©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Functional Reconstitution of P-glycoprotein Reveals an Apparent Near Stoichiometric Drug Transport to ATP Hydrolysis (*)

(Received for publication, June 26, 1995; and in revised form, October 5, 1995)

Gera D. Eytan (§) Ronit Regev Yehuda G. Assaraf (§)

From the Department of Biology, Technion-Israel Institute of Technology, Haifa 32000, Israel

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We have recently described an ATP-driven, valinomycin-dependent Rbuptake into proteoliposomes reconstituted with mammalian P-glycoprotein (Eytan, G. D., Borgnia, M. J., Regev, R., and Assaraf, Y. G.(1994) J. Biol. Chem. 269, 26058-26065). P-glycoprotein mediated the ATP-dependent uptake of Rb-ionophore complex into the proteoliposomes, where the radioactive cation was accumulated, thus, circumventing the obstacle posed by the hydrophobicity of P-glycoprotein substrates in transport studies. Taking advantage of this assay and of the high levels of P-glycoprotein expression in multidrug-resistant Chinese hamster ovary cells, we measured simultaneously both the ATPase and transport activities of P-glycoprotein under identical conditions and observed 0.5-0.8 ionophore molecules transported/ATP molecule hydrolyzed. The amount of Rb ions transported within 1 min via the ATP- and valinomycin-dependent P-glycoprotein was equivalent to an intravesicular cation concentration of 8 mM. Thus, this stoichiometry and transport capacity of P-glycoprotein resemble various ion-translocating ATPases, that handle millimolar substrate concentrations. This constitutes the first demonstration of comparable rates of P-glycoprotein-catalyzed substrate transport and ATP hydrolysis.


INTRODUCTION

Inherent as well as acquired resistance to antineoplastic agents pose a major obstacle toward curative cancer chemotherapy(1, 2) . Multidrug resistance (MDR) (^1)is characterized by the development of tumor cell resistance to diverse anticancer drugs. Mammalian cells with the typical MDR phenotype express increased levels of P-glycoprotein (Pgp), an integral component of the plasma membrane(3) . Consequently, these cells display resistance to multiple cytotoxic hydrophobic agents, mostly of natural origin, including anthracyclines, Vinca alkaloids, epipodophyllotoxins, actinomycin D, taxoids, and dolastatin 10. Pgp, which possesses an ATPase activity, functions as an energy-dependent extrusion pump that expels these hydrophobic cytotoxic agents out of MDR cells(4) .

Sharom et al.(5) have extracted most of the proteins from plasma membranes of MDR cells and have reconstituted the Pgp that remained in the membranes. The reconstituted proteoliposomes displayed an ATP-dependent transport of colchicine, an established substrate of Pgp. Shapiro and Ling (7) have purified Pgp from Pgp-rich cells by a combination of anion exchange and immunoaffinity chromatography. The Pgp preparation was 90% pure and after reconstitution exhibited an ATPase activity that was highly stimulatable by several MDR type drugs and chemosensitizers. Urbatsch et al.(8) have purified Pgp to apparent homogeneity from an extremely Pgp-rich Chinese hamster ovary cell line, reconstituted it, and characterized its drug-stimulatable ATPase activity.

Sharom et al.(5) have shown that colchicine was taken up actively into proteoliposomes with Pgp from CHO cells, against a 5.6-fold concentration gradient. However, the rate of colchicine uptake was about 15 pmol/mg/min with an ATPase activity of 0.5 µmol/mg/min. This extremely low stoichiometry of drug transport to ATP hydrolysis is probably due to the hydrophobicity and membrane permeability of Pgp substrates. Recently, Shapiro and Ling (9) have described the ATP-dependent uptake of the fluorescent Pgp substrate, Hoechst 33342, into proteoliposomes reconstituted with purified Pgp from highly MDR CHO cells. They reported a stoichiometry of 1 substrate molecule transported/50 ATP molecules hydrolyzed and attributed this low efficiency to fast rebinding of the dye to the vesicles.

The low transport efficiency reported for Pgp, either in membrane vesicles or in reconstituted proteoliposomes, led to proposals that other mechanisms were responsible for the relatively low levels of drugs observed in MDR cells(10) . Thus, demonstration of Pgp-mediated transport similar in rate to the Pgp ATPase will prove that Pgp is indeed a drug-efflux pump and could function as such also in vivo.

