Abstract
Drug-metabolizing enzymes and transporters are key factors that affect disposition of xenobiotics. Phase I enzyme induction by classes of microsomal enzyme inducers occurs via activation of transcription factors such as aryl hydrocarbon receptor (AhR), constitutive androstane receptor (CAR), pregnane X receptor (PXR), peroxisome proliferator-activated receptor α (PPARα), and nuclear factor erythroid 2-related factor 2 (Nrf2). However, regulation of organic anion-transporting polypeptide (Oatp) uptake transporters by these factors is poorly understood. Hepatic Oatp uptake of some chemicals must occur prior to biotransformation; thus, we hypothesize that expression of Oatps and biotransformation enzymes is coordinately regulated in liver. In the present study, the effects of known chemical activators of AhR, CAR, PXR, PPARα, and Nrf2 on the hepatic mRNA expression of mouse Oatps and drug-metabolizing enzymes were quantified by the branched DNA assay. All chemicals increased the expression of their well characterized target drug-metabolizing enzymes: AhR ligands increased Cyp1A1, CAR activators increased Cyp2B10, PXR ligands increased Cyp3A11, PPARα ligands increased Cyp4A14, and Nrf2 activators induced NAD(P)H:quinone oxidoreductase 1. AhR ligands (2,3,7,8-tetrachlorodibenzo-p-dioxin, polychlorinated biphenyl 126, and β-naphthoflavone) increased Oatp2b1 and 3a1 mRNA expression in liver. CAR activators [phenobarbital, 1,4-bis[2-(3,5-dichloropyridyloxy)]benzene, and diallyl sulfide] decreased Oatp1a1 mRNA expression. Two PXR ligands [pregnenolone-16α-carbonitrile (PCN) and spironolactone] increased Oatp1a4 mRNA expression in liver, whereas PXR ligands (PCN, spironolactone, and dexamethasone) and PPARα ligands (clofibrate, ciprofibrate, and diethylhexylphthalate) decreased Oatp1a1, 1b2, 2a1, and 2b1 mRNA expression in liver. Nrf2 activators (oltipraz, ethoxyquin, and butylated hydroxyanisole) down-regulated Oatp1a1 but up-regulated Oatp2b1 mRNA expression. Therefore, only a few transcription factor activators increased Oatp expression, and, surprisingly, many decreased Oatp expression.
Induction of phase I enzymes by microsomal enzyme inducers (MEIs) can be attributed to activation of signal-transduction pathways. Many MEIs exert their effects through activation of various orphan nuclear receptors, subsequently enhancing target gene transcription (Denison and Nagy, 2003; Sonoda et al., 2003). For example, 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) binds to the aryl hydrocarbon receptor (AhR), which subsequently releases the AhR from the cytosolic tethering protein HSP90, allowing for AhR translocation to the nucleus, heterodimerization with ARNT, and binding to xenobiotic response elements in the Cyp1A1 promoter. Similarly, constitutive androstane receptor (CAR) ligands induce Cyp2B10, pregnane X receptor (PXR) ligands induce Cyp3A11, and peroxisome proliferator-activated receptor α (PPARα) ligands induce Cyp4A14. The nuclear factor erythroid 2-related factor 2 (Nrf2) pathway is more complex: both antioxidants and oxidants can either alter the tethering protein Keap1 by sulfhydryl modifications or alter the cellular oxidative state in such a way as to allow Nrf2 to be released, allowing for subsequent translocation of Nrf2 to the nucleus, heterodimerization with small Maf proteins, and binding to EpRE/ARE in the promoter regions of genes, such as NAD(P)H:quinone oxidoreductase 1 (Nqo1) (Jaiswal, 2000).
Examples of receptor-mediated regulation of Oatp transporters have also been reported in the literature, such as the induction of Oatp1a4, via PXR activation and subsequent binding to the 5′-flanking region of the rat Oatp1a4 gene (Guo et al., 2002b). Similar observations in wild-type mice, but not in PXR-null mice, have also been reported (Staudinger et al., 2001a,b; Sonoda et al., 2002). Other observations, such as the decrease in Oatp1a4 expression in rats after treatment with the AhR ligand polychlorinated biphenyl (PCB) 126, suggest a receptor-mediated mechanism (Guo et al., 2002a).
