Sensitizing human cervical cancer cells In vitro to ionizing radiation with interferon beta or gamma.

Human cervical cancer is often associated with human papilloma virus (HPV). HPV products, such as the oncoproteins E6 and E7, are known to disrupt the function of TP53 (formerly known as p53). The protein encoded by the TP53 gene plays a central role in managing cellular damage. Interferons are known to down-regulate E6/E7 and may therefore restore TP53 function and influence radiation sensitivity. We investigated whether IFNB or IFNG, at various concentrations (2- 300 IU/ml) and for a range of durations of exposure (from 48 h before to 8 h after irradiation), were able to modify the radiation response of HeLa, C4-1, Me-180, C33-A and SiHa cells. In parallel to the clonogenic assays, we analyzed the effect on the mRNA that encodes IFNB and E6 by Northern blotting in the same experimental conditions. A significant change in the initial slope of the dose-response curve was observed more consistently with IFNB than with IFNG. No changes in the mRNA or protein level of TP53 and E6 could be detected. Thus other mechanisms of action need to be investigated to explain radiosensitization with recombinant IFNB in cells of human cervical cancer cell lines.     

Differential response to radiation of TP53-inactivated cells by overexpression of dominant-negative mutant TP53 or HPVE6

The inactivation of TP53 by transfection of a dominant- negative mutated TP53 (MP53.13 cells) was compared with inactivation of TP53 by transfection with the HPV E6 gene (RC10.1 cells) with respect to PLD repair, G(1)-phase arrest, and induction of color junctions. Functional G(1) arrest was demonstrated in parental (RKO) cells with wild-type TP53, while in RC10.1 cells the G(1) arrest was eliminated. In MP53.13 cells an intermediate G(1) arrest was found. Functionality of endogenous TP53 was confirmed in RKO and MP53.13 cells by accumulation of TP53 protein and its downstream target CDKN1A (p21). Radiation survival of MP53.13 cells was higher than that of RKO cells, and PLD repair was found in RKO cells and MP53.13 cells but not in RC10.1 cells. Both with and without irradiation, the number of color junctions was 50 to 80% higher in MP53.13 cells than in RKO and RC10.1 cells. In the MP53.13 cells, the genetic instability appears to lead to more aberrations and to radioresistance. In spite of the presence of an excess of mutated TP53, wild- type TP53 functions appear to be affected only partly or not at all.     

A novel cytostatic form of autophagy in sensitization of non-small cell lung cancer cells to radiation by vitamin D and the vitamin D analog,EB 1089

The standard of care for unresectable lung cancer is chemoradiation. However, therapeutic options are limited and patients are rarely cured. We have previously shown that vitamin D and vitamin D analogs such as EB 1089 can enhance the response to radiation in breast cancer through the promotion of a cytotoxic form of autophagy. In A549 and H460 non-small cell lung cancer (NSCLC) cells, 1,25-D₃ (the hormonally active form of vitamin D) and EB 1089 prolonged the growth arrest induced by radiation alone and suppressed proliferative recovery, which translated to a significant reduction in clonogenic survival. In H838 or H358 NSCLC cells, which lack VDR/vitamin D receptor or functional TP53, respectively, 1,25-D₃ failed to modify the extent of radiation-induced growth arrest or suppress proliferative recovery post-irradiation. Sensitization to radiation in H1299 NSCLC cells was evident only when TP53 was induced in otherwise tp53-null H1299 NSCLC cells. Sensitization was not associated with increased DNA damage, decreased DNA repair or an increase in apoptosis, necrosis, or senescence. Instead sensitization appeared to be a consequence of the conversion of the cytoprotective autophagy induced by radiation alone to a novel cytostatic form of autophagy by the combination of 1,25-D₃ or EB 1089 with radiation. While both pharmacological and genetic suppression of autophagy or inhibition of AMPK phosphorylation sensitized the NSCLC cells to radiation alone, inhibition of the cytostatic autophagy induced by the combination treatment reversed sensitization. Evidence for selectivity was provided by lack of radiosensitization in normal human bronchial cells and cardiomyocytes. Taken together, these studies have identified a unique cytostatic function of autophagy that appears to be mediated by VDR, TP53, and possibly AMPK in the promotion of an enhanced response to radiation by 1,25-D₃ and EB 1089 in NSCLC.     