We have recently described an ATP-driven, valinomycin-dependent Rb uptake into proteoliposomes reconstituted with mammalian P-glycoprotein(6) . Under these conditions mammalian Pgp transported a cation-ionophore complex and the cation, Rb in this case, accumulated in the intravesicular space. The apparent advantage of this assay is that although the actively-transported substrate, ionophore-cation complex, is hydrophobic, the accumulated species is the hydrophilic cations. In the present study, we took advantage of the methodology developed for assay of ionophore- and ATP-dependent Pgp-mediated Rb uptake to measure simultaneously both the ATPase and transport functions of reconstituted Pgp. The valinomycin- and ATP-dependent Rb uptake into proteoliposomes reconstituted with Pgp was close to the ATPase rate exhibited by these proteoliposomes under identical experimental conditions and thus constitutes the first direct demonstration that isolated Pgp could function as an efficient drug-efflux pump.


EXPERIMENTAL PROCEDURES

Materials

Gramicidin D, valinomycin, bovine serum albumin (essentially fatty-acid free), poly-L-tryptophan, and soybean phospholipids were purchased from Sigma. Rb was purchased from DuPont NEN. Cholesterol and phosphatidylserine were products of Avanti Polar Lipids.

In transport studies the effect of Na,K-ATPase was abolished by careful depletion of Na from all reagents used in the transport assay. The triphosphate nucleotides were treated with Dowex 50WX8. The pH of the solutions was monitored and resin was added, until no further acidification occurred. The solutions were passed through a 0.22-µm filter and titrated to pH 7.4 with solid Tris base.

Methods

Cell Cultures

A clonal derivative (C11) of parental CHO AA8 cells and their emetine-resistant sublines were maintained under monolayer conditions in alpha-minimal essential medium (Biological Industries, Beth Haemek, Israel) containing 5% dialyzed fetal calf serum (Beth Haemek), 2 mM glutamine, 100 units/ml penicillin G (Sigma), and 100 µg/ml streptomycin sulfate (Sigma). Exponentially growing cells were passaged twice a week using a standard trypsinization procedure. For preparation of membrane fractions, cells were seeded (10^4 cells/ml) in 3-liter spinner flasks (Cytostir, Kontes) in growth medium supplemented with 20 mM Hepes (pH 7.4) and maintained as suspension cultures.

Emetine-resistant variants were derived from wild type AA8 cells using a stepwise selection protocol of increasing drug concentrations. Drug selection was performed by first seeding 5 times 10^4 wild type cells/25-cm^2 tissue culture flask (Nunc) in growth medium (5 ml) containing 0.15 µM emetine (3 times the LD for parental AA8 cells). Following growth to midconfluence, emetine-selected cells were detached by trypsinization, counted and replated as above in the presence of a 50-100% increment in the emetine concentration. The gradual increase in emetine concentrations was terminated at 1 µM (20-fold LD).

Isolation, Reconstitution of Pgp, and ATPase Assays

Cells (10^9) growing under suspension culture conditions were harvested by sedimentation at 3,000 rpm in a Sorvall GSA rotor, washed with phosphate-buffered saline, and resuspended in 10 ml of lysis buffer containing: 10 mM Hepes-Tris (pH 7.4) at 4 °C, 5 mM EDTA, 5 mM EGTA, 1 mM dithiotreitol (DTT), as well as the protease inhibitors phenylmethylsulfonyl fluoride (PMSF, 2 mM), aprotinin (1 mM), pepstatin (10 µg/ml), and leupeptin (10 µg/ml). Following 5 min incubation on ice, cells were lysed using a Teflon-glass homogenizer and diluted 3-fold in lysis buffer. Nuclei and mitochondria were removed by consecutive 10-min centrifugations at 300 and 4,000 times g, respectively, and the microsomal fraction was recovered by a 30-min centrifugation at 100,000 times g, and finally resuspended in 1 ml of lysis buffer. The membrane fractions were frozen in liquid nitrogen and stored at -75 °C until analysis.

Extraction and Reconstitution of Pgp-rich Membrane Fractions

The extraction and reconstitution of Pgp was performed according to our recently published protocol (6) except for minor modifications. A liposome suspension was prepared from a mixture containing the acetone-insoluble, ether-soluble fraction of soybean phospholipids, phosphatidylserine, and cholesterol in a weight ratio of 5:1:1, respectively. The lipid solutions were mixed, and the solvents were removed under a stream of nitrogen and exposure to vacuum for 30 min. The lipids were suspended to a concentration of 50 mg/ml in a reconstitution medium containing: 25 mM HEPES-Tris (pH 7.4), 85 mM K(2)SO(4), 1 mM DTT, and 1 mM PMSF. Liposomes were formed by sonication to clarity in a round-bath sonicator (Laboratory Supplies Company, Hicksville, NY). Microsomal fraction obtained from either parental AA8 or Emt cells were incubated for 20 min on ice at a 0.2 or 1 mg/ml protein concentration in a solubilization buffer containing: 35 mM HEPES-Tris (pH 7.4), 1.3% n-octylglucoside, 0.7% liposome suspension, 15% glycerol, 3 mM DTT, 3 mM PMSF, 1 mM aprotinin, 100 µg/ml pepstatin, and 50 µg/ml leupeptin. The detergent-soluble proteins were obtained as the supernatant after centrifugation for 30 min at 130,000 times g; a liposome suspension was added to a final lipid concentration of 17 mg/ml and incubated on ice for 20 min.