Hepatic uptake must occur for some chemicals before undergoing biotransformation. Oatp uptake transporters function as an important part of the “first-pass” extraction of chemicals from systemic circulation into liver. Therefore, the potential for coregulation of drug-metabolizing enzymes and transporters exists because uptake and biotransformation of drugs could theoretically occur by a coordinated receptor activation mechanism. One such example exists with the PXR ligand pregnenolone-16α-carbonitrile (PCN), which markedly enhances both plasma disappearance and biliary excretion of cardiac glycosides in rats (Klaassen, 1974). Recently, the uptake transporter Oatp1a4, which transports cardiac glycosides with high affinity (Noé et al., 1997), has been shown to be induced by PCN in rats (Rausch-Derra et al., 2001; Guo et al., 2002a,b). Cardiac glycosides are taken up into the liver by Oatp1a4 in rodents, biotransformed by Cyp3A and UDP-glucuronosyltransferases (UGTs), and excreted into bile via the canalicular transporter Mdr1. Activation of PXR by PCN leads to coordinate induction of Oatp1a4, Cyp3A, and UGTs, as well as biliary excretion of cardiac glycosides (Klaassen, 1974; Rausch-Derra et al., 2001; Guo et al., 2002a,b; Chen et al., 2003). Another example of coordinate regulation of transporters and drug-metabolizing enzymes is with phenobarbital (PB), a CAR activator. PB increases the plasma clearance of the Oatp substrate bilirubin (Klaassen, 1970), thus implicating an uptake transporter, and furthermore induces bilirubin UGT1A1 in liver (Ritter et al., 1999).
There is limited information linking Oatp transporter regulation with phase I enzymes via transcription factor activation. Therefore, we hypothesize that the expression of drug-metabolizing enzymes and Oatps might be coordinately regulated in liver. In the present study, we investigate the effect of MEIs with known mechanisms of induction on mouse Oatp expression, to determine whether there is a correlation in the regulation of drug-metabolizing enzymes with Oatps in mouse liver.
Materials and Methods
Chemicals. TCDD was a gift from Dr. Karl Rozman (University of Kansas Medical Center, Kansas City, KS). Oltipraz was a gift from Dr. Steven Safe (Texas A&M University, College Station, TX). PCB126 was obtained from AccuStandard (New Haven, CT). All other chemicals, unless otherwise indicated, were purchased from Sigma-Aldrich (St. Louis, MO).
Animals and Treatments. Eight-week-old male C57BL/6 mice were purchased from The Jackson Laboratory (Bar Harbor, ME). Groups of five mice were administered one of the following chemicals once daily for 4 days: AhR ligands, TCDD (40 μg/kg i.p. in corn oil), β-naphthoflavone (BNF; 200 mg/kg i.p. in corn oil), and PCB126 (300 μg/kg p.o. in corn oil); CAR activators, PB (100 mg/kg i.p. in saline), TCPOBOP (3 mg/kg i.p. in corn oil), and diallyl sulfide (DAS; 200 mg/kg i.p. in corn oil); PXR ligands, PCN (200 mg/kg i.p. in corn oil), spironolactone (SPR; 200 mg/kg i.p. in corn oil), and dexamethasone (DEX; 75 mg/kg i.p. in corn oil); PPARα ligands, clofibric acid (CLFB; 500 mg/kg i.p. in saline), ciprofibrate (CPFB; 40 mg/kg i.p. in saline), and diethylhexylphthalate (DEHP; 1000 mg/kg p.o. in corn oil); Nrf2 activators, butylated hydroxyanisole (BHA; 350 mg/kg i.p. in corn oil), ethoxyquin (ETHOXYQ; 250 mg/kg p.o. in corn oil), and oltipraz (OPZ; 150 mg/kg p.o. in corn oil). Four different vehicle control groups (corn oil by i.p., corn oil by p.o., saline by i.p., and saline by p.o. routes) were used. No statistical difference between these groups was observed; thus, these groups were averaged together as a single vehicle control group. All injections were administered in a volume of 10 ml/kg. Livers were removed on day 5, snap-frozen in liquid nitrogen, and stored at –80°C.
