Photoaffinity probes for the alpha 1-adrenergic receptor and the calcium channel bind to a common domain in P-glycoprotein

P-glycoprotein is a 130-180-kDa integral membrane protein that is overproduced in multidrug-resistant cells. The protein appears to act as an energy-dependent drug efflux pump that has broad specificity for structurally diverse hydrophobic antitumor drugs. Many agents, such as the calcium channel blocker verapamil, reverse multidrug resistance and also interact with P-glycoprotein. The goal of this work was to determine if a common binding site participates in the transport of antitumor drugs and/or the reversal of drug resistance. This was done by comparing the peptide maps of P-glycoprotein (encoded by mdr1b) after it was labeled with a photoactive calcium channel blocker, [3H]azidopine, and a newly identified photoaffinity analog for P-glycoprotein 2-[4-(4-azido-3-[125I]iodobenzoyl) piperazin-1-yl]-4-amino-6,7-dimethoxyquinazoline [( 125I]iodoaryl azidoprazosin). [125I] Iodoaryl azidoprazosin, which classically has been used to identify the alpha 1-adrenergic receptor, bound to P-glycoprotein and was preferentially competed by vinblastine greater than actinomycin D greater than doxorubicin greater than colchicine. Peptide maps derived from P-glycoprotein labeled with [3H]azidopine or [125I]iodoaryl azidoprazosin were identical. After maximal digestion under conditions for Cleveland mapping, a single major 6-kDa fragment was obtained after digestion with V8 protease, whereas two major fragments, 6.5 and 5.5 kDa, were detected after digestion with chymotrypsin. The 6.0-kDa V8 fragment and the 6.5-kDa chymotrypsin fragment were both found when P-glycoprotein encoded by mdr1a and mdr1b was compared. Despite its specific interaction with P-glycoprotein, neither iodoaryl azidoprazosin nor prazosin markedly reversed resistance compared with verapamil or azidopine. Further, multidrug-resistant cells were 900-fold resistant to vinblastine but only 5-fold resistant to prazosin. These data demonstrate that structurally diverse reversal and/or antitumor agents are likely to have differential affinity for a small common domain of P-glycoprotein.     

Alternate overexpression of two P-glycoprotein [corrected] genes is associated with changes in multidrug resistance in a J774.2 cell line

In multidrug-resistant murine J774.2 cells, the mdr1a and mdr1b genes encode the 120- and 125-kDa P-glycoprotein precursors, respectively (Hsu, S. I., Lothstein, L., and Horwitz, S.B. (1989) J. Biol. Chem. 264, 12053-12062). It is shown here that a J774.2 cell line selected for vinblastine resistance (J7.V3) switched from the 125- to 120-kDa precursor when cells that were maintained in 20 nM vinblastine were grown in 40 nM vinblastine for 20 months. The rate of switching was accelerated by growing cells in higher levels of vinblastine. These findings suggest that cells which express mdr1a have a selective growth advantage compared to cells which express mdr1b. Consistent with this hypothesis, the switching event that occurs in cells maintained at 40 nM vinblastine was correlated with 3.5-5-fold higher levels of resistance to vinblastine, taxol, and doxorubicin in the absence of any detectable increase in the amount of immunoreactive P-glycoprotein. These findings suggest that P-glycoproteins derived from mdr1a and mdr1b are functionally distinct.     

The products of the mdr1a and mdr1b genes from multidrug resistant murine cells have similar degradation rates

Two vinblastine-resistant sublines of the murine macrophage-like cell line J774.2, J7.V1-1 and J7.V3-1, overproduce unique forms of P-glycoprotein that are encoded by distinct mdr genes, mdr1b and mdr1a, respectively. Degradation rates of the two P-glycoprotein isoforms were measured by immunoprecipitation of P-glycoprotein. The half-life of immunoprecipitable P-glycoprotein from J7.V1-1 cells was 16.8 +/- 0.5 hours and from J7.V3-1 cells, 17.4 +/- 0.5 hours. This rate was not influenced by the presence of vinblastine in the growth medium. The data indicate that P-glycoproteins derived from distinct genes have similar degradation rates.     

