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Symptom
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Enzyme
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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)
MDR results from overexpression of
P-glycoprotein
(Pgp) and multidrug resistance protein (
MRP
or MRP1) that function as ATP-dependent efflux pumps. Lung resistance related protein (LRP) is also supposed to be involved in MDR. The human canalicular multispecific organic anion transporter (cMOAT) gene that is responsible for the defects in Dubin-Johnson syndrome was isolated. cMOAT is homologous to MRP1 and supposed to be involved in drug resistance. Human cMOAT cDNA transfected LLC-PK1 cells, LLC/cMOAT-1, have increased resistance to vincristine (VCR), 7-ethyl-10-hydroxycamptothecin (SN-38), and cisplatin. The multidrug resistance (MDR)-reversing agents, cyclosporin A (CsA) and PAK-104P, almost completely reversed the resistance to VCR, SN-38 and cisplatin of LLC/cMOAT-1 cells by interacting with the substrate binding site of cMOAT. Treatment of human colorectal carcinoma SW-620 cells with sodium butyrate(NaB) induced LRP in the cells and conferred resistance to Adrianycin(ADM), VCR, VP-16, gramicidin D and taxol. Two LRP-specific ribozymes inhibited the NaB-induced expression of LRP in SW-620 cells and almost completely abolished their acquisition of the MDR phenotype. The accumulation of ADM, VCR and taxol was not decreased in NaB-treated cells, suggesting that ATP-binding cassette transporters are not involved in the MDR of NaB-treated cells. ADM was mainly located in the nuclei of untreated and the cytoplasm of NaB-treated cells. The accumulation level of ADM in the nuclei isolated from untreated cells or those from treated cells in the presence of anti-LRP polyclonal antibody was higher than that from treated cells in the absence of the antibody. Efflux of ADM from nuclei isolated from NaB-treated cells was enhanced compared with those from untreated cells and NaB-treated cells transfected with a LRP-specific ribozyme. The polyclonal antibody against LRP inhibited the enhanced efflux of ADM from nuclei isolated from NaB-treated cells. These findings indicate that LRP is involved in resistance to ADM, VCR, VP-16, taxol and gramicidin D, and has an important role in the transport of ADM from the nucleus to the cytoplasm.
...
PMID:[Mechanisms for resistance to anticancer agents and the reversal of the resistance]. 1069 15
1. The blood-brain barriers restrict the passive diffusion of many drugs into the brain and constitute a significant obstacle in the pharmacological treatment of central nervous system diseases and disorders. The degree of restriction they impose is variable, with some lipid-insoluble drugs effectively excluded from the brain, while many lipid-soluble drugs do not appear to be subject to any restriction. 2. The ease with which any particular drug diffuses across the blood-brain barrier is determined largely by the number and strength of intermolecular forces "holding" it to surrounding water molecules. By quantifying the molecular features that contribute to these forces, it is possible to predict the in vivo blood-brain barrier permeability of a drug from its molecular structure. Dipolarity, polarizability, and hydrogen bonding ability are factors that appear to reduce permeability, whereas molecular volume (size) and molar refraction are associated with increased permeability. 3. Increasing the passive entry of "restricted" drugs into the central nervous system can be achieved by disrupting the blood-brain barrier (increased paracellular diffusion) or by modifying the structure of "restricted" drugs to temporarily or permanently increase their lipid solubility (increased transcellular permeability). 4. Competitive inhibition of outwardly directed active efflux mechanisms (
P-glycoprotein
and
MRP
, the multidrug resistance-related protein) can also significantly increase the accumulation of certain drugs within the central nervous system.
...
PMID:Determinants of passive drug entry into the central nervous system. 1069 12
Transport by ATP-dependent efflux pumps such as
P-glycoprotein
is an increasingly recognized determinant of drug disposition.
