P-glycoprotein, the most extensively studied ATP-binding cassette (ABC) transporter, functions as a biological barrier by extruding toxins and xenobiotics out of cells. In vitro and in vivo studies have demonstrated that P-glycoprotein plays a significant role in drug absorption and disposition. Because of its localisation, P-glycoprotein appears to have a greater impact on limiting cellular uptake of drugs from blood circulation into brain and from intestinal lumen into epithelial cells than on enhancing the excretion of drugs out of hepatocytes and renal tubules into the adjacent luminal space. However, the relative contribution of intestinal P-glycoprotein to overall drug absorption is unlikely to be quantitatively important unless a very small oral dose is given, or the dissolution and diffusion rates of the drug are very slow. This is because P-glycoprotein transport activity becomes saturated by high concentrations of drug in the intestinal lumen. Because of its importance in pharmacokinetics, P-glycoprotein transport screening has been incorporated into the drug discovery process, aided by the availability of transgenic mdr knockout mice and in vitro cell systems. When applying in vitro and in vivo screening models to study P-glycoprotein function, there are two fundamental questions: (i) can in vitro data be accurately extrapolated to the in vivo situation; and (ii) can animal data be directly scaled up to humans? Current information from our laboratory suggests that in vivo P-glycoprotein activity for a given drug can be extrapolated reasonably well from in vitro data. On the other hand, there are significant species differences in P-glycoprotein transport activity between humans and animals, and the species differences appear to be substrate-dependent. Inhibition and induction of P-glycoprotein have been reported as the causes of drug-drug interactions. The potential risk of P-glycoprotein-mediated drug interactions may be greatly underestimated if only plasma concentration is monitored. From animal studies, it is clear that P-glycoprotein inhibition always has a much greater impact on tissue distribution, particularly with regard to the brain, than on plasma concentrations. Therefore, the potential risk of P-glycoprotein-mediated drug interactions should be assessed carefully. Because of overlapping substrate specificity between cytochrome P450 (CYP) 3A4 and P-glycoprotein, and because of similarities in P-glycoprotein and CYP3A4 inhibitors and inducers, many drug interactions involve both P-glycoprotein and CYP3A4. Unless the relative contribution of P-glycoprotein and CYP3A4 to drug interactions can be quantitatively estimated, care should be taken when exploring the underlying mechanism of such interactions.
To examine whether the relatively selective inhibition of hepatic cholesterol synthesis by the hydrophilic 3-hydroxyl-3-methylglutaryl-coenzyme A (HMG-CoA) reductase inhibitor pravastatin in vivo may be due to the existence of a specific uptake mechanism in the liver, the uptake by isolated rat hepatocytes was investigated. The uptake was composed of a saturable component [Michaelis constant (Km) 29 microM, maximal uptake rate 546 pmol.min-1.mg-1] and nonspecific diffusion (nonspecific uptake clearance 1.6 microliters.min-1.mg-1), inhibited by hypothermia, metabolic inhibitors, sulfhydryl-modifying reagents, and inhibitor of anion exchanger, whereas replacement of Na+ by choline+ or Cl- by gluconate- did not alter the uptake. Competitive inhibition was observed by a more highly lipophilic HMG-CoA reductase inhibitor simvastatin (open acid form), dibromosulfophthalein, cholate, and taurocholate. Pravastatin inhibited Na(+)-independent taurocholate uptake with an inhibition constant comparable with the Km value of pravastatin itself. Furthermore, the hepatic permeability clearance in vivo obtained with intact rats was comparable with that in vitro, indicating that the carrier-mediated active transport system we demonstrated in vitro is responsible for the hepatic uptake in vivo. These findings demonstrated that the hepatic uptake of pravastatin occurs via a carrier-mediated active transport mechanism utilizing the so-called multispecific anion transporter, which is common with the Na(+)-independent bile acid uptake system, and that this is one of the mechanisms for its selective inhibition of hepatic cholesterol synthesis in vivo.
