Induction of Rat Organic Anion Transporting Polypeptide 2 by Pregnenolone-16alpha -carbonitrile Is via Interaction with Pregnane X Receptor

doi:10.1124/mol.61.4.832

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Vol. 61, Issue 4, 832-839, April 2002

Induction of Rat Organic Anion Transporting Polypeptide 2 by Pregnenolone-16 $alpha$ -carbonitrile Is via Interaction with Pregnane X Receptor

Grace L. Guo, Jeff Staudinger,¹ Kenichiro Ogura,² and Curtis D. Klaassen

Department of Pharmacology, Toxicology, and Therapeutics, University of Kansas Medical Center, Kansas City, Kansas

	Abstract

Top Abstract Introduction Experimental Procedures Results Discussion References

The rat organic anion transporting polypeptide 2 (oatp2; Slc21a5) is a liver transporter that mediates the uptake of a varietyof structurally diverse compounds, and has a high affinity forcardiac glycosides. Treatment of rats with pregnenolone-16 $alpha$ -carbonitrile(PCN), a ligand for the rodent pregnane X receptor (PXR), significantlyenhances the rat oatp2 gene expression. To understand the molecularmechanism of oatp2 induction by PCN, rat oatp2 gene was cloned.The rat oatp2 gene consists of 16 exons; alternative splicingof the second noncoding exon gives rise to the two published ratoatp2 cDNAs. Approximately 8700 base pairs (bp) of the 5'-flankingregion of the rat oatp2 gene were linked to the luciferase reportergene and used in transient transfection assays in H4IIE cells.Treatment of PCN induced the expression of the reporter gene ina dose-dependent manner. Four potential PXR response elements(PXREs) were identified in the 5'-flanking region of the rat oatp2gene. One element (DR3-1) is located approximately $-$ 5000 bp withthree more (DR3-2, DR3-3, and DR3-4) clustered at about $-$ 8000bp. Results from electrophoretic mobility shift assays showedthat the PXR-retinoid X receptor $alpha$ heterodimer binds to the DR3-2with the highest affinity, to the DR3-4 and DR3-1 with a loweraffinity, and weakly or not at all to the DR3-3. Furthermore,a series of partial deletions of the 5'-flanking region illustratedthat both the proximal and distal clusters of PXREs are requiredfor maximal induction of rat oatp2 by PCN. In conclusion, thesedata elucidate the molecular mechanism by which PCN treatmentinduces rat oatp2 gene expression. In addition, this study identifiesrat oatp2 as a direct PXR-targeted gene and further supports thehypothesis that activation of PXR affects a network of genes thatis involved in either metabolism or transport of drugs, steroids,and bileacids.

	Introduction

Top Abstract Introduction Experimental Procedures Results Discussion References

Organic anion transporting polypeptide 2 (oatp2; Slc21a5) is a member of the organic anion transporting polypeptide familythat mediates sodium- and ATP-independent transport of a varietyof structurally unrelated endogenous and exogenous compounds,including conjugated and unconjugated bilirubin, conjugated steroids,neutral compounds, some type II organic cations, thyroid hormonesT3 and T4, and bile salts (Reichel et al., 1999; Suzuki and Sugiyama,2000). Cardiac glycosides, such as digoxin and ouabain, are transportedwith very high affinity by oatp2 (Noe et al., 1997). Oatp2 islocalized to the hepatic sinusoidal membrane (Noe et al., 1997;Abe et al., 1998, 1999), with selective expression in the midzonalto perivenous hepatocytes (Reichel et al., 1999). Expression ofoatp2 has also been detected in brain and retina (Noe et al.,1997; Abe et al., 1998, 1999; Gao et al., 1999).

Research from this laboratory has demonstrated that hepatic uptake of cardiac glycosides increases after treatment with somemicrosomal enzyme inducers, such as phenobarbital and pregnenolone-16 $alpha$ -carbonitrile(PCN) (Klaassen and Plaa, 1968; Klaassen, 1970a,b, 1974a,b; Eatonand Klaassen, 1979). However, the mechanism(s) by which this phenomenonoccurs is unknown. The advances in cloning of hepatic transportershave made the in-depth investigation of this phenomenon possible.Research from this laboratory demonstrated that the protein andmRNA expression of rat hepatic oatp2 are increased by PCN treatmentin adult and newborn animals (Klaasen et al., 2000; Rausch-Derraet al., 2001). The induction of oatp2 by PCN seems to be due toincreased transcription of the oatp2 gene (Guo et al., 2002).

PCN is a synthetic antiglucocorticoid identified by virtue of its ability to induce protection from various forms of intoxicantsin rodents (Selye, 1971). Further research revealed that PCN mediatedthis protection from chemical poisons by inducing drug-metabolizingactivities in liver (Kourounakis et al., 1976). It was subsequentlydiscovered that PCN treatment induces the transcription of theCYP3A subfamily of cytochrome P450 monooxygenases, which metabolizeover half of the environmental chemicals and clinically prescribeddrugs (Quattrochi and Guzelian, 2001). Induction of the rat CYP3A1gene by PCN is mediated through activation of the orphan nuclearreceptor family member PXR (NR112; Barnouin et al., 1998; Klieweret al., 1998).

PXR has been cloned in multiple species, including the rat (Zhang et al., 1999), mouse (Kliewer et al., 1998), rabbit (Savaset al., 2000), and human (Bertilsson et al., 1998; Blumberg etal., 1998; Lehmann et al., 1998), in which PXR is also calledthe steroid and xenobiotic receptor. PXR and CYP3A gene expressionare highest in those tissues that are the primary sites of drug-metabolizingenzymes, namely, liver, intestine, and kidney (Kliewer et al.,1998). Ligands that bind to a given species of PXR correspondto their ability to induce CYP3A expression in that species (Joneset al., 2001). PXR binds to specific response elements organizedas direct repeats containing the consensus sequence of AGG(T)TCAspaced by three nucleotides (DR3), or to everted repeats spacedby six nucleotides, as a heterodimer with the 9-cis retinoic acidreceptor (RXR $alpha$ , NR2B1; Quattrochi et al., 1995; Barwick et al.,1996; Huss et al., 1996; Blumberg et al., 1998). In addition,PXR regulates transcription through binding a direct repeat spacedby four nucleotides (DR4) in the 5'-flanking region of human MDR1,the gene that encodes human P-glycoprotein (Geick et al., 2001;Synold et al., 2001). Recently, Kast et al. (2002) reported thatmultidrug resistance-associated protein 2 is also a targeted PXRgene. Data generated using a PXR "knockout" mice in this laboratorysuggest that PXR is required for induction of mouse oatp2 by PCN(Staudinger et al., 2001).

Although xenobiotic compounds are routinely cleared by biotransformation, uptake of chemicals by hepatic sinusoidal transportersis critical for some chemicals to enter hepatocytes for subsequentbiotransformation and eventual excretion. Oatp2 is a transporterthat functions to mediate the hepatic uptake of a broad arrayof chemicals and drugs. The molecular mechanism by which PCN inducesrat oatp2 has not been investigated. Therefore, it is hypothesizedthat induction of oatp2 by PCN would be due to activation of PXR,which would bind to a PXR response element(s) in the 5'-flankingregion of rat oatp2 gene and activate oatp2 gene expression. Inthe present study, a rat oatp2 genomic clone was isolated, exon-intronjunctions of oatp2 gene were determined, and the 5'-flanking regionof oatp2 was sequenced in an effort to search for a PXR responseelement(s). The present study demonstrates that induction of oatp2by PCN seems to be due to direct interaction of PXR and the 5'-flankingregion of rat oatp2gene.