RNA Isolation. Total RNA was isolated using RNAzol Bee reagent (Tel-Test Inc., Friendswood, TX) per the manufacturer's protocol. The concentration of total RNA in each sample was quantified spectrophotometrically at 260 nm. The integrity of each RNA sample was evaluated by formaldehydeagarose gel electrophoresis before analysis.
Branched DNA (bDNA) Signal Amplification Assay. The mRNA for mouse Oatps (Oatp1a1, 1a4, 1a5, 1a6, 1b2, 1c1, 2a1, 2b1, 3a1, and 4a1) and five drug-metabolizing enzymes (Cyp1A1, Cyp2B10, Cyp3A11, Cyp4A14, and Nqo1) was quantified using the bDNA assay (QuantiGene bDNA signal amplification kit; Genospectra, Fremont, CA), with modifications according to Hartley and Klaassen (2000). The gene sequences of mouse Oatps and biotransformation enzymes were accessed from GenBank. Multiple oligonucleotide probe sets (containing capture probes, label probes, and blocker probes) specific to a single mRNA transcript were designed using ProbeDesigner software, version 1.0 (Bayer Corp., Emeryville, CA). Every probe developed in ProbeDesigner was submitted to the National Center for Biotechnology Information (Bethesda, MD) for nucleotide comparison by the basic local alignment search tool (BLASTn; National Center for Biotechnology Information), to ensure minimal cross-reactivity with other known mouse sequences and expressed sequence tags. Oligonucleotides with a high degree of similarity (>80%) to other mouse gene transcripts were eliminated from the design. Probes were designed with a melting temperature of approximately 63°C, enabling hybridization conditions to be held constant (i.e., 53°C) during each hybridization step and for each probe set. The probe sets for mouse Oatps have been published previously (Cheng et al., 2005). Probe sets for mouse cytochromes P450 and Nqo1 are shown in Table 1. All probes were synthesized (i.e., 50-nmol synthesis scale) by QIAGEN Operon (Palo Alto, CA) and were obtained desalted and lyophilized. Total RNA (1 μg/μl) was added to each well (10 μl/well) of a 96-well plate containing 50 μl of capture hybridization buffer and 50 μl of each diluted probe set. For each gene, total RNA was allowed to hybridize to the probe set overnight at 53°C. Subsequent hybridization steps were carried out according to the manufacturer's protocol, and luminescence was quantified with a Quantiplex 320 bDNA luminometer (Chiron Corp., Emeryville, CA) interfaced with Quantiplex Data Management Software, version 5.02 (Bayer Corp.-Diagnostics Div., Tarrytown, NY) for analysis of luminescence from 96-well plates. The luminescence for each well is reported as relative light units (RLU) per 10 μg of total RNA.
Statistics. The data are expressed as mean ± S.E. Statistical significance was determined by one-way analysis of variance, followed by Duncan's post hoc test. Statistical significance was set at P < 0.05.
Results
Effects of the Prototypical Microsomal Enzyme Inducers on the mRNA Levels of Mouse Biotransformation Enzymes. Male C57BL/6 mice were dosed with five classes of prototypical drug-metabolizing enzyme inducers. Each class contains three chemicals that are known to transcriptionally activate a specific signaling pathway. The doses were chosen according to what is commonly cited in the literature to activate specific transcription factors that target specific biotransformation enzymes (Cyp1A1, Cyp2B10, Cyp3A11, Cyp4A14, and Nqo1). To confirm that the doses selected were effective, the mRNA levels of these marker genes were quantified (Fig. 1). The mRNA levels of Cyp1A1 were increased by treatment with the AhR ligands TCDD (1230-fold), BNF (1230-fold), and PCB126 (1170-fold). The mRNA levels of Cyp2B10 were increased by the CAR activators (PB, 15-fold; TCPOBOP, 150-fold; and DAS, 22-fold). The mRNA levels of Cyp3A11 were increased by the PXR ligands (PCN, 5-fold; SPR, 5-fold; and DEX, 5-fold). The mRNA levels of Cyp4A14 were increased by the PPARα ligands (CLFB, 22-fold; CPFB, 93-fold; and DEHP, 87-fold). The mRNA levels of Nqo1 were increased by Nrf2 activators (BHA, 3-fold; ETHOXYQ, 5-fold; and OPZ, 2-fold).
