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)

The prokaryotic hlyB gene product is a member of a superfamily of ATP-binding transport proteins that include the eukaryotic multidrug-resistance P-glycoprotein, the yeast STE6, and the cystic fibrosis CFTR gene products (Juranka, P. F., Zastawny, R. L., and Ling, V. (1989) FASEB J. 3, 2583-2592). Previous genetic studies have indicated that HlyB is involved in the transport of the 107-kDa HlyA protein from Escherichia coli; however, the HlyB protein has not been purified for biochemical studies due to its low abundance. In this study, we have engineered a monoclonal antibody epitope into the C-terminal end of HlyB that did not destroy its function. This has allowed us to use immunological methods to identify and localize various molecular forms of the HlyB protein present in vivo.
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PMID:Characterization of the hemolysin transporter, HlyB, using an epitope insertion. 137 Dec 77

Expression of P-glycoprotein, the product of the MDR1 gene, confers multidrug resistance on cell lines and human tumours (reviewed in refs 1,2). P-glycoprotein (relative molecular mass 170,000) is an ATP-dependent, active transporter which pumps hydrophobic drugs out of cells, but its normal physiological role is unknown. It is a member of the ABC (ATP-binding cassette) superfamily of transporters, which includes many bacterial transport systems, the putative peptide transporter from the major histocompatibility locus, and the product of the cystic fibrosis gene (the cystic fibrosis transmembrane regulator, CFTR). CFTR is located in the apical membranes of many secretory epithelia and is associated with a cyclic AMP-regulated chloride channel. At least two other chloride channels are present in epithelial cells, regulated by cell volume and by intracellular Ca2+, respectively. Because of the structural and sequence similarities between P-glycoprotein and CFTR, and because P-glycoprotein is abundant in many secretory epithelia, we examined whether P-glycoprotein might be associated with one or other of these channels. We report here that expression of P-glycoprotein generates volume-regulated, ATP-dependent, chloride-selective channels, with properties similar to channels characterized previously in epithelial cells.
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PMID:Volume-regulated chloride channels associated with the human multidrug-resistance P-glycoprotein. 137 98

The traffic ATPases superfamily includes known transporters, both prokaryotic and eukaryotic, including the medically important proteins, P-glycoprotein, and the cystic fibrosis gene product (CFTR), which is known to be a Cl- channel. The structure and mechanism of action of the best-studied members of the superfamily, the periplasmic permeases, are described and related to that of CFTR and eukaryotic traffic ATPases in general. The contention is put forward that the distinction between the architecture and mechanisms of action of channels and transporters is blurred.
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PMID:ATP-dependent bacterial transporters and cystic fibrosis: analogy between channels and transporters. 137 40

The human multidrug resistance P-glycoprotein is an active transporter that pumps cytotoxic drugs out of cells. Expression of P-glycoprotein is also associated with a volume-activated chloride channel. Here we address the relationship between these two functions. Drug transport requires ATP hydrolysis while, in contrast, ATP binding is sufficient to enable activation of the chloride channel. The chloride channel and drug transport activities of P-glycoprotein appear to reflect two distinct functional states of the protein that can be interconverted by changes in tonicity. Transportable drugs prevent channel activation but have no effect on channel activity once it has been preactivated by hypotonicity. The transport and channel functions of P-glycoprotein have been separated by directed mutations in the nucleotide-binding domains of the protein. These data provide further evidence that P-glycoprotein is bifunctional with both transport and channel activities. Implications for the design of chemotherapeutic drugs and for the function of the related cystic fibrosis gene product, CFTR, are discussed.
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PMID:Separation of drug transport and chloride channel functions of the human multidrug resistance P-glycoprotein. 138 60