	Experimental Procedures

Top Abstract Introduction Experimental Procedures Results Discussion References

Materials. Restriction enzymes, T4 kinase, T4 DNA ligase, Klenow fragment, and terminal transferase were purchased from Invitrogen (Carlsbad,CA), unless otherwise indicated. Zeta probe membrane was obtainedfrom Bio-Rad (Hercules, CA). [ $alpha$ -³²P]ATP and [ $gamma$ -³²P]ATP were obtained from Amersham Biosciences, Inc. (Piscataway,NJ).

Genomic Cloning. A rat genomic bacterial artificial chromosome (BAC) library (BAC Rat Genomic library; Genome Systems, St. Louis, MO) was screenedwith a 636-bp ScaI fragment, containing part of the C-terminalcoding sequence and part of the 3'-untranslated region (UTR) fromrat oatp2 cDNA (generously provided by Dr. Peter Meier, UniversityHospital, Zurich, Switzerland; Genome Systems performed the libraryhybridization screening). One positive BAC clone containing anapproximately 90-kb insert was isolated and confirmed to be arat oatp2 genomic clone by partial gene sequencing. This BAC clonewas used for sequencing of intron-exon junctions and the 5'-flankingregion with an ABI Prism 377 DNA sequencer (Applied Biosystems,Foster City, CA), by using primers designed from rat oatp2 cDNA.Where necessary, sequencing was done with primer walking, by usingprimers designed from each newly obtained genomic sequence. Oligonucleotideprimer synthesis and sequencing reactions were performed at theBiotechnology Support Facility at the University of Kansas MedicalCenter (Kansas City,KS).

Sequence Analysis. Sequence alignments and analysis were performed with Dnasis software (Dnasis, version 2.1; Hitachi Software Engineering, Yokohama,Japan). The transcription factor-binding sites were predictedwith TRANSFAC 4.0 software (http://transfac.gbf.de/cgi-bin/matSearch/matsearch2.pl).

Putative Transcription Start Site Determination. 5'-Rapid amplification of cDNA ends (5'-RACE) was performed to determine the putative transcription start site for rat oatp2,by using rat Marathon-Ready cDNA library (CLONTECH, Palo Alto,CA) per the manufacturer's instructions. Oatp2 gene-specific primerfor the RACE was designed and synthesized based on the cDNA sequenceof rat oatp2 cloned by Noe et al. (1997). The 5'-RACE was performedwith Adapter primer 1 that came with the kit and oatp2 gene-specificprimer 5'-CCT TCA TAA GAG GTT GTT AAG CCT GCC ACT GGA-3'. PCRwas performed using Marathon cDNA amplification kit as follows:94°C × 45 s; 5 cycles of 94°C × 5 s, 72°C × 4 min; 5 cycles of94°C × 5 s, 70°C × 4 min; 28 cycles of 94°C × 5 s, 68°C × 4 min;and a final extension at 72°C × 10 min. The RACE products weresubcloned into pT-Adv vector (CLONTECH) and sequenced with ABIPrism 377 DNA sequencer (AppliedBiosystems).

Sequencing of 5'-Flanking Region of Rat oatp2 Gene. The 5'-flanking region of rat oatp2 gene was sequenced with primer walking, by using primers designed from each newly obtainedgenomic sequence. Whenever multiple priming was encountered, theprimers were designed from a sequence further to the 3' end ofthe last sequencingresult.

Electrophoretic Mobility Shift Assays. Electrophoretic mobility shift assays were performed as described previously (Goodwin et al., 2001). Rat PXR1 and human RXR $alpha$ were synthesized in vitro by using the TNT rabbit reticulocytelysate-coupled in vitro transcription/translation system (Promega,Madison, WI) according to the manufacturer's instructions. Gelmobility shift assays (20 µl) contained 10 mM Tris, pH 8.0, 40mM KCl, 0.05% Nonidet P-40, 6% glycerol, 1 mM dithiothreitol,0.2 µg of poly(dI-dC), and 2.5 µl each of in vitro-synthesizedPXR and RXR proteins. The total amount of reticulocyte lysatewas maintained constant in each reaction (5 µl) through the additionof unprogrammed lysate. Competitor oligonucleotides were includedat 5-, 25-, 50-, or 100-fold excess as indicated in the figurelegends. After 10-min incubation on ice, 10 ng of ³²P-labeled oligonucleotide was added and the incubation was continuedfor an additional 10 min. DNA-protein complexes were resolvedon a 4% polyacrylamide gel in 0.5× Tris borate-EDTA (1× Tris borate-EDTAis 90 mM Tris, 90 mM boric acid, 2 mM EDTA). Gels were dried andsubjected to autoradiography at $-$ 80°C. The oligonucleotides usedas probes or competitors corresponding to the wild-type and mutantDR3 of CYP3A1, DR3-1, DR3-2, DR3-3, and DR3-4 of oatp2 are detailedin Table 1.

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TABLE 1
Oligonucleotides for electrophoretic mobility shift assays

Reporter Gene Construction. Different constructs containing the 5'-flanking region of rat oatp2 were subcloned into pGL3-basic luciferase gene vector(generously provided by Dr. Michael Wolfe, University of KansasMedical Center), and the sequences of these constructs were confirmedby sequencing.

1.   pGL3-basic-oatp2-( $-$ 8701)-(+49). Oatp2 genomic DNA was digested with restriction enzymes SstI and XhoI to produce the $-$ 3111to $-$ 8701 segment of the oatp2 promoter, which was confirmed byPCR screening, and was isolated and cloned into PGL-3 basic vector.The $-$ 3111 to +49 segment of oatp2 promoter was PCR-amplified (forwardprimer: 5'-GAT GTT AAT GGT ATG CAC AGG CAG GGA GGC-3'; reverseprimer: 5'-AAG AAG CTC GAG AAG ACG GTC CTC TCC ATG C-3'), andsubcloned into pT-Adv vector (CLONTECH), which was subsequentlydigested by XhoI, and inserted into the pGL3-basic-( $-$ 8701)-( $-$ 3111),producing the pGL3-basic-oatp2-( $-$ 8701)-(+49)construct.

2.   pGL3-basic-oatp2-( $-$ 5425)-(+49). pGL3-basic-oatp2-( $-$ 8701)-(+49) was digested with SstI and Aat II, the ends were filled byKlenow enzyme, the larger fragment was gel-purified, and the vectorwas self-ligated.

3.   pGL3-basic-oatp2-( $-$ 2777)-(+49). pGL3-basic-oatp2-( $-$ 8701)-(+49) was cut with SstI and PstI, the ends were filled by Klenowenzyme, the larger fragment was gel-purified, and the vector wasself-ligated.

4.   pGL3-basic-oatp2-( $-$ 8701)-( $-$ 4668). pGL3-basic-oatp2-( $-$ 8701)-(+49) was cut with PstI and NdeI, the ends were filled by Klenowenzyme, the larger fragment was gel-purified, and the vector wasself-ligated.

5.   pGL3-basic-oatp2-( $-$ 8701)-( $-$ 6978). pGL3-basic-oatp2-( $-$ 8701)-( $-$ 4668) was digested with EcoRI, the larger fragment was gel-purified,and the vector was self-ligated.

6.   pGL3-basic-oatp2-( $-$ 5467)-( $-$ 4668). pGL3-basic-oatp2-( $-$ 8701)-( $-$ 4668) was digested with SstI and EcoR V, the ends were filledby Klenow enzyme, the larger fragment was gel-purified, and thevector was self-ligated.