In addition to the well characterized induction profile of drug-metabolizing enzymes by the five classes of MEIs, as shown in Fig. 1 and Table 2, there exists some nonspecificity of the transcription factor activators, since some of the chemicals administered induced the expression of genes in addition to their known target gene. As shown in Fig. 1, AhR ligands markedly induced Cyp1A1 as predicted, but these compounds as a class also induced Cyp3A11 and Nqo1 mRNA expression. CAR activators up-regulated not only Cyp2B10, but also Cyp3A11 and Nqo1 expression. PXR ligands were relatively specific in that they only induced Cyp3A11, with the exception of DEX, which also induced Cyp2B10. PPARα ligands were also relatively specific in that they primarily induced Cyp4A14, except DEHP, which also induced Cyp3A11 expression. Nrf2 activators mediated not only Nqo1 induction, but also Cyp3A11 induction, and ETHOXYQ increased Cyp2B10. Most microsomal enzyme inducers increased Cyp3A11.
Effects of the Prototypical Microsomal Enzyme Inducers on the mRNA Levels of Mouse Oatps. The regulation of mouse Oatps by microsomal enzyme inducers is shown in Figs. 2, 3, and 4. The effects of five classes of transcriptional activators on mouse Oatp1a1 mRNA expression are shown in Fig. 2. CAR activators, PXR ligands, and PPARα ligands, and the majority of AhR activators and Nrf2 activators decreased Oatp1a1 expression. Thus Oatp1a1 mRNA expression was decreased by all five classes of transcriptional activators tested.
Oatp1a4 is a sinusoidal uptake transporter that is known for transporting digoxin with high affinity (Noé et al., 1997). Mouse Oatp1a4 is up-regulated by PCN treatment (Staudinger et al., 2001a,b), which was also observed in the present study. Another PXR ligand, spironolactone, induced Oatp1a4 mRNA expression approximately 2-fold. The Nrf2 activator BHA also induced Oatp1a4 mRNA about 2-fold. Otherwise, Oatp1a4 mRNA was not significantly altered by treatment with any of the AhR, CAR, or PPARα activators (Fig. 2).
Regulation of Oatp1a5 in liver by classes of microsomal enzyme inducers is shown in Fig. 2. The expression of Oatp1a5 is minimal in liver, which has been reported previously (Choudhuri et al., 2003). The majority of CAR and PXR ligands decreased Oatp1a5 mRNA levels.
Like Oatp1a5, Oatp1a6 is minimally expressed in liver. Regulation of Oatp1a6 by the microsomal enzyme inducers is shown in Fig. 2. There was no significant alteration of Oatp1a6 expression following the treatment with any class of compound except for PPARα activators, which slightly decreased Oatp1a6.
Regulation of mouse Oatp1b2, a liver-predominant Oatp, is shown in Fig. 3. The AhR, PXR, PPARα, and Nrf2 activators did not alter Oatp1b2 mRNA expression as a class. Individually, the AhR ligand PCB126 increased Oatp1b2 mRNA expression, whereas the AhR ligand TCDD and the PXR ligand PCN decreased Oatp1b2 mRNA expression.
Regulation of Oatp1c1, which is minimally expressed in liver by the five classes of transcription factor activators, is shown in Fig. 3. None of the five classes of chemicals altered Oatp1c1 expression.
Chemical regulation of Oatp2a1, a prostaglandin transporter, is shown in Fig. 3. Both PXR and PPARα ligands caused a class-wide decrease in Oatp2a1 mRNA expression. Furthermore, an AhR ligand, BNF, and an Nrf2 activator, BHA, increased Oatp2a1 mRNA expression, but other AhR and Nrf2 activators did not alter Oatp2a1 mRNA expression.