Sequence of mdr3 cDNA encoding a human P-glycoprotein

We have determined the sequence of the human mdr3 gene using cDNA derived from liver RNA. The mdr3 gene codes for a member of a family of membrane proteins, the P-glycoproteins, overproduced in many multi-drug-resistant (MDR) cell lines. Like its relatives, the protein encoded by mdr3 has a deduced Mr of 140,000, which is presumably increased by glycosylation after synthesis. The sequence consists of two similar halves, each with a series of six hydrophobic segments that may form a membrane channel. The halves also possess nucleotide-binding consensus sequences, which presumably act as ATPases and drive drug transport. The presumed ATPase domains are all but identical to those of the human mdr1 gene product [Chen et al., Cell 47 (1986) 381-389]. We attribute this high level of sequence conservation to the repeated gene conversion that is evident from segments in which mdr1 and mdr3 differ only in a few silent mutations. Divergence between P-glycoprotein family members is greatest at the N terminus and in the 60 amino acid linker connecting the two halves. In the putative trans-membrane domains approx. 80% of the amino acids are conserved between the products of mdr1 and mdr3. Although the function of mdr3 is not yet known, its high homology with mdr1 suggests that it also encodes an efflux pump with broad specificity.     

Molecular mechanism of multidrug resistance in tumor cells

The ability of tumor cells to develop simultaneous resistance to multiple lipophilic cytotoxic compounds represents a major problem in cancer chemotherapy. This review describes recent molecular biological studies which resulted in the identification and cloning of the gene responsible for multidrug resistance in human tumor cells. This gene, designated mdr1, is overexpressed in all and amplified in many of the multidrug-resistant cell lines analyzed. Gene transfer and expression assays have indicated that the mdr1 gene is both necessary and sufficient for multidrug resistance. The product of the mdr1 gene is P-glycoprotein, a transmembrane protein which shares homology with several bacterial proteins involved in active membrane transport. P-glycoprotein appears to function as an energy-dependent efflux pump responsible for the removal of drugs from multidrug-resistant cells. The functions of the mdr system in normal cells and its potential clinical implications are discussed.     

Internal duplication and homology with bacterial transport proteins in the mdr1 (P-glycoprotein) gene from multidrug-resistant human cells

Resistance of tumor cells to multiple cytotoxic drugs is a major impediment to cancer chemotherapy. Multidrug resistance in human cells is determined by the mdr1 gene, encoding a high molecular weight membrane glycoprotein (P-glycoprotein). Complete primary structure of human P-glycoprotein has been determined from the cDNA sequence. The protein, 1280 amino acids long, consists of two homologous parts of approximately equal length. Each half of the protein includes a hydrophobic region with six predicted transmembrane segments and a hydrophilic region. The hydrophilic regions share homology with peripheral membrane components of bacterial active transport systems and include potential nucleotide-binding sites. These results are consistent with a function for P-glycoprotein as an energy-dependent efflux pump responsible for decreased drug accumulation in multidrug-resistant cells.     

Isolation and characterization of Drosophila multidrug resistance gene homologs.

Mammalian multidrug-resistant cell lines, selected for resistance to a single cytotoxic agent, display cross-resistance to a broad spectrum of structurally and functionally unrelated compounds. These cell lines overproduce a membrane protein, the P-glycoprotein, which is encoded by a member(s) of a multigene family, termed mdr or pgp. The amino acid sequence of the P-glycoprotein predicts an energy-dependent transport protein with homology to a large superfamily of proteins which transport a wide variety of substances. This report describes the isolation and characterization of two Drosophila homologs of the mammalian mdr gene. These homologs, located in chromosomal sections 49EF and 65A, encode proteins that share over 40% amino acid identity to the human and murine mdr P-glycoproteins. Fly strains bearing disruptions in the homolog in section 49EF have been constructed and implicate this gene in conferring colchicine resistance to the organism. This work sets the foundation for the molecular and genetic analysis of mdr homologs in Drosophila melanogaster.     

Multidrug resistance gene expression is controlled by steroid hormones in the secretory epithelium of the uterus

The multidrug resistance (mdr) gene family has been shown to encode a membrane glycoprotein, termed the P-glycoprotein, which functions as a drug efflux pump with broad substrate specificity. This multigene family is expressed in a tissue-specific fashion in a wide variety of normal and neoplastic tissues. The regulation of mdr gene expression in normal tissues is not understood. We have recently shown that mdr mRNA and the P-glycoprotein increases dramatically in the secretory luminal and glandular epithelium of the gravid murine uterus. This observation has suggested that mdr gene expression in the uterus is controlled by the physiologic changes associated with pregnancy. This report now demonstrates that mdr mRNA and P-glycoprotein are induced at high levels in the uterine secretory epithelium by the combination of estrogen and progesterone, the major steroid hormones of pregnancy. This regulation of mdr gene expression in the uterus does not require any other contribution from the fetus or placenta. The data indicate that this gene locus is hormonally responsive to estrogen and progesterone in the uterine secretory epithelium, suggesting an important and physiologically regulated role during pregnancy.     

