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)

Using an in situ kinase assay we have identified kinases that are elevated in some multidrug resistant cells. Kinases were detected by measurement of 32P incorporation in proteins that were renatured after being subjected to SDS-polyacrylamide gel electrophoresis and transferred to polyvinylidene difluoride membranes [Ferrell and Martin: J Biol Chem 264:20723-20729, 1989; Mol Cell Biol 10:3020-3026, 1990]. Kinases at 79, 84, and 92 kDa showed increased activity in the multidrug resistant human KB-V1 cells as compared to the sensitive parental KB-3-1 cells. The KB-V1 multidrug resistant cell line exhibited a 170 kDa membrane associated kinase activity that was not present in the parental drug sensitive line. The 170 kDa kinase activity was not affected by Ca++, phosphatidylserine, or cAMP, but was diminished after incubation in the presence of the kinase inhibitors staurosporine, K252a and KT5720. The 170 kDa kinase activity phosphorylated mainly threonine, with no evidence of tyrosine phosphorylation, and was not identical to either the multidrug resistance associated P-glycoprotein or the EGF receptor. Other multidrug resistant cell lines also showed elevated 170 kDa kinase activity, such as the human breast cancer MCF-7/Adr(R) and murine melanoma B16/Adr(R) cells, but the activity was not present in murine leukemia P-388 sensitive or multidrug resistant cells.
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PMID:Identification of a 170 kDa membrane kinase with increased activity in KB-V1 multidrug resistant cells. 769 26

We have already established a human leukemia sub-line resistant to the growth-inhibitory effect of TPA (12-O-tetradecanoylphorbol 13-acetate) (K562/TPA) derived from K562. K562/TPA was found to be a non-P-glycoprotein-mediated multidrug-resistant cell line, in which intracellular drug accumulation was not reduced. In K562/TPA, adriamycin (ADM) was distributed mainly in the cytoplasm and was scarcely observed in the nucleus. We determined the relative levels of multidrug-resistance-associated protein (MRP), which was recently identified as the novel transporter. The relative levels of MRP in K562/TPA were the same as in K562. Although the catalytic activity of K562/TPA topoisomerase II was about half that of the parental cells, resistance to other drugs could not be explained by topoisomerase-II activity. To elucidate the mechanism of drug resistance in K562/TPA, we tried to find chemicals that would reverse the drug resistance. Tyrosine-kinase inhibitors enhanced the cytotoxicity of anti-neoplastic drugs against K562/TPA. Therefore we examined the modification of nuclear ADM accumulation in K562/TPA by one of these tyrosine-kinase inhibitors, genistein. Although the amount of ADM was decreased in the nuclei of K562/TPA cells, it was significantly increased after incubation in the presence of genistein. The formation of DNA single-strand breaks by ADM, etoposide, and ACNU was significantly lower in K562/TPA than in K562, but was significantly increased in the presence of genistein. These results suggest that genistein could overcome drug resistance by enhancing the accumulation of drug into the nuclear fraction of K562/TPA.
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PMID:Reversal of multidrug resistance by tyrosine-kinase inhibitors in a non-P-glycoprotein-mediated multidrug-resistant cell line. 790 94

Site-directed mutagenesis was used to investigate whether amino acids located in the predicted transmembrane segment, TM6 (residues 330-351), of human P-glycoprotein play essential roles in drug transport. Mutant cDNAs were expressed in mouse NIH 3T3 cells and analyzed with respect to their ability to confer resistance to cytotoxic drugs. Four mutations were found to strongly alter the drug resistance profile conferred by P-glycoprotein. Mutation of Val338 to Ala resulted in a mutant P-glycoprotein which conferred enhanced resistance to colchicine and reduced relative resistance to vinblastine. By contrast, mutant Gly341 to Val conferred little resistance to colchicine or doxorubicin, while its ability to confer resistance to vinblastine or actinomycin D was retained. A reduction in the ability of P-glycoprotein to confer resistance to all four drugs was observed for mutant Ala342 to Leu. Mutation of Ser344 to Ala, Thr, Cys, or Tyr resulted in mutant P-glycoproteins which were unable to confer drug resistance. Photolabeling of P-glycoprotein with azidopine in the presence of varying amounts of vinblastine showed that mutation of Ser344 to Tyr required approximately 15-fold more vinblastine to inhibit photolabeling when compared to wild-type enzyme. All of the Ser344 mutants were found to have reduced drug-stimulated ATPase activity relative to wild-type enzyme. These results, together with our previous demonstration that changes to Phe335 affected dissociation of vinblastine, suggest that TM6 may play an important role in drug--protein interaction and coupling of drug binding to ATPase activity.
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PMID:Mutations to amino acids located in predicted transmembrane segment 6 (TM6) modulate the activity and substrate specificity of human P-glycoprotein. 794 14

