, 2012a and Sun et al., 2012b). Cav-1 could also be involved
in cancer resistance to the chemotherapeutic drugs anthracyclines. Interestingly, they have been reported to induce an up-regulation of cav-1, which appears to be involved in gastric cancer cell resistance (Yuan et al., 2012). To further underline that the role played by cav-1 in cancer is controversial and highly complex, it has also been reported that SRT1720 order cav-1 sensitizes cisplatin-induced cell apoptosis in lung cancer (Pongjit and Chanvorachote, 2011). Studies considering cav-1 role in cancers are rarely investigating the interrelationship between cav-1 and plasma membrane. However, it may be hypothesized that the complex role of cav-1 in cancer development and progression, or resistance to drug may at least partly, be due to its effects on the plasma membrane. A better knowledge of lipid rafts and raft-dependent signaling pathways would help us to choose strategies for prevention, cure and better management of cancers using possible combinations of natural compounds, synthetic inhibitors, CP-868596 purchase radiation and/or other forms of therapies. Cholesterol metabolism is deregulated in many malignancies, including myeloid leukemia, lung, and breast cancers (Bennis et al., 1993 and Li et al., 2003). For example, 3-hydroxy-3-methylglutaryl coenzyme A reductase, the rate-limiting enzyme in cholesterol
biosynthesis, is up-regulated in several tumors. Moreover, malignant cells have been reported to have elevated levels of mevalonate, a cholesterol precursor, and mevalonate treatment was found to promote tumor growth in vivo and to stimulate the proliferation of breast cancer cells ( Duncan et al., 2005). Cancer cell types with higher membrane cholesterol levels exhibit more rafts/caveolae, and are more sensitive to the apoptosis induced by cholesterol-depleting agents ( Li
et al., 2006). Lipid raft localization of EGFR alters the response of cancer cells to the EGFR tyrosine kinase inhibitor gefitinib ( Irwin et al., 2011). n-3 unsaturated fatty acid (PUFA) consumption decrease the risk of developing several cancer types (breast, prostate, colon) ( Blot et al., 1975, Caygill et al., much 1996, Martin-Moreno et al., 1994, Stoneham et al., 2000 and Trichopoulou et al., 2000). PUFA may also affect the effects of chemotherapeutic agents; thus, epidemiological studies showed that high doses of PUFA increase the risk of chemotherapy failure whereas a moderate absorption of PUFA (170 mg/day of eicosapentaenoic acid and 117 mg/day of docosahexaenoic acid, the two main PUFA) increase patients’ survival. In general, in vitro, PUFA increase the cell sensitivity to chemotherapeutic agents (doxorubicin, epirubicin, paclitaxel, 5-fluorouracil, mitomycin) ( Germain et al., 1998, Plumb et al., 1993 and Timmer-Bosscha et al., 1989).