7.   pGL3-basic-oatp2-( $-$ 8701)-( $-$ 5425). pGL3-basic-oatp2-( $-$ 8701)-(+49) was cut with Aat II and NdeI, the ends were filled by Klenowenzyme, the larger fragment was gel-purified, and the vector wasself-ligated.

8.   pGL3-basic-oatp2-( $-$ 8701)-( $-$ 7903)/( $-$ 5467)-( $-$ 4668). pGL3-basic-oatp2-( $-$ 8701)-( $-$ 4668) was cut with PvuI and EcoR V, the endswere filled by Klenow enzyme, the larger fragment was gel-purified,and the vector was self-ligated.

9.   pGL3-basic-oatp2-( $-$ 8203)-( $-$ 7903)/( $-$ 5467)-( $-$ 4668). pGL3-basic-oatp2-( $-$ 8701)-( $-$ 7903)/( $-$ 5467)-( $-$ 4668) was cut with SstI and StuI,the ends were filled by Klenow enzyme, the larger fragment wasgel-purified, and the vector was self-ligated.

Cell Culture and Transient Transfection Assays. Rat hepatoma cell line H4IIE was obtained from American Type Culture Collection (Manassas, VA) and maintained in phenol red-freeDulbecco's modified Eagle's medium (DMEM) (Invitrogen), supplementedwith 10% fetal bovine serum (FBS) (Hyclone Laboratories, Irvine,CA). The cells were seeded at 1.5 × 10⁵/ml into 12-well plates (500 µl/well) in phenol red-free DMEM,supplemented with 10% charcoal-stripped, delipidated FBS (SigmaChemical, St. Louis, MO), and 1% penicillin/streptomycin overnight.Cells were transfected by a 4-h exposure to LipofectAMINE^plus (Invitrogen), with each well containing 900 ng of the reporterconstructs, 500 ng of rPXR expression vector (pSG5-rPXR), and100 ng of the internal control vector for transfection efficiency,namely, the Rous sarcoma virus promoter- $beta$ -galactosidase (pRSV- $beta$ -GAL)reporter plasmid (provided by Dr. Michael Wolf, University ofKansas Medical Center) in OptiMEM I (Invitrogen). The media werechanged into phenol red-free DMEM, supplemented with 10% charcoal-stripped-delipidatedFBS, and 1% penicillin/streptomycin, containing either PCN orvehicle control, DMSO. After a 72-h incubation, the cells wereharvested, lysed, and luciferase activity was measured and normalizedwith $beta$ -galactosidase activity. Each reporter construct was assayedin triplicate wells, and each experiment was repeated at leastthreetimes.

Statistical Analysis. The data were expressed as mean ± S.E. Statistical significance between PCN- and vehicle-treated groups was analyzed by Student'st test or one-way analysis of variance, followed by Duncan's posthoc analysis. Significance was set at p < 0.05.

	Results

Top Abstract Introduction Experimental Procedures Results Discussion References

Genomic Organization of Rat oatp2. There are two existing cDNAs for rat oatp2 (Noe et al., 1997; Abe et al., 1998). The coding regions are the same between thesetwo cDNAs, but their 5'-UTRs are different. To understand themechanism by which heterogeneous oatp2 mRNAs are produced, aswell as to understand regulation of rat oatp2 at the genomic level,a rat BAC library was screened by using a fragment from a ratoatp2 cDNA as a probe. A single BAC clone containing a full spanof rat oatp2 gene was isolated and analyzed by partial sequencing.The genomic structure and exon-intron organization relative torat oatp2 cDNA reported by Abe et al. (1998) are shown in Fig.1 and Table 2. The rat oatp2 gene contains 16 exons. Exons 1and 2 contain the first 160 bp of the 5'-UTR of rat oatp2 cDNAcloned by Abe et al. (1998). Exon 3 is 118 bp and contains 58bp of the 5'-UTR, and the rest of exon 3 encodes the first 20amino acid residues of rat oatp2 protein. The last exon (exon16) is the largest, which consists of 1596 bp that contains thestop codon and the 3'-UTR. The initial and terminal dinucleotidesof all rat oatp2 introns showed the GT-AG configuration that ischaracteristic of splice junctions (Lewin, 1997). When the sequencesof the two published oatp2 cDNAs were compared with the genomicrat oatp2 DNA sequence, it was found that the cDNA of rat oatp2cloned by Noe et al. (1997) lacked the entire noncoding exon 2,which was included in the cDNA cloned by Abe et al. (1998). Althoughoatp2 cDNA by Noe et al. (1997) lacks the entire exon 2, it islonger due to larger contributions from exon 1 (60 versus 30 bpin Abe's cDNA) and exon 16 (1713 versus 814 bp in Abe's cDNA).The phases in the exon-intron boundaries of rat oatp2 consistof two phase 0, seven phase 1, and four phase 2 splice sites (Table2).

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Fig. 1. Exon-intron organization of the rat oatp2 gene and its organizational relationship to the two published oatp2 cDNAs cloned by Noe et al. (1997)

and Abe et al. (1998)

, respectively. Exons are arranged from the 5' to the 3' end. Dark gray boxes represent noncoding exons and light gray boxes represent coding exons. Black lines between exons represent introns (without determination of their length). The cDNA cloned by Noe et al. (1997)

lacks the entire exon 2, which is present in the cDNA cloned by Abe et al. (1998)

. The first and last exon contribute longer sequence to the cDNA cloned by Noe et al. (1997)

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TABLE 2
Structure of Rat Oatp2 Gene
The length of the first exon is 89 bp, from which 30 bp is in the cDNA cloned by Abe et al. (1998)

, and 60 bp in the cDNA cloned by Noe et al. (1997)

Analysis of the 5'-Flanking Sequence of Rat oatp2 Gene. Approximately 8.7 kb of the 5'-flanking region of rat oatp2 gene were sequenced by primer walking. The sequence of the 5'-flankingregion of rat oatp2 gene is not presented in this article dueto its length, but is available in the GenBank as accession numberAF426312. The putative transcription start site was estimatedby the 5'-RACE assay, by using rat oatp2 gene-specific primerdesigned from the 5'-UTR region, and tentatively determined bythe longest RACE product. The estimated transcription start siteis 89 bp from the start of intron 1, and is 29 bp upstream ofthe reported rat oatp2 cDNA cloned by Noe et al. (1997). Therefore,the calculated 5'-UTR would be 277 bp if all noncoding exons (exons1, 2, and 3) are present. A TATA box for eukaryotic promotersis absent in the proximal 5'-flanking region of the rat oatp2gene. Multiple repeats of alternative purine pyrimidine (AC orAG) were present in the proximal promoter of rat oatp2 ( $-$ 263 to $-$ 421), which is also present in the mouse oatp2 promoter region(Ogura et al., 2001). Potential binding sites for many transcriptionfactors were identified in the 5'-flanking region of rat oatp2gene detected by TRANSFAC, including three matches to aryl hydrocarbonreceptor/aryl hydrocarbon receptor nuclear translocator (AhR-Arnt)protein, three matches to chicken ovalbumin upstream promotertranscription factor, four matches to cyclic AMP response elementbinding protein, one match to glucocorticoid response element,four matches to hepatocyte nuclear factor (HNF) 1, 85 matchesto HNF3B, seven matches to NF- $kappa$ B, one match to peroxisome proliferator-activatedreceptor $alpha$ , and 12 matches to signal transducers and activatorsof transcription (STAT) 1, etc. The presence of the above-mentionedtrans-activator binding sites suggests their functional involvementin the transcriptional control of the rat oatp2 gene. However,further experiments are required to determine the regulation ofrat oatp2 by these transcription factors at the functionallevel.

