Nuclear Receptor Coactivator 6 Mediates the Synergistic Activation of Human Cytochrome P-450 2C9 by the Constitutive Androstane Receptor and Hepatic Nuclear Factor-4{alpha}

doi:10.1124/mol.108.048983

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Molecular Pharmacology Fast Forward
First published on June 13, 2008; DOI: 10.1124/mol.108.048983

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Mol Pharmacol 74:913-923, 2008

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Nuclear Receptor Coactivator 6 Mediates the Synergistic Activation of Human Cytochrome P-450 2C9 by the Constitutive Androstane Receptor and Hepatic Nuclear Factor-4 ${alpha}$

Sailesh Surapureddi, Ritu Rana, Janardan K. Reddy, and Joyce A. Goldstein

Laboratory of Pharmacology, National Institute of Environmental Health Sciences, National Institutes of Health, Research Triangle Park, North Carolina (S.S., R.R., J.A.G.); and Department of Pathology, Northwestern University, the Feinberg School of Medicine, Chicago, Illinois (J.K.R.)

Received for publication May 19, 2008.

Accepted for publication June 13, 2008.

Abstract

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Abstract
Materials and Methods
Results
Discussion
References

Nuclear receptor coactivator 6 (NCOA6) also known as PRIP/RAP250/ASC-2anchors a steady-state complex of cofactors and function asa transcriptional coactivator for certain nuclear receptors.This is the first study to identify NCOA6 as a hepatic nuclearfactor 4 ${alpha}$ (HNF4 ${alpha}$ )-interacting protein. CYP2C9 is an importantenzyme that metabolizes both commonly used therapeutic drugsand important endogenous compounds. We have shown previouslythat constitutive androstane receptor (CAR) (a xenobiotic-sensingreceptor) up-regulates the CYP2C9 promoter through binding toa distal site, whereas HNF4 ${alpha}$ transcriptionally up-regulates CYP2C9via proximal sites. We demonstrate ligand-enhanced synergisticcross-talk between CAR and HNF4 ${alpha}$ . We identify NCOA6 as crucialto the underlying mechanism of this cross-talk. NCOA6 was identifiedas an HNF4 ${alpha}$ -interacting protein in this study using a yeast two-hybridscreen and GST pull-down assays. Furthermore, we identifiedNCOA6, CAR, and other coactivators as part of a mega complexof cofactors associated with HNF4 ${alpha}$ in HepG2 cells. Although theinteraction of NCOA6 with CAR is specifically through the firstLXXLL motif of NCOA6, both LXXLL motifs are involved in itsinteraction with HNF4 ${alpha}$ . Silencing of NCOA6 abrogated the synergisticactivation of the CYP2C9 promoter and the synergistic inductionof the CYP2C9 gene by CAR-HNF4 ${alpha}$ . Chromatin immunoprecipitationanalysis revealed that NCOA6 can pull down both the proximalHNF4 ${alpha}$ and distal CAR binding sites of the CYP2C9 promoter andprovides the basis for the recruitment of other cofactors. Weconclude that the coactivator NCOA6 mediates the mechanism ofthe synergistic activation of the CYP2C9 gene by CAR and HNF4 ${alpha}$ .

Cytochrome P450 2C9 (CYP2C9) is a major member of the cytochromeP450 superfamily in human liver, metabolizing numerous therapeuticallyused drugs and physiologically important endogenous compounds(Goldstein, 2001

). Hepatic expression of CYP2C9 exhibits considerableinterindividual variability in humans. Some of this interindividualvariability is due to the up-regulation of CYP2C9 levels byprior exposure to drugs and xenobiotics such as rifampicin,hyperforin, phenobarbital, and paclitaxel (Taxol) (Raucy etal., 2002

; Madan et al., 2003

; Komoroski et al., 2004

). Studiesin primary hepatocytes and clinical studies in vivo in humanshave confirmed that CYP2C9 levels and the clearances of CYP2C9substrates are increased after the administration of drugs (Williamsonet al., 1998

