic gamma-irradiation (0.001 Gy min(-1)) or heat shock (44 degrees C), the cells were for the incidence of apoptotic bodies and DNA ladders, cellular levels of p53 and bax, and caspase-3 activity. RESULTS: It was found that (1) a challenge treatment with X-rays (5.O Gy) or heat shock (30 min) immediately after chronic pre-irradiation (1.5 Gy) but not acute pre-irradiation (1.5 Gy) resulted in lower levels of apoptosis than those observed after challenge treatment only in SAS/neo cells; (2) a challenge treatment-induced apoptosis was observed 48 h after cessation of chronic pre-irradiation in SAS/neo cells; (3) apoptosis was barely increased in SAS/mp53 cells; and (4) the levels of apoptosis-related proteins after challenge treatments were strongly correlated with the above phenomena. CONCLUSIONS: Chronic pre-irradiation at a low dose-rate suppressed induction of p53-dependent apoptosis via bax and caspase-3. These findings suggest that chronic pre-irradiation suppressed p53 function through radiation-induced signalling and/or p53 stability.     

Restoration by glycerol of p53-dependent apoptosis in cells bearing the mutant p53 gene.

PURPOSE: Effective heat-induced cell death in cultured cells bearing a mutant p53 (mp53) gene was sought by glycerol treatment which led to conformational change from mp53 to wild-type p53 (wtp53) in p53-null murine fibroblasts transfected with mp53. MATERIALS AND METHODS: Heat sensitivity was measured using a colony-forming assay. For heat-induced apoptosis, gel electrophoresis was applied to detect DNA fragmentation and Hoechst33342 staining for apoptotic bodies. Glycerol (0.6 M) was applied to the cultured cells 48 h before heating at 44 degrees C in a water bath. RESULTS: Wtp53 transfectants (MT158/wtp53-1) were sensitive to heat stress compared with mp53 transfectants (MT158/mp53-2 cells), and the combined treatment with glycerol enhanced cell killing only in the MT158/mp53-2 cells. After glycerol pretreatment for 48 h, the subsequent heat treatment enhanced DNA fragmentation and apoptosis in MT158/mp53-2 cells, while DNA fragmentation and apoptotic bodies were not enhanced with heat treatment alone in these cells. In contrast, DNA fragmentation or apoptotic bodies were clearly observed in MT158/wtp53-1 cells 3-24h after heat treatment. Treatment with glycerol alone did not induce apoptosis in the transfectants. CONCLUSIONS: Glycerol appears to function as a chemical chaperone that restores mp53 to wtp53 function.     

Restoration by glycerol of p53-dependent apoptosis in cells bearing the mutant p53 gene

Purpose: Effective heat-induced cell death in cultured cells bearing a mutant p53 (mp53) gene was sought by glycerol treatment which led to conformational change from mp53 to wild-type p53 (wtp53) in p53-null murine fibroblasts transfected with mp53. Materials and methods: Heat sensitivity was measured using a colony-forming assay. For heat-induced apoptosis, gel electrophoresis was applied to detect DNA fragmentation and Hoechst33342 staining for apoptotic bodies. Glycerol (0.6 m) was applied to the cultured cells 48 h before heating at 44 C in a water bath. Results: Wtp53 transfectants (MT158/wtp53-1) were sensitive to heat stress compared with mp53 transfectants (MT158/mp53-2 cells), and the combined treatment with glycerol enhanced cell killing only in the MT158/mp53-2 cells. After glycerol pretreatment for 48h, the subsequent heat treatment enhanced DNA fragmentation and apoptosis in MT158/mp53-2 cells, while DNA fragmentation and apoptotic bodies were not enhanced with heat treatment alone in these cells. In contrast, DNA fragmentation or apoptotic bodies were clearly observed in MT158/wtp53-1 cells 3-24h after heat treatment. Treatment with glycerol alone did not induce apoptosis in the transfectants. Conclusions: Glycerol appears to function as a chemical chaperone that restores mp53 to wtp53 function.     