Four potential PXR response elements, arranged as direct repeats separated by three nucleotides (DR3) were identified in the5'-flanking region of rat oatp2 gene; one was identified at $-$ 5000bp (DR3-1), and the other three clustered around the $-$ 8000-bpregion (DR3-2, DR3-3, and DR3-4) (Fig. 2). In comparison withthe DR3 [AGG(T)TCAnnnAGG(T)TCA] identified in the 5'-flankingregion of rat CYP3A1 (Huss and Kasper, 1998

), rat oatp2 DR3s differfrom it by one to three mismatches, with one mismatch in DR3-1and DR3-3, two mismatches in DR3-4, and three mismatches in DR3-2(Table 3).

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Fig. 2. 5'-Flanking region of rat oatp2 gene and position of putative PXR response elements (DR3s). The figure shows the position of the putative PXR response elements (DR3s) in the 5'-flanking region of the rat oatp2 gene in relation to the transcription start site (+1). Four PXR response elements are numbered DR3-1, DR3-2, DR3-3, and DR3-4, according to the sequence by which they were identified. DR3-1 was identified at 5 kb upstream of the transcription start site (+1), whereas DR3-2, DR3-3, and DR3-4 were identified as a cluster around 8 kb upstream of the transcription start site (+1).

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TABLE 3
Comparison of the DR3s from the rat CYP3A1 and oatp2

Characterization of Binding Activity of PXR-RXR $alpha$ Heterodimers to PXR Response Elements Found in 5'-Flanking Region of Rat oatp2. PXR binds as a PXR-RXR $alpha$ heterodimer to AGG(T)TCA hexamers arranged as direct repeats (DR3 or DR4) or everted repeat 6 identifiedin the 5'-flanking region of CYP3A and MDR1 genes (Bertilssonet al., 1998; Blumberg et al., 1998; Lehmann et al., 1998). BecausePXR seems to have a promiscuous ability to bind multiple hormoneresponse elements, the ability of PXR to bind the four identifiedpotential PXREs in the 5'-flanking region of the rat oatp2 genewas assessed. Binding of the radiolabeled rat CYP3A1 PXR responseelement (PXRE) was abolished by incubation with excess nonradiolabeledrat CYP3A1 DR3 (Fig. 3). Competition with 5-, 25-, and 100-foldmolar excess of the four putative PXREs (DR3-1 through DR3-4)revealed that DR3-2 binds the most efficiently, followed by DR3-4and DR3-1. DR3-3 bound very weakly or not at all. The mutant form( $Delta$ DR3s) of all of the PXREs did not compete with the binding ofthe PXR-RXR $alpha$ heterodimer to CYP3A1 DR3.

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Fig. 3. DR3s from rat oatp2 gene compete with the binding of the PXR/RXR $alpha$ heterodimer to the CYP3A1-DR3. Electrophoretic mobility shift assays using in vitro-translated proteins bound to ³²P-labeled oligonucleotides containing the DR3 from the 5'-flanking region of rat CYP3A1. Binding reactions contained (+) or lacked ( $-$ ) the indicated proteins. The figure illustrates the PXR, RXR $alpha$ , or PXR-RXR $alpha$ heterodimer binding to ³²P-labeled DR3 from CYP3A1, as well as the competition with wild-type and mutant ( $triangle$ ) unlabeled oligonucleotides containing the DR3 from the 5'-flanking region of CYP3A1, or DR3-1, DR3-2, DR3-3, and DR3-4 from the 5'-flanking region of rat oatp2. The numbers indicate the n-fold molar excess to which the competitor was added.

Because the PXR-RXR heterodimer bound most efficiently to the DR3-2, this element was labeled with ³²P in an effort to directly assay binding of the PXR-RXR heterodimerto this element. PXR-RXR $alpha$ heterodimer bound to DR3-2 and the bindingwas abolished by the addition of 5- and 50-fold molar excess ofnonradiolabeled rat CYP3A1 oligonucleotide (Fig. 4). Competitionexperiments with unlabeled DR3-1 through DR3-4 oligonucleotidesin a 5- and 50-fold molar excess revealed that DR3-2 competesthe most efficiently, followed by DR3-4 and DR3-1, whereas theDR3-3 oligonucleotide competed only weakly if at all. In addition,the binding was not competed by the presence of excess unlabeledoligonucleotides containing mutant forms of DR3s from CYP3A1 ( $Delta$ CYP3A1)and oatp2 DR3s ( $Delta$ DR3-1, $Delta$ DR3-2, $Delta$ DR3-3, and $Delta$ DR3-4). Direct bindingstudy of the PXR-RXR $alpha$ heterodimer with the ³²P-labeled DR3-1, DR3-3, and DR3-4 was also performed, and theresults confirmed what were observed in the aforementioned experiments(data not shown).

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Fig. 4. Characterization of the binding of the PXR/RXR $alpha$ heterodimer to the oatp2 DR3-2. Electrophoretic mobility shift assays using in vitro-translated proteins bound to ³²P-labeled oligonucleotides containing the DR3-2 from the 5'-flanking region of the rat oatp2 gene. Binding reactions contained (+) or lacked ( $-$ ) the indicated proteins. The figure illustrates the PXR, RXR $alpha$ , or PXR-RXR $alpha$ heterodimer binding to ³²P-labeled DR3-2, as well as the competition with wild-type and mutant ( $triangle$ ) unlabeled oligonucleotides containing the CYP3A1 DR3, rat oatp2 DR3-1, DR3-2, DR3-3, and DR3-4. The numbers indicate the n-fold molar excess to which the competitor was added.

PXR Trans-Activates Rat oatp2 Promoter. PXR has been shown to trans-activate the CYP3A1 promoter by using PCN as a model chemical. To determine whether PXR mediatesthe trans-activation of the oatp2 promoter in the presence ofPCN, an 8.7-kb 5'-flanking region of oatp2 (with DR3-1, DR3-2,DR3-3, and DR3-4) was cloned into a PGL3-basic vector, upstreamof the luciferase reporter gene. The construct was transientlytransfected into the rat hepatoma cell line H4IIE with concomitantcotransfection of pSG5-rat PXR, and in the presence of PCN at0.1, 1, 10, and 100 µM concentrations or vehicle (0.1% DMSO).As shown in Fig. 5, PCN dose dependently activated the 8.7-kb5'-flanking region of the rat oatp2 gene, and approximately 11-foldinduction was observed with 100 µM PCN.

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Fig. 5. Trans-activation of rat oatp2 promoter by PXR in the presence of PCN. Approximately 8.7 kb of the 5'-flanking region of rat oatp2 were cloned into PGL3-basic vector. The construct was transiently transfected into the rat hepatoma cell line H4IIE with rat PXR and RSV- $beta$ -gal vector. The cells were incubated with PCN at 0.1, 1, 10, or 100 µM or vehicle (DMSO) for 72 h. Cells were harvested and analyzed for luciferase and $beta$ -galactosidase activity. The data are presented as fold induction (PCN[luciferase activity/ $beta$ -galactosidase activity)]/[DMSO(luciferase activity/ $beta$ -galactosidase activity]). Asterisks (*) denote statistical significance between vehicle and PCN-treated groups (p < 0.05). The experiments were done in triplicate wells and repeated three times.