; Henderson et al., 2002

Recent studies have shown that the constitutive androstane receptor(CAR) and the pregnane X receptor (PXR) both bind to responsiveelements (REs) in the CYP2C9 promoter and are responsible forthe transcriptional up-regulation of CYP2C9 by various drugs(Ferguson et al., 2002; Gerbal-Chaloin et al., 2002; Chen etal., 2004). There is considerable overlap between the two receptorsfor similar sets of responsive elements in the promoters ofvarious genes (Xie et al., 2000; Goodwin et al., 2001; Smirliset al., 2001). Each of these receptors is preferentially activatedby a wide range of structurally unrelated compounds (Sueyoshiet al., 1999; Moore et al., 2000). Human CAR is activated preferentiallyby compounds such as phenobarbital, chlorpromazine, clotrimazole,methoxychlor, and CITCO (Timsit and Negishi, 2007), whereasPXR is activated preferentially by ligands such as rifampicin(rifampin) (Timsit and Negishi, 2007), paclitaxel, and hyperforin(Xie et al., 2000). The critical feature for activation of CARby xenobiotics is its translocation from the cytoplasm to thenucleus, where it heterodimerizes with retinoid X receptor,which facilitates its binding to CAR REs within the DNA of variouspromoters (Honkakoski et al., 1998; Kawamoto et al., 1999; Sueyoshiet al., 1999; Suino et al., 2004; Xu et al., 2004; Moore, 2005).Activation of CAR elicits a pleiotropic response regulatingdiverse pathways including various cytochrome P450 enzymes,liver growth, and liver tumor promotion by phenobarbital (Yamamotoet al., 2004).

Regulation of various promoters by CAR is substantially influencedby other nuclear receptors and transcription factors. We haveshown that the hepatic enriched transcriptional factor hepaticnuclear factor 4 ${alpha}$ (HNF4 ${alpha}$ ) transcriptionally up-regulates the CYP2C9promoter after binding to at least two proximal direct repeats;furthermore, HNF4 ${alpha}$ and CAR synergistically activate the CYP2C9promoter in HepG2 cells, and mutation of the HNF4 ${alpha}$ sites reducesor abolishes CAR-mediated induction of CYP2C9 (Chen et al.,2005). This suggests a potential cross-talk between a CAR siteat -1839 bp and one of the two proximal HNF4 ${alpha}$ binding sites inthe CYP2C9 promoter. The present study addresses the mechanismof this cross-talk.

Cofactors interact with nuclear receptors in the presence ofligands to bring about successful completion of gene transcription(Rosenfeld and Glass, 2001; McKenna and O'Malley, 2002). Thesecofactors have been found to be associated as complexes; severalsuch complexes have been purified: DRIP (Rachez et al., 1999),TRAP (Fondell et al., 1996), and PRIC (Surapureddi et al., 2002).Cofactors identified in such complexes include activators ofthe p160 family (Rosenfeld and Glass, 2001; McKenna and O'Malley,2002), CREB binding protein/p300 (Chrivia et al., 1993; Eckneret al., 1994), and mediator proteins such as PBP (Zhu et al.,1997), PRIP (Zhu et al., 2000), and PGC-1 ${alpha}$ (Puigserver et al.,1999). These cofactors all contain one or more conserved LXXLLmotifs, which have been found to be necessary for ligand-dependentinteraction with the AF-2 domain (Heery et al., 1997). PGC-1 ${alpha}$ has been studied extensively, also as a coactivator of HNF4 ${alpha}$ (Lin et al., 2005). In the present study, we identify NCOA6as a new interacting partner of HNF4 ${alpha}$ . NCOA6 is reported to belongto a novel steady-state complex called ASCOM (ASC-2/PRIP complex)that contains a subset of trithorax group of proteins (Goo etal., 2003). The current model of NR-mediated transcription proposesthat subsets of coactivator complexes contribute sequentiallyto the multiple subreactions of the transcription process (McKennaet al., 1999; Lonard and O'Malley, 2006).