Stepwise selection for increased mefloquine resistance in a line of Plasmodium falciparum in vitro resulted in increased resistance to halofantrine and quinine, increased sensitivity to chloroquine, and amplification and overexpression of the P-glycoprotein gene homolog (pfmdr1). A point mutation (tyrosine to phenylalanine) noted at amino acid 86 in pfmdr1 in the mefloquine-resistant line W2mef was amplified in more resistant lines derived from it by in vitro selection pressure with mefloquine. Conversely, lines selected for increased chloroquine resistance exhibited a revertant phenotype that was sensitive to mefloquine and halofantrine. These lines also demonstrated increased sensitivity to quinine, loss of amplification of pfmdr1, loss of the mefloquine/halofantrine phenylalanine-86 mutation, and selection for a tyrosine-86 mutation previously associated with chloroquine resistance. These findings provide strong evidence for pfmdr1 mediating cross-resistance to halofantrine and mefloquine in P. falciparum in vitro.
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PMID:A strong association between mefloquine and halofantrine resistance and amplification, overexpression, and mutation in the P-glycoprotein gene homolog (pfmdr) of Plasmodium falciparum in vitro. 798 58

The serine residue located at position 939 and 941 in the predicted transmembrane segment 11 of P-glycoprotein (P-gp) encoded by mouse mdr3 and mdr1, respectively, appears to be important for interaction of chemotherapeutic drugs and reversal agents with P-gp. To further understand the role of this residue in this process and to identify the structural requirements involved, we have replaced this serine residue by alanine, cysteine, threonine, tyrosine, tryptophan, and aspartic acid and tested the effect of these mutations on the overall activity and substrate specificity of mdr1 and mdr3. All mutant proteins could be expressed at high levels in the membrane fractions of LR73 Chinese hamster cells transfected with the corresponding mutant cDNAs. All introduced mutations had limited effect on the capacity of mdr1 and mdr3 to confer resistance to vinblastine. The modulatory effect of mutations on resistance to colchicine, adriamycin, and actinomycin D was more dramatic. The hydroxyl group of serine did not seem essential for interaction with these drugs since mutant mdr1 and mdr3 bearing alanine or cysteine at that position behaved essentially as wild type, while threonine-bearing mutants showed significantly reduced resistance to these drugs. The insertion at that site of residues with bulkier side chains had more complex effects on P-gp function. While introducing tyrosine, tryptophan, or aspartic acid caused an almost complete loss of colchicine and adriamycin resistance in both mdr1 and mdr3, the replacement to tyrosine or tryptophan had the opposite effect on mdr1 and mdr3 for actinomycin D resistance, causing either a 3-fold increase or a 4-8-fold decrease in resistance to this drug, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Modulatory effects on substrate specificity of independent mutations at the serine939/941 position in predicted transmembrane domain 11 of P-glycoproteins. 810 79

