The multidrug-resistance-reverser verapamil interferes with cellular P-glycoprotein-mediated pumping of daunorubicin as a non-competing substrate.

We examined P-glycoprotein-mediated verapamil transport, using two drug-sensitive and multi-drug resistant cell-line couples, i.e. A2780, 2780AD and SW-1573, SW-1573/1R500. The interaction of 3H-labeled verapamil with cells was measured using a flow-through system. The verapamil-containing medium was pumped over the cells and monitored on-line for radioactivity. In the P-glycoprotein-expressing cells, verapamil accumulation was increased by vinblastine and some known multidrug resistant (MDR) modifiers. Subsequent removal of these modifiers caused release of verapamil into the medium against a verapamil concentration gradient. In this manner, we obtained evidence that verapamil is actively transported by the MDR-related P-glycoprotein. Using the flow-through system, we also exposed the cells to flowing culture medium containing daunorubicin, and measured the inhibition of daunorubicin efflux by verapamil. We found that, although the active efflux of daunorubicin was maximally blocked by verapamil short-term, longer-term active efflux of daunorubicin resumed. At a daunorubicin concentration in the flowing medium of 5 microM, increasing the verapamil concentration resulted in the same short-term effects, but in a significantly longer period of a maximal inhibition of daunorubicin efflux from the cells. At a daunorubicin concentration of 20 microM, increasing the verapamil concentration affected neither the short-term nor the long-term effects. These and other observations are in agreement with a model in which daunorubicin and verapamil are non-competing substrates for P-glycoprotein. In conclusion, we obtained evidence that verapamil is actively transported by the MDR-related P-glycoprotein and that verapamil and daunorubicin are non-competing substrates for P-glycoprotein. Consequently, the effectiveness of verapamil as an MDR antagonist may be compromised because it is extruded by P-glycoprotein.

Kinetics of daunorubicin transport by P-glycoprotein of intact cancer cells.

Drug permeation across the plasma membrane of multidrug-resistant cells depends on the kinetics of the P-glycoprotein-mediated pump activity as well as on the passive permeation of the drug. We here demonstrate a method to characterize kinetically the pump in intact cells. To this purpose, we examined the membrane-transport properties of daunorubicin in various sensitive cancer cell lines and in their multidrug resistant (MDR) counterparts. First, we determined the passive permeability coefficient for daunorubicin. Then, using a flow-through system, the drug flux into the cell was measured after inhibition of the P-glycoprotein-mediated efflux pump. Combining the two results allowed us to calculate the intracellular free concentration of the drug. In the steady-state, the pump rate must equal the net rate of passive diffusion of the drug and, therefore, the same experiments gave us the pumping rate of daunorubicin. These experiments were then repeated at various extracellular drug concentrations. By plotting the pumping rate versus the intracellular drug concentration, we then characterized the P-glycoprotein kinetically. Four independent methods were used to measure the passive permeability coefficient for the cell line A2780. Similar values were obtained. Maximal pump rates (Vmax) showed a good correlation with the amount of P-glycoprotein in the cell lines used. We obtained saturation curves for the variation of the pump rates with the intracellular daunorubicin concentrations. These curves were typical for positive cooperativity, which provides evidence that at least two binding sites for daunorubicin are present on the active transport system of daunorubicin. The apparent Km values for P-glycoprotein-mediated transport, the intracellular free cytosolic daunorubicin concentrations at half-maximal velocity for the cell lines used, were approximately 1.5 microM. Except for the cell lines with the highest amount of P-glycoprotein, the passive efflux rate of daunorubicin proved to be a substantial part of the total daunorubicin efflux rate for the cell lines used. In cell lines with relatively low levels of P-glycoprotein, passive daunorubicin efflux was even the main route of daunorubicin transport from the cells, determining the intracellular steady-state concentrations of daunorubicin.

P-glycoprotein drug efflux pump involved in the mechanisms of intrinsic drug resistance in various colon cancer cell lines. Evidence for a saturation of active daunorubicin transport.