P-glycoprotein
does not only contribute to multidrug resistance (MDR) in tumor cells, it is also expressed in normal tissues with excretory function such as liver, kidney and intestine. Apical expression of
P-glycoprotein
in such tissues results in reduced drug absorption from the gastrointestinal tract and enhanced drug elimination into bile and urine. Moreover, expression of
P-glycoprotein
in the endothelial cells of the blood-brain barrier prevents entry of certain drugs into the central nervous system. Human
P-glycoprotein
has been shown to transport a wide range of structurally unrelated drugs such as digoxin, quinidine, cyclosporine and HIV-1 protease inhibitors. Drug administration to
P-glycoprotein
knock-out and control mice provided data on the importance of
P-glycoprotein
for absorption after oral administration and penetration through the blood-brain barrier. Moreover,
P-glycoprotein
knock-out mice were used to identify inhibition of
P-glycoprotein
-mediated transport as a mechanism for drug interactions such as the digoxin-quinidine interaction. Studies in humans indicate a particular importance of intestinal
P-glycoprotein
for bioavailability of the immunosuppressant cyclosporine. Moreover, induction of intestinal
P-glycoprotein
by rifampin has now been identified as the major underlying mechanism of reduced digoxin plasma concentrations during concomitant rifampin therapy. In summary,
P-glycoprotein
functions as a defense mechanism, which determines bioavailability and CNS concentrations of drugs. Modification of
P-glycoprotein
function is an important underlying mechanism of drug interactions in humans. However, disposition of a drug and its metabolites frequently is not only determined by
P-glycoprotein
, but also by drug-metabolizing enzymes and possibly by drug transporters other than
P-glycoprotein
[e.g. members of the
MRP
family (
MRP
= multidrug resistance-associated proteins)].
...
PMID:P-glycoprotein: a defense mechanism limiting oral bioavailability and CNS accumulation of drugs. 1070 93
1. We studied the functional interaction between transport and metabolism by comparing the transport of losartan and its active metabolite EXP 3174 (EXP) across cell monolayers. 2. Epithelial layers of Caco-2 cells as well as MDR1, MRP-1 and
MRP
-2 overexpressing cells, in comparison to the respective wildtypes, were used to characterize the transcellular transport of losartan and EXP. 3. Losartan transport in MDCK-MDR1 and Caco-2 cells was saturable and energy-dependent with a significantly greater basolateral-to-apical (B/A) than apical-to-basolateral (A/B) flux (ratio=31+/-1 in MDCK-MDR1 and ratio 4+/-1 in Caco-2 cells). The B/A flux of losartan was inhibited by cyclosporine and vinblastine, inhibitors of
P-glycoprotein
and
MRP
. In contrast, no active losartan transport was observed in MRP-1 or
MRP
-2 overexpressing cells. 4. The metabolite was only transported in Caco-2 cells with a B/A-to-A/B ratio of 5+/-1, while lacking active transport in the MDR1, MRP-1 or
MRP
-2 overexpressing cells. The B/A flux of EXP was significantly inhibited by cyclosporine and vinblastine. 5. In conclusion, losartan is transported by
P-glycoprotein
and other intestinal transporters, that do not include MRP-1 and
MRP
-2. In contrast, the carboxylic acid metabolite is not a
P-glycoprotein
substrate, but displays considerably higher affinity for other transporters than losartan, that again most probably do not include MRP-1 and
MRP
-2.
...
PMID:Active transport of the angiotensin-II antagonist losartan and its main metabolite EXP 3174 across MDCK-MDR1 and caco-2 cell monolayers. 1072 73
Multidrug resistance phenotype in mammalian cells is often correlated with overexpression of
P-glycoprotein
or Multidrug Resistance-Associated protein (
MRP
(1)). Both proteins are energy-dependent drug efflux pumps that efficiently reduce the intracellular accumulation and hence the cytotoxicity of many natural cytotoxins. Overexpression of these transporters by tumor cells is thought to be a significant factor in both intrinsic and acquired resistance to anticancer drugs. Consequently a great deal of interest is focused on identifying chemical agents that can either antagonise drug transport by these proteins or that can inhibit the proliferation of tumors cells despite the expression of these transporters.