A novel cytostatic form of autophagy in sensitization of non-small cell lung cancer cells to radiation by vitamin D and the vitamin D analog,EB 1089

The standard of care for unresectable lung cancer is chemoradiation. However, therapeutic options are limited and patients are rarely cured. We have previously shown that vitamin D and vitamin D analogs such as EB 1089 can enhance the response to radiation in breast cancer through the promotion of a cytotoxic form of autophagy. In A549 and H460 non-small cell lung cancer (NSCLC) cells, 1,25-D₃ (the hormonally active form of vitamin D) and EB 1089 prolonged the growth arrest induced by radiation alone and suppressed proliferative recovery, which translated to a significant reduction in clonogenic survival. In H838 or H358 NSCLC cells, which lack VDR/vitamin D receptor or functional TP53, respectively, 1,25-D₃ failed to modify the extent of radiation-induced growth arrest or suppress proliferative recovery post-irradiation. Sensitization to radiation in H1299 NSCLC cells was evident only when TP53 was induced in otherwise tp53-null H1299 NSCLC cells. Sensitization was not associated with increased DNA damage, decreased DNA repair or an increase in apoptosis, necrosis, or senescence. Instead sensitization appeared to be a consequence of the conversion of the cytoprotective autophagy induced by radiation alone to a novel cytostatic form of autophagy by the combination of 1,25-D₃ or EB 1089 with radiation. While both pharmacological and genetic suppression of autophagy or inhibition of AMPK phosphorylation sensitized the NSCLC cells to radiation alone, inhibition of the cytostatic autophagy induced by the combination treatment reversed sensitization. Evidence for selectivity was provided by lack of radiosensitization in normal human bronchial cells and cardiomyocytes. Taken together, these studies have identified a unique cytostatic function of autophagy that appears to be mediated by VDR, TP53, and possibly AMPK in the promotion of an enhanced response to radiation by 1,25-D₃ and EB 1089 in NSCLC.     

TP53 is not required for the constitutive or induced repair of DNA damage produced by ionizing radiation at the G1/S-phase border

We have previously described a novel DNA repair response that is induced in cells irradiated with ionizing radiation at the G1/S-phase border and is characterized by the formation of very long repair patches (VLRP) containing at least 150 nucleotides. In the current study, we examined whether there is a requirement for TP53 in this induced repair process. We find that in normal cells, the endogenous levels of TP53 are elevated at the G1/S-phase border, and that these levels are not further increased after irradiation with 5 Gy. In cells expressing the E6 oncoprotein of human papillomavirus, which inactivates TP53 function, there is a greatly accentuated induction of the VLRP that nearly masks the constitutive repair response. Incubation of cells in the presence of cycloheximide, which inhibits the induced repair, reveals the presence of the constitutive repair patches. All cells examined continue to replicate their DNA after exposure to ionizing radiation. In contrast, cells irradiated with UV radiation at the G1/S-phase border show an induction of TP53 protein and halt DNA synthesis, but do not induce the VLRP. Our results show that TP53 is not required for the constitutive or induced repair of DNA damage induced by ionizing radiation. In addition, these results suggest that TP53 may suppress the formation of VLRP and that the progression of cells through S phase after exposure to ionizing radiation signals the induced repair response.     