Proteoliposomes were formed by rapid dilution of the protein and lipid solution into 25 volumes of reconstitution medium containing PMSF as the sole protease inhibitor. The proteoliposomes were washed twice by centrifugation at 130,000 times g for 45 min, and suspended in 1 ml of reconstitution medium. The proteoliposomes were fused by adding CaCl(2) (25 mM final concentration), incubated for 20 min, and diluted into 7 ml of reconstitution buffer, and EDTA was added to a final concentration of 5 mM. The proteoliposomes were concentrated by centrifugation for 45 min at 130,000 times g and suspended in 0.5 ml of reconstitution buffer using a 27-gauge needle. The proteoliposomes were used either directly or after an overnight incubation on ice. Due to the high lipid content of the samples protein was determined according to Esen(11) , using bovine serum albumin (Fraction V, Sigma) as a standard.

ATPase and Transport Assays

The ATPase activity of Pgp was determined by a colorimetric monitoring of the inorganic phosphate released from ATP(12) . Reconstituted vesicles were diluted to a protein concentration of 20 µg/ml in an ice-cold ATPase assay medium, adapted from Urbatsch and Senior(8) , which contained: 3 mM ATP, 50 mM KCl, 25 mM MgSO(4), 25 mM Tris-HCl (pH 7.0), 0.5 mM EGTA, and 2 mM ouabain. Aliquots were incubated with the various drugs for 1 h at 37 °C in glass test tubes. The ATPase activity was linear for at least 1 h(13) . Water-insoluble drugs and peptides were added as ethanol solutions. The total amount of ethanol added was less than 1% and had no effect either on ATPase or on Rb uptake assays. At the end of the incubation, the vesicle suspensions were rapidly cooled in ice-cold water bath, and 50-µl portions were distributed into a 96-well microtiter plate. The reaction was not carried out in the plate since it was observed that hydrophobic drugs, such as valinomycin, were adsorbed to polystyrene. The enzymatic reaction was terminated and inorganic phosphate was determined by the addition of a solution consisting of: 0.2% ammonium molybdate, 1.3% sulfuric acid, 0.9% SDS, and freshly prepared 1% ascorbic acid, incubation for 30 min at room temperature, and enzyme-linked immunosorbent assay reading(14) . Background values were obtained with samples incubated in parallel on ice and were routinely subtracted from the measurements.

Valinomycin- and ATP-dependent Rb uptake was assayed essentially according to the assay strategy we have recently described(6) . The transport activity of Pgp was assessed indirectly by measuring uptake of Rb ions transported as a Rb-valinomycin complex into reconstituted proteoliposomes (see Fig. 1for a scheme describing the methodology). Rb serves as a convenient monitor of K. The assay of Rb uptake was based on the amplification of the isotope uptake by an outwardly oriented concentration gradient of K(15) . The principle of the method relies on the trapping of high K concentrations within the proteoliposomes. Upon dilution of the proteoliposomes into the assay buffer and selective permeation of the proteoliposomes to Rb and K ions by the ionophore mobile carrier-type valinomycin, a diffusion potential is formed, which maintains the K gradient. Rb is transported into the proteoliposomes until equilibration of its specific radioactivity with K is reached. Thus, even in absence of ATP hydrolysis, the K is concentrated in the proteoliposomes relatively to its concentration in the buffer. This accumulation of Rb is transient, as during the course of time, the cation gradient is collapsed, and the accumulated isotope will flow out of the proteoliposomes.


Figure 1: Scheme illustrating mechanism of ATP-driven and valinomycin-dependent Pgp-mediated Rb uptake. Pgp actively transports Rb ions into proteoliposomes by the following mechanism. Pgp catalyzes the ATP-dependent uptake of K-ionophorecomplex into the vesicles. The outward-oriented membrane potential prevents net efflux of cations, and the actively transported Rb ions remain trapped in the vesicles while the hydrophobic ionophore leaks out of the vesicle.