The present study first identifies the cofactor NCOA6 as a newHNF4 ${alpha}$ -interacting partner using yeast two-hybrid screens andprotein-protein interaction studies. NCOA6, HNF4 ${alpha}$ , and CAR wereidentified as part of a mega complex in HepG2 cells. Chromatinimmunoprecipitation (ChIP) assays show that antibody to NCOA6precipitated both the CAR and HNF4 ${alpha}$ binding sites of the CYP2C9promoter. Finally, silencing NCOA6 abolished the synergisticactivation of the CYP2C9 gene by CAR and HNF4 ${alpha}$ and reduced therecruitment of coactivators and methyltransferases to the HNF4 ${alpha}$ sites. These results strongly indicate that NCOA6 is crucialfor the formation of a bridge between the CAR and HNF4 ${alpha}$ receptorsites in the CYP2C9 promoter and for the cross-talk betweenthese two receptors.

Materials and Methods

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Abstract
Materials and Methods
Results
Discussion
References

Yeast Two-Hybrid Screening. ProNet technologies automated two-hybridscreening was performed by Myriad Genetics (Salt Lake City,UT) as described previously (Garrus et al., 2001). Full-lengthHNF4 ${alpha}$ or partial domains were used as bait. Human liver was usedto prepare "prey" libraries. Baits were mated with prey, andselection was based on the dropout media (-Trp, -Leu, -His,-Ade) plates. Interactions between bait and prey molecules wereidentified using His- and Ade-selections. Plasmids isolatedwere retransformed into yeast, and interactions were confirmedby liquid β-galactosidase assays. The identities of theprey were determined by DNA sequencing.

Plasmids and Adenovirus-Mediated Expression and RNA Interference.CAR, HNF4 ${alpha}$ , NCOA6, PBP, and PGC-1 ${alpha}$ were cloned in pcDNA3.1 byPCR amplification. GST-CAR and GST-HNF4 ${alpha}$ were cloned in pGEX-4T1.NCOA6 domains, NCOA6 I (1-353 aa; NC-I), NCOA6 II (338-673 aa;NC-II), NCOA6 III (648-998 aa containing the first LXXLL motifat 851 aa; NC-III), NCOA6 IV (986-1327 aa; NC-IV), NCOA6 V (1292-1641aa coding for the second LXXLL motif at 1491 aa; NC-V), NCOA6VI (1625-2065 aa; NC-VI), and NCOA6 VII (648-1641 aa; NC-VII)were cloned in pGEX-4T1 and pcDNA3.1. CYP2C9-1.9Kb/pGL3 construct,described previously (Chen et al., 2005), was used for the transienttransfection assay of CYP2C9 promoter expression. Adenovirusexpressing full-length CAR and HNF4 ${alpha}$ were made with AdEasy XLAdenoviral Vector system (Stratagene, La Jolla, CA). Virus particleswere purified on continuous cesium chloride, dialyzed, and storedin Tris-buffered sucrose. Small interfering RNA (siRNA) targetsfor NCOA6 were identified using Genscript's target finder, constructbuilder, and sequence scrambler for construction of negativecontrol siRNA. The following siRNAs were designed to silenceNCOA6 mRNA coding sequence: NC-I, @146 bp: 5'-TTGTGGCCTTCAAAGGAAATA-3';NC-II, @500 bp: 5'-TGGCAAGTGGTCCAGGAATAA-3'; NC-III, @2241 bp:5'-CTCCGAACATGCAAGGAAATA-3'; NC-IV, @2451 bp: 5'-GATGCCTGATGTTAGCATTCA-3';and NC-V, @3262 bp: 5'-GTGCCACCATCACCTGATAAA-3'. Using the constructbuilder, double-stranded short hairpin RNA oligonucleotideswere designed for pRNAT-H1.1/Adeno (SD-1219) with H1 promoterand cGFP as the marker. NC-III siRNA target sequence was usedto design the scrambled siRNA 5'-CACTGAAGTATACCAAGAGCA-3'. Adenovirusesexpressing each short hairpin RNA were prepared and purified.HepG2 cells were routinely infected with 2.5 x 10⁹ virus particles(VP).