P-glycoprotein
-mediated multidrug resistance is reversed by a variety of compounds, but surprisingly, few agents reverse the
MRP
(1)-mediated multidrug resistance. However, it has recently been shown that 2-[4-(diphenylmethyl)-1-piperazinyl]ethyl-5-(trans-4,6-dimethyl-1, 3, 2-dioxaphosphorinan-2-yl)-2, 6-dimethyl-4-(3-nitrophenyl)-3-pyridinecarboxylate P oxide (PAK-104P) was able to inhibit the
P-glycoprotein
and
MRP
(1)-mediated efflux of several compounds. Understanding of the interactions between transporters and multidrug resistance reversing agents is important in the design of more effective multidrug resistance modulators. We now examined the effect of PAK-104P on Pgp-and MRP1-mediated efflux of three anthracyclines, daunorubicin, pirarubicin, hydroxydoxorubicin and of calcein acetoxymethyl ester and calcein. Our data show that PAK-104P non-competitively inhibits the
P-glycoprotein
-mediated efflux of anthracycline derivatives and calcein acetoxymethyl ester with an inhibitory constant K(I)=0. 25+/-0.05 microM. PAK-104P also non-competitively inhibits the
MRP
(1)-mediated efflux of daunorubicin, pirarubicin, hydroxyrubicin, calcein acetoxymethyl ester and calcein. However, surprisingly, in this case the K(I) values obtained were very different ranging from 0.06 for hydroxyrubicin to 10 microM for calcein. These data strongly suggested the existence of two different mechanisms for the inhibition by PAK-104P of the
MRP
(1)-mediated efflux of molecules: a first mechanism, involving a low-affinity site for PAK-104P, and which would concern molecules such as calcein, cysteinyl leukotriene LCT(4) etc. whose efflux do not depend on glutathione. A second mechanism involving a high-affinity site for PAK-104P and which would concern molecules such as anthracyclines, calcein acetoxymethyl ester whose efflux depends on the presence of glutathione.
...
PMID:Inhibition of the P-glycoprotein- and multidrug resistance protein-mediated efflux of anthracyclines and calceinacetoxymethyl ester by PAK-104P. 1072 60
A major problem in the treatment of leukemia is the development of resistance to chemotherapeutic agents. There are several ways for cancer cells to develop resistance or defense mechanisms against cytotoxic drugs. This review paper will focus on membrane transport-associated multidrug resistance (MDR). The proteins involved,
P-glycoprotein
(
P-gp
), MRP1 and LRP/MVP, share the ability to act as drug transport proteins. Following upregulation of the mdr-1 gene, the energy-dependent transmembrane
P-gp
overexpression results in diminished intracellular concentrations of anthracyclins, vinca-alkaloids and epipodophyllotoxins. The other transmembrane protein, MRP1, also has intracellular epitopes which are involved in intracellular redistribution and sequestration of drugs. The last named mechanism has also been ascribed to LRP, a protein which only occurs intracellularly. In leukemia patients, cellular drug resistance profiles determined in vitro at the time of presentation show a strong correlation with outcome. In AML, mdr-1 overexpression at diagnosis is a strong independent predictor for CR and long-term survival. In ALL, mdr-1 expression is of minor importance for prediction of outcome. In AML, MRP1 expression at diagnosis is not correlated with clinical response and survival in most studies. In ALL, MRP1 expression at diagnosis is not associated with response and long-term survival in the few studies on this aspect which have been published. The studies on LRP in AML emphasize the importance of the correlation between LRP-expression and anthracycline accumulation and suggest that LRP-expression has prognostic value at diagnosis. However, there is an equal number of studies where a predictive value in the case of LRP-expression in de novo AML cannot be shown. The highest levels of LRP have been reported in multiple relapses of ALL. Furthermore, new membrane-associated drug transport proteins have been reported including the transporter associated with antigen processing (TAP), the anthracyclin resistance-associated protein (ARA), five new homologues of
MRP
(MRP2, or MOAT, MRP3, MRP4, MRP5, and MRP6), the sister of
P-glycoprotein
(sP-gp) and breast cancer resistance protein (BCRP). Studies on the (clinical) significance of these proteins have not yet been reported.
...
PMID:The prognostic significance of membrane transport-associated multidrug resistance (MDR) proteins in leukemia. 1073 13
P-glycoprotein
was initially isolated due to its role in multidrug resistance to cancer chemotherapeutics. Recent work, however, makes it increasingly apparent that this transporter is also involved in the pharmacokinetics of many drugs. P-gp is strategically expressed in the luminal epithelial cells of organs often associated with drug absorption and disposition, for example, hepatocyte canalicular membrane, renal proximal tubules, and the intestinal mucosa. P-gp is also expressed in the endothelial cells comprising the blood-brain barrier. This localization clearly suggests the potential for this protein to serve as a protective mechanism against entry of toxic xenobiotics and also suggests that P-gp is well situated to participate in the removal of therapeutic agents. Numerous investigations with drugs such as digoxin, etoposide, cyclosporine, vinblastine, Taxol, loperamide, dom-peridone, and ondansteron demonstrate that P-gp has an important role in determining the pharmacokinetics of substrate drugs. Pharmacological modulation of P-gp function to increase drug bioavailability, both on a organismal and a cellular level, is one approach currently being explored to enhance therapeutic effectiveness. This approach is not without potential collateral consequences given the wide tissue distribution of P-gp. While animals deficient in P-gp are viable and without obvious abnormalities, the pharmacokinetics and toxic consequences of several compounds are significantly altered in these animals. Thus blockade of the protective P-gp barrier in humans may have adverse effects on substrate drugs. In particular, this situation may arise when several compounds which may be substrates compete for P-gp-mediated transport. Additional multidrug transporters, notably
MRP
and family members, have been identified and may also determine the fate of pharmaceuticals. Further understanding the physiological role of each of the multidrug transporters is critical for determining their role in pharmacokinetics and for evaluating the consequences of modification of their activities. Such information is also important in the development of novel drugs which may be substrates for these transporters.