Distinct functions for WRN and TP53 in a shared pathway of cellular response to 1-beta-D-arabinofuranosylcytosine and bleomycin

Mutations in the WRN or the TP53 genes lead to spontaneous genetic instability, an elevated risk of tumor formation, and sensitivity to compounds that interfere with DNA replication, such as camptothecin and DNA interstrand cross-linking drugs. We investigated the hypothesis that WRN and TP53 are involved in cellular responses to DNA replication-blocking lesions by exposing WRN deficient and TP53 mutant lymphoblastoid cell lines (LCLs) to 1-beta-d-arabinofuranosylcytosine (AraC) and bleomycin. Loss of WRN or TP53 function resulted in induction of apoptosis and lesser proliferative survival in response to AraC and bleomycin. WRN and TP53 operate in a shared DNA damage response pathway, since in cells in which TP53 was inactivated by SV-40 transformation, no difference in AraC and bleomycin sensitivity was found regardless of WRN status. In contrast to TP53 mutant LCLs, WRN-deficient cells showed unaffected cell cycle arrest after AraC and bleomycin exposure, which indicates that WRN is not involved in DNA damage-activated cell cycle arrest. Neither WRN nor TP53 deficiency affected cellular recovery from exposure to AraC and bleomycin, which disagrees with a direct role in repair of these DNA lesions. Our results indicate that WRN and TP53 perform different functions in a shared DNA damage response pathway.     

X radiation causes a persistent induction of reactive oxygen species and a delayed reinduction of TP53 in normal human diploid fibroblasts

Multiple genetic changes are required for the development of a malignant cell. The frequency of such changes in cancer cells is higher than can be explained through random mutation, and it was proposed that a subpopulation of cells develop a persistent mutator phenotype. Evidence for such a phenotype has been observed in mammalian cells after treatment with ionizing radiation. The mechanism that promotes this effect has not been defined, but proposed explanations include increased levels of reactive oxygen species (ROS) in irradiated cells and their progeny. The tumor suppressor TP53 is of prime importance in coordinating the cellular response to damage, and it has been suggested to have a role in regulating the cellular redox state. We investigated the persistence of induced levels of ROS in normal diploid human cells for 1 month after X-ray exposure and the role of TP53 in this oxidant response. X radiation induced an oxidant response that persisted for 2 weeks after exposure in cells with normal TP53 function. ROS levels in cells with abrogated TP53 function were decreased in magnitude and duration. X radiation caused a primary transient induction of TP53 followed by a reinduction of TP53 5 days after irradiation. This reinduction persisted for at least 2 days and coincided with the largest induction of apoptosis. The persistently elevated levels of ROS and delayed reinduction of TP53 reported here are further evidence of the delayed effects of ionizing radiation and add to the growing number of such observations.     

Induction of telomerase activity by irradiation in human lymphoblasts

Neuhof, D., Ruess, A., Wenz, F. and Weber, K. J. Induction of Telomerase Activity by Irradiation in Human Lymphoblasts. Radiat. Res. 155, 693-697 (2001). Telomerase activity is a radiation-inducible function, which suggests a role of this enzyme in DNA damage processing. Since the tumor suppressor TP53 plays a central role in the regulation of the cellular response to DNA damage, our study explored the ability of ionizing radiation to change telomerase activity and telomere length in two closely related human lymphoblast cell lines with different TP53 status. TK6 cells (wild-type TP53) and WTK1 cells (mutated TP53) were exposed to different doses of X rays, and telomerase activity was measured by PCR ELISA at different times after irradiation. A dose-dependent increase in telomerase activity was observed. One hour after irradiation with 4 Gy, TK6 and WTK1 cells showed an approximately 2.5-fold increase; for lower doses (0.1 to 1 Gy), telomerase induction was seen only in TK6 cells. Telomerase induction was observed by 0.5 h after irradiation, with a further increase up to 24 h. Irradiated TK6 and WTK1 cells had longer telomeres (+1.3 kb) than unirradiated cells 14 days after exposure. Our data demonstrate a dose-dependent induction of telomerase activity and lengthening of telomeres by ionizing radiation in human lymphoblasts. Induction of telomerase activity by radiation does not generally appear to be controlled by the TP53-dependent DNA damage response pathway. However, for low doses, induction of telomerase requires wild-type TP53.     