The mechanism by which P-glycoprotein (P-gp) interacts with a number of structurally unrelated substrates or inhibitors remains unknown. We have recently shown that a serine residue within the predicted transmembrane (TM) domain 11 of P-gps encoded by mouse mdr1 (Ser941) and mdr3 (Ser939) plays an important role in the substrate specificity of P-gp. We wished to determine if Ser939/941 is also important for efficient interaction of P-gp with structurally different modulating agents, a cyclic peptide (cyclosporin A, CsA), a diaminoquinazoline (CP100356), and a chiral, tricyclic structure (CP117227). For this, the capacity of these compounds to modulate the vinblastine (VBL) resistance phenotype of transfected cells expressing similar levels of P-gps bearing either the wild-type Ser or a mutant Phe at position 941 (mdr1) or 939 (mdr3) was initially tested. The Ser-->Phe substitution indeed affected the potency and P-gp isoform specificity of some of the modulators, in particular that of CP117227 (racemic mixture and enantiomers), which were active against wild-type but not mutant mdr3. The modulatory effect of the mutation on CP117227-mediated reversal of VBL resistance was parallelled by a comparable modulation of the steady-state levels of VBL accumulation in Ser939- and Phe939-expressing cells, but was not linked to differential cellular accumulation of the modulator, which was identical in both cell types. To further assess the role of this amino acid residue in P-gp interactions with modulators, the effect of additional mutations (Ala, Cys, Thr, Asp, Tyr, Trp) at that site on potencies of CsA, CP117227 enantiomers, and CP100356 was evaluated.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Structurally distinct MDR modulators show specific patterns of reversal against P-glycoproteins bearing unique mutations at serine939/941. 817 79

The role of protein kinase C and protein phosphatases was examined in the control of mutagenic metabolites of aromatic amines. Various metabolic activating systems derived from rat liver were treated with: 12-O-tetradecanoylphorbol-13-acetate (TPA), a protein kinase C modulator; okadaic acid (OA), a potent inhibitor of serine/threonine protein phosphatases (PP1 and PP2A); and ortho-vanadate (OV), an inhibitor of tyrosine phosphatases. TPA used over a wide concentration range (10(-9)-10(-6) M) did not affect the bacterial mutagenicity of the aromatic amines and of the aromatic amide investigated, 2-aminoanthracene, 2-aminofluorene and 2-acetylaminofluorene (2AAF). At the molecular level, TPA did not affect the function of cytochrome P450s 1A1 or 1A2, which are known key factors for the activation and inactivation of aromatic amines/amides. By contrast the OA and OV treatment of rat hepatocytes, rat liver homogenate, fraction S9 and the nuclear fraction drastically reduced (by > 80%) the mutagenicity of the aromatic amines/amide investigated. This is by far the most pronounced change in genotoxicity observed to date via modulation of phosphorylation. Whilst the mutagenicity of the primary toxication product 2-N-OH-acetylaminofluorene (2-N-OH-AAF) in the presence of exogenous activating systems (hepatocytes, S9-fraction, nuclear fraction) was also reduced by OV, OA had no influence. Thus the tyrosine protein phosphatase inhibitor and the serine/threonine protein phosphatase inhibitor influence the genotoxicity of aromatic amines/amides on different levels. Moreover, this shows that the drastic reduction in mutagenicity by OA was due to its influence on a step prior to the presence of the primary toxication product 2-N-OH-AAF. This reduction could be due to changes in the activity of cytochrome P4501A1 and/or 1A2. However, no incorporation of 32P-labelled phosphate from intracellularly prelabelled [32P]-ATP into cytochromes P450 1A1 or 1A2 nor any change in their catalytic activities was observed in the presence of OA. Furthermore, a phosphorylation dependent change in the function of P-glycoprotein (known for its role in the transport of diverse xenobiotic substances and their metabolites) was shown not to contribute to the observed decrease in mutagenicity. Our results reveal an important role for protein phosphatase 1 and/or 2A and tyrosine phosphatase(s) in the control of the genotoxicity of aromatic amines and amides. However, the present study does not distinguish between effects mediated by individual proteins affected by these protein phosphatases.
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PMID:Control of the mutagenicity of aromatic amines by protein kinases and phosphatases. I. The protein phosphatase inhibitors okadaic acid and ortho-vanadate drastically reduce the mutagenicity of aromatic amines. 933 96