Cell Culture, Transient Transfections, and Ligands. HepG2 cellswere maintained in the Eagle's minimal essential medium supplementedwith 10% fetal bovine serum and penicillin-streptomycin at 37°Cunder 5% CO₂. All transient transfections were carried out asdescribed in Lipofectamine 2000 protocol (Invitrogen, Carlsbad,CA). In brief, 0.2 µg of CYP2C9 luciferase construct,0.1 µg of each receptor construct, and 0.1 µg ofcoactivator construct (2:1:1) with 0.02 µg of pRL-TK vectoras internal control, and pcDNA 3.1 as the empty vector to makethe total amount of DNA transfected to 0.8 µg were combinedin 50 µl of OPTI-MEM, mixed with transfection reagentas suggested, and overlaid on 80 to 90% confluent HepG2 cellsin serum-containing media. Twenty-four hours later, medium wasreplaced, and ligands were added at the appropriate concentrations(0.1% of dimethyl sulfoxide and 0.1 µM CITCO). Ligandswere incubated with the HepG2 cells for 24 h and assayed forpromoter activity using a dual luciferase assay kit (Promega,Madison, WI). Firefly luciferase readings were normalized withRenilla reniformis readings to calculate promoter activity.

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Fig. 1. Purification and identification of nuclear proteins interacting with HNF4 ${alpha}$ and CAR. a, isolation of HNF4 ${alpha}$ binding complex from nuclear extracts of HepG2 cells in which Ad-CAR was overexpressed (AdCAR-NEs). SDS/gradient gel analysis (4-20%) and silver staining of HNF4 ${alpha}$ binding complexes from 7.5 mg of AdCAR-NEs bound to GST (lane 2) and GST-HNF4 ${alpha}$ (lane 4). GST-HNF4 ${alpha}$ without the addition of NE is shown as a control (lane 3), and 50 µg of AdCAR-NE is shown as input (lane 1). b, immunoblots identifying CAR and various coactivators in the GST-HNF4 ${alpha}$ bound complex. Samples from input, AdCAR-expressing NEs; GST, GST bound proteins from AdCAR-NEs; GST-HNF4 ${alpha}$ , bound proteins from Ad-CAR-NEs were immunoblotted with specific antibodies for CBP, PGC-1 ${alpha}$ , NCOA6, PIMT, and CAR. Lane 1, NE input; lane 2, NE bound to GST as a control; lane 3, GST-HNF4 ${alpha}$ complex from AdCAR-NEs.

CAR, HNF4 ${alpha}$ Expression HepG2 Nuclear Extracts, Isolation of InteractingProteins, and Immunoblotting. Ten plates (15 cm) of 90% confluentHepG2 cells were infected with 2.5 x 10¹¹ VP for 48 h with eitherAdCAR or AdHNF4 ${alpha}$ . The cells were harvested after a quick washin ice-cold phosphate-buffered saline; nuclear extracts wereprepared according Dignam et al.'s method (Dignam et al., 1983

).GST and GST-HNF4 ${alpha}$ fusion proteins immobilized on GSH-Sepharosebeads were incubated with 5 to 10 mg of AdCAR-overexpressingHepG2 nuclear extracts (AdCAR-NEs) overnight. The beads wereextensively (100 volumes) washed after incubation with TEGNbuffer (20 mM Tris, pH 8.0, 0.2 mM EDTA, 10% glycerol, and 0.1%Nonidet P-40) containing 180 mM NaCl and once with TEGN buffercontaining no salt. The bound proteins were eluted in SDS-PAGEsample buffer and heat-denatured. The proteins were separatedona4to20% gradient gels and silver stained for visualization.GST and GST-HNF4 ${alpha}$ bound proteins after separation on 4 to 20%gradient gels were transferred onto nitrocellulose membrane,blocked with 5% milk in Tris-buffered saline/Tween 20, and immunoblottedwith antibodies for CAR (Santa Cruz Biotechnology, Inc., SantaCruz, CA) and reconfirmed with a monoclonal CAR antibody fromR&D Systems (Minneapolis, MN), HNF4 ${alpha}$ , CBP, PIMT, PGC-1 ${alpha}$ (allfrom Santa Cruz Biotechnology), and NCOA6 (Bethyl Laboratories,Montgomery, TX).