Oatp2b1 is also a liver-predominant Oatp. As shown in Fig. 4, expression of Oatp2b1 was decreased by PXR and PPARα ligands, and increased by AhR and Nrf2 activators. Two CAR activators, PB and DAS, decreased Oatp2b1 mRNA expression. However, TCPOBOP, a third CAR activator, increased Oatp2b1 mRNA expression.
Oatp3a1 and 4a1 are minimally expressed in liver. Regulation of these two transporters by the five classes of transcription factor activators is shown in Fig. 4. All AhR ligands increased Oatp3a1 mRNA expression, whereas PXR ligands decreased Oatp3a1 mRNA expression. As also shown in Fig. 4, none of the five classes of ligands (AhR ligands, CAR activators, PXR ligands, PPARα ligands, and Nrf2 activators) caused a class-specific alteration of Oatp4a1 expression. Because of the minimal expression of Oatp3a1 and 4a1 in liver, any change in the function of these transporters associated with alterations in mRNA expression may be biologically irrelevant.
Discussion
Virtually all chemicals were once believed to enter the liver through passive diffusion; however, an emerging role for the Oatp family in hepatic uptake suggests a more important role for transporters than once believed. In vivo, uptake transporters such as OATPs/Oatps are necessary for some chemicals to cross the membrane to access phase I and II enzymes. However, in vitro assays such as microsomal preparations allow for direct access of a substrate to these microsomal enzymes. Therefore, regulation of uptake transport by microsomal enzyme inducers may lead to increased availability of drugs and chemicals for metabolism. Thus, integration of the regulation of the four processes (uptake, phase I metabolism, phase II metabolism, and efflux) may increase the efficacy of detoxication. This study examines the potential of transcription factors that activate phase I drug metabolism to also affect the regulation of Oatp hepatic uptake transporters.
Phase I drug-metabolizing enzymes often have low expression in naive liver but can be induced tens- to hundreds-fold after exposure to chemicals that activate specific transcription factors. Except for Cyp3A11, the basal expression of phase I enzymes examined in this study (Cyp1A1, Cyp2B10, Cyp4A14, and Nqo1) is very low in liver. However, AhR ligands (TCDD, BNF, and PCB126) induced Cyp1A1 over 1000-fold, CAR activators produced 20 times more Cyp2B10 mRNA, and PPARα ligands increased Cyp4A14 mRNA 120-fold (Fig. 1). The most robust up-regulation of these cytochromes P450, such as the induction of Cyp1a1 after TCDD exposure, has been extensively examined (Jaiswal et al., 1985; Jones et al., 1986). Furthermore, transcriptional up-regulation of Cyp1A1 seems to be monospecific, since Cyp1A1 is almost exclusively regulated by AhR. However, more recent studies have demonstrated that some phase I enzymes, such as Cyp3A11 and Nqo1, may be regulated by several transcription factor activators, as observed in the present work (Fig. 1; Table 2). Increases in Cyp3A4 expression after exposure to inducers are thought to occur primarily through PXR activation and subsequent binding to everted repeat 6 response elements in the 5′ flanking regions of Cyp3A4 (Lehmann et al., 1998; Xie et al., 2000). In humans, exposure to rifampicin or RU486 can evoke a similar increase in Cyp3A4 via PXR activation, whereas in rodents, Cyp3A11 is up-regulated by chemicals such as PCN and DEX (Lehmann et al., 1998; Staudinger et al., 2001a,b). However, the expression of Cyp3A4 can also be markedly increased after treatment with PB or DEX (Fig. 1) (Burk et al., 2004; Zhang et al., 2004). Known up-regulation of Cyp3A after activation of CAR or the glucocorticoid receptor (Xie et al., 2000; Pascussi et al., 2001) demonstrates that multiple receptors can regulate Cyp3A11 by different classes of chemicals, such as CAR activators (PB, TCPOBOP) and Nrf2 activators (OPZ and ETHOXYQ). However, the induction of Cyp3A11 by AhR ligands and Nrf2 activators suggests a novel mechanism of Cyp3A11 regulation (Fig. 1). Overlap of Nrf2/AhR activators has been observed previously for other phase I and II enzymes, including UGT1A6 by oltipraz and induction of Nqo1 by TCDD (Auyeung et al., 2003; Ma et al., 2004). It has been suggested that oxidative stress can induce CYP3A4 expression in the human erythroleukemia cell line K562 (Nagai et al., 2004). The protective role of Nrf2 in oxidative stress has been well established, and these results, when taken together, may suggest a role for Nrf2 in regulation of Cyp3A11.
