Abstract
The antitumor activities of four novel doxorubicin (DOX) analogues, YM1, YM3, YM4 and YM6 in relation to their structure and drug transport properties, have been investigated in U937 monocytic and CCRF-CEM lymphoid drug sensitive leukemia cell lines, as well as in CEM/VLB100, a drug resistant subline displaying high levels of P-glycoprotein. Treatment of all cell lines with YM1, 3, 4 and 6 produced a dose-dependent decrease in DNA, RNA and protein synthesis as measured by [3H]-thymidine, [3H]-uridine and [3H]-leucine uptake respectively. YM1 was more effective than YM3, YM4 or YM6 against the drug sensitive cells. The antitumor effects of all these DOX-analogues on macromolecule synthesis in U937 and CCRF-CEM cells were lower than that of DOX and epirubicin (EDR). A rapid accumulation of the novel anthracyclines was found in all cell lines compared with DOX or EDR. However, the maximal accumulation of the DOX-analogues was lower than that of EDR. There is a greater efflux from CCRF-CEM sensitive cells and less from CEM/VLB100 resistant cells of the DOX-derivatives when compared with EDR and DOX. Drug-induced cytotoxicity significantly correlated (P < 0.05) with drug retention levels in CCRF-CEM and U937 drug sensitive cells as indicated by an inverse correlation curve between anthracycline retention and drug-induced IC50 value. It was demonstrated that an increased level of drug retained within the sensitive cells would therefore produce a more cytotoxic effect of the drug. However, no such correlation was observed in CEM/VLB100 resistant cells. YM3 was shown to have an increased antitumor activity against CEM/VLB100 resistant cells compared with DOX with a lower resistance factor. These results showed that the antitumor effects of four novel DOX-analogues, like DOX or EDR, were associated with inhibition of DNA replication, transcription and translation. The finding that resistant leukemic cells are more susceptible to the cytotoxic effect of YM3 than DOX warrants further investigation to identify the intrinsic mechanism of resistance.
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