The cystic fibrosis gene product, CFTR, and the multidrug resistance P-glycoprotein (encoded by the MDR1 gene) are structurally related proteins and both are associated with epithelial chloride channel activities. We have compared their cell-specific expression in the rat by in situ hybridization. In all tissues examined the two genes were found to have complementary patterns of expression, demonstrating exquisite regulation in both cell-specific and temporal fashions. Additionally, a switch in expression from one gene to the other was observed in certain tissues. For example, expression in the intestine switches from CFTR to MDR1 as the cells migrate across the crypt-villus boundary. A switch from CFTR to MDR1 expression was also observed in the uterine epithelium upon pregnancy. These data suggest that CFTR and P-glycoprotein serve analogous roles in epithelial cells and provide additional evidence that P-glycoprotein has a physiological role in regulating epithelial cell volume. The patterns of expression suggest that the regulation of these two genes is coordinately controlled.
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PMID:The multidrug resistance and cystic fibrosis genes have complementary patterns of epithelial expression. 138 12

In this review, we will emphasize the role of ATP-dependent membrane transporters in protein export and intracellular protein trafficking in prokaryotic and eukaryotic cells. ATP-binding-cassette (ABC)-transport proteins, also termed "traffic ATPases," belong to a superfamily of ubiquitous ATP-driven membrane transporters that share extensive sequence similarity and highly conserved domain organization. They are implicated in a remarkable variety of transmembrane transport processes, including the transport of ions, heavy metals, sugars, anticancer drugs, amino acids, oligopeptides, and proteins. Bacterial ABC-proteins include the well-characterized periplasmic permeases involved in nutrient uptake, but also include protein secretion systems, such as the exporter for the Escherichia coli enterotoxin hemolysin A. Prominent eukaryotic members of this superfamily include the human P-glycoprotein (which is associated with the phenomenon of multiple drug resistance in tumor cells), the product of the cystic fibrosis gene (CFTR), the gene (pfmdr) implicated in chloroquine resistance of the malarial parasite, putative peptide transporters encoded at the locus for the class II major histocompatibility complex (MHC), and the yeast Ste6 transporter which mediates export of a peptide hormone that lacks a classical hydrophobic signal peptide. The well-established function of prokaryotic ABC-transporters in the secretion of proteins without typical signal sequences, and the example set by the Ste6 transporter, have led to the reasonable hypothesis that certain ABC-proteins in animal cells may be operating by a similar mechanism to mediate the export of a new class of secretory proteins, those lacking a classical hydrophobic signal peptide.
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PMID:Secretion of peptides and proteins lacking hydrophobic signal sequences: the role of adenosine triphosphate-driven membrane translocators. 142 85

The ATP-binding cassette (ABC) superfamily of transport systems now includes over thirty proteins that share extensive sequence similarity and domain organization. This superfamily includes the well characterized periplasmic binding protein-dependent uptake systems of prokaryotes, bacterial exporters, and eukaryotic proteins including the P-glycoprotein associated with multidrug resistance in tumours (MDR), the STE6 gene product that mediates export of yeast a-factor mating pheromone, pfMDR that is implicated in chloroquine resistance of the malarial parasite, and the product of the cystic fibrosis gene (CFTR). Here we present a tertiary structure model of the ATP-binding cassettes characteristic of this class of transport system, based on similarities between the predicted secondary structures of members of this family and the previously determined structure of adenylate kinase. This model has implications for both the molecular basis of transport and cystic fibrosis and provides a framework for further experimentation.
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PMID:Structural model of ATP-binding proteins associated with cystic fibrosis, multidrug resistance and bacterial transport. 237 3

The maltose transport system of Escherichia coli is a well-characterized member of the ATP binding cassette transporter superfamily. Members of this family share sequence similarity surrounding two short sequences (the Walker A and B sequences) which constitute a nucleotide binding pocket. It is likely that the energy from binding and hydrolysis of ATP is used to accomplish the translocation of substrate from one location to another. Periplasmic binding protein-dependent transport systems, like the maltose transport system of E.coli, possess a water-soluble ligand binding protein that is essential for transport activity. In addition to delivering ligand to the membrane-bound components of the system on the external face of the membrane, the interaction of the binding protein with the membrane complex initiates a signal that is transmitted to the ATP binding subunit on the cytosolic side and stimulates its hydrolytic activity. Mutations that alter the membrane complex so that it transports independently of the periplasmic binding protein also result in constitutive activation of the ATPase. Genetic analysis indicates that, in general, two mutations are required for binding protein-independent transport and constitutive ATPase. The mutations alter residues that cluster to specific regions within the membrane spanning segments of the integral membrane components MalF and MalG. Individually, the mutations perturb the ability of MBP to interact productively with the membrane complex. Genetic alteration of this signalling pathway suggests that other agents might have similar effects. These could be potentially useful for modulating the activities of ABC transporters such as P-glycoprotein or CFTR, that are implicated in disease.
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PMID:Mutations that alter the transmembrane signalling pathway in an ATP binding cassette (ABC) transporter. 815 12