Valinomycin exhibits a high affinity toward K and Rb ions; thus, in the presence of relatively high cation concentrations present in the uptake medium, valinomycin is presented to Pgp predominantly as a cation-ionophore complex. Moreover, most known substrates of Pgp are hydrophobic and cationic in nature, and thus it is likely that the ionophore-cation complex is a preferred substrate for Pgp when compared with the unloaded ionophore. The ATP- and valinomycin-dependent Rb uptake required preloading of the proteoliposomes with K ions, and was abolished by dissipation of the K gradient. Thus, Pgp transports the cation-ionophore complex into the intravesicular volume of the vesicles. The Rb ions cotransported with valinomycin equilibrate with the cations trapped within the vesicles. Since the amount of Rb ions transported is in large excess compared to the total amount of valinomycin present in the medium, valinomycin plays a catalytic role and is recycled. Presumably, the electric potential formed by the K-gradient across the proteoliposome membrane hinders the release of Rb together with the accumulated valinomycin, and valinomycin leaks out of the proteoliposomes as the unloaded species. Thus, although the actual Pgp substrate is the hydrophobic Rb-valinomycin complex, the accumulated substrate is hydrophilic Rb ions.

The transport of Rb was measured by rapid removal of extravesicular cations with the strong cation exchange resin, Dowex-50WX8, 100-mesh(15) , as modified by Garty and Karlish (16) . Unless otherwise stated, the transport buffer contained: 25 mM Hepes-Tris (pH 7.4), 0.25 M sucrose, 8 mg/ml bovine serum albumin, 4 mM MgCl(2), 2 µCi/ml carrier-free Rb, various amounts of valinomycin, and either 1 mM ATP or AMPPCP in a final volume of 0.125 ml. The buffer was preincubated for 2 min at 37 °C, and the transport was initiated by addition of 5 µl of reconstituted proteoliposomes. Non-hydrolyzable analogs of ATP (i.e. AMPPCP) were included in the control samples since the cation-permeability of the proteoliposomes was very sensitive to Mg-concentrations and nucleotide triphosphates are efficient Mg-chelators capable of altering the Mg-concentrations. At appropriate times, the transport reactions were stopped by withdrawing 0.1-ml samples. The extravesicular cations were removed as described by Garty and Karlish (15) , and the amount of radioactivity associated with the vesicles was determined. The stopping procedure was concluded within 15 s. The amount of radioactivity associated with proteoliposomes incubated in the absence of ionophores was less than 0.05% of the total radioactivity added and did not increase upon a 30-min incubation at 37 °C. This amount, presumably representing nonspecific adsorption, was routinely subtracted from all samples.


RESULTS

We undertook this study in order to estimate the stoichiometry of drug transport to ATP hydrolysis catalyzed by Pgp. To this end, both the ATPase and transport functions of Pgp had to be measured simultaneously under identical experimental conditions.

In this respect, we have described an assay of valinomycin uptake into proteoliposomes reconstituted with Pgp from rat liver, the amount of transported valinomycin was assessed as the quantity of Rb ions cotransported with the ionophore (6) . The amount of Pgp present in canalicular vesicles from rat liver was low, and its presence could be detected only by Western blotting with a monoclonal antibody(6) . As a result, its ATPase activity was relatively low and was masked by other ATPases present in the preparation. In contrast, Pgp ATPase activity has been demonstrated with Pgp from multidrug-resistant CHO cells where it is highly overexpressed(5, 8, 9, 13) . Thus, the aim of the present study was to measure simultaneously both ATPase and Rb uptake functions assayed under identical conditions as valinomycin-dependent activities of hamster Pgp.

Toward this end, a CHO variant (Emt) highly-expressing Pgp was established by stepwise selection with the MDR drug, emetine. The Pgp content in the microsomal fraction of this Emt subline constituted 4.5% of the total protein content. Upon reconstitution, the relative amount of Pgp was increased to 18%, and under the assay conditions used here all the ATPase activity was attributable to Pgp(13) . The ATPase activity was stimulated by known substrates of Pgp, inhibited by known inhibitors of Pgp including vanadate and oligomycin, and insensitive to ouabain and EGTA. Reconstitution of Pgp from Emt plasma membranes, the Pgp content of which was 18%, yielded proteoliposomes with a Pgp content of 40% and a consistently higher ATPase activity(13) . However, the yield of these proteoliposomes was low, and since they did not pose a clear advantage over proteoliposomes reconstituted with Pgp from the microsomal fraction, the latter were routinely used.