The moderate level of P-gp mediated transport and low affinity of SV, SVA, and AVA for P-gp inhibition compared to systemic drug levels suggest that drug interactions due to competition for P-gp transport is unlikely to be a significant factor in adverse drug interactions. Moreover, the inconsistencies between P-gp inhibition studies and P-gp transport of SV, SVA, and AVA indicate that the inhibition studies are not a valid means to identify statins as Pgp substrates.
The drug efflux transporter P-glycoprotein (P-gp) is known to confer multidrug resistance in cancer chemotherapy. The P-gp is highly expressed in many types of tumor cells, as well as many normal tissues, including the apical surface of intestinal epithelial cells, and the luminal surface of capillary endothelial cells in the brain. Because of its expression and localization, it has been suggested that P-gp plays an important role in cancer chemotherapy, intestinal absorption, and brain uptake. This review addresses the significance of the role of P-gp in cancer chemotherapy, drug absorption, and brain uptake. Based on the clinical and animal studies with P-gp modulators, it has become apparent that the role of P-gp in multidrug resistance is far less important compared to other biological factors. Although P-gp is highly expressed in both intestinal epithelial cells and endothelial cells of brain capillaries and functions as an efflux transporter in both organs, the magnitude of P-gp's impact on intestinal absorption and brain uptake of drugs is quantitatively very different. From animal and clinical studies, it is evident that P-gp plays a very important role in CNS penetration of drugs, whereas the effect of P-gp on drug absorption is not as important as generally believed.
Multidrug resistance protein (MRP) is a broad specificity, primary active transporter of organic anion conjugates that confers a multidrug resistance phenotype when transfected into drug-sensitive cells. The protein was the first example of a subgroup of the ATP-binding cassette superfamily whose members have three membrane-spanning domains (MSDs) and two nucleotide binding domains. The role(s) of the third MSD of MRP and its related transporters is not known. To begin to address this question, we examined the ability of various MRP fragments, expressed individually and in combination, to transport the MRP substrate, leukotriene C 4 (LTC 4 ). We found that elimination of the entire NH 2 -terminal MSD or just the first putative transmembrane helix, or substitution of the MSD with the comparable region of the functionally and structurally related transporter, the canalicular multispecific organic anion transporter (cMOAT/ MRP2), had little effect on protein accumulation in the membrane. However, all three modifications decreased LTC 4 transport activity by at least 90%. Transport activity could be reconstituted by co-expression of the NH 2 -terminal MSD with a fragment corresponding to the remainder of the MRP molecule, but this required both the region encoding the transmembrane helices of the NH 2 -terminal MSD and the cytoplasmic region linking it to the next MSD. In contrast, a major part of the cytoplasmic region linking the NH 2 -proximal nucleotide binding domain of the protein to the COOH-proximal MSD was not required for active transport of LTC 4 . Multidrug resistance protein (MRP)1 is a member of the ATP-binding cassette (ABC) superfamily of transmembrane transporters (1, 2). When transfected into drug-sensitive recipient cells, MRP increases resistance to natural product chemotherapeutic agents including epipodophyllotoxins, Vinca alkaloids, and certain anthracyclines (3-6). The resistance of MRPtransfected cells is associated with an energy-dependent decrease in drug accumulation and an increase in drug efflux (4, 6). Thus MRP confers a form of multidrug resistance that shares several characteristics with that caused by overexpression of P-glycoprotein (P-gp).MRP can also act as a primary active transporter of a wide range of organic, anionic conjugates, some of which are potential physiological substrates (reviewed in Loe et al. (7)). These include a structurally diverse array of glutathione, glucuronide, and sulfate conjugates, with the cysteinyl leukotriene, LTC 4 , being one of the highest affinity MRP substrates characterized to date (8 -11). However, it has not been possible to detect binding or measure primary active transport of unmodified xenobiotics (8, 9, 12). We have been able to demonstrate MRP-mediated, ATP-dependent transport of vincristine, and more recently, aflatoxin B 1 , but only in the presence of physiological concentrations of GSH (8, 13).P-gp (encoded by the MDR1 gene) and MRP share only approximately 18% overall amino acid identity, but despite the lack of primary structure co...
