The transporter protein genes and lipids in human ovarian carcinomaderived KF28 cells with anticancer-drug-sensitive properties were compared with those in resistant cells, taxol-resistant KF28TX, cisplatin-resistant KFr13, and taxol-and cisplatin-resistant KFr13TX, to identify the molecules required for anticancer-drug resistance. In accordance with previous reports, taxol and cisplatin resistance was closely correlated with expression of the multidrug resistance 1 and bile acid export pump, and multidrug resistance-associated protein 2 genes, respectively. In addition, we found a distinct difference in glycosphingolipids between the sensitive and resistant cells. Although GlcCer was the major glycolipid (83.0%) in sensitive cells, GalCer, LacCer and, particularly, Gb 3 Cer were characteristically increased in all resistant cells, irrespective of whether the resistance was to taxol or cisplatin, and comprised 65 -84% of total glycosphingolipids. GM3, which was present at 0.04 µ µ µ µg/mg dry weight in the sensitive cells, showed a twofold increase in the taxol-resistant cells, but was absent in the cisplatin-resistant cells. The altered glycolipid composition was proven to be due to enhanced or suppressed expression of the respective sugar transferase genes. In addition, the ceramide moiety of ceramide monohexoside in the sensitive cells constituted 83% of non-hydroxy fatty acids, but that in the resistant cells comprised 67 -74% of α α α α-hydroxy fatty acids. Thus, cells containing Gb 3 Cer with α α α α-hydroxy fatty acids were found to survive selectively in the presence of taxol and cisplatin, and modification of the glycolipid structure was revealed to occur in association with anticancer-drug resistance. (Cancer Sci 2006; 97: 1321-1326) T he chemosensitivity or chemoresistance of cancer cells toward anticancer drugs is closely related to the rates of entry and extrusion of drugs into and out of cells through transporter molecules, and with the signal transduction cascade leading to apoptosis in response to anticancer drugs.(1) In particular, ABC transporters, such as MDR or MRP transporters, have been revealed to be closely implicated in the chemoresistance of cancer cells. (2,3) The chemoresistance mediated by ABC transporters is mainly due to decreased cellular accumulation of anticancer drugs due to extrusion of the drugs out of the cells, and the correlation between several types of drugs and the expression of various transporter genes has been extensively studied to optimize chemotherapies, as well as to characterize the genetic mechanism underlying the acquisition of resistance during chemotherapy. (4) Chemosensitivity is relevant to the ceramide-mediated apoptosis induced by anticancer drugs. Stimuli, including anticancer drugs and γ-irradiation, have been reported to activate sphingomyelinase to generate ceramide, which triggers apoptosis as a second messenger.(5-8) When sphingolipids in anticancer drug-sensitive and -resistant cancer cells were compared, glucosylceramide was found to increase cha...
