Ellagic Acid, a Dietary Polyphenol, Selectively Cytotoxic to HSC-2 Oral Carcinoma Cells.

BACKGROUND: The antiproliferative and apoptotic effects of ellagic acid, a dietary polyphenol, were studied. MATERIALS AND METHODS: The neutral red cytotoxicity assay compared the sensitivities of gingival fibroblasts and HSC-2 oral carcinoma cells to ellagic acid. The ferrous ion oxidation xylenol orange assay and levels of intracellular reduced glutathione were used to assess pro-oxidant nature of ellagic acid. Antioxidant activity was demonstrated in cells co-treated with H2O2 and ellagic acid by 2',7'-dichlorodihydrofluorescein diacetate staining and in cells co-treated with gallic acid and ellagic acid by morphological analysis. Apoptosis was assessed by microscopy, flow cytometry, luminescence, and immunoblotting. RESULTS: Ellagic acid was cytotoxic to carcinoma cells, but not to normal cells. Its pro-oxidant nature was minimal, whereas its antioxidant property was biologically significant. Ellagic acid-treated cells demonstrated apoptotic morphology, induction of apoptosis (flow cytometry), increase in caspase 3/7 activities (luminescence), and activation of caspase 3 and cleavage of poly ADP ribose polymerase (immunoblot). CONCLUSION: Ellagic acid exhibited significant antioxidant, but not pro-oxidant, activity and was selectively cytotoxic to oral carcinoma cells.

Research strategies in the study of the pro-oxidant nature of polyphenol nutraceuticals.

Polyphenols of phytochemicals are thought to exhibit chemopreventive effects against cancer. These plant-derived antioxidant polyphenols have a dual nature, also acting as pro-oxidants, generating reactive oxygen species (ROS), and causing oxidative stress. When studying the overall cytotoxicity of polyphenols, research strategies need to distinguish the cytotoxic component derived from the polyphenol per se from that derived from the generated ROS. Such strategies include (a) identifying hallmarks of oxidative damage, such as depletion of intracellular glutathione and lipid peroxidation, (b) classical manipulations, such as polyphenol exposures in the absence and presence of antioxidant enzymes (i.e., catalase and superoxide dismutase) and of antioxidants (e.g., glutathione and N-acetylcysteine) and cotreatments with glutathione depleters, and (c) more recent manipulations, such as divalent cobalt and pyruvate to scavenge ROS. Attention also must be directed to the influence of iron and copper ions and to the level of polyphenols, which mediate oxidative stress.

Pomegranate extract, a prooxidant with antiproliferative and proapoptotic activities preferentially towards carcinoma cells.

The antiproliferative and proapoptotic effects of pomegranate extract (PE), as correlated with its prooxidant activity, were studied. PE exerted greater antiproliferative effects towards cancer, than to normal, cells, isolated from the human oral cavity. In cell-free systems, PE generated hydrogen peroxide (H(2)O(2)) in cell culture media and in phosphate buffered saline, with prooxidant activity increasing from acidic to alkaline pH, and oxidized glutathione (GSH) in an alkaline, phosphate buffer. Detection of PE-generated H(2)O(2) was greatly lessened in medium amended with N-acetyl-L-cysteine. Using HSC-2 carcinoma cells as the bioindicator, the cytotoxicity of PE was potentiated towards cells pretreated with the GSH depleter, 1-chloro-2,4-dinitrobenzene, and attenuated in cells co-treated with the H(2)O(2) scavengers, catalase, pyruvate, and divalent cobalt ion. Intracellular GSH was lessened in cells treated with PE; GSH depletion in PE-treated cells was confirmed visually with the fluorescent dye, Cell Tracker™ Green 5-chloromethylfluorescein diacetate. These studies demonstrated that the antiproliferative mechanism of PE was, in part, by induction of oxidative stress. The mode of cell death was by apoptosis, as shown by flow cytometry, activation of caspase-3, and cleavage of PARP. Lessening of caspase-3 activation and of PARP cleavage in cells co-treated with PE and either cobalt or pyruvate, respectively, as compared to PE alone, indicated that apoptosis was through the prooxidant nature of PE.

Gingko biloba leaf extract induces oxidative stress in carcinoma HSC-2 cells.

The antiproliferative effects of a Gingko biloba leaf extract to cells from tissues of the human oral cavity were studied. Toxicity to carcinoma HSC-2 cells was correlated with the prooxidative nature of the extract. G. biloba leaf extract generated reactive oxygen species (ROS) in cell culture medium and, albeit to a lesser extent, in buffer, with higher levels detected at alkaline pH. Lowered levels of ROS were detected in culture medium coamended with the extract and with either catalase or superoxide dismutase, indicating the generation of hydrogen peroxide and superoxide anion, respectively. Biological activity of the extract was through oxidative stress. Toxicity to the HSC-2 cells was lessened by the ROS scavengers, divalent cobalt and pyruvate, by catalase, and by the antioxidant, N-acetyl-L-cysteine, and was potentiated by the glutathione depleters, DL-buthionine-[S,R]-sulfoximine, 1-chloro-2,4-dinitrobenzene, and bis(2-chloroethyl)-N-nitrosourea. G. biloba reacted directly with authentic glutathione and lowered the intracellular glutathione content in HSC-2 cells. Induction of apoptosis upon exposure of HSC-2 cells to G. biloba extract was noted by apoptotic cell morphologies, by TUNEL staining, and by PARP cleavage. The data strongly suggest that the prooxidative nature of the G. biloba extract was the cause of apoptotic cell death.

Theaflavin-3,3'-digallate, a component of black tea: an inducer of oxidative stress and apoptosis.

Treatment of human oral squamous carcinoma HSC-2 cells and normal GN46 fibroblasts with theaflavin-3,3'-digallate (TF-3), a polyphenol in black tea, showed a concentration and time dependent inhibition of growth, with the tumor cells more sensitive than the fibroblasts. In buffer and in cell culture medium, TF-3 generated reactive oxygen species, with lower levels detected in buffer amended with catalase and superoxide dismutase, indicating the generation of hydrogen peroxide and superoxide, respectively, and suggesting that TF-3 may be an inducer of oxidative stress. The toxicity of TF-3 was decreased in the presence of catalase, pyruvate, and divalent cobalt, all scavengers of reactive oxygen species, but was potentiated in the presence of diethyldithiocarbamate, an inhibitor of superoxide dismutase. The intracellular level of glutathione in HSC-2 cells was lessened after a 4-h exposure to 250 and 500 microM TF-3. However, for GN46 fibroblasts, a 4-h exposure to 250 microM TF-3 stimulated, but to 500 microM TF-3 lessened, intracellular glutathione. Treatment of the cells with the glutathione depleters, 1,3-bis(2-chloroethyl)-N-nitrosourea, 1-chloro-2,4-dinitrobenzene, and d,l-buthionine-[S,R]-sulfoximine potentiated the toxicity of TF-3. Induction of apoptotic cell death in HSC-2 cells treated with TF-3 was noted by apoptotic cell morphologies, by TUNEL staining, by PARP cleavage, and by elevated activity of caspase-3. Apoptosis was not noted in GN46 fibroblasts treated with TF-3.