Inhibition of c-Jun N-terminal kinase 2 expression suppresses growth and induces apoptosis of human tumor cells in a p53-dependent manner

c-Jun N-terminal kinase (JNK) plays a critical role in coordinating the cellular response to stress and has been implicated in regulating cell growth and transformation. To investigate the growth-regulatory functions of JNK1 and JNK2, we used specific antisense oligonucleotides (AS) to inhibit their expression. A survey of several human tumor cell lines revealed that JNKAS treatment markedly inhibited the growth of cells with mutant p53 status but not that of cells with normal p53 function. To further examine the influence of p53 on cell sensitivity to JNKAS treatment, we compared the responsiveness of RKO, MCF-7, and HCT116 cells with normal p53 function to that of RKO E6, MCF-7 E6, and HCT116 p53(-/-), which were rendered p53 deficient by different methods. Inhibition of JNK2 (and to a lesser extent JNK1) expression dramatically reduced the growth of p53-deficient cells but not that of their normal counterparts. JNK2AS-induced growth inhibition was correlated with significant apoptosis. JNK2AS treatment induced the expression of the cyclin-dependent kinase inhibitor p21(Cip1/Waf1) in parental MCF-7, RKO, and HCT116 cells but not in the p53-deficient derivatives. That p21(Cip1/Waf1) expression contributes to the survival of JNK2AS-treated cells was supported by additional experiments demonstrating that p21(Cip1/Waf1) deficiency in HCT116 cells also results in heightened sensitivity to JNKAS treatment. Our results indicate that perturbation of JNK2 expression adversely affects the growth of otherwise nonstressed cells. p53 and its downstream effector p21(Cip1/Waf1) are important in counteracting these detrimental effects and promoting cell survival.     

p53 promotes the fidelity of DNA end-joining activity by, in part, enhancing the expression of heterogeneous nuclear ribonucleoprotein G

Many studies have suggested the involvement of wild-type (wt) p53 in the repair of DNA double-strand breaks (DSBs) via DNA end-joining (EJ) process. To investigate this possibility, we compared the capacity and fidelity of DNA EJ in RKO cells containing wt p53 and RKO cells containing no p53 (RKO cells with p53 knockdown). The p53 knockdown cells showed lower fidelity of DNA EJ compared to the control RKO cells. The DNA end-protection assay revealed the association of a protein complex including heterogeneous nuclear ribonucleoprotein G (hnRNP G) with the DNA ends in RKO cells containing wt p53, but not with the DNA ends in RKO cells with p53 knockdown. Depletion of endogenous hnRNP G notably diminished the fidelity of EJ in RKO cells expressing wt p53. Moreover, an ectopic expression of hnRNP G significantly enhanced the fidelity of DNA EJ and the protection of DNA ends in human cancer cells lacking hnRNP G protein or containing mutant hnRNP G. Finally, using recombinant hnRNP G proteins, we demonstrated the hnRNP G protein is able to bind to and protect DNA ends from degradation of nucleases. Our results suggest that wt p53 modulates DNA DSB repair by, in part, inducing hnRNP G, and the ability of hnRNP G to bind and protect DNA ends may contribute its ability to promote the fidelity of DNA EJ.     

Analysis of the p53-mediated G1 growth arrest pathway in cells expressing the human papillomavirus type 16 E7 oncoprotein.

Cells expressing human papillomavirus type 16 (HPV-16) E7, similar to those which express HPV-16 E6, are resistant to a p53-mediated G1 growth arrest. We examined the p53-mediated DNA damage response pathway in E7-expressing cells to determine the mechanism by which E7-containing cells continue to cycle. In response to DNA damage, no dramatic difference was detected in G1- or S-phase cyclin or cyclin-dependent kinase (Cdk) levels when E7-expressing cells were compared to the parental cell line, RKO. Furthermore, Cdk2 kinase activity was inhibited in both RKO cells and E7-expressing cells, while Cdk2 remained active in E6-expressing cells. However, the steady-state levels of pRB and p107 protein were substantially lower in E7-expressing cells than in the parental RKO cells or E6-expressing cells. There was no reduction in pRB mRNA levels, but the half-life of pRB in E7-expressing cells was markedly shorter. Infection of primary human foreskin keratinocytes with recombinant retroviruses expressing HPV-16 E7 resulted in a decrease in pRB protein levels, indicating this phenomenon is a consequence of E7 expression, not of immortalization or transformation. These data strongly suggest E7 interferes with the stability of pRB and p107 protein. We propose that the removal of these components of the p53-mediated G1 growth arrest pathway in E7-expressing cells contributes to the ability of E7 to overcome a p53-mediated G1 growth arrest.     

