Background/Aim: Oxysterol plays important physiological roles in diverse biological processes including apoptosis. However, the mechanisms underlying oxysterolinduced apoptosis remain unknown. is an oxysterol synthesized by cholesterol 25hydroxylase from cholesterol during sterol metabolism. The aim of present study was to investigate 25-HC-induced apoptosis and associated signalling pathways in FaDu cells, which is originated form human head and neck squamous cell carcinoma cells. Materials and Methods: 25-HC-induced apoptosis was investigated by cell cytotoxicity assay using MTT, cell viability assay using cell LIVE/DEAD cell viability assay, haematoxylin & eosin staining, nuclear staining, fluorescence-activated cell sorting, western blotting using specific antibodies associated with extrinsic and intrinsic apoptosis pathways, and caspase-3/-7 activity assay in FaDu cells. Results: 25-HC dose-dependently decreased the viability of FaDu cells and up-regulated apoptotic events, such as alteration in morphology, and nuclear condensation.
Flow cytometric analysis showed an increase in apoptotic population upon 25-HC treatment, suggesting that 25-HC induces apoptosis in FaDu cells. Moreover, 25-HC-induced apoptosis in FaDu cells was dependent on the activation of caspases by Fas antigen ligand-triggered death receptor-mediated extrinsic pathway and mitochondria-dependent intrinsic pathway via mitogen activated protein kinases. Conclusion: Cholesterol-derived oxysterol, 25-HC has potential anti-cancer function in FaDu cells and may have potential properties for the discovery of anti-cancer agents.Cholesterol, a type of lipid sterol is biosynthesized by all animal cells and is a crucial structural component that modulates the fluidity of cell membranes. Additionally, it is an essential precursor of steroid hormones and bile acid which maintain physiological homeostasis (1). Oxysterols are 27-carbon derivatives are derived from cholesterol via endogenous auto-oxidation or enzymatic processes (2). Oxidation promotes the addition of hydroxyl, keto, hyperoxy, carbonyl, or epoxy group at C4-7 or C24, C25, and C27 positions in the cholesterol backbone (3). The derivatives synthesized from oxidation of cholesterol are crucial physiological factors that are associated with the maintenance of diverse biological processes such as cholesterol homeostasis, lipid metabolism, protein prenylation, cell proliferation, and cell differentiation (4). A recent study on the physiological role of oxysterol reported that short-term exposure of cholesterol derivatives such as 7ketocholesterol, cholestane-3β-5α-6β-triol, and 5αcholestane-3β,6β-diol selectively triggers apoptosis in tumour cell lines (5). Furthermore, these cholesterol derivatives have showed varying effects depending on the cell type and oxysterol concentration (5). Thus, many recent studies have suggested the potential pharmacological efficacy of cytotoxic oxysterols in chemotherapy using oxysterol synthesized by auto-oxidation of cholesterol (6).