The Protein Microcharacterization Facility at NIEHS providedprotein sequencing-mass spectrometry. Protein bands of GST andGST-HNF4 ${alpha}$ lanes were sliced in 2-mm thickness and tryptic-digested.Coomassie blue-stained SDS-PAGE gels were cut, and proteinswere digested with trypsin essentially as described in Choiet al. (2007). Resulting peptide digests were then analyzedby nano-LC electrospray ionization-mass spectrometry and MS/MSon and Agilent XCT Ultra ion trap mass spectrometer (AgilentTechnologies, Palo Alto, CA), and data were processed and searchedagainst the National Center for Biotechnology Information nonredundantdatabase as described previously (Choi et al., 2007).

Expression and Purification of Recombinant Proteins, GST Pull-DownAssay. Full-length recombinant proteins of CAR and HNF4 ${alpha}$ wereexpressed as GST fusion proteins in Escherichia coli BL21 (DE3).GST pull-down assays were performed by incubating 5 µlof [³⁵S]methionine-labeled proteins in a 500 µl of NETNbuffer containing 1 mg/ml fatty acid-free bovine serum albuminin the presence and absence of respective ligands. The boundproteins were washed three times with NETN buffer and were heat-denaturedin SDS sample buffer. These proteins were separated on 4 to20% gradient gels, and after fixing and amplifying the signals,the gels were dried and autoradiographed.

qPCR-Total RNA was extracted using RNeasy MiniPrep system (QIAGEN,Valencia, CA). Reverse transcription PCR analysis was performedin two steps by initial reaction with Superscript II (Invitrogen,Carlsbad, CA) reverse transcriptase. PCR with Taqman UniversalPCR Master Mix (Applied Biosystems, Foster City, CA) was thenperformed with gene-specific primers using relative quantificationmethods (2^-CT) and measured on an Applied Biosystems GeneampPCR System 9700 using Taqman probes for CYP2C9, NCOA6, PGC-1 ${alpha}$ ,PBP, SRC-1, GRIP-1, and HNF4 ${alpha}$ with TBP as the internal control.

ChIP Analysis. Five plates (15 cm) of 90% confluent HepG2 cellswere infected with 2.5 x 10¹¹ VP for 48 h each with adenovirus-expressinglacZ, CAR, HNF4 ${alpha}$ , CAR-HNF4 ${alpha}$ , CAR-HNF4 ${alpha}$ with siRNA for NCOA6 (NC-III),and CAR-HNF4 ${alpha}$ with siRNA for NCOA6 (NC-IV) individually. After48 h, the cells were cross-linked with 1% formaldehyde directlyin the media for 10 min, and the chromatins were prepared (Qiet al., 2003). Chromatin extracts were precleared by incubatingwith rabbit serum for 3 h, and the IgG-bound proteins were pulleddown by incubating with preswollen Protein A beads. The supernatantwas stored or used for immunoprecipitations. All of the chromatinsused in the immunoprecipitations were checked to contain equalamounts of the target gene by PCR amplification and adjustedto 100 µl, which was further diluted to 500 µl tobe used in the immunoprecipitation with 2 µg of each antibody.CAR, CBP, NCOA6, and PIMT immunoprecipitates were washed twicewith buffer C and four times with buffer D. HNF4 ${alpha}$ antibody precipitateswere washed three times with buffer C and six times with bufferD (buffers described previously) (Qi et al., 2003). The DNAbinding proteins bound cognate cis-acting elements, and DNAfragments from the chromatin extracts (inputs) were purifiedand used as control for PCR reactions. The primers used foramplification of the human CYP2C9 promoter are 5'-TAAAGACAGCAACCGAGC-3'and 5'-TACAATGATTCAGGATTTCG-3' spanning for the CAR-responseelement and 5'-ATATACAAGGCATAGAATATGGCC-3' and 5'-GACCAATCACCTAGGTCCAC-3'spanning the HNF4 ${alpha}$ -response elements. Negative control primersare 5'-ATGGTTGCCACTGGGGATCT-3' and 5'-TGCCAAAGCCTAGGGGAAGA-3'.

Statistical Comparisons. Results were analyzed by two-way orone-way analysis of variance, and pair-wise comparisons weremade using Bonferroni t test.