Another novel observation from this study is that TCPOBOP, an efficacious CAR activator, and DAS, a garlic component, up-regulate Nqo1 mRNA expression (Fig. 1). The mechanism of TCPOBOP and DAS induction of Nqo1 is not known, but it could be due to generation of reactive oxidants by the increased amount of Cyp2B. A precedent for this possibility is the induction of Nqo1 by TCDD. Nrf2 is an important regulator of Nqo1 expression, but Nqo1 can also be up-regulated in response to AhR ligands such as TCDD (Jaiswal, 1991; Marchand et al., 2004). Recent studies have shown that chemicals with strong AhR ligand binding, such as TCDD, induce Nqo1 via Nrf2 (Ma et al., 2004). Nqo1 induction is thought to be a result of increased Cyp1A1 activity, which leads to an increased production of oxidative metabolites. These reactive species activate Nrf2, which ultimately up-regulates Nqo1. Therefore, CAR activators may also indirectly cause oxidative stress by up-regulation of phase I enzymes, and this generation of oxidative stress may ultimately increase expression of Nrf2 target genes (Fig. 1).
Information on chemical regulation of Oatp transporters is limited, but there are some reports on the regulation of Oatps after exposure to various challenges. For example, PCN treatment increases hepatic Oatp1a4 mRNA expression in rats (Rausch-Derra et al., 2001; Guo et al., 2002a,b), and in mice (Staudinger et al., 2001a,b). Lipopolysaccharide dramatically decreases Oatp1a1, 1a4, and 1b2 mRNA expression in rats (Cherrington et al., 2004) and Oatp1b2 in mice (Li et al., 2004). Cholic acid, an Oatp substrate, increases Oatp1a4 but decreases Oatp1b2 protein expression in rats (Rost et al., 2003). Carbon tetrachloride decreases mRNA expression of Oatp1a1 and 1a4 in rats and mice, but not 1b2 (Geier et al., 2002; Aleksunes et al., 2005). Thus, reports on Oatp regulation are few, with the data predominately from rats. The present study provides a systematic evaluation of the effects of MEIs on Oatp expression in mice. The effects of altered expression of Oatp transporters will ultimately aid in predicting drug-drug interactions at the level of hepatic uptake, whereas therapeutic modulation of Oatp expression by chemicals may also be clinically beneficial in hepatic disease states such as cholestasis or fibrosis.
Oatp transporters, in general, are not up-regulated by microsomal enzyme inducers as are the cytochromes P450, and more often are decreased than increased, as summarized in Table 2. The AhR class of ligands up-regulated Oatp2b1 and 3a1 expression to a modest extent (Figs. 3 and 4). CAR ligands down-regulated Oatp1a1 and 1a5 mRNA expression, and slightly down-regulated Oatp2b1 (Figs. 2, 3, and 4). PXR ligands altered the expression of several Oatps, including down-regulation of Oatp1a1, 1a5, 2a1, 2b1, and 3a1, although the decreases in expression were modest (Figs. 2, 3, and 4). Conversely, the PXR ligands induced expression of Oatp1a4. PPARα activators also decreased Oatp1a1, 1a6, 2a1, and 2b1 mRNA expression (Figs. 2, 3, and 4). Finally, the majority of Nrf2 activators decreased Oatp1a1 mRNA expression (Fig. 2), whereas only Oatp2b1 was increased by the Nrf2 class of activators (Fig. 4).
