Cisplatin associated with LY294002 increases cytotoxicity and induces changes in transcript profiles of glioblastoma cells.

Glioblastoma, one of the deadliest forms of brain tumor, responds poorly to available therapies. This highlights the intense search for new treatment approaches, and an emerging strategy is based on molecular targets. In the present work, we aimed to study whether glioblastoma cells can be sensitized by cisplatin combined with LY294002 (LY), which is an inhibitor of PI3K-related family (ATM, ATR, DNA-PK). We observed that cisplatin caused a pronounced reduction in cell proliferation in U343 and U87 cells, and LY significantly increased the cytotoxic effects caused by cisplatin under these conditions. Differently of U343, U87 cells did not show a significant induction of apoptosis. The phosphorylation level of damage response proteins was analyzed after drug-treatment either with/without LY. The presence of γH2AX foci and phosphorylation of TP53(ser15) and CHK1(ser317) were shown in U343 cells, compatible with cisplatin-induced DNA damage. Similarly, the level of ATR phosphorylation (ser428) was also increased (24 h). The transcript expression profiles of drug-treated compared with untreated U343 cells showed significant changes in the expression of 108 genes, while 274 genes were modulated by cisplatin+LY. The combined treatment caused a high proportion of down-regulated genes, which were mainly involved with DNA repair, cell death and cell cycle control/proliferation, metabolism, transcription regulation and cellular adhesion. Altogether, the present results indicate that most probably, PI3K-related kinases may play an important role in the resistance of glioblastomas cells to cisplatin, and the combination with LY can, at least in part, sensitize these cells to drug treatment.

Ionizing radiation-induced gene expression changes in TP53 proficient and deficient glioblastoma cell lines.

The genetic heterogeneity presented by different cell lines derived from glioblastoma (GBM) seems to influence their responses to antitumoral agents. Although GBM tumors present several genomic alterations, it has been assumed that TP53, frequently mutated in GBM, may to some extent be responsible for differences in cellular responses to antitumor agents, but this is not clear yet. To directly determine the impact of TP53 on GBM response to ionizing radiation, we compared the transcription profiles of four GBM cell lines (two with wild-type (WT) TP53 and two with mutant (MT) TP53) after 8Gy of gamma-rays. Transcript profiles of cells analyzed 30 min and 6h after irradiation showed that WT TP53 cells presented a higher number of modulated genes than MT TP53 cells. Our findings also indicate that there are several pathways (apoptosis, DNA repair/stress response, cytoskeleton organization and macromolecule metabolic process) in radiation responses of GBM cell lines that were modulated only in WT TP53 cells (30 min and 6h). Interestingly, the majority of differentially expressed genes did not present the TP53 binding site, suggesting secondary effects of TP53 on transcription. We conclude that radiation-induced changes in transcription profiles of irradiated GBM cell lines mainly depend on the functional status of TP53.