Results

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Abstract
Materials and Methods
Results
Discussion
References

Isolation and Cloning of NCOA6 Interacting Protein by YeastTwo-Hybrid Screening. In the initial studies, yeast two-hybridscreens were performed using two human liver cDNA librarieswith HNF4 ${alpha}$ as the bait. Two of 11 HNF4 ${alpha}$ baits (93-352 and 165-355aa) identified several strong interacting proteins that couldpass two rounds of screening. One of the prey proteins identifiedby both of the bait molecules was NCOA6 (1993-2726 and 2322-2724bp) coding for the first LXXLL motif. This is the first timeNCOA6 has been identified as an HNF4 ${alpha}$ -interacting protein. Otherknown coactivators of HNF4 ${alpha}$ identified by the screen includePGC-1 ${alpha}$ . The complete coding sequence of human NCOA6 protein wasassembled in pcDNA3.1(+) using IMAGE and EST clones (Invitrogen).

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Fig. 2. Mass spectrometric identification of CAR. a, six peptides of CAR (genInfo identifier number 83921568), shown in red, resulting in 22% sequence coverage, were observed by mass spectrometry and MS/MS. b, generally, the precursor ions show good agreement between observed masses and theoretical masses for the predicted peptides. Extensive b- and y-series ions were observed for all six peptides. The MS/MS spectra of the ion (m/z 659.82) corresponding to the most N-terminal peptide observed (residues 89-100) and of the ion (m/z 729.23) corresponding to the most C-terminal peptide observed (residues 331-342) are shown as examples (c and d).

Identification of Nuclear Proteins that Bind Selectively toImmobilized GST-HNF4 ${alpha}$ . Nuclei were isolated from HepG2 cellsinfected with AdCAR for 48 h to ensure the translocation ofCAR and its binding proteins to induce the transcriptional activityof the target gene of interest, CYP2C9. To maximize the captureof proteins, we used full-length HNF4 ${alpha}$ . HepG2 nuclear extractsenriched with CAR were incubated with immobilized GST and GST-HNF4 ${alpha}$ .After extensively washing, the bound proteins were denaturedand subjected to SDS-PAGE. Very few nuclear proteins were boundto GST alone (Fig. 1a, lane 2). In contrast, more than 25 nuclearproteins with electrophoretic motilities greater than 40 kDawere detected that bound to GST-HNF4 ${alpha}$ (lane 4). An equivalentamount of GST-HNF4 ${alpha}$ purified from bacteria is shown as a control(lane 3). Protein sequencing data identified a polypeptide bandwith a molecular mass of $~$ 40 kDa as the constitutive androstanereceptor (Fig. 2). CAR (genInfo identifier number 83921568)was positively identified in the GST-HNF4 ${alpha}$ bound proteins andwas not observed in the GST-only bound proteins. CAR was identifiedwith a SpectrumMill distinct summed MS/MS search score of 94.23with 22% sequence coverage (Fig. 2a). Specifically, six differenttryptic peptides (Fig. 2b) that are unique to CAR were observedvia mass spectrometry and MS/MS. Each of the six peptides wasunambiguously identified by extensive b- and y-series ions inMS/MS experiments, as seen from the representative MS/MS spectrashown in Fig. 2 (c and d).

Although current identification of additional large proteinsby protein microsequencing is in progress, we used immunoblottingto identify some of the expected cofactors in the GST-HNF4 ${alpha}$ bindingcomplex. We also detected CAR by immunoblotting in both theinput and in the proteins bound to GST-HNF4 ${alpha}$ but not in proteinseluting from GST confirming the MS/MS results (Fig. 1b). Becausewe identify CAR and HNF4 ${alpha}$ in nuclear complexes in HepG2 cellsbut were unable to show evidence of a direct interaction betweenCAR and HNF4 ${alpha}$ using GST-HNF4 ${alpha}$ and radiolabeled CAR or GST-CARand radiolabeled HNF4 ${alpha}$ (data not shown), we hypothesized thatcofactors might be responsible for bringing these two nuclearreceptors together as a nuclear mega-complex. We have identifiedseveral cofactors, including NCOA6, CBP, PGC-1 ${alpha}$ , and PIMT, byimmunoblotting the Ad-CAR-expressing nuclear extracts (inputs)and in proteins bound to GST-HNF4 ${alpha}$ but not in proteins retainedby GST alone, suggesting that the HNF4 ${alpha}$ -CAR complex representsa functional transcriptional complex (Fig. 1, a and b). Theidentification of NCOA6 and PGC-1 ${alpha}$ as HNF4 ${alpha}$ -interacting proteinsby immunoblotting was consistent with the results of our two-hybridscreen. PIMT is also a known NCOA6-interacting protein witha methyltransferase domain.