Radiation sensitization of mammalian cells by metal chelators

The cell cycle effects, alteration in radiation response, and inherent cytotoxicity of the metal chelators mimosine, desferrioxamine (DFO), N,N'-bis(o-hydroxybenzyl)-ethylenediamine-N,N'-diacetic acid (HBED), and deferiprone (L1) were studied in exponentially growing Chinese hamster V79 cells. Incubation of cells with 200-1000 microM mimosine for 12 h reduced clonogenic survival to 50-60%, while incubation for 24 h reduced survival further to 0.5%. Mimosine treatment resulted in cell cycle blocks at the G(1)/S-phase border and in S phase. Pulse labeling with 5-bromodeoxyuridine indicated that the S-phase cells ceased to actively replicate DNA after only 2 h of mimosine treatment and were unable to replicate DNA for extended periods. Treatment of V79 cells with 600 microM mimosine for 12 h resulted in radiosensitization, yielding a sensitizer enhancement ratio (SER) of 2.7 +/- 0.3 at the 10% survival level. To study the kinetics of the sensitization, V79 cells were incubated with mimosine for various times up to 12 h and irradiated with a single 10-Gy dose of X rays. It was found that the radiosensitization increased continually up to 8 h (from a 3- to a 100-fold difference in survival) and then reached a plateau after 8 h. Mimosine also equally radiosensitized human lung cancer cells having either a normal or mutated TP53 gene, suggesting a TP53-independent mechanism. To test whether iron binding by mimosine was responsible for the observed radiosensitization, additional experiments were performed using the iron chelators DFO, HBED and L1. V79 cells treated with 500 microM of these agents for 8 h followed by various doses of X rays gave SERs similar to that for mimosine (2.0-2.7). These studies indicate that metal chelators are potent radiosensitizers in V79 and human cells. Importantly, when the DFO was preloaded together with Fe(3+) [Fe(III)-DFO], the radiosensitizing effect was lost. These preliminary findings warrant further studies for the possible application of metal chelators as radiation sensitizers in radiation oncology.     

TP53 and TP53-related genes associated with protection from apoptosis in the radioadaptive response

We investigated the effect of administering priming low-dose radiation prior to high-dose radiation on the level of apoptosis and on the expression of TP53 and TP53-related genes in mouse splenocytes. The percentage of apoptotic cells was significantly lower in TP53(+/+) mice receiving priming radiation 2 to 168 h before the high-dose irradiation, compared to TP53(+/+) mice exposed to 2 Gy alone. In contrast, TP53(+/-) mice exhibited a reduced level of apoptosis only when priming was performed for 2 or 4 h prior to the high-dose irradiation. In TP53(+/+) mice, primed mice had higher TP53 expression than mice exposed to 2 Gy. Phospho-TP53 (ser15/18) expression was the highest in mice exposed to 2 Gy and intermediate in primed mice. Expression of p21 (CDKN1A) was higher in primed mice compared with mice exposed to 2 Gy. MDM2 expression remained at a high level in all mice receiving 2 Gy. Elevated phospho-ATM expression was observed only in mice exposed to 2 Gy. We conclude that TP53 plays a critical role in the radioadaptive response and that TP53 and TP53-related genes might protect cells from apoptosis through activation of the intracellular repair system.     