Minimum of 300 bp around $-$ 8-kb Region of 5'-Flanking Sequence of Rat oatp2 Is Required for PCN Response. To determine which region(s) in the 5'-flanking region of oatp2 is responsible for trans-activation by PCN, series deletionsto generate different lengths of the 5'-flanking region of ratoatp2 gene (constructs 1-9) were made (Fig. 6). They were transientlytransfected into H4IIE cells with pSG5-rat PXR in the presenceof 100 µM PCN. The deletion of the upstream region of $-$ 5425 ( $-$ 5425to $-$ 8700) significantly decreased the induction by PCN from 8-to 2.5-fold (construct 2, with DR3-1). Partial deletion of thedownstream region of $-$ 5425 ( $-$ 2777 to $-$ 5425) did not affect thedegree of induction (2.5- to 2.5-fold) (construct 3, no DR3s).Deletion of the proximal portion of the 5'-flanking region ofoatp2 ( $-$ 369 to $-$ 4668) seems to increase the degree of induction(8- to 13.4-fold), suggesting the presence of a suppressive regionbetween $-$ 369 to $-$ 4668 (construct 4, with DR3-1, DR3-2, DR3-3,and DR3-4). Deletion of $-$ 4696 to $-$ 6978 from the backbone of construct4, resulting in lack of the DR3-1, reduced the fold inductionfrom 13.4- to 10.7-fold (construct 5, with DR3-2, DR3-3, and DR3-4).Deletion of $-$ 5467 to $-$ 8700 from the backbone of construct 4 resultedin loss of the three distal DR3s (DR3-2, DR3-3, and DR3-4), andthe fold induction significantly reduced from 13.4- to 2.4-fold(construct 6, with DR3-1). Inclusion of the region between $-$ 5425to $-$ 8700 (construct 7) increased induction (2.4- to 5.3-fold);however, the degree was still lower than construct 5, indicatingthe presence of a suppressive region between DR3-1 and the threeother DR3s. Deletion of the region between $-$ 5467 and $-$ 7903 (construct8, with DR3-1, DR3-2, DR3-3, and DR3-4) restored the inductionby PCN (13.2-fold). Further deletion from the 5' end of construct8 ( $-$ 8203 to $-$ 8700) yielded a somewhat stronger induction (18.8-fold)(construct 9), suggesting the existence of another suppressiveregion between $-$ 8203 to $-$ 8700. These data demonstrate that thedistal region in the 5'-flanking region of oatp2 gene, which containsthe three putative DR3s (DR3-2, DR3-3, and DR3-4), was more responsiveto the induction of PCN than the relatively proximal region whereDR3-1 was identified.

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Fig. 6. Trans-activation of the 8.7-kb 5'-flanking region of rat oatp2 by PXR in the presence of PCN requires a 300-bp region around $-$ 8 kb ( $-$ 8203 to 7903). Series deletions within the 5'-flanking region of rat oatp2 were made by restriction enzyme digestion, followed by self-ligation of the vector. The sequences were confirmed by sequencing. Structures of different constructs are illustrated on the left side of the graph, numbered from 1 to 9. These constructs were transiently transfected into the H4IIE cells, with rat PXR and RSV- $beta$ -gal vector. The cells were incubated with PCN at 100 µM for 72 h. Cells were harvested and analyzed for luciferase and $beta$ -galactosidase activity. The data are presented as fold induction by PCN [PCN(luciferase activity/ $beta$ -galactosidase activity)]/[DMSO(luciferase activity/ $beta$ -galactosidase activity)]. Asterisks (*) denote statistical significance between intact and deleted constructs of the 5'-flanking region of rat oatp2 (p < 0.05). The experiments were done in triplicate wells and repeated three to four times.

	Discussion

Top Abstract Introduction Experimental Procedures Results Discussion References

Rat oatp2, a hepatic sinusoidal transporter, mediates hepatic uptake of a variety of structurally diverse compounds. Althoughits substrate spectrum overlaps with other oatp family members,its affinity for cardiac glycosides, such as ouabain and digoxin,is very high (Noe et al., 1997; Abe et al., 1998; Kakyo et al.,1999). Expression levels of rat hepatic oatp2 protein and mRNAare increased in adult and newborn rats by treatment with PCN(Rausch-Derra et al., 2001). Moreover, increased oatp2 gene transcriptionseems to be responsible for the increased oatp2 mRNA expressionafter PCN treatment (Guo et al., 2001). PXR is the PCN receptorand its activation correlates with the induction of CYP3A familymembers in all species tested (Jones et al., 2001), and PCN inductionof mouse oatp2 mRNA was abolished in PXR knockout mice (Staudingeret al., 2001). Therefore, it was hypothesized that PCN inductionof rat oatp2 would be through interaction with PXR aswell.

In the current study, a rat oatp2 genomic clone was isolated, and analysis of the genomic clone indicated that the rat oatp2gene consists of 16 exons (Table 2). The intron and exon boundariesall followed the GT-AG rule for intron splicing. Comparison ofthe two published cDNAs for rat oatp2 showed that although thecoding region of these two oatp2 cDNAs is the same, their 5'-UTRsare different (Noe et al., 1997; Abe et al., 1998). The analysisof rat oatp2 gene structure clearly shows that the cDNA clonedby Noe et al. (1997) lacked the second noncoding exon (exon 2)that was present in the cDNA cloned by Abe et al. (1998). Therefore,the two cDNAs are the result of alternative splicing of the noncodingexon of the rat oatp2 gene (Fig. 1). Research from this laboratorypreviously indicated the presence of heterogeneous 5'-UTR of themouse oatp2 gene, due to alternative splicing (Ogura et al., 2001).

Exon-intron structure of rat oatp2 is similar to other members of the oatp family, namely, mouse oatp2 (Ogura et al., 2001);mouse lst-1 (Ogura et al., 2000); rat lst-1 (Choudhuri et al.,2000); human OATP-A, OATP-C, and OATP8 (Konig et al., 2000); andPGT genes (Lu and Schuster, 1998). Gene structure analysis indicatesthat the coding sequences of these genes are all separated by13 introns. Mouse oatp2 gene consists of 17 exons, which is oneexon longer than rat oatp2, due to the presence of an additionalnoncoding exon in the mouse oatp2 gene (Ogura et al., 2001). Thephases in exon-intron junction are identical among the aforementionedoatp family members, all consisting of two phase 0, seven phase1, and four phase 2 splice sites. This indicates that these genesmay have derived from a common ancestral gene that was convertedinto different genes during evolution. Because there is a clusterof phase 1 from exon 6 through exon 10, there is the possibilityfor alternatively spliced forms of rat oatp2mRNA.

Approximately 8.7 kb of the 5'-flanking region of the rat oatp2 gene were sequenced by primer walking after the putative transcriptionstart site was identified by the 5'-RACE assay. Sequence analysisrevealed many putative transcription factor-binding sites, includingAhR-Arnt, HNF1, HNF3B, NF- $kappa$ B, peroxisome proliferator-activatedreceptor $alpha$ , and STAT1. The numerous HNF1 and HNF3B binding sites(4 and 85 matches, respectively) in the 5'-flanking region ofthe rat oatp2 gene might explain the high level expression ofoatp2 in liver. In addition, the observation that rat hepaticoatp2 protein expression is down-regulated by AhR ligands (2,3,7,8-tetrachlorodibenzo-p-dioxin,indole-3-carbinol, $beta$ -naphthoflavone, and polychlorinated biphenyl126) (Guo et al., 2002) suggests that this might be due to thepresence of AhR-Arnt in the promoter region of the rat oatp2 gene.Moreover, the presence of NF- $kappa$ B and STAT in the rat oatp2 promotersuggests that rat oatp2 might be subject to their regulation.These putative transcription factor-binding sites need to be furthercharacterized by functional assays to determine potential mechanismsby which rat oatp2 is regulated by xenobiotics, pathophysiologicalconditions, and tissue specificity at the molecularlevel.

