Modulation of radiation-induced cytotoxicity in U 87 cells by RH-3 (a preparation of Hippophae rhamnoides).

Background & objectives: Hippophae rhamnoides L. has been widely exploited for medicinal purposes and an extract of its whole berries coded as RH-3 has been found to render radioprotection. Effect of pre-irradiation treatment of up to 10 μg/ml RH-3 was studied in U 87 cells using MTT assay. This study aims at unraveling the mechanism of action of RH-3 in amelioration of radiation-induced cytotoxicity in vitro. Methods: Most effective doses selected were studied further for the elucidation of radiomodifying properties of RH-3, especially with respect to early and late events of apoptosis. Results: RH-3 at concentrations of 7.5 and 10 μg/ml (-15 min) were found most effective in protecting against 2 Gy induced cytotoxicity in terms of MTT reducing ability in U 87 cells. RH-3 was observed to mitigate radiation-induced cellular and mitochondrial free radicals. Mitochondrial membrane potential depletion (studied up to 12 h) was prevented by RH-3 pre-irradiation administration. It could also restore the level of antiapoptotic protein Bcl-2 at 24 and 48 h comparable to the control value. RH-3 also prevented radiation-induced increase in mitochondrial mass at 48 and 72 h post-treatment and the values were comparable to that of control cells. Annexin-V-FITC assay at 12 and 24 h time intervals indicated significant protection against radiation-induced apoptosis by RH-3 pre-irradiation treatment. Interpretation & conclusion: Our findings showed that probably RH-3 acts as an antioxidant preventing cellular and mitochondrial free radical generation that could contribute to its ability to inhibit radiationinduced apoptosis and cytotoxicity.

Glycolytic inhibitor, 2-deoxy-D-glucose, does not enhance radiation-induced apoptosis in mouse thymocytes and splenocytes in vitro.

Earlier studies have shown that 2-deoxy-D-glucose (2-DG), a glucose analogue and inhibitor of glycolytic ATP production selectively enhances radiation-induced damage in cancer cells by inhibiting the energy (ATP) dependent postirradiation DNA and cellular repair processes. A reduction in radiation induced cytogenetic damage has been reported in normal cells viz., peripheral blood lymphocytes and bone marrow cells. Since induction of apoptosis plays a major role in determining the radiosensitivity of some most sensitive normal cells including splenocytes and thymocytes, we investigated the effects of 2-DG on radiation induced apo tosis in these cells in vitro. Thymocytes and splenocytes isolated from normal Swiss albino mouse were irradiated with Co60 gamma-rays and analyzed for apoptosis at various post-irradiation times. 2-DG added at the time of irradiation was present till the termination of cultures. A time dependent, spontaneous apoptosis was evident in both the cell systems, with nearly 40% of the cells undergoing apoptosis at 12 hr of incubation. The dose response of radiation-induced apoptosis was essentially similar in both the cell systems and was dependent on the incubation time. More than 70% of the splenocytes and 60% of the thymocytes were apoptotic by 12 hr following an absorbed dose of 2 Gy. Presence of 2-DG marginally reduced the fraction of splenocytes undergoing apoptosis at all absorbed doses, while no change was observed in thymocytes. Presence of 2-DG did not significantly alter either the level or the rate of induction of spontaneous apoptosis in both these cell systems. These results are consistent with the earlier findings on radiation-induced cytogenetic damage in human PBL in vitro and mouse bone marrow cells and lend further support to the proposition that 2-DG does not enhance radiation damage in normal cells, while radiosensitizing the tumors and hence is an ideal adjuvant in the radiotherapy of tumors.

Heterogeneity in the radiosensitizing effects of the DNA ligand hoechst-33342 in human tumor cell lines.

The AT specific minor grove DNA binding ligands bisbenzimidazole derivatives like hoechst-33342 and hoechst-33258 which scavenge free radicals and stabilize macromolecular structure have been shown to afford radioprotection by reducing the induction of DNA damage. However, their ability to inhibit topoisomerases I & II, which play important roles in damage response pathways including DNA repair can enhance radiation damage under certain conditions. Since pool sizes of the topoisomerases differ not only between normal and tumor cells, but also among different tumors, it is anticipated that radiosensitization by hoechst-33342 can vary among tumors. The present studies were, therefore, undertaken to verify this proposition in human glioma (BMG-1 &U-87) and squamous carcinoma (4197 &4451) cell lines which differ in their biological behavior (ploidy, p53, cyclins, bcl, bax etc). Isotoxic concentrations of hoechst-33342 (IC50 i.e producing 50% cell kill) administered immediately following irradiation resulted in the radiosensitization of all cell lines, with a 4&7 fold increase in the cell death (loss of clonogenic cell survival) in U-87&BMG-1 and a 3 fold increase in 4197 &4451 cells. Growth inhibition and increase in cytogenetic damage (micronuclei formation) as well as delayed apoptosis observed under these conditions corroborated well with the enhanced cell death. The ligand induced a significant cell cycle delay, particularly in the late S and G2 phases of BMG-1, U-87 and 4197 cells, while no significant changes could be observed in 4451 cells. Higher endogenous levels of cyclin B1 found in both the glioma cell lines, was enhanced further by the ligand as compared to the squamous carcinoma cells. These results clearly demonstrate that the radiosensitizing effects of the ligand are indeed heterogeneous among different human tumor cell lines. The radiaosensitization is p53 independent and accompanied by enhanced mitotic death (linked to cytogenetic damage) as well as induction of cyclin B1 mediated apoptosis.