Effects of p53 status and wortmannin treatment on potentially lethal damage repair,with emphasis on the response of intratumor quiescent cells

PURPOSE: To examine the effects of p53 status and wortmannin treatment on potentially lethal damage repair, referring to the response of intratumor quiescent cells. METHODS: Human head and neck squamous cell carcinoma cells transfected with mutant TP53 (SAS/mp53) or with neo vector as a control (SAS/neo) were injected subcutaneously into both hind legs of Balb/cA nude mice. Mice bearing the tumors received 5-bromo-2'-deoxyuridine (BrdU) continuously to label all proliferating (P) cells in the tumors. The mice then received gamma-rays with or without subsequent wortmannin administration. Right after or 24 h after gamma-ray irradiation alone or 24 h after wortmannin administration following irradiation, the tumors were excised, minced, and trypsinized. The tumor cell suspensions thus obtained were incubated with a cytokinesis blocker (cytochalasin-B), and the micronucleus (MN) frequency in cells without BrdU labeling [quiescent (Q) cells] was determined using immunofluorescence staining for BrdU. The MN frequency in total (P+Q) tumor cells was determined from the tumors that were not pretreated with BrdU. RESULTS: On the whole, larger values of MN frequency and surviving fraction were observed in SAS/mp53 cells than in SAS/neo cells, and Q cells showed lower MN frequencies than total cells. Without wortmannin, SAS/neo tumor cells, especially Q cells within SAS/neo tumors, showed large potentially lethal damage repair (PLDR) capacities, compared with total or Q tumor cells within SAS/mp53 tumors that showed little PLDR capacity. Wortmannin treatment inhibited the PLDR in SAS/neo tumors very effectively, but showed no apparent effect on either total or Q tumor cells within SAS/mp53 tumors. CONCLUSION: PLDR in vivo was thought to be a p53-dependent event whether in total or Q tumor cell populations.     

Analysis of death pattern in cancer cells by using different kinds of LET radiation

We investigated the death pattern of cancer cells by using different kinds of linear energy transfer (LET) radiation. We used two human squamous cell carcinoma cell lines with an identical genotype except for the p53 gene. SAS/mp53 cells were established by transfection with the mp53 gene to SAS cells having functional p53 (wtp53). As the control, a neovector was transfected to the SAS cells (SAS/neo cells). Both types of cells were exposed to X-rays (1.5 KeV/micron) or accelerated C-beams (30-100 KeV/micron). The frequency of cell death (apoptosis and necrosis) was measured by acridine orange/ethidium bromide(AO/EB) double staining for fluorescence microscopy. We found that (1) low-LET radiation induced apoptosis only in SAS/neo cells; (2) high-LET radiation at an iso-survival dose induced apoptosis not but necrosis in SAS/neo cells at a higher frequency; (3) high-LET radiation induced p53-independent apoptosis even in SAS/mp53 cells. Our findings suggest that high-LET radiotherapy is expected to (1) have validity in its application to patients carrying mutated p53 cancer cells and (2) reduce injury to adjacent normal tissue for high-frequency-induced apoptosis without inflammatory response. We propose that elucidation of p53-independent apoptosis-related genes might provide new insights into radiotherapy for cancer.     

p53 -Dependent thermal enhancement of cellular sensitivity in human squamous cell carcinomas in relation to LET

Purpose : To investigate the dependence on p53 gene status of the thermal enhancement of cellular sensitivity against different levels of linear energy transfer (LET) from X-rays or carbon-ion (C-) beams. Materials and methods : Two kinds of human squamous cell carcinoma cell lines were used with an identical genotype except for the p53 gene. SAS/m p53 cells were established by transfection with mutated p53 (m p53) gene to SAS cells having functional wild-type p53 (wtp53). As the control, a neo vector was transfected to the SAS cells (SAS/ neo cells). Both cells were exposed to X-rays or accelerated C-beams (30-150 KeV w m -1) followed by heating at 44°;C. Cellular sensitivity was determined by colony-forming activity. Induction of apoptosis was analysed by Hoechst 33342 staining of apoptotic bodies and agarose-gel electrophoresis for the formation of DNA ladders. Results : It was found that (1) there was no significant difference in cellular sensitivity between SAS/ neo and SAS/m p53 cells to LET radiation of >30 KeV w m -1, although the radiosensitivity of SAS/ neo cells to X-rays was higher (1.2-fold) than that of SAS/m p53 cells; (2) there was an interactive thermal enhancement of radiosensitivity below an LET of 70 KeV w m -1 in SAS/ neo cells, although only additive thermal enhancement was observed in SAS/m p53 cells through all LET levels examined; (3) low-LET radiation induced apoptosis only in SAS/ neo cells; (4) high-LET radiation at an isosurvival dose-induced apoptosis of SAS/ neo cells at a higher frequency compared with that with low-LET radiation; (5) high-LET radiation-induced p53-independent apoptosis in SAS/m p53 cells; and (6) thermal enhancement of cellular sensitivity to X-rays was due to induction of p53-dependent apoptosis. Conclusions : The findings suggest that thermal enhancement of radiosensitivity may result from p53-dependent apoptosis induced by inhibition of p53-dependent cell survival system(s) through either regulation of the cell cycle or induction of DNA repair. It is also suggested that the analysis of p53 gene status of cancer cells may predict response to combined therapies with low-LET radiation and hyperthermia.     