Rat hepatic oatp2 protein and mRNA levels are induced by PCN treatment in both adult and newborn animals (Klaasen et al.,2001; Raush-Derra et al., 2001). PCN treatment induces hepatoprotectionin rodents (Selye, 1971), and UDP-glucuronosyltransferase in rats(Watkins and Klaassen, 1982). Analysis of 8.7 kb of the 5'-flankingregion revealed four putative DR3s in the promoter of the ratoatp2 gene. One DR3 (DR3-1) is located at around $-$ 5000 bp in theupstream region, whereas the other three (DR3-2, DR3-3, and DR3-4)are clustered together at about $-$ 8000 bp upstream of the putativetranscription start site. Electrophoretic mobility shift assayanalysis revealed that the PXR-RXR heterodimer binds the mostefficiently to DR3-2, whereas it binds weakly to DR3-1 and DR3-4,or not at all to DR3-3.

Transient transfection studies using rat PXR and the rat oatp2 promoter linked to the luciferase reporter gene reveal thatthis promoter is induced by PCN treatment in a dose-dependentmanner that is dependent upon the presence of rat PXR. A seriesof deletion mutations established that both the proximal PXRE(DR3-1) and the distal PXREs (DR3-2 through DR3-4) are requiredfor maximal induction of this promoter by PCN. A minimum of 300base pairs that includes the entire distal cluster of putativePXREs is sufficient and required for induction by PCN.

In summary, this study indicates that the mechanism by which PCN induces rat oatp2 gene is via interaction with PXR. Thisresearch furthers our understanding of the coordinate regulationof a biochemically linked set of genes that is important for xenobioticdisposition and elimination, including oatp2, CYP3A, MDR1, andmultidrug resistance-associated protein 2 whose expression isinduced in a coordinate manner so as to reduce the intracellularconcentration of drugs, steroids, and bile acids. In addition,the results aid in understanding more about drug-drug interactionsat the hepatic uptakelevel.

	Acknowledgments

We thank Dr. Michael Wolfe (University of Kansas Medical Center, Lawrence, KS) for providing plasmids pGL3-basic and pRSV- $beta$ -galfor constructing reporter gene constructs, as well as for providingthe facilities to determine luciferase and $beta$ -galactosidase activity.We also appreciate the constructive discussions with Dr. SupratimChoudhuri, Thengi Thway, and Dr. Lesley Hecker (University ofKansas MedicalCenter).

	Footnotes

Received October 19, 2001; Accepted December 28, 2001

¹ Present address: Department of Pharmacology and Toxicology, School of Pharmacy, University of Kansas, Lawrence, KS 66045-2505.

² Present address: Department of Drug Metabolism and Molecular Toxicology, Tokyo University of Pharmacy and Life Sciences, 1432-1Horinouchi, Hachioji, Tokyo 192-0392,Japan.

This work was supported by grants ES09649 and ES03192 from the National Institute of Environmental Health Sciences. J.S. wassupported by National Institutes of Health Training GrantES07079.

Address correspondence to: Curtis D. Klaassen Ph.D., Department of Pharmacology, Toxicology, and Therapeutics, University of Kansas Medical Center, 3901 Rainbow Blvd., Kansas City, KS 66160-7417. E-mail: cklaasse{at}kumc.edu

	Abbreviations

oatp2, organic anion transporting polypeptide 2; PCN, pregnenolone-16 $alpha$ -carbonitrile; PXR, pregnane X receptor; DR, direct repeat; RXR $alpha$ , retinoid X receptor $alpha$ ; MDR1, multidrug resistant protein 1; BAC, bacterial artificial chromosome; bp, basepair(s); UTR, untranslated region; RACE, rapid amplification of cDNA ends; PCR, polymerase chain reaction; DMEM, Dulbecco's modified Eagle's medium; FBS, fetal bovine serum; DMSO, dimethyl sulfoxide; PXRE, pregnane X receptor response element; AhR-Arnt, aryl hydrocarbon receptor/aryl hydrocarbon receptor nuclear translocator; HNF, hepatocyte nuclear factor; NF- $kappa$ B, nuclear factor- $kappa$ B; STAT, signal transducers and activators of transcription.

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Toxicol. Sci., December 1, 2004; 82(2): 374 - 380.
[Abstract] [Full Text] [PDF]

M. V. St-Pierre, T. Stallmach, A. Freimoser Grundschober, J.-F. Dufour, M. A. Serrano, J. J. G. Marin, Y. Sugiyama, and P. J. Meier
Temporal expression profiles of organic anion transport proteins in placenta and fetal liver of the rat
Am J Physiol Regulatory Integrative Comp Physiol, December 1, 2004; 287(6): R1505 - R1516.
[Abstract] [Full Text] [PDF]

B. Bauer, A. M. S. Hartz, G. Fricker, and D. S. Miller
Pregnane X Receptor Up-Regulation of P-Glycoprotein Expression and Transport Function at the Blood-Brain Barrier
Mol. Pharmacol., September 1, 2004; 66(3): 413 - 419.
[Abstract] [Full Text] [PDF]

R. Z. Turncliff, P. J. Meier, and K. L. R. Brouwer
EFFECT OF DEXAMETHASONE TREATMENT ON THE EXPRESSION AND FUNCTION OF TRANSPORT PROTEINS IN SANDWICH-CULTURED RAT HEPATOCYTES
Drug Metab. Dispos., August 1, 2004; 32(8): 834 - 839.
[Abstract] [Full Text] [PDF]

D. P. Hartley, X. Dai, Y. D. He, E. J. Carlini, B. Wang, S.-e. W. Huskey, R. G. Ulrich, T. H. Rushmore, R. Evers, and D. C. Evans
Activators of the Rat Pregnane X Receptor Differentially Modulate Hepatic and Intestinal Gene Expression
Mol. Pharmacol., May 1, 2004; 65(5): 1159 - 1171.
[Abstract] [Full Text]

R. G. Tirona, B. F. Leake, L. M. Podust, and R. B. Kim
Identification of Amino Acids in Rat Pregnane X Receptor that Determine Species-Specific Activation
Mol. Pharmacol., January 1, 2004; 65(1): 36 - 44.
[Abstract] [Full Text] [PDF]

C. Handschin and U. A. Meyer
Induction of Drug Metabolism: The Role of Nuclear Receptors
Pharmacol. Rev., December 1, 2003; 55(4): 649 - 673.
[Abstract] [Full Text] [PDF]

N. Mizuno, T. Niwa, Y. Yotsumoto, and Y. Sugiyama
Impact of Drug Transporter Studies on Drug Discovery and Development
Pharmacol. Rev., September 1, 2003; 55(3): 425 - 461.
[Abstract] [Full Text] [PDF]

C. Chen, J. L. Staudinger, and C. D. Klaassen
NUCLEAR RECEPTOR, PREGNANE X RECEPTOR, IS REQUIRED FOR INDUCTION OF UDP-GLUCURONOSYLTRANSFERASES IN MOUSE LIVER BY PREGNENOLONE-16{alpha}-CARBONITRILE
Drug Metab. Dispos., July 1, 2003; 31(7): 908 - 915.
[Abstract] [Full Text] [PDF]

R. Walter, C. Ullmann, D. Thummler, and W. Siegmund
INFLUENCE OF PROPIVERINE ON HEPATIC MICROSOMAL CYTOCHROME P450 ENZYMES IN MALE RATS
Drug Metab. Dispos., June 1, 2003; 31(6): 714 - 717.
[Abstract] [Full Text] [PDF]