The basal (i.e. with no substrates added) ATPase activity of proteoliposomes reconstituted with Emt microsomal fraction was 1.1 ± 0.25 µmol of P(i)/min/mg of protein (Fig. 2A and (13) ). A similar basal activity was reported for various Pgp preparations(5, 7, 8, 17, 18) . This basal activity was stimulated by valinomycin and emetine, the selecting drug used to establish Emt cells (Fig. 2). However, a major problem became evident as the minimal valinomycin concentrations required for demonstrating stimulation of ATPase activity were higher than 0.1 µM, whereas appreciable ATP- and valinomycin-dependent Rb uptake was already evident at a concentration of 0.1 µM valinomycin. Thus, the high basal activity demonstrated by Pgp presumably masked the ATPase activity required for valinomycin-dependent transport. To overcome this obstacle, we looked for a Pgp inhibitor capable of reversibly repressing the basal ATPase activity without exerting a deleterious effect on the proteoliposomes. In this respect we have recently found that various hydrophobic homopolypeptides modulate Pgp ATPase activity. (^2)Poly-L-tryptophan met these expectations; at concentrations lower than 100 nM, it inhibited both the basal ATPase and the substrate-stimulatable activities of Pgp (Fig. 2B). These concentrations of poly-L-tryptophan had no deleterious effects on the integrity of the proteoliposomes as revealed by retention of encapsulated Rb or calcein (data not shown). Most importantly for this study, low concentrations of poly-L-tryptophan repressed the basal ATPase activity and, at concentrations required for mediation of ATP-dependent Rb uptake (see below), valinomycin reactivated it in a competitive manner (Fig. 3). The Michaelis-Menten type competitive inhibition exerted by poly-L-tryptophan on the stimulatory effect of valinomycin is presented in Fig. 3B as a Lineweaver-Burk plot.


Figure 2: Modulation of Pgp ATPase activity by emetine, valinomycin, and poly-L-tryptophan. Pgp was extracted from the MDR cells, Emt, and reconstituted into proteoliposomes. The ATPase activity of these proteoliposomes was determined in the presence of various concentrations of either emetine (squares) or valinomycin (circles) for 1 h and is presented in panel A. Panel B describes the ATPase activity of Pgp proteoliposomes determined in the presence of 100 µM (squares) or absence (circles) of valinomycin and various concentrations of poly-L-tryptophan (mass 5.4 kDa). The ATPase rates presented were calculated by subtracting the values obtained in the presence of 10 µM orthovanadate.




Figure 3: Activation of poly-L-tryptophan-inhibition of Pgp ATPase by valinomycin. The ATPase activity of Pgp proteoliposomes was determined in the presence of various concentrations of valinomycin or emetine, and the following concentrations (µM) of poly-L-tryptophan (mass = 5.4 kDa): 0, circles; 1, squares; 10, triangles; 100, inverted triangles. The ATPase rates presented were calculated by subtracting the values obtained in presence of 10 µM orthovanadate. The same experimental data are presented as a Lineweaver-Burk plot on panel B.



ATP- and Valinomycin-dependent Rb Uptake into Reconstituted Proteoliposomes

Valinomycin is a cation ionophore with high affinity toward K ions, and as expected it allowed uptake of Rb ions into the proteoliposomes. ATP hydrolysis accelerated both the rate and maximal level of valinomycin-dependent Rb uptake in K-loaded Pgp reconstituted proteoliposomes. The ATP-dependent transport, calculated as the difference between the uptake values obtained in the presence of ATP and those obtained in the presence of its non-hydrolyzable analog AMPPCP, reached a maximum after 2 min (Fig. 4A) and was dissipated after 30 min of incubation (data not shown). The ATP-dependent uptake of Rb was observed only with K-loaded proteoliposomes, indicating that the ATP-dependent uptake relies on the dilution of the isotope with trapped K ions and that this transport is directed into the intravesicular volume. As expected for Pgp-mediated activity, the ATP-dependent uptake component was restricted to proteoliposomes reconstituted with a Pgp-rich fraction from Emt cells and was absent from proteoliposomes reconstituted with parallel fraction from parental drug-sensitive cells AA8 (Fig. 4B).


Figure 4: Time course of Rb uptake into reconstituted proteoliposomes. Pgp fraction from Emt cells (panel A) and a corresponding protein fraction from Pgp-poor AA8 cells (panel B) were extracted and reconstituted for Rb uptake as described under ``Experimental Procedures.'' Rb uptake was measured in an assay medium containing: 0.25 M sucrose, 8 mg/ml bovine serum albumin, 25 mM Hepes-Tris (pH 7.4), 4 mM MgCl(2), 3 mM DTT, 2 µCi/ml carrier-free Rb, 0.5 µM valinomycin, and either 3 mM ATP (squares) or AMPPCP (circles), in a final volume of 0.125 ml. The buffer was preincubated for 2 min at 37 °C, and the reaction was initiated by the addition of 5 µl Pgp-reconstituted proteoliposomes. The ATP-dependent Rb uptake (triangles) was calculated by subtracting the values obtained in the presence of AMPPCP. Each point represents the mean value ± S.D., n = 8.



