Detection of P-glycoprotein in the nuclear envelope of multidrug resistant cells

P-glycoprotein is a plasma membrane efflux pump which is responsible for multidrug resistance of many cancer cell lines. A number of studies have demonstrated the presence of P-glycoprotein molecules, besides on the plasma membrane, also in intracellular sites, such as the Golgi apparatus and the nucleus. In this study, the presence and function of P-glycoprotein in the nuclear membranes of human breast cancer cells (MCF-7 WT) and their multidrug resistant variants (MCF-7 DX) were investigated. Electron and confocal microscopy immunolabelling experiments demonstrated the presence of P-glycoprotein molecules in the nuclear membranes of MCF-7 DX cells. Moreover, the labelling pattern was strongly dependent on pH values of the incubation buffer. At physiological pH (7.2), a strong labelling was detected in the cytoplasm and the nuclear matrix in both sensitive and resistant MCF-7 cells. By raising the pH to 8.0, the P-glycoprotein molecules were easily detected in the cytoplasm (transport vesicles and Golgi apparatus), plasma and nuclear membranes exclusively in MCF-7 DX cells. Furthermore, drug uptake and efflux studies, performed by flow cytometry on isolated nuclei in the presence of the P-glycoprotein inhibitor cyclosporin A, suggested the presence of a functional P-glycoprotein in the nuclear membrane, but not in the nuclear matrix, of drug resistant cells. Therefore, P-glycoprotein in the nuclear envelope seems to represent a further defense mechanism developed by resistant cells against antineoplastic agents.     

Spectroscopic and biophysical approaches for studying the structure and function of the P-glycoprotein multidrug transporter.

Multidrug resistance is a serious obstacle to the successful chemotherapeutic treatment of many human cancers. A major cause of multidrug resistance is the overexpression of a 170-kDa plasma membrane protein, known as P-glycoprotein, which appears to function as an ATP-driven efflux pump with a very broad specificity for hydrophobic drugs, peptides, and natural products. P-Glycoprotein is a member of the ABC superfamily and is proposed to consist of two homologous halves, each comprising six membrane-spanning segments and a cytosolic nucleotide binding domain. In recent years, P-glycoprotein has been purified and functionally reconstituted into lipid bilayers, where it retains both ATPase and drug transport activity. The availability of purified active protein has led to substantial advances in our understanding of the molecular structure and mechanism of action of this unique transporter. This review will focus on the recent application of fluorescence spectroscopy, infra-red spectroscopy, circular dichroism spectroscopy, electron microscopy, and other biophysical techniques to the study of P-glycoprotein structure and function.     

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.     

Purification of the 170- to 180-kilodalton membrane glycoprotein associated with multidrug resistance. 170- to 180-kilodalton membrane glycoprotein is an ATPase

170-180-kDa membrane glycoprotein (P-glycoprotein) associated with multidrug resistance is involved in drug transport mechanisms across the plasma membrane of resistant cells. From sequence analysis of cDNAs of the P-glycoprotein gene, it is postulated that the active drug-efflux pump function may be attributable to the protein. However, purification of the P-glycoprotein while preserving its enzymatic activity has not been reported. In this study, we have purified the P-glycoprotein from the human myelogenous leukemia K562 cell line resistant to adriamycin (K562/ADM) by means of one-step immunoaffinity chromatography using a monoclonal antibody against P-glycoprotein. The procedure was simple and efficiently yielded an electrophoretically homogeneous P-glycoprotein sample. By solubilization with 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate, the purified P-glycoprotein was found to have ATPase activity. This ATP hydrolysis may be coupled with the active efflux of anticancer drugs across the plasma membrane of multidrug-resistant cells.     

