EC:3.6.3.44 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.6.3.44 (P-glycoprotein)
13,344 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

MRP is a member of the ABC trafficking proteins thought to mediate the transport of glutathione S-conjugates and amphiphilic natural products. However, unlike P-glycoprotein, the biochemical mechanism by which MRP mediates the resistance to cytotoxic drugs is not clear. In this report, we describe the interactions of a quinoline-based drug, N-{4-[1-hydroxy-2-(dibutylamino)ethyl] quinolin-8-yl}-4-azidosalicylamide (IAAQ), with MRP. Our results demonstrate the ability of IAAQ to photoaffinity label a 190 kDa protein in resistant Small Cell Lung Cancer cells (H69/AR) but not in the parental H69 cells. The photoaffinity labeling of the 190 kDa protein with IAAQ was both saturable and specific. The identity of the 190 kDa protein, as MRP, was confirmed by immunoprecipitation with the monoclonal antibody, QCRL-1. Furthermore, a molar excess of LTC4, MK 571 or vinblastine inhibited the photoaffinity labeling of MRP with IAAQ in intact cells and plasma membranes. Cell growth and drug transport studies showed H69/AR cells to be less sensitive to and to accumulate less IAAQ than the parental H69 cells. In addition, MK 571 and doxorubicin increased the sensitivity to and the accumulation of IAAQ in H69/AR cells. Together, the results of this study show for the first time the direct binding of unaltered cytotoxic drug to MRP. Moreover, given the structural similarities between IAAQ and MK 571, we suggest that MK 571 modulates MRP-mediated resistance by direct binding to MRP.
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PMID:The quinoline-based drug, N-[4-[1-hydroxy-2-(dibutylamino)ethyl] quinolin-8-yl]-4-azidosalicylamide, photoaffinity labels the multidrug resistance protein (MRP) at a biologically relevant site. 940 41

A variety of cellular mechanisms of multidrug resistance (MDR) have been identified in human drug-resistant cell lines, and may play an important role in the clinical response of hematologic malignancies to chemotherapy. P-glycoprotein (P-gp)-mediated drug efflux is the most well-characterized cellular mechanism of MDR; however, several other non-P-gp membrane transporter proteins have also been implicated in the development of an MDR phenotype in hematologic malignancies. These include the MDR-related protein (MRP), the lung-resistance protein (LRP), and the transporter of antigenic peptides (TAP). The transporter proteins MRP and TAP are both members of the adenosine triphosphate (ATP)-binding cassette (ABC) family of transmembrane transporters, but each has distinct differences in substrate specificity. Despite effective modulation of P-gp, one or more of these alternate mechanisms of drug resistance may contribute to an MDR phenotype in tumor cell lines. Development of multifunctional MDR modulators or novel therapeutics may be necessary to effectively circumvent MDR in hematologic malignancies.
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PMID:Non-P-glycoprotein drug export mechanisms of multidrug resistance. 940 57

In order to elucidate the mechanism by which the multidrug resistance P-glycoprotein extrudes cytotoxic drugs from the cell, and particularly the number and nature of the drug binding site(s), knowledge of the structure of P-gp is essential. A considerable body of genetic and biochemical data has accrued which gives insights into P-gp structure and function. These data are critically reviewed, particularly in relation to the low resolution structure of P-gp which has recently been determined by electron microscopy. P-gp is one of the best characterised of the ABC transporters and these structure-function studies may have more general implications.
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PMID:Structure of the multidrug resistance P-glycoprotein. 944 43

P-glycoprotein and CFTR are prominent members of the ABC Transporter family. Both use ATP, the former to drive extrusion of drugs from cells and confer multidrug-resistance, the latter to drive opening and closing of anion channels. We compare current working models of catalytic cycle and mechanism of the two proteins. In Pgp the NBDs appear functionally equivalent, in CFTR they appear functionally distinct. In both proteins, ATP hydrolysis occurs in both NBDs, and it is proposed that the two NBDs alternate in catalysis. Other differences and similarities are noted, fostering ideas for future developments.
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PMID:ATP hydrolysis cycles and mechanism in P-glycoprotein and CFTR. 944 44