Wild-type TP53 inhibits G(2)-phase checkpoint abrogation and radiosensitization induced by PD0166285, a WEE1 kinase inhibitor

The WEE1 protein kinase carries out the inhibitory phosphorylation of CDC2 on tyrosine 15 (Tyr15), which is required for activation of the G(2)-phase checkpoint in response to DNA damage. PD0166285 is a newly identified WEE1 inhibitor and is a potential selective G(2)-phase checkpoint abrogator. To determine the role of TP53 in PD0166285-induced G(2)-phase checkpoint abrogation, human H1299 lung carcinoma cells expressing a temperature-sensitive TP53 were used. Upon exposure to gamma radiation, cells cultured under nonpermissive conditions (TP53 mutant conformation) underwent G(2)-phase arrest. However, under permissive conditions (TP53 wild-type conformation), PD0166285 greatly inhibited the accumulation of cells in G(2) phase. This abrogation was accompanied by a nearly complete blockage of Tyr15 phosphorylation of CDC2, an increased activity of CDC2 kinase, and an enhanced sensitivity to radiation. However, under permissive conditions (TP53 wild-type conformation), PD0166285 neither disrupted the G(2)-phase arrest nor increased cell death. The compound inhibited Tyr15 phosphorylation only partially and did not activate CDC2 kinase activity. To understand the potential mechanism(s) by which TP53 inhibits PD0166285-induced G(2)-phase checkpoint abrogation, two TP53 target proteins, 14-3-3rho and CDKN1A (also known as p21), that are known to be involved in G(2)-phase checkpoint control in other cell models were examined. It was found that 14-3-3rho was not expressed in H1299 cells, and that although CDKN1A did associate with CDC2 to form a complex, the level of CDKN1A associated with CDC2 was not increased in response to radiation or to PD0166285. The level of cyclin B1, required for CDC2 activity, was decreased in the presence of functional TP53. Thus inhibition of PD0166285-induced G(2)-phase checkpoint abrogation by TP53 was achieved at least in part through partial blockage of CDC2 dephosphorylation of Tyr15 and inhibition of cyclin B1 expression.     

Expression of securin promotes colorectal cancer cell death via a p53-independent pathway after radiation

Securin has been shown to regulate genomic stability; nevertheless, the role of securin on the cytotoxicity after radiation is still unclear. Exposure to 1–10 Gy X-ray radiation induced cell death in RKO colorectal cancer cells. The protein levels of securin, p53, and p21 were elevated by radiation. The proteins of phosphorylation of p53 at serine-15, which located on the nuclei of cancer cells, were highly induced by radiation. However, radiation increased securin proteins, which located on both of nuclei and cytoplasma in RKO cells. The p53-wild type colorectal cancer cells were more susceptible on cytotoxicity than the p53-mutant cells following exposure to radiation. Besides, the existence of securin in colorectal cancer cells induced higher apoptosis than the securin-null after radiation. Securin proteins were elevated by radiation in the p53-wild type and -mutant cells; furthermore, radiation raised the p53 protein expression in both the securin-wild type and -null cells. As a whole, these findings suggest that the existence of securin promotes apoptosis via a p53-indpendent pathway after radiation in human colorectal cancer cells.     

Repair of potentially lethal damage does not depend on functional TP53 in human glioblastoma cells

The functionality of G(1)-phase arrest was investigated in relation to repair of potentially lethal damage (PLD) in human glioblastoma Gli-06 cells. Confluent cultures were irradiated and plated for clonogenic survival either immediately or 24 h after gamma irradiation. Bivariate flow cytometry was performed to assess the distribution over the cell cycle. Levels of TP53 and CDKN1A protein were assessed with Western blotting and levels of CDKN1A mRNA with RT-PCR. Confluence significantly reduced the number of proliferating cells. Marked PLD repair was found in the absence of an intact G(1) arrest. No accumulation of TP53 was observed, and the protein was smaller than the wild-type TP53 of RKO cells. No increased expression of CDKN1A at the mRNA or protein levels was found in Gli-06 cells. The TP53 of Gli-06 cells was unable to transactivate the CDKN1A gene. From this study, it is evident that PLD repair may be present without a functional TP53 or G(1) arrest.     