Differing patterns of cross-resistance resulting from exposures to specific antitumour drugs or to radiationin vitro

This article revies the patterns of cross-resistance identified in various P-glycoprotein-mediated and non-P-glycoprotein-mediated drug resistant mammalian tumour cell lines. The differing patterns of cross-resistance and the variable levels of resistance expressed are summarised and discussed. Although the mechanism by which P-glycoprotein can recognise and transport a large group of structurally-unrelated substrates remains to be defined, the recent evidence indicating that membrane associated domains participate in substrate recognition and binding is summarised, and other possible explanations for these variable cross-resistance patterns are considered. Amongst the non-P-glycoprotein-overexpressing multidrug resistant cell lines, two subsets are clearly identifiable, one lacking and the other expressing cross-resistance to the Vinca alkaloids. Resistance mechanisms implicated in these various sublines and possible explanations for their differing levels and patterns of cross-resistance are summarised.Clinical resistance is identified in patients following treatment not only with antitumour drugs, but also after radiotherapy. Experimental data providing a biological basis for this observation are summarised. A distinctive multiple drug resistance phenotype has been identified in tumour cells following exposurein vitro to fractionated X-irradiation characterised by: the expression of resistance to the Vinca alkaloids and the epipodophyllotoxins but not the anthracyclines and overexpression of P-glycoprotein which is post-translationally regulated, but without any concomitant overexpression of P-glycoprotein mRNA.Finally, the possible clinical relevance of these variable patterns of cross-resistance to the antitumour drugs commonly used in the clinic is considered.     

Adriamycin resistance in HL60 cells in the absence of detectable P-glycoprotein

Previous studies have shown that the development of multi-drug resistance in cell lines treated with chemotherapeutic agents is closely associated with the overexpression of a 170-180 kilodalton surface membrane glycoprotein (P-glycoprotein). In the present study a monoclonal antibody against the P-glycoprotein was used to determine if this protein is overexpressed in multi-drug resistant HL60 cells. Using either indirect immunofluorescent staining or immunoblot analysis P-glycoprotein could not be detected in HL60 cells isolated for resistance to adriamycin. In contrast HL60 cells isolated for resistance to vincristine contain the P-glycoprotein and the amount of this material increases with increasing levels of resistance. These studies thus demonstrate adriamycin resistance in P-glycoprotein negative HL60 cells. Furthermore adriamycin and vincristine are found to have distinct effects in inducing overexpression of P-glycoprotein in the HL60 cell line. This information could be useful in the development of therapeutic strategies for the treatment of certain forms of cancer.     

Characterization of a membrane-associated protein kinase of multidrug-resistant HL60 cells which phosphorylates P-glycoprotein

Cells containing increased levels of the membrane phosphoprotein P-glycoprotein exhibit a multidrug-resistant phenotype. In the present study we have analyzed protein kinases capable of phosphorylating P-glycoprotein in membranes of HL60 cells isolated for resistance to vincristine. Analysis of this system demonstrates that in isolated membranes the protein kinase inhibitor staurosporine greatly reduces P-glycoprotein phosphorylation. In contrast, the kinase inhibitor H-7 does not affect this reaction. Fractionation of solubilized membrane proteins from sensitive and resistant cells on DEAE-cellulose reveals a major protein kinase (PK-1) which exhibits optimal activity in the presence of Mn2+ and histone H1. This enzyme fraction does not contain detectable levels of protein kinase C or cAMP-dependent protein kinase. PK-1 phosphorylation of two endogenous proteins is, however, greatly enhanced in the presence of phosphatidylserine or phosphatidyl-inositol. In reaction mixtures containing Mg2+ or Mn2+ in the absence of phospholipid, PK-1 from resistant cells phosphorylates an endogenous protein of 180 kilodaltons (P180), which exhibits an electrophoretic mobility identical to P-glycoprotein. In parallel experiments with PK-1 from sensitive cells there is no detectable phosphorylation of a P180 protein. P180 phosphorylated by PK-1 from resistant cells is immunoprecipitated by antibody against P-glycoprotein. Additional studies demonstrate that PK-1 is capable of phosphorylating specific synthetic peptides which correspond to the sequence of P-glycoprotein. Peptide phosphorylation occurs at both serine and threonine residues. These studies thus identify a novel membrane-associated protein kinase in HL60 cells which is capable of phosphorylating P-glycoprotein. This enzyme may have an important role in regulating levels of multidrug resistance.     

Detection of P-glycoprotein in human leukemias using monoclonal antibodies

Overexpression of a Mr 170,000 membrane glycoprotein (P-glycoprotein) is consistently associated with multidrug resistance in cell lines. Two monoclonal antibodies (Mab) against P-glycoprotein (265/F4 and C 219) were used to examine tumour samples from patients with leukemias for evidence of P-glycoprotein overexpression. High levels of P-glycoprotein (greater than 5% positive cells) were detected with both antibodies in samples from 3 out of 18 patients suggesting that a multidrug resistant phenotype may also occur in human leukemias.     