The response of T cells in relation to the cell cycle has not been extensively studied. We have attempted to address this question using Jurkat T cells treated with cytostatic drugs known to arrest cells at various transition points of their cycle. We tested several concentrations of drugs that act at G1/S (hydroxyurea, lovastatin, thymidine), early S (aphidicolin, cyclosporin A, rapamycin) or G2+M (colchicine, nocodazole) in 24 h cultures. Cytofluorimetric analyses showed that cycling Jurkat cells were equally distributed between the G1 (44.9 +/- 6.5%) and S (42.3 +/- 8.0%) phases. Cell distribution in G2+M was 12.7 +/- 2.8%. Hydroxyurea but not lovastatin increased the percentage of cells in S phase to approximately 60-70% and both drugs decreased it to approximately 30% in G1. Thymidine had no effects. Aphidicolin increased the distribution in S phase to approximately 70% with a decrease in G1 to approximately 30%. Cyclosporin A and rapamycin increased the percentage of the cells in G1 to approximately 70% and decreased it to approximately 25% in S phase. Nocodazole increased cell distribution in G2+M to approximately 60% and induced a decrease in G1 to approximately 10%. The effects of the drugs were not related to their toxicity and their limited efficiency raised the possibility that Jurkat cells possessed an intrinsic resistance to these xenobiotics. Time-course analysis showed (scanning electron microscopy) that the early morphological changes induced by colchicine were reversible. Drug efflux experiments (vinblastine) suggested that an ATP-dependent process could be involved. However, Northern blot analyses showed a weak signal for MDR1 (P-glycoprotein). In contrast, a probe for MRP (P-190) showed a strong signal in Jurkat and peripheral lymphocytes. The presence of drugs (cyclosporin A, nocodazole, thymidine) (24 h) did not upregulate its message and cell treatment with DL-butathione (S,R)-sulfoximine only moderately affected the efficiency of the glutathione S-conjugate MRP transporter. Our data suggest that the intrinsic multidrug resistance of leukemic Jurkat T cells does not appear to involve the MDR1 and MRP members of the ABC family of reverse drug transporters and these observations raise the possibility of the involvement of multifaceted mechanisms.
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PMID:The MDR1 (P-glycoprotein) and MRP (P-190) transporters do not play a major role in the intrinsic multiple drug resistance of Jurkat T lymphocytes. 944 42

ABC transporters are key players in the multidrug resistance of cancer cells and yeast, and they appear to be involved in the drug resistance of various pathogenic protozoa. No member of this ubiquitous protein family has yet been described in Trypanosoma brucei spp., the causative agents of African sleeping sickness and animal trypanosomiases. However, different cases of artificially induced drug resistance were shown to be linked to a reduction in net drug uptake. We used polymerase chain reaction with degenerate oligonucleotide primers corresponding to particularly conserved regions within the ATP-binding cassette to probe the genome of T. brucei spp. for the presence of ABC transporter genes. Three different sequence segments encoding ATP-binding cassettes were identified, which, upon Southern blotting, appeared to belong to distinct genes designated Tbabc1, Tbabc2, and Tbabc3. They appear to be single-copy genes in both drug-susceptible and drug-resistant stocks of T. brucei spp., expressed in bloodstream forms as well as in the procyclic life stage. Whereas Tbabc3 shows moderate homology to various known ABC transporters, Tbabc1 and Tbabc2 are highly homologous to P-glycoprotein A of Leishmania tarentolae and to the multidrug resistance protein 1 of L. donovani, respectively.
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PMID:Identification of three ABC transporter genes in Trypanosoma brucei spp. 949 8

ABC transporters are a large superfamily of integral membrane proteins involved inATP-dependent transport across biological membranes. Members of this superfamily play roles in a number of phenomena of biomedical interest, including cystic fibrosis (CFTR) and multidrug resistance (P-glycoprotein, MRP). Most ABC transporters are predicted to consist of four domains, two membrane-spanning domains and two cytoplasmic domains. The latter contain conserved nucleotide-binding motifs. Attempts to determine the structure of ABC transporters and of their separate domains are in progress but have not yet been successful. To aid structure determination and possibly learn more about the domain boundaries, we set out to model nucleotide-binding domains (NBDs) of ABC transporters based on a known structure. Previous attempts to predict the 3D structure of NBDs were based solely on sequence similarity with known nucleotide-binding folds. We have analyzed the sequences of a number of nucleotide-binding domains with the algorithm THREADER, developed by D.T. Jones, and a possible fold was found in the structure of aspartate aminotransferase. We present a model for the N-terminal NBD of CFTR, based on the large domain of the A chain of aspartate aminotransferase. The model is refined using multiple sequence alignment, secondary structure prediction, and 3D-1D profiles. Our model seems to be in good agreement with known properties of nucleotide-binding domains and has some appealing characteristics compared with the previous models.
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PMID:A model for the nucleotide-binding domains of ABC transporters based on the large domain of aspartate aminotransferase. 951 43