In order to discern between the ATP-dependent uptake and the ATP-independent ionophore-mediated equilibration of Rb, reconstituted proteoliposomes were incubated for 3 min in a transport buffer containing valinomycin but lacking ATP. Under these conditions, Rb was allowed to reach apparent equilibration with the K trapped in the proteoliposomes, and the intravesicular K concentration reached a transient constant concentration held by its diffusion potential (Fig. 4). At this point ATP or AMPPCP was added and Rb uptake was determined (Fig. 5). The ATP-dependent component of Rb uptake was not affected by the preincubation. Thus, the ATP-dependent uptake results from an authentic active Rb uptake and not from effects on the ionophore-mediated equilibration of Rb across the proteoliposome membrane. The ATP- and valinomycin-dependent Rb uptake occurred only with K-preloaded vesicles, indicating that the Rb ions were transported into the intravesicular milieu. As shown for Pgp from rat liver and MDR cells (6) , the ATP- and valinomycin-dependent Rb uptake mediated by CHO Pgp was specific to ATP and did not occur with UTP, CTP, ADP, and non-hydrolyzable trinucleotides (data not shown).


Figure 5: The effect of preincubation of reconstituted proteoliposomes in the absence of ATP on subsequent ATP-dependent uptake of Rb. A transport buffer similar to that described in the legend to Fig. 4was used except that ATP was omitted here. After preincubation for 3 min at 37 °C, 5 µl of proteoliposomes reconstituted with either a Pgp fraction from Emt cells (panel A) or a corresponding protein fraction from the Pgp-poor AA8 cells (panel B) and further incubated for 3 min. At this time point, 1 mM ATP (squares) or AMPPCP (circles) was added. The ATP-dependent Rb uptake (triangles) was calculated by subtracting the values obtained in the presence of AMPPCP. Each point represents the mean value ± S.D., n = 4.



Stoichiometry of Pgp-mediated Drug Transport and ATP Hydrolysis

On the one hand, substrate transport mediated by Pgp, was measured indirectly as the ATP-driven and valinomycin-dependent Rb influx. On the other hand, the ATPase activity of reconstituted Pgp from Emt cells can be readily measured. Assessment of both ATPase activity and drug transport under the same assay conditions should allow estimation of the stoichiometry of drug transport to ATP hydrolysis.

Determination of the stoichiometry of drug transport to ATP hydrolysis relies on a quantitative assay of the valinomycin-dependent ATPase and transport activities of Pgp under identical experimental conditions. As shown in Fig. 6, measurement of Pgp-mediated ATPase and Rb uptake as a function of increasing valinomycin concentrations, revealed valinomycin-dependent components of both activities. However, as pointed above, Pgp exhibited high basal activity, in absence of added substrate, which masked the increase in ATPase activity required to mediate the ATP-driven and valinomycin-dependent Rb uptake. We have overcome this obstacle by using poly-L-tryptophan to suppress the basal activity of Pgp. In the presence of poly-L-tryptophan, low valinomycin concentrations mediated an increase in both ATPase activity and Rb uptake (Fig. 6B). In five independent experiments, it was determined that 0.5-0.8 Rb ions were transported/ATP molecule hydrolyzed. This apparent stoichiometry of drug transport to ATP hydrolysis was determined as the ratio of the components of Rb uptake to ATP hydrolysis, measured under identical conditions, which were dependent on both ATP and valinomycin.


Figure 6: Pgp ATPase and Rb uptake activities as a function of valinomycin concentration. Pgp was extracted and reconstituted for Rb uptake as described in Fig. 4. Both the ATPase and Rb uptake were measured simultaneously in the same assay medium containing: 0.25 M sucrose, 8 mg/ml bovine serum albumin, 25 mM Hepes-Tris (pH 7.4), 3 mM DTT, 4 mM MgCl(2), 2 µCi/ml carrier-free Rb, in the absence (panel A) or presence (panel B) of 2 µM poly-L-tryptophan (5.4 kDa), and either 3 mM ATP, or AMPPCP, in a final volume of 0.125 ml. The buffer was preincubated for 2 min at 37 °C, and the reaction was initiated by the addition of 5 µl of reconstituted proteoliposomes. The Rb uptake (circles) and ATPase activity (squares) were assayed for 0.5 and 60 min, respectively. The ATP-dependent Rb uptake was calculated by subtracting the values obtained in the presence of AMPPCP. Each point represents the mean value ± S.D., n = 8. The ATPase rates presented were calculated by subtracting the corresponding values obtained in absence of valinomycin.



