Using purified P-glycoprotein to understand multidrug resistance

Cellular drug efflux and reversal therapy of cancer

A prevalent form of multidrug resistance (MDR) in cancer cells is caused by an ATP-dependent drug efflux pump; this pump catalyzes the rapid exit of cytotoxic chemotherapy drugs from the cells. The Michaelis equation can be used to describe drug efflux through the MDR pump at a low drug substrate concentration [S]. The inhibition mechanism of an MDR reversal agent can be characterized when two different values of [S] are used to determine two values for the half-inhibition of efflux through the pump (I50). The reaction is noncompetitive when the two values of I50 are identical; the reaction is competitive when an increase in [S] produces a significant increase in the value of I50. The I50 has been determined for several different reversal agents with the substrate rhodamine 123. The inhibition potency observed is: cyclosporin A > DMDP > amiodarone > verapamil > quinidine > quinine > propranolol. Chemotherapy drugs that are potent inhibitors of the MDR pump could be used for the treatment of MDR neoplasia.

The catalytic cycle of P-glycoprotein

P-glycoprotein is a plasma-membrane glycoprotein which confers multidrug-resistance on cells and displays ATP-driven drug-pumping in vitro. It contains two nucleotide-binding domains, and its structure places it in the 'ABC transporter' family. We review recent evidence that both nucleotide-sites bind and hydrolyse Mg-ATP. The two catalytic sites interact strongly. A minimal scheme for the MgATP hydrolysis reaction is presented. An alternating catalytic sites scheme is proposed, in which drug transport is coupled to relaxation of a high-energy catalytic site conformation generated by the hydrolysis step. Other ABC transporters may show similar catalytic features.

Both P-glycoprotein nucleotide-binding sites are catalytically active

The technique of vanadate trapping of nucleotide was used to study catalytic sites of P-glycoprotein (Pgp) in plasma membranes from multidrug-resistant Chinese hamster ovary cells. Vanadate trapping of Mg- or Co-8-azido-nucleotide (1 mol/mol of Pgp) caused complete inhibition of Pgp ATPase activity, with reactivation rates at 37 degrees C of 1.4 x 10(-3) s-1 (t1/2 = 8 min) or 3.3 x 10(-4) s-1 (t1/2 = 35 min), respectively. UV irradiation of the inhibited Pgp yielded permanent inactivation of ATPase activity and specific photolabeling of Pgp. Mild trypsin digestion showed that the two nucleotide sites were labeled in equal proportion. The results show that both nucleotide sites in Pgp are capable of nucleotide hydrolysis, that vanadate trapping of nucleotide at either site completely prevents hydrolysis at both sites, and that vanadate trapping of nucleotide in the N- or C-terminal nucleotide sites occurs non-selectively. A minimal scheme is presented to explain inhibition by vanadate trapping of nucleotide and to describe the normal catalytic pathway. The inhibited Pgp-Mg-nucleotide.vanadate complex is probably an analog of the catalytic transition state, implying that when one nucleotide site assumes the catalytic transition state conformation the other site cannot do so and suggesting that the two sites may alternate in catalysis.