...
PMID:Multidrug-resistance transporters. 1074 82
The ATP binding cassette (ABC) superfamily is a large, ubiquitous and diverse group of proteins, most of which mediate transport across biological membranes. ABC transporters have been shown to function not only as ATP-dependent pumps, but also as ion channels and channel regulators. Whilst members of this gene family have been extensively characterised in mammalian and microbial systems, the study of plant ABC transporters is a relatively new field of investigation. Sequences of over 20 plant ABC proteins have been published and include homologues of
P-glycoprotein
,
MRP
, PDR5 and organellar transporters. At present, functions have been assigned to a small proportion of these genes and only the
MRP
subclass has been extensively characterised. This review aims to summarise literature relevant to the study of plant ABC transporters, to review methods of cloning, to discuss the utility of yeast and mammalian systems as models and to speculate on possible roles of uncharacterised ABC transporters in plants.
...
PMID:Plant ABC transporters. 1074 48
The failure of chemotherapy to eradicate tumor cells is often due to the development of drug resistance. MDR(multidrug resistance) whose one form of resistance results from a decreased intracellular accumulation of the drugs, most often mediated by the overexpression of
P-glycoprotein
.
MRP
also related to pump function of cell membrane in acute leukemia. We have developed the new quantitative assay based on real-time PCR to measure expression of drug-resistance related genes such as MDR-1 and
MRP
in clinical samples. These results indicates that real-time PCR system is a reliable method to quantitatively determine drug resistant genes expression, it may be to predict responsiveness to chemotherapy by using this technique.
...
PMID:[Genetic diagnosis for drug resistance in cancers]. 1080 20
Mechanisms of drug resistance other than
P-glycoprotein
are of increasing interest as the list of newly identified members of the ABC transport family has grown. We sought to characterize the phenotype of the newly discovered ABC transporter encoded by the mitoxantrone resistance gene, MXR, also known as ABCP1 or BCRP. The pharmacodynamics of mitoxantrone and 12 other fluorescent drugs were evaluated by confocal microscopy in four multidrug-resistant human colon (S1) and breast (MCF-7) cancer cell lines. We utilized two sublines, MCF-7 AdVp3000 and S1-M1-80, and detected overexpression of MXR by PCR, immunoblot assay and immunohistochemistry. These MXR overexpressing sublines were compared to cell lines with
P-glycoprotein
- and
MRP
-mediated resistance. High levels of cross-resistance were observed for mitoxantrone, the anthracyclines, bisantrene and topotecan. Reduced levels of mitoxantrone, daunorubicin, bisantrene, topotecan, rhodamine 123 and prazosin were observed in the two sublines with high MXR expression. Neither the
P-glycoprotein
substrates vinblastine, paclitaxel, verapamil and calcein-AM, nor the
MRP
substrate calcein, were extruded from MCF-7 AdVp3000 and S1-M1-80 cells. Thus, the multidrug-resistant phenotype due to MXR expression is overlapping with, but distinct from, that due to
P-glycoprotein
. Further, cells that overexpress the MXR protein seem to be more resistant to mitoxantrone and topotecan than cells with
P-glycoprotein
-mediated multidrug resistance. Our studies suggest that the ABC half-transporter, MXR, is a potent, new mechanism for conferring multiple drug resistance. Definition of its mechanism of transport and its role in clinical oncology is required.
...
PMID:The multidrug-resistant phenotype associated with overexpression of the new ABC half-transporter, MXR (ABCG2). 1080 12
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