The effects of different fibric acid derivatives (bezafibrate, clofibrate, clofibric acid, fenofibrate, fenofibric acid and gemfibrozil) on human organic anion transporting-polypeptide 1B1 (OATP2, OATP-C, SLC21A6), multidrug resistance protein 2 (MRP2/ABCC2) and MDR1-type P-glycoprotein (P-gp/ABCB1) were examined in vitro. Cyclosporin A (a known inhibitor of OATP1B1 and P-gp), MK-571 (a known inhibitor of MRP2) and cimetidine (an organic cation) were also tested. Bezafibrate, fenofibrate, fenofibric acid and gemfibrozil showed concentration-dependent inhibition of estradiol 17-beta-D-glucuronide uptake by OATP1B1-stably transfected HEK cells, whereas clofibrate and clofibric acid did not show any significant effects up to 100 microM. Inhibition kinetics of gemfibrozil, which exhibited the most significant inhibition on OATP1B1, was shown to be competitive with a Ki = 12.5 microM. None of the fibrates showed any significant inhibition of MRP2-mediated transport, which was evaluated by measuring the uptake of ethacrynic acid glutathione into MRP2-expressing Sf9 membrane vesicles. Only fenofibrate showed moderate P-gp inhibition as assessed by measuring cellular accumulation of vinblastine in a P-gp overexpressing cell-line. Cyclosporin A significantly inhibited OATP1B1 and P-gp, whereas only moderate inhibition was observed on MRP2. The rank order of inhibitory potency of MK-571 was determined as OATP1B1 (IC50: 0.3 microM) > MRP2 (4 microM) > P-gp (25 microM). Cimetidine did not show any effects on these transporters. In conclusion, neither MRP2- nor P-gp-mediated transport is inhibited significantly by the fibrates tested. Considering the plasma protein binding and IC50 values for OATP1B1, only gemfibrozil appeared to have a potential to cause drug-drug interactions by inhibiting OATP1B1 at clinically relevant concentrations.
The pharmacological effects of a drug are highly dependent on the absorption, metabolism, elimination, and distribution of the drug. In the past few years it has become apparent that transport proteins play a major role in regulating the distribution, elimination and metabolism of some drugs. As a consequence of our new understanding of the influence of transport proteins on the pharmacokinetic and pharmacodynamic behavior of drugs, increasing attention has been focused on the potential for drug-drug interactions arising from interactions with drug transport proteins. The efflux transporter P-glycoprotein (P-gp) has received the most attention with regard to its role in restricting drug absorption and distribution and as a potential source for variability in drug pharmacokinetics and pharmacodynamics. This review will focus on the evaluation of drug candidates to assess the potential for drug interactions at the level of P-gp. We will discuss the role of P-gp in drug disposition, the biochemistry of P-gp efflux as it relates to model systems to study drug interactions with P-gp, and the implementation of P-gp assay models within the drug discovery process.
ABSTRACT:Caspofungin (CANCIDAS, a registered trademark of Merck & Co., Inc.) is a novel echinocandin antifungal agent used in the treatment of esophageal and invasive candidiases, invasive aspergillosis, and neutropenia. Available data suggest that the liver is a key organ responsible for caspofungin elimination in rodents and humans. Caspofungin is primarily eliminated by metabolic transformation; however, the rate of metabolism is slow. Accordingly, it was hypothesized that drug uptake transporters expressed on the basolateral domain of hepatocytes could significantly influence the extent of caspofungin uptake and subsequent elimination. In this study, experiments ranging from perfused rat livers to heterologous expression of individual hepatic uptake transporters were utilized to identify the transporter(s) responsible for the observed liver-specific uptake of this compound. Data from perfused rat liver studies were consistent with the presence of carrier-mediated caspofungin hepatic uptake, although this process appeared to be slow. To identify a relevant hepatic uptake transporter, we developed novel Tet-on HeLa cells expressing OATP1B1 (OATP-C, SLC21A6) and OATP1B3 (OATP8, SLC21A8), whose target gene can be overexpressed by the addition of doxycycline. A modest but statistically significant uptake of caspofungin was observed in cells overexpressing OATP1B1, but not OATP1B3. Taken together, these findings suggest that OATP1B1-mediated hepatic uptake may contribute to the overall elimination of this drug from the body.
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