Molecular basis of multidrug transport by ATP-binding cassette transporters: a proposed two-cylinder engine model

ATP-binding cassette multidrug transporters are probably present in all living cells, and are able to export a variety of structurally unrelated compounds at the expense of ATP hydrolysis. The elevated expression of these proteins in multidrug resistant cells interferes with the drug-based control of cancers and infectious pathogenic microorganisms. Multidrug transporters interact directly with the drug substrates. Insights into the structural elements in drug molecules and transport proteins that are required for this interaction are now beginning to emerge. However, much remains to be learned about the nature and number of drug binding sites in the transporters, and the mechanism(s) by which ATP hydrolysis is coupled to changes in affinity and/or accessibility of drug binding sites. This review summarizes recent advances in answering these questions for the human multidrug resistance P-glycoprotein and its prokaryotic homolog LmrA. The relevance of these findings for other ATP-binding cassette transporters will be discussed.     

Molecular analysis of the multidrug transporter, P-glycoprotein

Inherent or acquired resistance of tumor cells to cytotoxic drugs represents a major limitation to the successful chemotherapeutic treatment of cancer. During the past three decades dramatic progress has been made in the understanding of the molecular basis of this phenomenon. Analyses of drug-selected tumor cells which exhibit simultaneous resistance to structurally unrelated anti-cancer drugs have led to the discovery of the human MDR1 gene product, P-glycoprotein, as one of the mechanisms responsible for multidrug resistance. Overexpression of this 170 kDa N-glycosylated plasma membrane protein in mammalian cells has been associated with ATP-dependent reduced drug accumulation, suggesting that P-glycoprotein may act as an energy-dependent drug efflux pump. P-glycoprotein consists of two highly homologous halves each of which contains a transmembrane domain and an ATP binding fold. This overall architecture is characteristic for members of the ATP-binding cassette or ABC superfamily of transporters. Cell biological, molecular genetic and biochemical approaches have been used for structure-function studies of P-glycoprotein and analysis of its mechanism of action. This review summarizes the current status of knowledge on the domain organization, topology and higher order structure of P-glycoprotein, the location of drug- and ATP binding sites within P-glycoprotein, its ATPase and drug transport activities, its possible functions as an ion channel, ATP channel and lipid transporter, its potential role in cholesterol biosynthesis, and the effects of phosphorylation on P-glycoprotein activity. This revised version was published online in August 2006 with corrections to the Cover Date.     

P-glycoprotein structure and evolutionary homologies

Analysis of multidrug resistant cell lines has led to the identification of the P-glycoprotein multigene family. Two of the three classes of mammalian P-glycoproteins have the ability to confer cellular resistance to a broad range of structurally and functionally diverse cytotoxic agents. P-glycoproteins are integral membrane glycoproteins comprised of two similar halves, each consisting of six membrane spanning domains followed by a cytoplasmic domain which includes a nucleotide binding fold. The P-glycoprotein is a member of a large superfamily of transport proteins which utilize ATP to translocate a wide range of substrates across biological membranes. This superfamily includes transport complexes comprised of multicomponent systems, half P-glycoproteins and P-glycoprotein-like homologs which appear to require approximately 12 α-helical transmembrane domains and two nucleotide binding folds for substrate transport. P-glycoprotein homologs have been isolated and characterized from a wide range of species. Amino acid sequences, the similarities between the halves and intron/exon boundaries have been compared to understand the evolutionary origins of the P-glycoprotein. This revised version was published online in August 2006 with corrections to the Cover Date.     

The multi-structural feature of the multidrug resistance gene product P-glycoprotein: implications for its mechanism of action

P-glycoprotein is a member of the ATP-binding cassette (ABC) transport superfamily. It plays an important role in the development of multidrug resistance in cancers by effluxing a wide variety of anticancer drugs. A large amount of information on the structure and function of P-glycoprotein has been accumulated over recent years from studies using molecular, biochemical, and biophysical approaches. It remains unclear, however, how this protein folds in membranes and how it transports such a wide variety of hydrophobic compounds. This paper highlights the recent progress in the structural and biogenesis aspects of P-glycoprotein. A model mechanism of P-glycoprotein action is proposed as a hypothesis that is based on recent progress in studying the topological folding of P-glycoprotein.     