An alternative approach to determine the ratio of Pgp-dependent ATP hydrolysis to drug transport was to use inhibitors that suppress both the ATPase and Rb uptake and thereby determine the apparent stoichiometry as the ratio of parallel reductions in Rb uptake and ATP hydrolysis. The Pgp ATPase as well as the valinomycin- and ATP-dependent Rb uptake were both eliminated by established inhibitors of Pgp such as vanadate (Fig. 7A) and oligomycin (Fig. 7B). High concentrations of poly-L-tryptophan competitively inhibited both Pgp ATPase activity and the valinomycin-dependent and ATP-driven Rb uptake (Fig. 7C). The ratio of the drug transport component that was eliminated by these different three inhibitors to the fraction of ATPase activity inhibited by these compounds was again equivalent to 0.5-0.8 mol of Rb transported/mol of ATP hydrolyzed. Pgp substrates such as doxorubicin inhibited Rb uptake, with little or no effect on Pgp ATPase activity (Fig. 7D). Presumably, this well known Pgp substrate competed with valinomycin on the Pgp pharmacophore(13) .


Figure 7: Inhibition of Rb uptake and ATPase activities by vanadate, oligomycin, poly-L-tryptophan, and doxorubicin. The experimental conditions were similar to those described in the legend to Fig. 5, except that the valinomycin concentration here was 0.5 µM and poly-L-tryptophan was omitted except for in panel C. The ATPase rates presented were calculated by subtracting the values obtained in presence of 10 µM orthovanadate.



Thus, the different approaches revealed an apparent near stoichiometry of Pgp-mediated ionophore molecules transported to ATP molecules hydrolyzed.


DISCUSSION

Pgp catalyzes the ATP-driven efflux of various cytotoxic xenobiotics out of MDR cells. However, the hydrophobicity of the various Pgp substrates hindered efforts aimed at estimating the stoichiometry of drug transport to ATP hydrolysis. In this respect, using a highly Pgp-rich proteoliposome system, Shapiro and Ling (9) recently reported a stoichiometry of 1 molecule of Hoechst 33342 transported/50 ATP molecules hydrolyzed; this low stoichiometry was attributed to the rapid rebinding of this hydrophobic chromophore to the liposome membrane, thus suggesting that the actual rate of transport is much faster. Recently, we devised an assay that circumvents this obstacle of the hydrophobicity of Pgp substrates; in this assay, Pgp-reconstituted proteoliposomes displayed an ATP-dependent uptake of Rb-valinomycin complex(6) . Thus, Pgp mediated an ATP-driven Rb accumulation, whereas the ionophore was recycled. Taking advantage of this assay of hydrophilic cation accumulation, we here combined a simultaneous determination of Pgp ATPase activity and its ability to take up Rb-valinomycin as reflected in the Rb accumulation in the Pgp-reconstituted proteoliposomes. Using this approach, a stoichiometry of 0.5-0.8 substrate molecules transported/ATP molecule hydrolyzed was estimated. Thus, the high specific activity of Pgp ATPase (12.5 µmol of P(i)/mg of protein/min) along with its near stoichiometric drug transport to ATP hydrolysis resemble various ion-translocating ATPases including Na, K-ATPase and Ca-ATPase which handle millimolar substrate concentrations. Indeed, the ATP-driven, valinomycin-dependent uptake of Rb ions was equivalent to an intravesicular concentration of 8 mM.

One perplexing theme that emerges from the present study is that 1) despite the millimolar substrate translocation capability of Pgp, even when consisting 18% (this paper) or 32% (8) of total plasma membrane proteins, and 2) although Pgp can surprisingly consume as much as 12% of total cellular ATP in highly MDR cells(19, 20) , Pgp can protect highly MDR cells only against 10 µM emetine (this paper) or 30 µM colchicine(8) . This apparent discrepancy of 3 orders of magnitude between Pgp's translocation ability combined with its strong ATPase activity versus its low efficiency in protecting cells from cytotoxic agents is highly dependent on the preferred, rapid copartition, and rapid diffusion of these hydrophobic drugs through the membrane. This is best exemplified in the case of the hydrophobic peptide ionophores valinomycin and gramicidin D. Although valinomycin proved an excellent Pgp substrate (i.e. low K(m) and high ATPase V(max)), Pgp was shown to confer upon highly MDR cells only a modest protection against this ionophore (see (13) and (21) ), the transmembrane flip-flop of which was found to be on the order of 25 times 10^4/s(22) . In contrast, in spite of the slow gramicidin D translocation and consequent inhibition of Pgp ATPase activity, Pgp proved very efficient in protecting highly MDR cells against this channel-forming ionophore(13, 21) . This is not surprising given the relatively slow transmembrane flip-flop (i.e. minutes half-time) gramicidin D monomers must undergo prior to dimerization and channel formation(23) . Based on the turnover number of Pgp, which was estimated to be 900 substrate molecules/min (K = 15 s; see (8) and (13) ), gramicidin D monomers, but not valinomycin, can be efficiently extracted from the plasma membrane and extruded.


