Reversal of multidrug resistance by verapamil and modulation by alpha 1-acid glycoprotein in wild-type and multidrug-resistant Chinese hamster ovary cell lines.
Chatterjee M., Robson CN., Harris AL.
Multidrug resistance can be reversed by a range of "calcium channel"-blocking drugs in vitro, of which verapamil is the most widely used. Verapamil is bound to alpha 1-acid glycoprotein (AAG) in vivo in humans but is absent from calf serum, used in tissue culture media. The effect of AAG on the ability of verapamil to alter Adriamycin cytotoxicity was assessed in parental Chinese hamster ovary cells (CHO-K1) and in a multidrug-resistant subline (CHO-Adrr). In both the parental and the resistant cells, there was a dose-related potentiation of Adriamycin cytotoxicity by verapamil. At 10 microM verapamil, there was a 5-fold decrease in the concentration of Adriamycin that caused 50% reduction in growth of CHO-K1 cells but a 15-fold decrease in CHO-Adrr cells. In the presence of increasing AAG concentrations within the range found in cancer patients, there was a concentration-related reduction in the effects of verapamil. In CHO-Adrr cells, there was complete reversal of the potentiating effect of 10 microM verapamil at 2 mg/ml AAG. In contrast, in CHO-K1 cells, AAG reduced the effects of verapamil by only 20% at a similar concentration. There was a much higher internal uptake of fluorescein-labeled AAG by CHO-Adrr cells than by CHO-K1 cells. These results suggest that, in addition to a plasma membrane site, there may be a major endosomal site of action of verapamil in multidrug-resistant cells. The implications are that verapamil in vivo in the presence of AAG may effectively reverse low levels of multidrug resistance, but not high levels. Thus selection of patients with low AAG levels may be appropriate for clinical studies.