Certain calcium channel blockers bind specifically to multidrug-resistant human KB carcinoma membrane vesicles and inhibit drug binding to P-glycoprotein

The calcium channel blockers verapamil and diltiazem have been shown to reverse multidrug resistance, but the mechanism of action of these agents is still unknown. We measured [3H]verapamil, [3H]desmethoxyverapamil, [3H]diltiazem, and [3H]nitrendipine binding to membrane vesicles made from drug-sensitive (KB-3-1), multidrug-resistant (KB-C4 and KB-V1), and revertant (KB-V1-R2) cells. Membrane vesicles from KB-V1 cells bound 10-20-fold more [3H]verapamil and [3H]diltiazem and about 30-fold more [3H]desmethoxyverapamil than did vesicles from the parental KB-3-1 or revertant KB-V1-R2 cell lines. These drugs reverse the multidrug resistance phenotype by increasing accumulation of drugs in the resistant cells. No difference in binding of [3H]nitrendipine, which did not reverse drug resistance, was observed. The binding of vinblastine, desmethoxyverapamil, and diltiazem to KB-V1 vesicles was specific and saturable and was inhibited by desmethoxyverapamil and quinidine greater than vinblastine and diltiazem much greater than daunomycin. In addition, verapamil and diltiazem inhibited the vinblastine photoaffinity labeling of P170, the protein previously shown to be a marker of multidrug resistance.     

Expression and functional activity of P-glycoprotein in cultured hepatocytes from Oncorhynchus mykiss

P-glycoproteins encoded by multidrug resistance 1 (mdr1) genes are ATP-dependent transporters located in the plasma membrane that mediate the extrusion of hydrophobic compounds from the cell. Using cultured isolated rainbow trout hepatocytes, we characterized an mdr1-like transport mechanism of the teleost liver. Immunoblots with the monoclonal antibody C219, which recognizes a conserved epitope of P-glycoproteins, revealed the presence of immunoreactive protein(s) of 165 kDa in trout liver and cultured hepatocytes. In trout liver sections, the immunohistochemistry with C219 stained bile canalicular structures. Compounds known to interfere with mdr1-dependent transport (verapamil, vinblastine, doxorubicin, cyclosporin A, and vanadate) all increased the accumulation of rhodamine 123 by hepatocytes. Verapamil, vinblastine, and cyclosporin A decreased the efflux of rhodamine 123 from hepatocytes preloaded with rhodamine 123. By contrast, the substrate of the canalicular cation transporter tetraethylammonium and the inhibitor of the multidrug resistance-associated protein MK571 had no effect on rhodamine 123 transport. The results demonstrate the presence of an mdr1-like transport system in the teleost liver and suggest its function in biliary excretion.     

The function of Gp170, the multidrug resistance gene product, in rat liver canalicular membrane vesicles

Gp170 (also known as P-glycoprotein) is a transmembrane glycoprotein which is overexpressed in multidrug-resistant tumor cells and is also found in the apical plasma membrane domain of several normal human and animal tissues. Gp170 has been postulated to function as an energy-dependent efflux pump for cytotoxic drugs. In rat liver, Gp170 is restricted to the bile canalicular domain of the plasma membrane. Canalicular membrane vesicles (CMV), but not sinusoidal membrane vesicles, contained a approximately 160-kDa protein which reacts with anti-Gp170 monoclonal antibody and manifest ATP-dependent [3H]daunomycin transport which is temperature dependent, osmotically sensitive, and saturable. Among several nucleotides, ATP was a potent stimulator of transport whereas non- or slowly hydrolyzable analogues (adenosin-5-O-(3-thiotriphosphate, adenyl-5-yl-imidodiphosphate) were ineffective. ATP-dependent daunomycin transport was inhibited by cytotoxic drugs (vinblastine, vincristine, and adriamycin) and other drugs, such as verapamil and quinidine, which restore anti-cancer drug sensitivity in resistant cells. Inside-out CMV were separated from right side-out CMV by antibody-induced affinity density perturbation. Only inside-out CMV manifested ATP-dependent daunomycin transport. These results suggest that Gp170 is an ATP-dependent efflux pump which is responsible for the undirectional, energy-dependent transport of daunomycin and other drugs by rat liver into the bile.     