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Fig. 3. In vitro protein-protein interactions between coactivator NCOA6 and the nuclear receptors CAR, HNF4 ${alpha}$ , and domain mapping. The first LXXLL motif of NCOA6 interacts with HNF4 ${alpha}$ and CAR. a, GST-CAR and HNF4 ${alpha}$ were immobilized on GSH-Sepharose beads. NCOA6 and PBP as a positive control were translated in vitro in the presence of [³⁵S]methionine using Promega's in vitro system. Full-length radiolabeled proteins were allowed to interact with GST, GST-CAR, and GST-HNF4 ${alpha}$ (±100 nM CITCO or dimethyl sulfoxide as the control). Bound proteins were heat-denatured, separated by electrophoresis on 4 to 20% gradient gels, and fixed; signal was amplified; and proteins were dried for autoradiography. One tenth of the transcription/translation mixes was loaded as input. b, schematic representation of NCOA6 domains. GST-NCOA6 domains or GST control were incubated with [³⁵S]methionine-labeled CAR (in the presence and absence of 100 nM CITCO) (c) or [³⁵S]methionine-labeled HNF4 ${alpha}$ (no ligand) (d) and subjected to SDS-gel electrophoresis. Gels were dried and autoradiographed as described under Materials and Methods.

NCOA6 Interacts with Nuclear Receptors CAR and HNF4 ${alpha}$ . To identifyNCOA6 interactions, we first used a GST fusion protein of atruncated NCOA6 (648-900 aa; coding for the first LXXLL motif).GST-NCOA6 was used for binding assays with [³⁵S]methionine-labeledHNF4 ${alpha}$ and CAR. Both of the nuclear receptors bound to GST-NCOA6strongly in the absence and presence of CITCO, which is knownto be a high-affinity ligand for human CAR (Maglich et al.,2003

). To verify the reciprocal relationships, GST-CAR and GST-HNF4 ${alpha}$ were incubated with in vitro-translated full-length NCOA6, andthe known coactivators PBP and PGC-1 ${alpha}$ were used as a positivecontrol. GST-CAR and GST-HNF4 ${alpha}$ fusion proteins retained the radiolabeledNCOA6, PBP, and PGC-1 ${alpha}$ in the presence and absence of 100 nMCITCO; GST alone did not retain NCOA6 (Fig. 3a). The CAR ligandCITCO augmented the retention of NCOA6 and PBP by GST-CAR. Asexpected, GST-CAR and GST-HNF4 ${alpha}$ fusion proteins also retainedother in vitro-translated known coactivators such as SRC-1 andGRIP (data not shown). To define the interacting domain(s) ofNCOA6, GST-NCOA6 domains were allowed to interact with in vitro[³⁵S]methionine-translated CAR or HNF4 ${alpha}$ . NCOA6 domains expressedas GST fusion proteins are shown schematically in Fig. 3b. GST-NCOA6-IIIdomain (648-998 aa; the first LXXLL at 851 aa) interacted significantlywith CAR (Fig. 3c) in a ligand-independent manner. The otherNCOA6 domains did not interact appreciably with CAR, suggestingthat only the first LXXLL motif was involved in the interaction.The first LXXLL motif of NCOA6 has been shown previously tointeract with other nuclear receptors such as peroxisome proliferator-activatedreceptor ( ${alpha}$ and ${gamma}$ ), thyroid hormone receptor alpha, and estrogenreceptor- ${alpha}$ (Zhu et al., 2000