J. Sonoda, W. Xie, J. M. Rosenfeld, J. L. Barwick, P. S. Guzelian, and R. M. Evans
Regulation of a xenobiotic sulfonation cascade by nuclear pregnane X receptor (PXR)
PNAS, October 15, 2002; 99(21): 13801 - 13806.
[Abstract] [Full Text] [PDF]

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1.	pGL3-basic-oatp2-( $-$ 8701)-(+49). Oatp2 genomic DNA was digested with restriction enzymes SstI and XhoI to produce the $-$ 3111to $-$ 8701 segment of the oatp2 promoter, which was confirmed byPCR screening, and was isolated and cloned into PGL-3 basic vector.The $-$ 3111 to +49 segment of oatp2 promoter was PCR-amplified (forwardprimer: 5'-GAT GTT AAT GGT ATG CAC AGG CAG GGA GGC-3'; reverseprimer: 5'-AAG AAG CTC GAG AAG ACG GTC CTC TCC ATG C-3'), andsubcloned into pT-Adv vector (CLONTECH), which was subsequentlydigested by XhoI, and inserted into the pGL3-basic-( $-$ 8701)-( $-$ 3111),producing the pGL3-basic-oatp2-( $-$ 8701)-(+49)construct.
2.	pGL3-basic-oatp2-( $-$ 5425)-(+49). pGL3-basic-oatp2-( $-$ 8701)-(+49) was digested with SstI and Aat II, the ends were filled byKlenow enzyme, the larger fragment was gel-purified, and the vectorwas self-ligated.
3.	pGL3-basic-oatp2-( $-$ 2777)-(+49). pGL3-basic-oatp2-( $-$ 8701)-(+49) was cut with SstI and PstI, the ends were filled by Klenowenzyme, the larger fragment was gel-purified, and the vector wasself-ligated.
4.	pGL3-basic-oatp2-( $-$ 8701)-( $-$ 4668). pGL3-basic-oatp2-( $-$ 8701)-(+49) was cut with PstI and NdeI, the ends were filled by Klenowenzyme, the larger fragment was gel-purified, and the vector wasself-ligated.
5.	pGL3-basic-oatp2-( $-$ 8701)-( $-$ 6978). pGL3-basic-oatp2-( $-$ 8701)-( $-$ 4668) was digested with EcoRI, the larger fragment was gel-purified,and the vector was self-ligated.
6.	pGL3-basic-oatp2-( $-$ 5467)-( $-$ 4668). pGL3-basic-oatp2-( $-$ 8701)-( $-$ 4668) was digested with SstI and EcoR V, the ends were filledby Klenow enzyme, the larger fragment was gel-purified, and thevector was self-ligated.
7.	pGL3-basic-oatp2-( $-$ 8701)-( $-$ 5425). pGL3-basic-oatp2-( $-$ 8701)-(+49) was cut with Aat II and NdeI, the ends were filled by Klenowenzyme, the larger fragment was gel-purified, and the vector wasself-ligated.
8.	pGL3-basic-oatp2-( $-$ 8701)-( $-$ 7903)/( $-$ 5467)-( $-$ 4668). pGL3-basic-oatp2-( $-$ 8701)-( $-$ 4668) was cut with PvuI and EcoR V, the endswere filled by Klenow enzyme, the larger fragment was gel-purified,and the vector was self-ligated.
9.	pGL3-basic-oatp2-( $-$ 8203)-( $-$ 7903)/( $-$ 5467)-( $-$ 4668). pGL3-basic-oatp2-( $-$ 8701)-( $-$ 7903)/( $-$ 5467)-( $-$ 4668) was cut with SstI and StuI,the ends were filled by Klenow enzyme, the larger fragment wasgel-purified, and the vector was self-ligated.

				H. E. Meyer zu Schwabedissen, R. G. Tirona, C. S. Yip, R. H. Ho, and R. B. Kim Interplay between the Nuclear Receptor Pregnane X Receptor and the Uptake Transporter Organic Anion Transporter Polypeptide 1A2 Selectively Enhances Estrogen Effects in Breast Cancer Cancer Res., November 15, 2008; 68(22): 9338 - 9347. [Abstract] [Full Text] [PDF]

				X. Cheng and C. D. Klaassen Critical Role of PPAR-{alpha} in Perfluorooctanoic Acid- and Perfluorodecanoic Acid-Induced Downregulation of Oatp Uptake Transporters in Mouse Livers Toxicol. Sci., November 1, 2008; 106(1): 37 - 45. [Abstract] [Full Text] [PDF]

				T. Wang, X. Ma, K. W. Krausz, J. R. Idle, and F. J. Gonzalez Role of Pregnane X Receptor in Control of All-Trans Retinoic Acid (ATRA) Metabolism and Its Potential Contribution to ATRA Resistance J. Pharmacol. Exp. Ther., February 1, 2008; 324(2): 674 - 684. [Abstract] [Full Text] [PDF]

				M. G. Donner, S. Schumacher, U. Warskulat, J. Heinemann, and D. Haussinger Obstructive cholestasis induces TNF-{alpha}- and IL-1 -mediated periportal downregulation of Bsep and zonal regulation of Ntcp, Oatp1a4, and Oatp1b2 Am J Physiol Gastrointest Liver Physiol, December 1, 2007; 293(6): G1134 - G1146. [Abstract] [Full Text] [PDF]

				T. Maeda, M. Oyabu, T. Yotsumoto, R. Higashi, K. Nagata, Y. Yamazoe, and I. Tamai Effect of Pregnane X Receptor Ligand on Pharmacokinetics of Substrates of Organic Cation Transporter Oct1 in Rats Drug Metab. Dispos., September 1, 2007; 35(9): 1580 - 1586. [Abstract] [Full Text] [PDF]

				X. Ma, Y. M. Shah, G. L. Guo, T. Wang, K. W. Krausz, J. R. Idle, and F. J. Gonzalez Rifaximin Is a Gut-Specific Human Pregnane X Receptor Activator J. Pharmacol. Exp. Ther., July 1, 2007; 322(1): 391 - 398. [Abstract] [Full Text] [PDF]

				E. K. Pacyniak, X. Cheng, M. L. Cunningham, K. Crofton, C. D. Klaassen, and G. L. Guo The Flame Retardants, Polybrominated Diphenyl Ethers, Are Pregnane X Receptor Activators Toxicol. Sci., May 1, 2007; 97(1): 94 - 102. [Abstract] [Full Text] [PDF]

				Y. M. Shah, X. Ma, K. Morimura, I. Kim, and F. J. Gonzalez Pregnane X receptor activation ameliorates DSS-induced inflammatory bowel disease via inhibition of NF-{kappa}B target gene expression Am J Physiol Gastrointest Liver Physiol, April 1, 2007; 292(4): G1114 - G1122. [Abstract] [Full Text] [PDF]

				C. Chen, X. Cheng, M. Z. Dieter, Y. Tanaka, and C. D. Klaassen Activation of cAMP-Dependent Signaling Pathway Induces Mouse Organic Anion Transporting Polypeptide 2 Expression Mol. Pharmacol., April 1, 2007; 71(4): 1159 - 1164. [Abstract] [Full Text] [PDF]