The role of individual intracellular (IC) loops linking transmembrane (TM) domains in P-glycoprotein (P-gp) function remains largely unknown. The high degree of sequence conservation of these regions in the P-gp family and other ABC transporters suggests an important role in a common mechanism of action of these proteins. To gain insight into this problem, we have randomly mutagenized a portion of TM2, the entire IC1 loop, TM3, the entire extracellular loop (EC2), and part of TM4, and analyzed the effect of such mutations on P-gp function. Random mutagenesis was carried out using Taq DNA polymerase and dITP under conditions of low polymerase fidelity, and the mutagenized segments were reintroduced in the full length mdr3 cDNA by homologous recombination in the yeast Saccharomyces cerevisiae strain JPY201. The biological activity of mutant P-gp variants was analyzed in yeast by their ability to confer cellular resistance to the antifungal drug FK506 and the peptide ionophore valinomycin, and by their ability to complement the yeast Ste6 gene and restore mating in a yeast strain bearing a null mutation [Raymond, M., et al. (1992) Science 256, 232-4] at this locus. The analysis of 782 independent yeast transformants allowed the identification of 49 independent mutants bearing single amino acid substitutions in the mutagenized segment resulting in an altered P-gp function. The mutants could be phenotypically classified into two major groups, those that resulted in partial or complete overall loss of function and those that seemed to affect substrate specificity. Several of the mutants affecting overall activity mapped in IC1; in particular we identified a segment of four consecutive mutation sensitive residues (TRLT, positions 169-172) with such a phenotype. On the other hand, we identified a cluster of mutants affecting substrate specificity within the short EC2 segment and in the adjacent portion of the neighboring TM4 domain. Expression and partial purification of a representative subset of these mutants showed that in all but two cases, loss of function was associated with loss of drug-induced ATPase activity of P-gp. Therefore, it appears that TM domains, IC and EC loops, are structurally and functionally tightly coupled in the process of drug stimulatable ATPase characteristic of P-gp.
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PMID:Mutational analysis of the P-glycoprotein first intracellular loop and flanking transmembrane domains. 952 54

One cause of multidrug resistance (MDR) in human cancers is the overexpression of the P-glycoprotein multidrug transporter, a member of the ABC superfamily of membrane proteins. Natural products and chemotherapeutic drugs are pumped out of the cell by P-glycoprotein in an ATP-dependent fashion. There is growing evidence that many hydrophobic peptides are also P-glycoprotein substrates. With the use of a fluorescence-quenching assay, we have shown that some linear and cyclic hydrophobic peptides interact with P-glycoprotein, whereas others do not. The measured values of the quenching constant, Kq, for interaction of peptides with P-glycoprotein ranged from 200 nM for cyclosporine A to 138 microM for the tripeptide N-acetyl-leucyl-leucyl-norleucinal. Peptides that interacted with P-glycoprotein in the fluorescence assay also blocked colchicine transport into plasma membrane vesicles from MDR cells. The values of Dm, the peptide concentration causing 50% inhibition of drug uptake, were highly correlated with the values of Kq, over three orders of magnitude. The P-glycoprotein ATPase stimulation/inhibition profile of the peptides was not helpful in making a quantitative assessment of the ability of a peptide to interact with P-glycoprotein or to block drug transport. Some hydrophobic peptides were able to restore accumulation in MDR cells of the chemotherapeutic drug daunorubicin and the fluorescent dye rhodamine 123 to the levels observed in the drug-sensitive parent. Peptides that interacted with P-glycoprotein also displayed a relatively low overall toxicity to intact MDR cells, and inhibited drug transport at concentrations below the toxic range. Hydrophobic peptides should be given serious consideration for development as clinical chemosensitizing agents.
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PMID:Linear and cyclic peptides as substrates and modulators of P-glycoprotein: peptide binding and effects on drug transport and accumulation. 967 21

We have developed two defined experimental systems for biochemical investigation of P-glycoprotein, namely, plasma membranes highly enriched in Pgp, obtained from the CR1R12 Chinese hamster ovary cell line, and pure, reconstituted Pgp, obtained by solubilization of Pgp from CR1R12 plasma membranes, Reactive Red 120 chromatography, and reconstitution in liposomes. Studies of the ATPase catalytic mechanism by kinetic methods and covalent inactivation have been greatly facilitated by the availability of these experimental systems. The technique of vanadate trapping of nucleotide has been particularly useful. As a result of these studies, we now have explicit, testable, proposals for (1) the normal catalytic pathway of ATP hydrolysis, (2) a postulated alternating catalytic site cycle, and (3) coupling of ATP hydrolysis to drug transport. The experimental methods described here should prove valuable for future studies of Pgp and of ABC transporters in general.
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PMID:ATPase activity of Chinese hamster P-glycoprotein. 971 79

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