We studied the resistance of colon tumors to anticancer agents in vitro. Using daunorubicin (DN), a number of cellular parameters which normally indicate acquired or multidrug resistance (MDR), were compared for several human wild-type colon cell lines, i.e. HT29, SW1116 and COLO 320, and the murine colon cell line C-26. The sensitive/MDR human ovarian cancer cell line couple A2780/2780AD was used as a reference. The amount of P-glycoprotein (P-gp) was in the order HT29, A2780 less than or equal to SW1116 less than C26 less than or equal to COLO 320 less than 2780AD. The MDR modifiers verapamil, Cremophor EL, cyclosporin A and Ro 11-2933/001 had significant effects on DN cytotoxicity, total DN accumulation and efflux, only if P-gp was present. A flow-through system was used to study the mechanism of DN transport. For the first time, evidence for saturation of an active transport of DN from the cells is reported. We discussed the possible presence of cooperative activity between at least two binding sites on the protein responsible for DN efflux, likely to be P-gp.

Measurement of in vitro cellular pharmacokinetics of 5-fluorouracil in human and rat cancer cell lines and rat hepatocytes using a flow-through system.

A flow-through system was used to study the cellular pharmacokinetics of 5-fluorouracil (5-FU) in four human cell lines (squamous-cell carcinoma HEp-2, colon carcinoma WiDr, hepatoma Hep G2, and breast carcinoma MCF-7) as well as in the rat hepatoma H35 cell line and in freshly isolated rat hepatocytes. The system made it possible to restrict the decrease in the concentration of 5-FU in the medium, to keep the volume in which the metabolites accumulated relatively small, and to study the dynamics of a response during and after a change in the composition of the eluent. Clearance of 5-FU from the eluent was achieved predominantly (greater than 95%) by its catabolism to dihydrofluorouracil in the tumor cell lines and to 2-fluoro-beta-alanine in the hepatocytes. Not only rat hepatocytes but also HEp-2 cells showed relatively high clearance values. A concentration-dependent 5-FU elimination was observed, indicating saturation of 5-FU elimination according to Michaelis-Menten kinetics (Km 14-22 microM). The maximal velocity (Vmax) values ranged from 0.025 to 0.13 nmol 5-FU/10(6) cells per minute. For HEp-2 cells, high-concentration pulse injections of 5-FU, thymine, uridine, or uracil immediately led to a reduction in 5-FU conversion, followed by recovery within 5 min. The flow-through system proved to be adequate for the study of the non-linear pharmacokinetics of 5-FU in different intact cells and for the comparison of various manipulations of these pharmacokinetics.

Evidence for daunomycin efflux from multidrug-resistant 2780AD human ovarian carcinoma cells against a concentration gradient.

Using a flow-through system human multidrug-resistant 2780AD ovarian carcinoma cells were exposed to flowing culture medium containing the anticancer agent daunomycin (5 microM). A pulse of medium containing verapamil caused increased cellular daunomycin accumulation, resulting in a dip in the fluorescence signal from daunomycin in the effluent. After passage of this pulse we observed an efflux of more than 90% of this extra accumulated daunomycin within 10 min. This daunomycin efflux against a concentration gradient provides evidence for drug efflux from these cells being an active process. After the addition of methylamine to the medium to increase intravesicular pH, the dip in the fluorescence signal was not decreased, indicating that vesicular transport was not an important component of this efflux.

Conformational studies on the N-linked carbohydrate chain of bromelain.

1H- and 13C-NMR assignments for the carbohydrate part of the glycopeptide alpha-D-Man-(1----6)-[beta-D-Xyl-(1----2)]-beta-D-Man-(1----4)-beta-D- GlcNAc-(1----4)-[alpha-L-Fuc-(1----3)]-beta-D-GlcNAc-(1----N)-Asn approximately, derived from the proteolytic enzyme bromelain (EC 3.4.22.4), have been obtained using homo- and heteronuclear correlation spectroscopy, two-dimensional homonuclear Hartmann-Hahn and nuclear Overhauser enhancement experiments. A conformational model for the carbohydrate chain, deduced from the NMR data and consistent with hard-sphere exo-anomeric calculations shows that the rotamer population about the C-5--C-6 bond of beta-Man is restricted to the P omega = 180 rotamer, mainly.