Localization of the 1,4-dihydropyridine drug acceptor of P-glycoprotein to a cytoplasmic domain using a permanently charged derivative N-methyl dexniguldipine.

Abstract

P-glycoprotein (P-gp) is a 170 kDa ATPase which can transport a wide range of natural product cytotoxic drugs out of cells, thus conferring the multidrug resistance (MDR) phenotype. In this paper we used the 1,4-dihydropyridine (1,4-DHP) MDR-reversing agent dexniguldipine (DN), and a derivative with a quaternary nitrogen which is permanently charged, N-methyl-DN, to explore the sidedness of block of [3H]-vinblastine transport by P-gp. In cytotoxicity assays, 1 microM DN sensitized MCF7 ADR cells, causing a 13-fold decrease in the EC50 of vinblastine from 400 +/- 80 nM to 30 +/- 25 nM. In marked contrast, N-methyl-DN was without effect. In intact MCF7 ADR cells, DN reversed the [3H]vinblastine uptake deficit with an EC50 of 445 +/- 100 nM, again, N-methyl-DN was inactive. In photoaffinity labelling studies using the arylazide [3H]-B9209-005 in whole cells, DN potently inhibited incorporation of the photoaffinity label into P-gp whilst N-methyl-DN was without effect. However, in photoaffinity labelling studies in membrane fragments, both DN and N-methyl-DN potently inhibited [3H]-B9209-005 photoaffinity labelling of P-gp. Furthermore, in membrane fragments [3H]-vinblastine binding to P-glycoprotein was potently inhibited by both N-methyl-DN (Ki 10.7 +/- 4.9 nM) and DN (Ki 11.2 +/- 3.8 nM), and both N-methyl-DN and DN blocked ATP-dependent [3H]-vinblastine transport into inside-out vesicles. Thus, in intact cells the permanently charged 1,4-dihydropyridine, N-methyl-DN is unable to reverse the MDR phenotype or photoaffinity labelling of P-gp. However, in cell fragments and inside-out vesicles, N-methyl-DN binds avidly to P-gp and this binding blocks [3H]-vinblastine transport. These data are consistent with the hypothesis that 1,4-DHPs block [3H]-vinblastine binding, and thereby transport by P-gp, by acting at a domain accessible only from the cytoplasm.