mdr1a deficiency corrects sterility in Niemann-Pick C1 protein deficient female mice

Niemann-Pick type C disease is a progressive neurological disease with cholesterol storage in liver, and npc1-/- mice share these features and are sterile. We have searched for the cause of sterility and found normal folliculogenesis and progesterone levels but lack of implantation. Multiple drug resistance (MDR) P-glycoproteins are plasma membrane proteins implicated in the movement of drugs and lipids across membranes. Their functions are inhibited by progesterone, which has been shown to alter cellular cholesterol homeostasis and has implicated P-glycoproteins in the movement of cholesterol to the endoplasmic reticulum. We have introduced the mdr1a knockout into the npc1 mutant line. While the neurological disease continues at its usual rate, preventing the females from taking care of their litters, npc1-/-, mdr1a-/- females became fertile. Although the mdr1a P-glycoprotein co-localizes with caveolae, neither caveolin-1 nor npc1 levels were significantly altered in the livers of double homozygotes. The absence of mdr1a was confirmed by immunoblotting, but npc1 deficiency was not associated with consistent changes in cerebellar mdr1a in mdr1a+/+ mice. The results show that a mdr1a mutation is an in vivo suppressor of female sterility in npc1 deficient mice.     

Progesterone photoaffinity labels P-glycoprotein in multidrug-resistant human leukemic lymphoblasts

We show for the first time that [3H]progesterone ([3H]PRG) can directly photoaffinity label membrane proteins prepared from a multidrug-resistant human leukemic lymphoblastic cell line CEM/VLB5K. A 170-kDa protein in CEM/VLB5K cell membranes was specifically labeled by [3H]PRG, which we identified as P-glycoprotein (Pgp) by immunoprecipitation with monoclonal antibody C219. The anticancer drug vinblastine and multidrug resistance reversing agent verapamil as well as several steroidal hormones were examined for their ability to interfere with [3H]PRG binding to Pgp. We found that 200-fold molar excess of vinblastine strongly inhibited (93%) the binding of [3H]PRG to Pgp compared with verapamil (80%), progesterone (78%), testosterone (46%), dexamethasone (25%), and aldosterone (56%). The results of this study provide direct evidence that progesterone can bind to Pgp and support the hypothesis that under physiological conditions Pgp may play a role in the excretion of progesterone from certain cells. Importantly, our results show that under our conditions vinblastine and verapamil are better able to compete with [3H]PRG for binding to Pgp than are other steroids, including testosterone, corticosteroids, and mineralocorticoids.     

Purification and reconstitution of functional human P-glycoprotein

The overexpression of the P-glycoprotein, theMDR1 gene product, has been linked to the development of resistance to multiple cytotoxic natural product anticancer drugs in certain cancers and cell lines derived from tumors. P-glycoprotein, a member of the ATP-binding cassette (ABC) superfamily of transporters, is believed to function as an ATP-dependent drug efflux pump with broad specificity for chemically unrelated hydrophobic compounds. We review here recent studies on the purification and reconstitution of P-glycoprotein to elucidate the mechanism of drug transport. P-glycoprotein from the human carcinoma multidrug resistant cell line, KB-V1, was purified by sequential chromatography on anion exchange followed by a lectin (wheat germ agglutinin) column. Proteoliposomes reconstituted with pure protein exhibited high levels of drug-stimulated ATPase activity as well as ATP-dependent [³H]vinblastine accumulation. Both the ATPase and vinblastine transport activities of the reconstituted P-glycoprotein were inhibited by vanadate. In addition, the vinblastine transport was inhibited by verapamil and daunorubicin. These studies provide strong evidence that the human P-glycoprotein functions as an ATP-dependent drug transporter. The development of the reconstitution system and the availability of recombinant protein in large amounts due to recent advances in overexpression of P-glycoprotein in a heterologous expression system should facilitate a better understanding of the function of this novel protein.     