Chemoresistance gene transfer is an experimental method to protect hematopoietic cells from the toxicity of anticancer drugs. Because multiple drugs are usually given together in cancer therapy, this strategy will ultimately require vectors expressing multiple chemoresistance genes. For this reason, we designed a bicistronic retroviral vector (HaMID) containing a modified human multidrug resistance-1 cDNA and a mutant human dihydrofolate reductase cDNA bearing a leucine to tyrosine substitution at codon 22 (L22Y). To determine if this vector would confer dual drug resistance to hematopoietic cells, recombinant retrovirus was used to transduce the human CEM T lymphoblastic cell line as well as primary murine myeloid progenitors. Growth suppression assays, using polyclonal transduced CEM cells, demonstrated increased resistance to taxol (13-fold), trimetrexate (8.9-fold), vinblastine (5.6-fold), methotrexate (2.5-fold), and etoposide (1.5-fold) when used as single agents. HaMID-transduced cells also grew at a logarithmic rate in the simultaneous presence of 25 nM taxol and 100 nM trimetrexate while control cells were entirely growth inhibited by this drug combination. Similarly, HaMID-transduced murine myeloid progenitors acquired increased resistance to taxol (2.9-fold) and trimetrexate (140-fold), and were able to form colonies in the simultaneous presence of both drugs. Our results suggest that retroviral transfer of HaMID into primary hematopoietic cells should reduce the myelosuppression associated with the combined use of antifolates and P-glycoprotein-effluxed drugs.
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PMID:A bicistronic retroviral vector for protecting hematopoietic cells against antifolates and P-glycoprotein effluxed drugs. 935 27

Photoaffinity labelling of hamster P-glycoprotein was carried out after trapping of radioactive Mg-8-azido-ADP in the catalytic sites by vanadate or beryllium fluoride. With either trapping agent the same labelled peptide was obtained in homogeneous form, with the sequence -FNEVVFNxPTRPDI-, corresponding to residues 1034-1037 in the C-terminal nucleotide binding site. The missing residue 'x' corresponds to Tyr-1041, which is therefore a primary reaction target of 8-azido-ADP. This tyrosine is conserved in all hamster, mouse and human P-glycoproteins. A second major labelled peptide fraction was also identified. The major sequence in this fraction was -NIHFSxPSR-, corresponding to residues 393-401 of hamster P-glycoprotein, where 'x' corresponds to Tyr-398 in the N-terminal nucleotide binding site. Therefore Tyr-398, which is also conserved in other P-glycoproteins, is also a reaction target for 8-azido-ADP. In sequence alignment of the two nucleotide binding sites, Tyr-398 exactly corresponds to Tyr-1041. The data indicate that these two tyrosines lie close to the adenine ring of bound substrate MgATP in the respective catalytic sites of P-glycoprotein.
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PMID:Photoaffinity labelling of P-glycoprotein catalytic sites. 939 88

We generated Chinese hamster ovary cells which are highly multidrug-resistant by selection in colchicine. Purified plasma membranes from these cells are enriched in P-glycoprotein (Pgp), up to 32% w/w of membrane protein. From plasma membranes we purified Pgp to homogeneity and reconstituted it in proteoliposomes. Both plasma membranes and purified reconstituted Pgp show drug-stimulated ATPase activity (approximately 20 s-1), comparable to other transport ATPases. These materials enable investigation and characterization of the catalytic sites and mechanism. Various approaches have been used, notably enzyme kinetics, photoaffinity and other covalent labelling, use of vanadate as transition-state analog, and inhibition by beryllium and aluminum fluoride. Both Pgp nucleotide sites hydrolyse MgATP and are of relatively low specificity and affinity for nucleotides. Trapping of nucleotide by vanadate in either site blocks catalysis at both sites; covalent inactivation of either site completely blocks turnover. Therefore the catalytic sites interact strongly, and it appears that when one site enters the transition-state conformation the other site is prohibited from doing so. A minimal reaction scheme for ATP hydrolysis has been determined. We have proposed an alternating catalytic sites scheme, in which drug-transport is coupled to relaxation of a high chemical potential conformation of the catalytic site (Pgp.MgADP.Pi) which is generated by the hydrolysis step itself. Photoaffinity labelling of Pgp catalytic sites has revealed equivalent Tyr residues which lie close to the adenine ring of bound MgATP in both sites.
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PMID:Catalytic mechanism of P-glycoprotein. 978 63


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