The multi-structural feature of the multidrug resistance gene product P-glycoprotein: implications for its mechanism of action (hypothesis).

P-glycoprotein is a member of the ATP-binding cassette (ABC) transport superfamily. It plays an important role in the development of multidrug resistance in cancers by effluxing a wide variety of anticancer drugs. A large amount of information on the structure and function of P-glycoprotein has been accumulated over recent years from studies using molecular, biochemical, and biophysical approaches. It remains unclear, however, how this protein folds in membranes and how it transports such a wide variety of hydrophobic compounds. This paper highlights the recent progress in the structural and biogenesis aspects of P-glycoprotein. A model mechanism of P-glycoprotein action is proposed as a hypothesis that is based on recent progress in studying the topological folding of P-glycoprotein.     

Identification of P-glycoprotein in renal brush border membranes

A monoclonal antibody (C219) that recognizes the P-glycoprotein (Mr = 170,000) in plasma membranes of multidrug-resistant Chinese hamster ovary (CHO) cell lines was used to assay renal brush border membrane (BBM) and basolateral membrane (BLM) fractions for the presence of a cross-reactive polypeptide. The C219 antibody bound to a 155,000 dalton protein in immunoblots of rat BBM but not BLM proteins resolved by sodium dodecyl sulfate gel electrophoresis. The corresponding human kidney BBM and dog kidney BBM proteins had molecular weights of 170,000 and 160,000 respectively. The glycoprotein nature of the renal protein was shown by its sensitivity to N-glycanase treatment which reduced the apparent molecular weight of the dog protein to 120,000. In addition, dog P-glycoprotein could be bound to and eluted from immobilized wheat germ agglutinin. The molecular weight, antibody crossreactivity, glycosidase sensitivity and lectin binding show that this protein is a normal kidney analogue of the P-glycoprotein induced in multidrug resistant cell lines.     

Molecular analysis of the multidrug transporter

The multidrug resistance gene product, P-glycoprotein or the multidrug transporter, confers multidrug resistance to cancer cells by maintaining intracellular levels of cytotoxic agents below a killing threshold. P-glycoprotein is located within the plasma membrane and is thought to act as an energy-dependent drug efflux pump. The multidrug transporter represents a member of the ATP-binding cassette superfamily of transporters (or traffic ATPases) and is composed of two highly homologous halves, each of which harbors a hydrophobic transmembrane domain and a hydrophilic ATP-binding fold. This review focuses on various biochemical and molecular genetic approaches used to analyze the structure, function, and mechanism of action of the multidrug transporter, whose most intriguing feature is its ability to interact with a large number of structurally and functionally different amphiphilic compounds. These studies have underscored the complexity of this membrane protein which has recently been suggested to assume alternative topological and quaternary structures, and to serve multiple functions both as a transporter and as a channel. With respect to the multidrug transporter activity of P-glycoprotein, progress has been made towards the elucidation of essential amino acid residues and/or polypeptide regions. Furthermore, the drug-stimulatable ATPase activity of P-glycoprotein has been established. The mechanism of drug transport by P-glycoprotein, however, is still unknown and its physiological role remains a matter of speculation.     

Expression of a human multidrug resistance cDNA (MDR1) in the bone marrow of transgenic mice: resistance to daunomycin-induced leukopenia.

The human multidrug resistance gene (MDR1) encodes a drug efflux pump glycoprotein (P-glycoprotein) responsible for resistance to multiple cytotoxic drugs. A plasmid carrying a human MDR1 cDNA under the control of a chicken beta-actin promoter was used to generate transgenic mice in which the transgene was mainly expressed in bone marrow and spleen. Immunofluorescence localization studies showed that P-glycoprotein was present on bone marrow cells. Furthermore, leukocyte counts of the transgenic mice treated with daunomycin did not fall, indicating that their bone marrow was resistant to the cytotoxic effect of the drug. Since bone marrow suppression is a major limitation to chemotherapy, these transgenic mice should serve as a model to determine whether higher doses of drugs can cure previously unresponsive cancers.     