FOOTNOTES

*
This work was supported by research grants (to Y. G. A.) from Chemotech Technologies Ltd. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence may be addressed. Tel.: 972-4-293406; Fax: 972-4-225153; :eytan{at}techunix.technion.ac.il.

(^1)
The abbreviations used are: MDR, multidrug resistance; AMPPCP, beta,-methyleneadenosine 5`-triphosphate; CHO, Chinese hamster ovary; DTT, dithiothreitol; Pgp, P-glycoprotein; PMSF, phenylmethylsulfonyl fluoride.

(^2)
G. D. Eytan and Y. G. Assaraf, manuscript in preparation.


REFERENCES

  1. Frei, E., III (1985) Cancer Res. 45, 6523-6537 [Abstract]
  2. Chabner, B. A., and Collins, J. M. (eds) (1990) Cancer Chemotherapy: Principles and Practice , Lippincot, Philadelphia _
  3. Gottesman, M. M., and Pastan, I. (1993) Annu. Rev. Biochem. 62, 385-427 [CrossRef][Medline] [Order article via Infotrieve]
  4. Gottesman, M. M., and Pastan, I. (1988) J. Biol. Chem. 263, 12163-12166 [Free Full Text]
  5. Sharom, F. J., Yu, X. H., and Doige, C. A. (1993) J. Biol. Chem. 268, 24197-24202 [Abstract/Free Full Text]
  6. Eytan, G. D., Borgnia, M. J., Regev, R., and Assaraf, Y. G. (1994) J. Biol. Chem. 269, 26058-26065 [Abstract/Free Full Text]
  7. Shapiro, A. B., and Ling, V. (1994) J. Biol. Chem. 269, 3745-3754 [Abstract/Free Full Text]
  8. Urbatsch, I. L., Al-Shawi, M. K., and Senior, A. E. (1994) Biochemistry 33, 7069-7076 [Medline] [Order article via Infotrieve]
  9. Shapiro, A. B., and Ling, V. (1995) J. Biol. Chem. 270, 16167-16175 [Abstract/Free Full Text]
  10. Simon, S., Roy, D., and Schindler, M. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 1128-1132 [Abstract]
  11. Esen, A. (1978) Anal. Biochem. 89, 264-273 [Medline] [Order article via Infotrieve]
  12. Chifflet, S., Torriglia, A., Chiesa, R., and Tolosa, A. (1988) Anal. Biochem. 168, 1-4 [Medline] [Order article via Infotrieve]
  13. Borgnia, M. J., Eytan, G. D., and Assaraf, Y. G. (1996) J. Biol. Chem. 271, 3163-3171 [Abstract/Free Full Text]
  14. Doige, C. A., Yu, X., and Sharom, F. J. (1993) Biochim. Biophys. Acta 1146, 65-72 [Medline] [Order article via Infotrieve]
  15. Garty, H., and Karlish, S. J. D. (1989) Methods Enzymol. 172, 155-164 [Medline] [Order article via Infotrieve]
  16. Gasko, O. D., Knowles, A. F., Shetzer, H. G., Suolinna, E.-M., and Racker, E. (1976) Anal. Biochem. 72, 57-65 [Medline] [Order article via Infotrieve]
  17. Ambudkar, S. V., Lelong, I. H., Zhang, J., Cardarelli, C. O., Gottesman, M. M., and Pastan, I. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 8472-8476 [Abstract]
  18. Al-Shawi, M. K., and Senior, A. (1993) J. Biol. Chem. 268, 4197-4206 [Abstract/Free Full Text]
  19. Broxterman, H. J., Pinedo, H. M., Kuiper, C. M., Kaptein, L. C. M., Schuurhuis, G. J., and Lankelma, J. (1988) FASEB J. 2, 2278-2282 [Abstract/Free Full Text]
  20. Broxterman, H. J., Pinedo, H. M., Kuiper, C. M., Schuurhuis, G. J., and Lankelma, J. (1989) FEBS Lett. 247, 405-410 [CrossRef][Medline] [Order article via Infotrieve]
  21. Assaraf, Y. G., and Borgnia, M. J. (1994) Eur. J. Biochem. 222, 813-824 [Abstract]
  22. Benz, R., and Läuger, P. (1976) J. Membr. Biol. 27, 1441-1450
  23. O'Connell, A. M., Koeppe, R. E., II, and Andersen, O. S. (1990) Science 250, 1256-1259 [Medline] [Order article via Infotrieve]

©1996 by The American Society for Biochemistry and Molecular Biology, Inc.