Different inducibility of radiation- or heat-induced p53 -dependent apoptosis after acute or chronic irradiation in human cultured squamous cell carcinoma cells

Purpose : This study was undertaken to clarify the effects of acute or chronic pre-irradiation on the induction of p53 -dependent apoptosis by X-rays or heat shock. Materials and methods : Having an identical genotype except for p53 -status, the human cultured squamous cell carcinoma cells (SAS) were transfected with a mutant p53 gene (SAS/m p53) or neo alone (SAS/ neo) as a control. After acute X-irradiation (1Gy min -1) , chronic gamma-irradiation (0.001 Gy min -1) or heat shock (44°C), the cells were for the incidence of apoptotic bodies and DNA ladders, cellular levels of p53 and bax, and caspase-3 activity. Results : It was found that (1) a challenge treatment with X-rays (5.0 Gy) or heat shock (30 min) immediately after chronic pre-irradiation (1.5Gy) but not acute pre-irradiation (1.5 Gy) resulted in lower levels of apoptosis than those observed after challenge treatment only in SAS/ neo cells; (2) a challenge treatment-induced apoptosis was observed 48h after cessation of chronic pre-irradiation in SAS/ neo cells; (3) apoptosis was barely increased in SAS/m p53 cells; and (4) the levels of apoptosis-related proteins after challenge treatments were strongly correlated with the above phenomena. Conclusions : Chronic pre-irradiation at a low dose-rate suppressed induction of p53 -dependent apoptosis via bax and caspase-3. These findings suggest that chronic pre-irradiation suppressed p53 function through radiation-induced signalling and/or p53 stability.     

Brief communication: heat-induced accumulation of p53 and hsp72 is suppressed in lung fibroblasts from the SCID mouse

PURPOSE: To investigate how DNA-dependent protein kinase (DNA-PK) contributes to p53-dependent signal transduction after heat shock, thermosensitivity and accumulation of p53 and hsp72 after heat shock in lung fibroblasts derived from the SCID mouse were analysed. MATERIALS AND METHODS: Thermosensitivity at 44 degrees C in colony-forming units and Western blot analysis of p53 and hsp72 were analysed. RESULTS: The results indicated that (1) the thermosensitivity at 44 degrees C of SCID cells was higher than that of parental cells and (2) heat-induced accumulation of p53 and hsp72 was abolished and suppressed in SCID cells as compared with that in parental cells respectively. CONCLUSIONS: The findings suggest that the catalytic subunit of DNA-PK may play an important role upstream of p53 and hsp72, which are possible determinants of cellular thermosensitivity.     

Heat-induced accumulation of p53 and hsp72 is suppressed in lung fibroblasts from the SCID mouse

Purpose : To investigate how DNA-dependent protein kinase (DNA-PK) contributes to p53-dependent signal transduction after heat shock, thermosensitivity and accumulation of p53 and hsp72 after heat shock in lung fibroblasts derived from the SCID mouse were analysed. Materials and methods : Thermosensitivity at 44°C in colony-forming units and Western blot analysis of p53 and hsp72 were analysed. Results : The results indicated that (1) the thermosensitivity at 44°C of SCID cells was higher than that of parental cells and (2) heat-induced accumulation of p53 and hsp72 was abolished and suppressed in SCID cells as compared with that in parental cells respectively. Conclusions : The findings suggest that the catalytic subunit of DNA-PK may play an important role upstream of p53 and hsp72, which are possible determinants of cellular thermosensitivity.     

