Alterations of cellular redox state during NNK-induced malignant transformation and resistance to radiation

Cancer cells often exhibit increased reactive oxygen species generation and altered redox regulation. The current study was conducted to investigate the biochemical and molecular events associated with redox alterations during chemical-induced malignant transformation and to evaluate their potential roles in radiation sensitivity. Immortalized nonmalignant human bronchial epithelial cells were exposed to the tobacco carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), and a clone of cells exhibiting malignant behaviors was isolated and characterized. This clone initially exhibited an increase in cellular superoxide that eventually decreased after a long-term culture in vitro, associated with altered expression of antioxidant molecules, including an increase in thioredoxin-1 and manganese superoxide dismutase, and a decrease in glutathione peroxidase-1. These cells also showed a significant decrease in sensitivity to ionizing radiation, as demonstrated by less cell death in acute apoptosis analyses and long-term cell proliferation assays. Using biochemical redox modulation and siRNA approach, we showed that the increase in thioredoxin-1 played a significant role in conferring resistance to IR. Although there was a substantial increase in cellular glutathione, inhibition of glutathione synthesis did not increase IR sensitivity. Our study showed complex redox alterations during NNK-induced malignant transformation, and identified Trx-1 as a radiosensitivity modulator.     

Effective elimination of fludarabine-resistant CLL cells by PEITC through a redox-mediated mechanism

Chronic lymphocytic leukemia (CLL) is the most common adult leukemia, and resistance to fludarabine-based therapies is a major challenge in CLL treatment. Because CLL cells are known to have elevated levels of reactive oxygen species (ROS), we aimed to test a novel ROS-mediated strategy to eliminate fludarabine-resistant CLL cells based on this redox alteration. Using primary CLL cells and normal lymphocytes from patients (n = 58) and healthy subjects (n = 12), we showed that both fludarabine-resistant and -sensitive CLL cells were highly sensitive to beta-phenylethyl isothiocyanate (PEITC) with mean IC(50) values of 5.4 microM and 5.1 microM, respectively. Normal lymphocytes were significantly less sensitive to PEITC (IC(50) = 27 microM, P < .001). CLL cells exhibited intrinsically higher ROS level and lower cellular glutathione, which were shown to be the critical determinants of CLL sensitivity to PEITC. Exposure of CLL cells to PEITC induced severe glutathione depletion, ROS accumulation, and oxidation of mitochondrial cardiolipin leading to massive cell death. Such ROS stress also caused deglutathionylation of MCL1, followed by a rapid degradation of this cell survival molecule. Our study demonstrated that the natural compound PEITC is effective in eliminating fludarabine-resistant CLL cells through a redox-mediated mechanism with low toxicity to normal lymphocytes, and warrants further clinical evaluation.     

Selective killing of oncogenically transformed cells through a ROS-mediated mechanism by beta-phenylethyl isothiocyanate

Reactive oxygen species (ROS) stimulate cell proliferation and induce genetic instability, and their increase in cancer cells is often viewed as an adverse event. Here, we show that such abnormal increases in ROS can be exploited to selectively kill cancer cells using beta-phenylethyl isothiocyanate (PEITC). Oncogenic transformation of ovarian epithelial cells with H-Ras(V12) or expression of Bcr-Abl in hematopoietic cells causes elevated ROS generation and renders the malignant cells highly sensitive to PEITC, which effectively disables the glutathione antioxidant system and causes severe ROS accumulation preferentially in the transformed cells due to their active ROS output. Excessive ROS causes oxidative mitochondrial damage, inactivation of redox-sensitive molecules, and massive cell death. In vivo, PEITC exhibits therapeutic activity and prolongs animal survival.     

Partial Substitution of Glucose with Xylitol Suppressed the Glycolysis and Selectively Inhibited the Proliferation of Oral Cancer Cells

Suitable diet for cancer survivors remains an unresolved challenge. Increased glucose utilization is a hallmark of various cancers. Therefore, alternative carbohydrate supplying normal tissue but retarding cancer growth is needed. This study investigated the effect of sugar alcohols on the proliferation of oral cancer cells compared to nontransformed cells and explored the mechanism. Six oral squamous cell carcinoma (CAL-27, FaDu, SCC4, SCC9, SCC15, and SCC25) and one nontransformed oral keratinocyte (OKF6/TERT2) lines were cultured in media containing 1 mg/ml glucose and 5.8 mg/ml xylitol or sorbitol, yielding equal energy input to control group (4.5 mg/ml glucose). Partial substitution of glucose with sugar alcohols especially xylitol significantly suppressed proliferation of oral cancer but not nontransformed cells. Despite the addition of isocaloric quantities of the sugars, cancer cells exposed to low glucose plus xylitol had retarded ATP generation and decreased activity of phosphofructokinase (PFK), the rate-limiting enzyme in glycolysis. Furthermore, D-xylulose, its key metabolic intermediate, enhanced the anticancer effect of xylitol. These findings suggested a selective anticancer activity of xylitol and the potential mechanism involving inhibition of glucose utilization. Partial substitution of glucose with xylitol may be a proper nutrient for oral cancer survivors, deserving further investigation in animal and clinical settings.