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

Digoxin, a widely used cardiac glycoside with a low therapeutic index, is known to interact with a large and diverse group of co-administered drugs, frequently leading to toxic accumulation of the glycoside. Establishing the mechanism(s) of these interactions, therefore, has potential clinical significance. The present studies implicate P-glycoprotein, the MDR1 gene product overexpressed in multidrug resistant cells, as the apical membrane protein responsible for the renal secretion of digoxin and provide an explanation for the occurrence of digoxin toxicity in the presence of certain co-administered medications. Since digoxin is considered a prototype for endogenous digitalis-like glycosides, the results also allow for speculation that endogenous digitalis-like glycosides may be the natural substrates for P-gp.
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PMID:The MDR1 gene product, P-glycoprotein, mediates the transport of the cardiac glycoside, digoxin. 136 Feb 7

We have previously shown that absence of the mouse mdr1a (also called mdr3) P-glycoprotein in mdr1a (-/-) "knockout" mice has a profound effect on the tissue distribution and elimination of vinblastine and ivermectin, and hence on the toxicity of these compounds. We show here that the mouse mdr1a and the human MDR1 P-glycoprotein actively transport ivermectin, dexamethasone, digoxin, and cyclosporin A and, to a lesser extent, morphine across a polarized kidney epithelial cell layer in vitro. Injection of these radio-labeled drugs in mdr1a (-/-) and wild-type mice resulted in markedly (20- to 50-fold) higher levels of radioactivity in mdr1a (-/-) brain for digoxin and cyclosporin A, with more moderate effects for dexamethasone (2- to 3-fold) and morphine (1.7-fold). Digoxin and cyclosporin A were also more slowly eliminated from mdr1a (-/-) mice. Our findings show that P-glycoprotein can be a major determinant for the pharmacology of several medically important drugs other than anti-cancer agents, especially in the blood-brain barrier. These results may explain a range of pharmacological interactions observed between various drugs in patients.
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PMID:Absence of the mdr1a P-Glycoprotein in mice affects tissue distribution and pharmacokinetics of dexamethasone, digoxin, and cyclosporin A. 756 60

The mechanism for renal tubular secretion of digoxin as well as its interaction with quinidine or verapamil were investigated using the isolated perfused rat kidney. [3H]Digoxin was instantaneously administered into the renal artery together with [14C]inulin and Evans blue-albumin, and renal venous and urinary outflow curves were measured. The ratio of fractional excretion to filtration fraction for digoxin was 2.40 +/- 0.40, indicating involvement of tubular secretion. Quinidine and verapamil decreased the ratio of fractional excretion to filtration fraction in a concentration-dependent manner, and this inhibition was indicated to occur at transport from cells to lumen across luminal membranes. Neither tetraethylammonium nor p-aminohippurate affected the renal handling of digoxin. Because ouabain and digitoxose showed no influence on the value of fractional excretion to filtration fractions, Na+,K(+)-ATPase is not involved in the tubular secretion of digoxin. A metabolic inhibitor, 2,4-dinitrophenol, markedly inhibited digoxin secretion. Agents that bind to P-glycoprotein, such as vinblastine, daunorubicin and reserpine, markedly inhibited the secretion of digoxin. Recently, we have found that digoxin is a substrate transported by P-glycoprotein. The findings obtained here support the hypothesis that digoxin is secreted by P-glycoprotein located on the luminal membrane of renal tubular epithelial cells, and that clinically important interactions with quinidine and verapamil are caused by the inhibition of P-glycoprotein.
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PMID:Role of P-glycoprotein in renal tubular secretion of digoxin in the isolated perfused rat kidney. 810 98