Functional expression of human P-glycoprotein in Schizosaccharomyces pombe

Human MDR1 cDNA was introduced into the human cultured cells KB-3-1 and Schizosaccharomyces pombe pmdI null mutant KN3. The drug sensitivity of KB-G2 and KN3/pgp, expressing human P-glycoprotein, was examined. KB-G2 was resistant to the peptide antibiotics valinomycin and gramicidin D as well as having a typical multidrug resistance (MDR) phenotype. KN3/pgp was resistant to valinomycin and actinomycin D, but not to adriamycin. The ATP-hydrolysis-deficient mutant did not confer KN3 resistance to these antibiotics. Human P-glycoprotein expressed in S. pombe seemed to lack N-glycosylation. The N-glycosylation-deficient mutant, however, conferred a typical MDR phenotype on KB-3-1. These results suggest that human P-glycoprotein functions as an efflux pump of valinomycin and actinomycin D in the membrane of S. pombe.     

Evaluation of P-glycoprotein expression in soft tissue sarcomas of the extremities

Soft tissue sarcomas comprise a heterogeneous group of mesenchymal tumors accounting for less than one-percent of adult neoplasms. In the last few years, the use of adjuvant chemotorapy has been proposed for the treatment of these lesions in order to obain a better systemic control, but its usefulness is still controversial. In this study, we evaluated whether P-glycoprotein, a membrane protein strictly associated with multidrug resistance, is overexpressed in soft tissue sarcomas. By using human multidrug resistant sarcoma cell lines as controls, we analyzed P-glycoprotein expression in 34 primary and in 23 relapsed soft tissue sarcomas of the extremities. Overexpression of P-glycoprotein was found in 6 out of 34 primaries (18%) and in 8 out of 23 relapses (35%). In particular, in malignant fibrous histiocytoma, the most frequent soft tissue sarcoma of adults, P-glycoprotein overexpression was found in 23% of primary untreated cases, in agreement with the reported relapse rate of this tumor after surgery and chemotherapy. These data suggest that, in soft tissue sarcomas, overexpression of P-glycoprotein may be of prognostic value and that the assessment of P-glycoprotein expression may be useful for the design of chemotherapy protocols.Abbreviations MDR multidrug-resistance - STS soft tissue sarcomas     

Interaction of transported drugs with the lipid bilayer and P-glycoprotein through a solvation exchange mechanism

Broad substrate specificity of human P-glycoprotein (ABCB1) is an essential feature of multidrug resistance. Transport substrates of P-glycoprotein are mostly hydrophobic and many of them have net positive charge. These compounds partition into the membrane. Utilizing the energy of ATP hydrolysis, P-glycoprotein is thought to take up substrates from the cytoplasmic leaflet of the plasma membrane and to transport them to the outside of the cell. We examined this model by molecular dynamics simulation of the lipid bilayer, in the presence of transport substrates together with an atomic resolution structural model of P-glycoprotein. Taken together with previous electron paramagnetic resonance studies, the results suggest that most transported drugs are concentrated near the surface zone of the inner leaflet of the plasma membrane. Here the drugs can easily diffuse laterally into the drug-binding site of P-glycoprotein through an open cleft. It was concluded that the initial high-affinity drug-binding site was located in the interfacial surface area of P-glycoprotein in contact with the membrane interface. Based on these results and our recent kinetic studies, a “solvation exchange” drug transport mechanism of P-glycoprotein is discussed. A molecular basis for the improved colchicine transport efficiency by the much-studied colchicine-resistance G185V mutant human P-glycoprotein is also provided.     

The mdr1 gene, responsible for multidrug-resistance, codes for P-glycoprotein

The development of simultaneous resistance to multiple drugs in cultured cells occurs after selection for resistance to single agents. This multidrug-resistance phenotype is thought to mimic multidrug-resistance in human tumors treated with chemotherapy. Both the expression of a membrane protein, termed P170 or P-glycoprotein, and the expression of a cloned DNA fragment, termed mdr1, have been shown independently to be associated with multidrug-resistance in cultured cells. In this work, we show that human KB carcinoma cells which express the mdr1 gene also express P-glycoprotein, and that cDNAs encoding P-glycoprotein cross-hybridize with mdr1 cDNAs. Thus, the mdr1 gene codes for P-glycoprotein.