Alterations in radiation induced cell cycle perturbations by 2-deoxy-D-glucose in human tumor cell lines.

In the present studies, effects of glucose analogue, 2-deoxy-D-glucose (2-DG) on radiation-induced cell cycle perturbations were investigated in human tumor cell lines. In unirradiated cells, the levels of cyclin B1 in G2 phase were significantly higher in both the glioma cell lines as compared to squamous carcinoma cells. Upon irradiation with Co60 gamma-rays (2 Gy), the cyclin B1 levels were reduced in U87 cells, while no significant changes could be observed in other cell lines, which correlated well with the transient G2 delay observed under these conditions by the BrdU pulse chase measurements. 2-DG (5 mM, 2 hr) induced accumulation of cells in the G2 phase and a time-dependent increase in the levels of cyclin B1 in both the glioma cell lines, while significant changes could not be observed in any of the squamous carcinoma cell lines. 2-DG enhanced the cyclin B1 level further in all the cell lines following irradiation, albeit to different extents. Interestingly, an increase in the unscheduled expression of B1 levels in G1 phase 48 hr after irradiation was observed in all the cell lines investigated. 2-DG also increased the levels of cyclin D1 at 24 hr in BMG-1 cell line. These observations imply that 2-DG-induced alterations in the cell cycle progression are partly responsible for its radiomodifying effects.

Contribution of oxidative stress to radiosensitization by a combination of 2-DG and 6-AN in human cancer cell line.

In the present studies, the role of oxidative stress in radiosensitization by a combination of 2-DG and 6-aminonicotinamide (6-AN) was examined in a human glioma cell line (BMG-1: wild type p53). Presence of 2-DG or 6-AN for 4 hr after irradiation (gamma ray 2.5 Gy) significantly enhanced the radiation-induced cell death by 18% and the combination (2-DG + 6-AN) enhanced the cell death by 35%. Neither 2-DG nor 6-AN had any further significant effect on the glutathione levels in irradiated cells. However, the combination (2-DG + 6-AN) caused a significant decrease in GSH content, increase in GSSG levels, and enhanced the superoxide radical generation under these conditions. The enhanced cell death caused by the combination (2-DG + 6-AN) mainly resulted by the process of apoptosis as revealed by annexin V binding and was associated with elevated levels of Cyclin B1. However, no significant change was observed in the levels of Bcl-2. Thus, for the first time, our results have demonstrated that the radiosensitizing effects of these modifiers could also be mediated through alterations in the oxidative stress besides energy limited inhibition of repair and recovery processes.

Radioprotective effects of DNA ligands Hoechst-33342 and 33258 in whole body irradiated mice.

Radioprotective effects of bisbenzimidole derived DNA ligands Hoechst-33342 (H-342) and Hoechst-33258 (H-258) have been investigated in whole body irradiated stain-A and Balb/c mice (Co-60 Gamma-ray, absorbed doses of 2.5 to 10 Gy delivered at dose rates of 0.01 to 0.50 Gy/min). Biodistribution of Hoechst dyes (2 or 5 mg/kg, body wt., i.v.) and their effects on cell cycle kinetics in bone marrow were studied by flow cytometry. Protection against radiation-induced chromosomal aberrations, micronuclei formation, alterations in DNA content dispersion, inhibition of erythropoiesis and animal lethality were investigated. Significant amount of DNA bound Hoechst could be observed in liver, intestine, kidney and brain for more than 14 days after its administration, while in the bone marrow cells, a reduction in the bound Hoechst was noticed after 7 days. H-342 significantly reduced the radiation-induced chromosome aberrations mainly due to a decrease in the frequency of acentrics (nearly 30%), while a marginal decrease (10%) in the dicentrics was observed at all the dose rates studied. Both H-342 and H-258 reduced the radiation-induced micronuclei formation in a dose dependent manner (2-10 mg/kg body wt.) and this protective effect was observed up to 6 days after the administration. Neither of the two compounds induced any cytogenetic damage in the bone marrow cells of unirradiated animals nor induced tumours at the doses used here (< 5 mg/kg, body wt. i.v.). Reduction in cytogenetic damage of bone marrow cells led to a faster recovery of erythropoesis as observed by increased PCE/NCE ratio in the peripheral blood erythrocytes of the animals which received Hoechst before irradiation. H-258 (5 mg/kg body wt.) given 18 hr before irradiation reduced radiation-induced animal death (5-9 Gy), while no significant effect was observed at higher doses (10 Gy). However, H-342, which has a higher cell permeability, even at a lower dose (2 mg/kg body wt.) showed significant protection at 10 Gy. The protective effects could be enhanced further, by combining these DNA binding agents with the glucose analogue, 2-deoxy-D-glucose (2-DG) which has been shown earlier to protect bone marrow cells against radiation damage.