Digoxin-quinidine interaction is well documented in the literature. The mechanism is, however, unknown. Previously, it was shown that quinidine reduced digoxin secretion by inhibiting P-glycoprotein (Pgp) in the renal tubule. Because Pgp is expressed in the small intestine to an extent no less than that in the kidney, the study was designed to investigate the possible effect of quinidine on the absorption and exsorption of digoxin in the rat intestine. Results from the everted sac study using different Pgp inhibitors and inducers support that digoxin is a substrate of Pgp in both jejunum and ileum. Plasma concentration of digoxin after intravenous administration increased 2-fold when 1 mg/hr quinidine was coinfused, whereas the amount that appeared in the intestinal lumen decreased by approximately 40%. In the presence of quinidine, total clearance decreased from 318.0 +/- 19.3 to 167.1 +/- 11.0 ml/hr, whereas intestinal clearance decreased from 28.8 +/- 1.7 to 11.1 +/- 1.6 ml/hr. In a separate study, 3H-labeled digoxin was infused intravenously together with luminal perfusion of unlabeled digoxin in the intestine. The change of 3H-labeled digoxin concentrations in plasma and in the intestinal lumen was similar to those in the exsorption study. However, concentration of unlabeled digoxin in plasma or the intestinal lumen did not alter significantly with the addition of quinidine. The absorption clearance in the control group (N = 6, 6.4 +/- 0.47 ml/hr) was significantly higher than that in the group with quinidine coadministration (N = 6, 4.8 +/- 0.31 ml/hr; p < 0.05). This indicates that quinidine may affect not only the elimination of digoxin, such as renal secretion, but also the absorption/exsorption of digoxin in the gastrointestinal tract. This study suggests that Pgp is involved in the drug interaction between digoxin and quinidine in the small intestine. It is clinically important to understand the effect of quinidine on digoxin absorption for further assessment.
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PMID:Inhibition of the intestinal digoxin absorption and exsorption by quinidine. 874 24

Digoxin-drug interactions are relatively common causes of digitalis toxicity. Recently, the clinical importance of the renal tubular secretion of digoxin has been proven by documenting drug interactions at this level. The authors describe a model using cultured renal tubular cell monolayers that can be used to predict drug interactions with the cardiac glycoside. This model accurately documents known clinical digoxin interactions such as those with verapamil and propafenone. The common feature of these interactions is that they involve P-glycoprotein substrates (e.g., digoxin, vincristine, vinblastine) or inhibitors (e.g., quinidine, cyclosporine). In the case of the newly described interaction of digoxin with itraconazole, the model preceded the emergence of clinical cases.
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PMID:A model for the prediction of digoxin-drug interactions at the renal tubular cell level. 955 26

Digoxin, a cardiac glycoside, is a substrate of the multidrug transporter P-glycoprotein (Pgp), and in rats has also been identified as a substrate for cytochrome P450 3A (CYP3A). Ketoconazole, an antifungal agent, was shown to inhibit Pgp in a multidrug-resistant cell line, and is known to be a potent inhibitor of CYP3A. Here, we determined the effects of ketoconazole on digoxin absorption and disposition in rats. Digoxin was administered intravenously or orally with or without a concomitant oral dose of ketoconazole. When given intravenously, digoxin AUC increased from 93 +/- 22 to 486 +/- 26 microg x h/l with ketoconazole administration. Similarly, ketoconazole raised the AUC of orally administered digoxin from 63 +/- 17 to 411 +/- 50 microg x h/l. Concomitant ketoconazole administration prolonged digoxin elimination, yielding a nonlinear pharmacokinetic profile. Using time-averaged values, digoxin bioavailability increased from 0.68 +/- 0.18 to 0.84 +/- 0.10, while mean absorption time was reduced from 1.1 +/- 0.4 to 0.3 +/- 0.1 h. Thus, in rats, ketoconazole increases digoxin plasma concentrations, rate of absorption and bioavailability. Although the effects of ketoconazole on AUC could be explained by inhibition of both CYP3A and Pgp, which cannot be differentiated in this study, the decreased mean absorption time can only be explained by inhibition of Pgp in the intestine.
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PMID:Effects of ketoconazole on digoxin absorption and disposition in rat. 965 17

We present a digoxin-clarithromycin interaction in two patients in whom digoxin concentrations were unexpectedly increased. The ratio of renal digoxin clearance to creatinine clearance in one patient was lower during the concomitant administration of clarithromycin (0.64 and 0.73) than that after cessation of clarithromycin administration (1.30 +/- 0.20; mean +/- SD). Because P-glycoprotein could play an important role in the renal secretion of digoxin, we hypothesized that clarithromycin decreases renal digoxin excretion by inhibiting P-glycoprotein-mediated transport. Digoxin transport was evaluated with use of a kidney epithelial cell line, which expresses the human P-glycoprotein on the apical membrane by transfection with MDR1 complementary deoxyribonucleic acid. Clarithromycin inhibited the transcellular transport of digoxin from the basolateral to the apical side in a concentration-dependent manner and concomitantly increased the cellular accumulation of digoxin. These results suggest that clarithromycin may inhibit the P-glycoprotein-mediated tubular secretion of digoxin, and this interaction mechanism may contribute to an increase in the serum digoxin concentration.
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PMID:Effect of clarithromycin on renal excretion of digoxin: interaction with P-glycoprotein. 969 27