Induction of accelerated senescence by gamma radiation in human solid tumor-derived cell lines expressing wild-type TP53

Recent studies have demonstrated that p21WAF1 (now known as CDKN1A)-dependent and -independent accelerated senescence responses are a major determinant of the sensitivity of cancer cells to chemotherapeutic agents. The objective of the present study was to determine whether human solid tumor-derived cell lines that express wild-type TP53 can exhibit levels of CDKN1A induction after exposure to ionizing radiation that are sufficient to activate the accelerated senescence program. Exposure to 60Co gamma radiation (< or =8 Gy) triggered accelerated senescence in all five TP53 wild-type tumor cell lines examined, albeit to differing degrees. Three of the TP53 wild-type tumor cell lines, HCT116, A172 and SKNSH, activated the TP53 signaling pathway similarly to normal human fibroblasts, as judged by the nuclear accumulation of TP53, magnitude and duration of induction of CDKN1A mRNA and CDKN1A protein, and propensity to undergo accelerated senescence after radiation exposure. In the clonogenic survival assay, the degree of radiosensitivity of these three tumor cell lines was also in the range displayed by normal human fibroblasts. On the other hand, two other TP53 wild-type tumor cell lines, A498 and A375, did not maintain high levels of CDKN1A mRNA and CDKN1A protein at late times postirradiation and exhibited only low levels of accelerated senescence after radiation exposure. Studies with a CDKN1A knockout cell line (HCT116CDKN1A-/-) confirmed that the radiation-triggered accelerated senescence is dependent on CDKN1A function. We conclude that (1) clinically achievable doses of ionizing radiation can trigger CDKN1A-dependent accelerated senescence in some human tumor cell lines that express wild-type TP53; and (2) as previously documented for normal human fibroblasts, some TP53 wild-type tumor cell lines (e.g. HCT116, A172 and SKNSH) may lose their clonogenic potential in response to radiation-inflicted injury primarily through undergoing accelerated senescence.     

Restoration of mutant TP53 to normal TP53 function by glycerol as a chemical chaperone

We have previously reported that heat stress induces expression of wild-type TP53 (formerly known as p53) activated factor 1 (CDKN1A, formerly known as WAF1) only when TP53 protein is wild-type using cells of a human glioblastoma cell line (A-172) and cells of its transformant (A-172/mp53/ 143) with a mutant TP53 (point mutation at codon 143 from Val to Ala) vector. Transfection of A-172 cells with the mutant TP53 vector abolished the heat-induced expression of CDKN1A, demonstrating the dominant negative nature of this TP53 mutant over the endogenous wild-type TP53. This kind of dominant negative TP53 mutant occurs frequently in various types of cancer. Overcoming this dominance or restoring the normal functions to these TP53 mutants is a new strategy for TP53-targeted cancer therapies. We examined whether glycerol can act as a chemical chaperone to correct the mutant TP53 conformation. No CDKN1A expression was induced after heating or treatment with glycerol at concentrations of 0.6 and 1.2 M in these transformants. In contrast, A-172/mp53/ 143 cells showed CDKN1A expression when they were heated in the presence of glycerol at 0.6 or 1.2 M, which was similar to the response of the parental and neo vector-transfected control cells. To test the generality of the effects of glycerol on mutant TP53, we used human osteosarcoma Saos-2 cells (lacking TP53) transfected with mutant TP53 and cells of two other human glioblastoma cell lines carrying mutant TP53. These cells showed similar CDKN1A expression when heated in the presence of glycerol at 0.6 or 1.2 M. These results suggest that glycerol is effective in restoring several TP53 mutants to normal TP53 function, leading to normal CDKN1A expression after heat stress. This observation provides a novel tool for correction of mutant TP53 conformation and may be applicable for TP53-targeted cancer therapy.