Radicicol potentiates heat-induced cell killing in a human oesophageal cancer cell line: the Hsp90 chaperone complex as a new molecular target for enhancement of thermosensitivity

PURPOSE: To examine the ability of a heat shock protein 90 (Hsp90) chaperone complex inhibitor, radicicol, to modify thermal response and heat-induced cell killing, and to clarify the underlining mechanisms. MATERIALS AND METHODS: A human oesophageal cancer cell line (TE-1), with a mutant p53 gene, was used. To examine the effect of radicicol on heat-induced cell killing, radicicol at a concentration of 100 nM was incubated with the cells for 7 h during heat treatment. Changes in the expression of proteins were examined by Western blot and immunofluorescence analysis. RESULTS: Radicicol in combination with heat synergistically potentiated heat-induced cellular killing despite an increase in the expression of Hsp72 and Hsp27 caused by radicicol. Heat alone activated Raf-1 and p42/p44 extracellular signal-regulated kinase (Erk), and heat in combination with radicicol inhibited the activation of Raf-1 and p42/p44 Erk through reduced binding of Raf-1 to Hsp90. Phosphorylation of Akt was also decreased by radicicol. CONCLUSIONS: The Hsp90 chaperone complex inhibitor, radicicol, potentiated heat-induced cellular killing, and inhibition of p42/p44 Erk and Akt activation rather than modification of Hsp expression might be involved in enhancing cellular thermosensitivity. Results suggest that the Hsp90 chaperone complex could be a new molecular target for the modification of the cellular response to heat.     

Induction of radioresistance to accelerated carbon-ion beams in recipient cells by nitric oxide excreted from irradiated donor cells of human glioblastoma

Purpose : To investigate whether nitric oxide excreted from cells irradiated with accelerated carbon-ion beams modulates cellular radiosensitivity against irradiation in human glioblastoma A-172 and T98G cells. Materials and methods : Western-blot analysis of inducible nitric oxide synthase, hsp72 and p53, the concentration assay of nitrite in medium and cell survival assay after irradiation with accelerated carbon-ion beams were performed. Results : The accumulation of inducible nitric oxide synthase was caused by accelerated carbon-ion beam irradiation of T98G cells but not of A-172 cells. The accumulation of hsp72 and p53 was observed in A-172 cells after exposure to the conditioned medium of the T98G cells irradiated with accelerated carbon-ion beams, and the accumulation was abolished by the addition of an inhibitor for inducible nitric oxide synthase to the medium. The radiosensitivity of A-172 cells was reduced in the conditioned medium of the T98G cells irradiated with accelerated carbonion beams compared with conventional fresh growth medium, and the reduction of radiosensitivity was abolished by the addition of an inducible nitric oxide synthase inhibitor to the conditioned medium. Conclusions : Nitric oxide excreted from the irradiated donor cells with accelerated carbon-ion beams could modulate the radiosensitivity of recipient cells. These findings indicate the importance of an intercellular signal transduction pathway initiated by nitric oxide in the cellular response to accelerated heavy ions.     

Induction of radioresistance to accelerated carbon-ion beams in recipient cells by nitric oxide excreted from irradiated donor cells of human glioblastoma

PURPOSE: To investigate whether nitric oxide excreted from cells irradiated with accelerated carbon-ion beams modulates cellular radiosensitivity against irradiation in human glioblastoma A-172 and T98G cells. MATERIALS AND METHODS: Western-blot analysis of inducible nitric oxide synthase, hsp72 and p53, the concentration assay of nitrite in medium and cell survival assay after irradiation with accelerated carbon-ion beams were performed. RESULTS: The accumulation of inducible nitric oxide synthase was caused by accelerated carbon-ion beam irradiation of T98G cells but not of A-172 cells. The accumulation of hsp72 and p53 was observed in A-172 cells after exposure to the conditioned medium of the T98G cells irradiated with accelerated carbon-ion beams, and the accumulation was abolished by the addition of an inhibitor for inducible nitric oxide synthase to the medium. The radiosensitivity of A-172 cells was reduced in the conditioned medium of the T98G cells irradiated with accelerated carbon-ion beams compared with conventional fresh growth medium, and the reduction of radiosensitivity was abolished by the addition of an inducible nitric oxide synthase inhibitor to the conditioned medium. CONCLUSIONS: Nitric oxide excreted from the irradiated donor cells with accelerated carbon-ion beams could modulate the radiosensitivity of recipient cells. These findings indicate the importance of an intercellular signal transduction pathway initiated by nitric oxide in the cellular response to accelerated heavy ions.