BACKGROUND: Alterations of the p53 (also called TP53) gene are one of the most common abnormalities in gliomas. We have previously reported that restoration of wild-type p53 protein function in glioma cells results in programmed cell death (apoptosis). Since p53 functions are mediated by genes that directly control the tumor suppressor effect of the p53 protein, understanding the relationship between p53 and p53-related genes in glioma cells will aid in the design of more rational treatment strategies for brain tumors. PURPOSE: We conducted this study to examine the timing of the p53-mediated events preceding apoptosis. More specifically, we undertook this work to characterize the genetic and cell cycle-related factors that may increase the resistance of glioma cells to p53-induced apoptosis. METHODS: Two human glioma cell lines (U-251 MG and U-373 MG) that express mutant p53 protein and two (U-87 MG and EFC-2) that express wild-type p53 protein were used. Replication-deficient adenovirus was utilized as an expression vector to transfer exogenous p53 and p21 complementary DNAs into the glioma cells; control cells were infected with the viral expression vector alone. To monitor gene transfer and the expression of exogenous genes (as well as the expression of endogenous genes), we used western blot analyses and immunohistochemistry analyses. Flow cytometry studies of cellular DNA content were performed to determine the cell cycle phenotype of the glioma cells before and after treatment. RESULTS: p53-mediated apoptosis was preceded by elevation in the levels of the p21 (cell cycle-related) and Bax (apoptosis-related) proteins. In addition, cell cycle analyses showed that glioma cells were arrested in the G2 phase before undergoing cell death. Transfer of p21 induced a G2 block but did not induce apoptosis. Moreover, coexpression of p21 and p53 prevented glioma cells from undergoing apoptosis. Expression of exogenous p53 in wild-type p53 cells did not induce elevation of Bax levels, arrest in G2 phase, or apoptosis. CONCLUSIONS AND IMPLICATIONS: Our data confirmed the ability of wild-type p53 to induce apoptosis in p53 mutant glioma cells. In addition, our results document that p21 plays a role in protecting cells from p53-mediated programmed cell death and suggest that p53-mediated apoptosis and p21 induction may represent, at least in certain cases, opposite signals. Finally, our data suggest that over expression of p21 in gliomas may be related to resistance to treatments that induce apoptosis.
BACKGROUND: Alterations of the p53 (also called TP53) gene are one of the most common abnormalities in gliomas. We have previously reported that restoration of wild-type p53 protein function in glioma cells results in programmed cell death (apoptosis). Since p53 functions are mediated by genes that directly control the tumor suppressor effect of the p53 protein, understanding the relationship between p53 and p53-related genes in glioma cells will aid in the design of more rational treatment strategies for brain tumors. PURPOSE: We conducted this study to examine the timing of the p53-mediated events preceding apoptosis. More specifically, we undertook this work to characterize the genetic and cell cycle-related factors that may increase the resistance of glioma cells to p53-induced apoptosis. METHODS: Two humanglioma cell lines (U-251 MG and U-373 MG) that express mutant p53 protein and two (U-87 MG and EFC-2) that express wild-type p53 protein were used. Replication-deficient adenovirus was utilized as an expression vector to transfer exogenous p53 and p21 complementary DNAs into the glioma cells; control cells were infected with the viral expression vector alone. To monitor gene transfer and the expression of exogenous genes (as well as the expression of endogenous genes), we used western blot analyses and immunohistochemistry analyses. Flow cytometry studies of cellular DNA content were performed to determine the cell cycle phenotype of the glioma cells before and after treatment. RESULTS:p53-mediated apoptosis was preceded by elevation in the levels of the p21 (cell cycle-related) and Bax (apoptosis-related) proteins. In addition, cell cycle analyses showed that glioma cells were arrested in the G2 phase before undergoing cell death. Transfer of p21 induced a G2 block but did not induce apoptosis. Moreover, coexpression of p21 and p53 prevented glioma cells from undergoing apoptosis. Expression of exogenous p53 in wild-type p53 cells did not induce elevation of Bax levels, arrest in G2 phase, or apoptosis. CONCLUSIONS AND IMPLICATIONS: Our data confirmed the ability of wild-type p53 to induce apoptosis in p53 mutant glioma cells. In addition, our results document that p21 plays a role in protecting cells from p53-mediated programmed cell death and suggest that p53-mediated apoptosis and p21 induction may represent, at least in certain cases, opposite signals. Finally, our data suggest that over expression of p21 in gliomas may be related to resistance to treatments that induce apoptosis.
Authors: Pedro R Lowenstein; Donata Suwelack; Jinwei Hu; Xianpeng Yuan; Maximiliano Jimenez-Dalmaroni; Shyam Goverdhana; Maria G Castro Journal: Int Rev Neurobiol Date: 2003 Impact factor: 3.230
Authors: Ok-Hee Lee; Juan Fueyo; Jing Xu; W K Alfred Yung; Michael G Lemoine; Frederick F Lang; B Nebiyou Bekele; Xian Zhou; Marta A Alonso; Kenneth D Aldape; Gregory N Fuller; Candelaria Gomez-Manzano Journal: Neoplasia Date: 2006-05 Impact factor: 5.715
Authors: Y J Li; K Hoang-Xuan; X P Zhou; M Sanson; K Mokhtari; T Faillot; P Cornu; M Poisson; G Thomas; R Hamelin Journal: J Neurooncol Date: 1998-11 Impact factor: 4.130
Authors: Toshiyuki Amano; Akira Nakamizo; Sandip K Mishra; Joy Gumin; Naoki Shinojima; Raymond Sawaya; Frederick F Lang Journal: J Neurooncol Date: 2009-04-09 Impact factor: 4.130