Digoxin, which has a very narrow therapeutic window, is one of the most commonly prescribed drugs in the treatment of congestive heart failure. In some cases of atrial fibrillation digoxin is used in combination with verapamil. Verapamil can increase the plasma concentration of digoxin up to 60-90%. So far the precise mechanism of this pharmacokinetic drug-drug interaction is not known. Many studies suggest that verapamil reduces the renal clearance of digoxin. The energy-dependent membrane-bound transport enzyme, P-glycoprotein, may also be involved. Reports from oncology research show that verapamil can interact with P-glycoprotein as a modulator. Also taking into account that digoxin, like many anticancer drugs, is a substrate for P-glycoprotein, it is likely that P-glycoprotein modulation accounts for the digoxin-verapamil interaction. Current knowledge suggest that the non-competitive digoxin-verapamil interaction is due to inhibition of P-glycoprotein activity by verapamil resulting in a decreased renal tubular elimination of digoxin.
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PMID:P-glycoprotein system as a determinant of drug interactions: the case of digoxin-verapamil. 1052 40

The effect of atovarstatin on digoxin pharmacokinetics was assessed in 24 healthy volunteers in two studies. Subjects received 0.25 mg digoxin daily for 20 days, administered alone for the first 10 days and concomitantly with 10 mg or 80 mg atorvastatin for the last 10 days. Mean steady-state plasma digoxin concentrations were unchanged by administration of 10 mg atorvastatin. Mean steady-state plasma digoxin concentrations following administration of digoxin with 80 mg atorvastatin were slightly higher than concentrations following administration of digoxin alone, resulting in 20% and 15% higher Cmax and AUC(0-24) values, respectively. Since tmax and renal clearance were not significantly affected, the results are consistent with an increase in the extent of digoxin absorption in the presence of atorvastatin. Digoxin is known to undergo intestinal secretion mediated by P-glycoprotein. Since atorvastatin is a CYP3A4 substrate and many CYP3A4 substrates are also substrates for P-glycoprotein transport, the influence of atorvastatin and its metabolites on P-glycoprotein-mediated digoxin transport in monolayers of the human colon carcinoma (Caco-2) cell line was investigated. In this model system, atorvastatin exhibited efflux or secretion kinetics with a K(m) of 110 microM. Atorvastatin (100 microM) inhibited digoxin secretion (transport from the basolateral to apical aspect of the monolayer) by 58%, equivalent to the extent of inhibition observed with verapamil, a known inhibitor of P-glycoprotein transport. Thus, the increase in steady-state digoxin concentrations produced by 80 mg atorvastatin coadministration may result from inhibition of digoxin secretion into the intestinal lumen.
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PMID:Atorvastatin coadministration may increase digoxin concentrations by inhibition of intestinal P-glycoprotein-mediated secretion. 1063 27

P-glycoprotein (Pgp), which is coded by human MDR1 (multidrug resistance) gene, is an energy-dependent efflux pump that exports its substrates out of the cell. Human Pgp is present not only in tumor cells but also in normal tissues including the kidney, liver, small and large intestine, brain, testis, and adrenal gland, and the pregnant uterus. This tissue distribution indicates that Pgp plays a significant role in excreting xenobiotics and metabolites into urine and bile and into the intestinal lumen, and in preventing their accumulation in the brain. The roles of Pgp in drug disposition include a urinary excretion mechanism in the kidney, a biliary excretion mechanism in the liver, an absorption barrier and determinant of oral bioavailability, and the blood-brain barrier that limits the accumulation of drugs in the brain. The inhibition of the transporting function of Pgp can cause clinically significant drug interactions and can also increase the penetration of drugs into the brain and the accumulation of drugs in the brain. Digoxin is a typical substrate for Pgp, which regulates the renal tubular secretion and brain distribution of digoxin. At present, potent Pgp inhibitors are being investigated in clinical trials aimed at overcoming the intrinsic or acquired multidrug resistance of human cancers. The clinical application of these Pgp inhibitors should take into consideration the physiologic function of pgp.
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PMID:Role of P-glycoprotein in drug disposition. 1068 77


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