Immunocytochemical localization of P170 at the plasma membrane of multidrug-resistant human cells

P170 (P-glycoprotein) is a membrane protein found in high levels in multidrug-resistant cultured cell lines. We have localized this protein using monoclonal antibody MRK16 by immunofluorescence and electron microscopy in the multidrug-resistant human carcinoma cell line KB-C4. The P170 determinant recognized by antibody MRK16 was found on drug-resistant KB-C4 cells, but not on parental drug-sensitive KB-3-1 cells. The determinant was present on the external surface of the plasma membrane and on the luminal side of Golgi stack membranes. P170 was excluded from coated pits at the plasma membrane and absent from endocytic vesicles and lysosomes. This determinant was detected only in small amounts in the endoplasmic reticulum. The high protein concentration of P170 in the plasma membrane is consistent with a role of this protein as a drug efflux pump at the cell surface.     

Role of P-Glycoprotein in the Blood-Brain Transport of Colchicine and Vinblastine

Abstract: Classically, drug penetration through the blood-brain barrier depends on the lipid solubility of the substance, except for some highly lipophilic drugs, like colchicine and vinblastine, both substrates of P-glycoprotein, a drug efflux pump present at the luminal surface of the brain capillary endothelial cells. Colchicine and vinblastine uptake into the brain was studied in the rat using the in situ brain perfusion technique and two inhibitors of P-glycoprotein, verapamil and SDZ PSC-833. When rats were pretreated with PSC-833 (10 mg/kg, intravenous bolus), colchicine and vinblastine uptake was enhanced 8.42- and 9.08-fold, respectively, in all the gray areas of the rat brain studied. The mean colchicine distribution volume was increased from 0.67 ± 0.41 to 5.64 ± 0.70 µl/g and vinblastine distribution volume from 2.74 ± 1.15 to 24.88 ± 4.03 µl/g. When rats were pretreated with verapamil (1 mg/kg, intravenous bolus), colchicine distribution volume was increased 3.70-fold. The increase in colchicine and vinblastine did not differ between the eight brain gray areas. PSC-833 and verapamil pretreatment had no influence on the distribution volume of either drug in the choroid plexus. Nevertheless, distribution volumes remained small, considering the highly lipophilic nature of the substances. We suggest that P-glycoprotein is either only partially inhibited (difficulty of fully saturating P-glycoprotein, especially under in vivo conditions) or not the only barrier to these two drugs.     

P-glycoproteins: mediators of multidrug resistance

Multidrug resistance represents a major obstacle to successful chemotherapy of metastatic disease. Elevated levels in cancer cells if the product of the multidrug resistance gene, P-glycoprotein or the multidrug transporter, have been associated with the development of simultaneous resistance to a great variety of amphiphilic cytotoxic drugs. P-glycoproteins is an integral plasma membrane protein which contains 12 putative transmembrane regions and two ATP binding sites. It confers multidrug resistance by functioning as an energy-dependent drug efflux pump. Here we describe recent studies on the biosynthesis, structure, function, and mechanism of action of P-glycoprotein which have provided insights into the complexity of this multifunctional transport system and revealed an additional chloride channel activity. The physiological role of P-glycoprotein, however, still remains to be elucidated.     

Transition state P-glycoprotein binds drugs and modulators with unchanged affinity,suggesting a concerted transport mechanism

The P-glycoprotein multidrug transporter is a plasma membrane efflux pump for hydrophobic natural products, drugs, and peptides, driven by ATP hydrolysis. Determination of the details of the catalytic cycle of P-glycoprotein is critical if we are to understand the mechanism of drug transport and design ways to inhibit it. It has been proposed that the vanadate-trapped transition state of P-glycoprotein (Pgp x ADP x V(i) x M(2+), where M(2+) is a divalent metal ion) has a very low affinity for drugs compared to resting state protein, thus leading to binding of substrate on the cytoplasmic side of the membrane and release of substrate to the extracellular medium (or the extracellular membrane leaflet). We have used several different fluorescence spectroscopic approaches to show that isolated purified P-glycoprotein, when trapped in a stable transition state with vanadate and either Co(2+)or Mg(2+), binds drugs with high affinity. For vinblastine, colchicine, rhodamine 123, and doxorubicin, the affinity of the vanadate-trapped transition state for drugs was only very slightly (less than 2-fold) lower than the binding affinity of resting state Pgp, whereas for the modulators cyclosporin A and verapamil and the substrate Hoechst 33342, the binding affinity was very similar for the two states. The drug binding affinity of the ADP-bound form of the transporter was also comparable to that of the unoccupied transporter. These results suggest that release of drug from the transporter during the catalytic cycle precedes formation of the transition state.