Increased uptake and biotransformation can enhance either the elimination and detoxication or the hepatotoxicity of chemicals (Nozawa et al., 2004). For example, microcystin and phalloidin, two Oatp substrates, cause hepatotoxicity after accumulating in the liver (Hagenbuch and Meier, 2003). Conversely, pretreatment of rats with PCN or SPR (PXR ligands) decreases the toxicity of digoxin by increasing hepatic uptake and biotransformation, via PXR activation and subsequent up-regulation of Oatp1a4 and Cyp3A11. Similarly, induction of Oatp1A4 and Cyp3A11, and down-regulation of Cyp7A1 have been observed after PXR activation by lithocholic acid. This mechanism is believed to occur as a feedback pathway to protect the liver from bile acid toxicity by decreasing bile acid synthesis, and increasing uptake and metabolism of hydrophobic bile acids by increasing Oatp1a4 and Cyp3A11 levels (Staudinger et al., 2001a,b).
In summary, the present study examines expression of some phase I enzymes known to be regulated by specific transcription factors, in parallel with Oatp expression. The induction profile of biotransformation enzymes by these prototypical MEIs was generally similar to that reported in the literature; however, some novel observations were observed in this study, including the induction of Cyp3A11 by AhR and Nrf2 activators, Cyp2B10 by ETHOXYQ, and Nqo1 by CAR activators. In general, the MEIs used in this study induced their corresponding phase I enzyme to a far greater extent than any up-regulation observed with the Oatp family members. Furthermore, no significant down-regulation was observed with the phase I enzymes, whereas several of the Oatps were down-regulated after MEI exposure. The Oatps were generally not induced by chemical activators after treatment. However, down-regulation in hepatic Oatp expression, especially of the highly expressed Oatp1a1, was observed after exposure to a variety of compounds. This could suggest that a hepatoprotective mechanism may exist to protect against further hepatic uptake by Oatp transporters after MEI exposure. Down-regulation of Oatps would result in decreased uptake of substrates into liver, thus decreasing the chemical challenge to the liver and serving to protect hepatocytes from chemical toxicity. Thus, the effects of MEI exposure on phase I enzyme regulation are generally opposite to the effects on Oatp expression, with the notable exception of Cyp3A11 and Oatp1a4, which are up-regulated in parallel after PXR activation.
Footnotes
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This work was supported by National Institutes of Health Grant ES-09649 to C.D.K.
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Article, publication date, and citation information can be found at http://dmd.aspetjournals.org.
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doi:10.1124/dmd.105.003988.
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ABBREVIATIONS: MEI, microsomal enzyme inducer; TCDD, 2,3,7,8-tetrachlorodibenzo-p-dioxin; AhR, aryl hydrocarbon receptor; ARNT, aryl hydrocarbon receptor nuclear translocator; CAR, constitutive androstane receptor; PXR, pregnane X receptor; PPARα, peroxisome proliferatoractivated receptor α; Nrf2, nuclear factor erythroid 2-related factor 2; Nqo1, NAD(P)H:quinone oxidoreductase 1; Oatp, organic anion-transporting polypeptide; PCB126, polychlorinated biphenyl 126; PCN, pregnenolone-16α-carbonitrile; UGT, UDP-glucuronosyltransferase; PB, phenobarbital; BNF, β-naphthoflavone; TCPOBOP, 1,4-bis[2-(3,5-dichloropyridyloxy)]benzene; DAS, diallyl sulfide; SPR, spironolactone; DEX, dexamethasone; CLFB, clofibric acid; CPFB, ciprofibrate; DEHP, diethylhexylphthalate; BHA, butylated hydroxyanisole; ETHOXYQ, ethoxyquin; OPZ, oltipraz; bDNA, branched DNA; RU486, 17β-hydroxy-11β-[4-dimethylamino phenyl]-17α-[1-propynyl]estra-4,9-dien-3-one; RLU, relative light units.
- Received February 1, 2005.
- Accepted May 25, 2005.
- The American Society for Pharmacology and Experimental Therapeutics