				D. D. Moore, S. Kato, W. Xie, D. J. Mangelsdorf, D. R. Schmidt, R. Xiao, and S. A. Kliewer International Union of Pharmacology. LXII. The NR1H and NR1I Receptors: Constitutive Androstane Receptor, Pregnene X Receptor, Farnesoid X Receptor {alpha}, Farnesoid X Receptor beta, Liver X Receptor {alpha}, Liver X Receptor beta, and Vitamin D Receptor Pharmacol. Rev., December 1, 2006; 58(4): 742 - 759. [Abstract] [Full Text] [PDF]

				X. Cheng and C. D. Klaassen Regulation of mRNA Expression of Xenobiotic Transporters by the Pregnane X Receptor in Mouse Liver, Kidney, and Intestine Drug Metab. Dispos., November 1, 2006; 34(11): 1863 - 1867. [Abstract] [Full Text] [PDF]

				X. Cheng, J. Maher, H. Lu, and C. D. Klaassen Endocrine Regulation of Gender-Divergent Mouse Organic Anion-Transporting Polypeptide (Oatp) Expression Mol. Pharmacol., October 1, 2006; 70(4): 1291 - 1297. [Abstract] [Full Text] [PDF]

				X. Gu, S. Ke, D. Liu, T. Sheng, P. E. Thomas, A. B. Rabson, M. A. Gallo, W. Xie, and Y. Tian Role of NF-{kappa}B in Regulation of PXR-mediated Gene Expression: A MECHANISM FOR THE SUPPRESSION OF CYTOCHROME P-450 3A4 BY PROINFLAMMATORY AGENTS J. Biol. Chem., June 30, 2006; 281(26): 17882 - 17889. [Abstract] [Full Text] [PDF]

				A. Geier, C. G. Dietrich, S. Voigt, M. Ananthanarayanan, F. Lammert, A. Schmitz, M. Trauner, H. E. Wasmuth, D. Boraschi, N. Balasubramaniyan, et al. Cytokine-dependent regulation of hepatic organic anion transporter gene transactivators in mouse liver Am J Physiol Gastrointest Liver Physiol, November 1, 2005; 289(5): G831 - G841. [Abstract] [Full Text] [PDF]

				X. Cheng, J. Maher, M. Z. Dieter, and C. D. Klaassen REGULATION OF MOUSE ORGANIC ANION-TRANSPORTING POLYPEPTIDES (OATPS) IN LIVER BY PROTOTYPICAL MICROSOMAL ENZYME INDUCERS THAT ACTIVATE DISTINCT TRANSCRIPTION FACTOR PATHWAYS Drug Metab. Dispos., September 1, 2005; 33(9): 1276 - 1282. [Abstract] [Full Text] [PDF]

				S. S. Ferguson, Y. Chen, E. L. LeCluyse, M. Negishi, and J. A. Goldstein Human CYP2C8 Is Transcriptionally Regulated by the Nuclear Receptors Constitutive Androstane Receptor, Pregnane X Receptor, Glucocorticoid Receptor, and Hepatic Nuclear Factor 4{alpha} Mol. Pharmacol., September 1, 2005; 68(3): 747 - 757. [Abstract] [Full Text] [PDF]

				L. M. Augustine, R. J. Markelewicz Jr., K. Boekelheide, and N. J. Cherrington XENOBIOTIC AND ENDOBIOTIC TRANSPORTER MRNA EXPRESSION IN THE BLOOD-TESTIS BARRIER Drug Metab. Dispos., January 1, 2005; 33(1): 182 - 189. [Abstract] [Full Text] [PDF]

				G. L. Guo, J. S. Moffit, C. J. Nicol, J. M. Ward, L. A. Aleksunes, A. L. Slitt, S. A. Kliewer, J. E. Manautou, and F. J. Gonzalez Enhanced Acetaminophen Toxicity by Activation of the Pregnane X Receptor Toxicol. Sci., December 1, 2004; 82(2): 374 - 380. [Abstract] [Full Text] [PDF]

				M. V. St-Pierre, T. Stallmach, A. Freimoser Grundschober, J.-F. Dufour, M. A. Serrano, J. J. G. Marin, Y. Sugiyama, and P. J. Meier Temporal expression profiles of organic anion transport proteins in placenta and fetal liver of the rat Am J Physiol Regulatory Integrative Comp Physiol, December 1, 2004; 287(6): R1505 - R1516. [Abstract] [Full Text] [PDF]

Induction of Rat Organic Anion Transporting Polypeptide 2 by Pregnenolone-16-carbonitrile Is via Interaction with Pregnane X Receptor

Induction of Rat Organic Anion Transporting Polypeptide 2 by Pregnenolone-16 $alpha$ -carbonitrile Is via Interaction with Pregnane X Receptor

				B. Bauer, A. M. S. Hartz, G. Fricker, and D. S. Miller Pregnane X Receptor Up-Regulation of P-Glycoprotein Expression and Transport Function at the Blood-Brain Barrier Mol. Pharmacol., September 1, 2004; 66(3): 413 - 419. [Abstract] [Full Text] [PDF]

				R. Z. Turncliff, P. J. Meier, and K. L. R. Brouwer EFFECT OF DEXAMETHASONE TREATMENT ON THE EXPRESSION AND FUNCTION OF TRANSPORT PROTEINS IN SANDWICH-CULTURED RAT HEPATOCYTES Drug Metab. Dispos., August 1, 2004; 32(8): 834 - 839. [Abstract] [Full Text] [PDF]

				D. P. Hartley, X. Dai, Y. D. He, E. J. Carlini, B. Wang, S.-e. W. Huskey, R. G. Ulrich, T. H. Rushmore, R. Evers, and D. C. Evans Activators of the Rat Pregnane X Receptor Differentially Modulate Hepatic and Intestinal Gene Expression Mol. Pharmacol., May 1, 2004; 65(5): 1159 - 1171. [Abstract] [Full Text]

				R. G. Tirona, B. F. Leake, L. M. Podust, and R. B. Kim Identification of Amino Acids in Rat Pregnane X Receptor that Determine Species-Specific Activation Mol. Pharmacol., January 1, 2004; 65(1): 36 - 44. [Abstract] [Full Text] [PDF]

				C. Handschin and U. A. Meyer Induction of Drug Metabolism: The Role of Nuclear Receptors Pharmacol. Rev., December 1, 2003; 55(4): 649 - 673. [Abstract] [Full Text] [PDF]

				N. Mizuno, T. Niwa, Y. Yotsumoto, and Y. Sugiyama Impact of Drug Transporter Studies on Drug Discovery and Development Pharmacol. Rev., September 1, 2003; 55(3): 425 - 461. [Abstract] [Full Text] [PDF]

				C. Chen, J. L. Staudinger, and C. D. Klaassen NUCLEAR RECEPTOR, PREGNANE X RECEPTOR, IS REQUIRED FOR INDUCTION OF UDP-GLUCURONOSYLTRANSFERASES IN MOUSE LIVER BY PREGNENOLONE-16{alpha}-CARBONITRILE Drug Metab. Dispos., July 1, 2003; 31(7): 908 - 915. [Abstract] [Full Text] [PDF]

				R. Walter, C. Ullmann, D. Thummler, and W. Siegmund INFLUENCE OF PROPIVERINE ON HEPATIC MICROSOMAL CYTOCHROME P450 ENZYMES IN MALE RATS Drug Metab. Dispos., June 1, 2003; 31(6): 714 - 717. [Abstract] [Full Text] [PDF]

				J. Sonoda, W. Xie, J. M. Rosenfeld, J. L. Barwick, P. S. Guzelian, and R. M. Evans Regulation of a xenobiotic sulfonation cascade by nuclear pregnane X receptor (PXR) PNAS, October 15, 2002; 99(21): 13801 - 13806. [Abstract] [Full Text] [PDF]