Secretion of the 107-kDa hemolysin A (HlyA) from Escherichia coli is mediated by the membrane proteins hemolysin B and hemolysin D. Hemolysin B is a member of the so-called ATP binding cassette transporter superfamily, which includes the multidrug resistance P-glycoprotein, the cystic fibrosis CFTR protein, and the major histocompatibility complex-associated transporter of antigenic peptides. Recognition of HlyA by the hemolysin B/D transporter is dependent on a signal sequence mapped to the C-terminal 50 or so amino acids of the HlyA molecule. We show that the C-terminal 70 amino acids of leukotoxin from Pasteurella hemolytica can substitute functionally for the HlyA signal sequence. This 70-amino acid sequence contains no primary sequence similarity to the HlyA signal sequence; however, structural motifs of helix-turn-helix followed by strand-loop-strand can be deduced for both sequences. We also demonstrate by site-directed mutagenesis that changes to these predicted motifs affect transport function. It thus appears that the transport signal of HlyA may be defined by a higher-order structure and that the hemolysin transporter may recognize a much wider diversity of primary sequences than previously anticipated. This finding may have implications for understanding the basis of substrate specificity of other ATP binding cassette transporters.
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PMID:Functional replacement of the hemolysin A transport signal by a different primary sequence. 848 36

Two distinct Drosophila melanogaster P-glycoprotein (Pgp) gene homologues of different chromosomal origin, MDR49 and MDR65, have been previously identified (38). Most Pgps are implicated in the development of the multidrug-resistance phenotype. Despite intense efforts to identify the molecular mechanism(s) associated with Pgp function, the endogenous substrate(s) of these transport molecules is largely unknown. Recent studies from our laboratory indicate that a murine Pgp homologue (E. H. Abraham, A. G. Prat, L. Gerweck, T. Seneveratne, R. J. Arceci, R. Kramer, G. Guidotti, and H. F. Cantiello. Proc. Natl. Acad. Sci. USA 90: 312-316, 1993) and a related protein, the cystic fibrosis transmembrane conductance regulator (CFTR; I. L. Reisin, A. Prat, E. H. Abraham, J. F. Amara, R. J. Gregory, D. A. Ausiello, and H. F. Cantiello. J. Biol. Chem. 269: 20584-20591, 1994), are novel ATP-permeable ion channels. The common feature of these two proteins is the conserved ATP-binding cassettes (ABC); thus molecules structurally linked to the ABC transporter family may be also functionally associated with ATP channel activity. In this study, MDR65 and MDR49 Pgps were functionally expressed in Sf9 cells, and patch-clamp techniques were applied to assess the role of these proteins in the electrodiffusional movement of ATP. In the presence of intracellular ATP and external NaCl, expression of MDR65 was associated with a linear electrodiffusional pathway that was permeable to both ATP and Cl-. Under symmetrical ATP conditions, only voltage depolarization activated a MDR65-mediated ATP-conductive pathway. Expression of MDR49 was also associated with a voltage-activated ATP conductance in symmetrical ATP, but no apparent permeability to either Cl- or ATP was observed under asymmetrical conditions. The different functional properties of MDR65 and MDR49 may be indicative of distinct physiological roles in this organism. The study indicates, however, that the two Drosophila Pgp homologues share strong functional similarities with their mammalian relatives Pgp and CFTR.
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PMID:Expression of Drosophila melanogaster P-glycoproteins is associated with ATP channel activity. 894 36

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