). The NCOA6-CAR interaction differsfrom PBP-CAR interactions in that PBP requires both LXXLL motifsto bind with CAR (Jia et al., 2005

). The interacting domainsbetween NCOA6 and HNF4 ${alpha}$ were similarly mapped with [³⁵S]methionine-HNF4 ${alpha}$ (Fig. 3d); the GST-NCOA6-III domain strongly retained the radiolabeledHNF4 ${alpha}$ , suggesting a robust interaction. We were surprised tofind that there was also a moderate interaction between theGST-NCOA6-V domain (containing the second LXXLL motif) and HNF4 ${alpha}$ ,suggesting a new role for this LXXLL motif. The second LXXLLmotif of NCOA6 was also recently shown to be involved in theinteraction with LXR (another liver-specific receptor) in regulatinglipogenesis and cholesterol/bile acid homeostasis in the liverand interaction with estrogen receptor- ${alpha}$ (Li et al., 2007a

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Fig. 4. Effects of coactivators on the synergistic activation of CYP2C9 promoter expression by HNF4 ${alpha}$ and CAR in HepG2 cells. a, NCOA6 does not affect CAR-mediated transactivation. HepG2 cells were transfected with CAR, NCOA6, and PGC-1 ${alpha}$ along with CYP2C9 reporter construct in the presence (

) and absence (

) of 100 nM CITCO as the ligand with pRL as the internal control. All transfections were performed in triplicate. Values are means of triplicates ± S.E. CAR significantly up-regulates the CYP2C9 promoter in the absence and presence of ligand at ^*, p < 0.05; ^**, p < 0.01; ^***, p < 0.001. Transfection with PGC-1 ${alpha}$ and CAR significantly transactivates the CYP2C9 promoter more than CAR alone at ${dagger}$ ${dagger}$ ${dagger}$ , p < 0.001, whereas NCOA6 had no effect. b, effect of NCOA6 and PGC-1 ${alpha}$ on HNF4 ${alpha}$ -mediated transactivation. HNF4 ${alpha}$ and NCOA6 were expressed along with the CYP2C9 promoter in HepG2. ^*, p < 0.05; ^**, p < 0.01; and ^***, p < 0.001 indicates that values are significantly greater than CYP2C9 promoter alone. NCOA6 alone does not transactivate CYP2C9 promoter. Cotransfection with PGC-1 ${alpha}$ and HNF4 ${alpha}$ activates the CYP2C9 promoter significantly greater than HNF4 ${alpha}$ alone at ${dagger}$ ${dagger}$ ${dagger}$ , p < 0.001. c, CAR and HNF4 ${alpha}$ synergistically activate CYP2C9 promoter expression in the presence of CITCO and the effect of coactivators NCOA6 and PGC-1 ${alpha}$ . HepG2 cells were transfected with CAR and HNF4 ${alpha}$ individually and in combination, and coactivators NCOA6 and PGC-1 ${alpha}$ were added to CAR-HNF4 combination in the presence (

) and absence of 100 nM CITCO as the ligand with CYP2C9 reporter constructs. All transfections were performed in triplicate, and values represent the means ± S.E. The values represent -fold activation over CYP2C9 promoter alone. CAR, HNF4 ${alpha}$ , or CAR + HNF4 ${alpha}$ significantly up-regulates CYP2C9 promoter activity compared with CYP2C9 promoter alone at ^*, p < 0.05; ^**, p < 0.01; and ^***, p < 0.001. ${dagger}$ ${dagger}$ ${dagger}$ designates synergistic rather than additive response to cotransfection with HNF4 ${alpha}$ and CAR at p < 0.001 (analysis of variance with interaction). Transfection with NCOA6 significantly enhances the activation of CAR and HNF4 ${alpha}$ at p < 0.01, ##, whereas transfection with PGC-1 ${alpha}$ had no significant effect.

CAR and HNF4 ${alpha}$ Synergistically Activate the CYP2C9 Promoter ina Ligand-Enhanced Manner, and NCOA6 Modestly Augments This Effect.CAR transactivates the CYP2C9 promoter, and the CAR ligand CITCOenhances this effect (p < 0.01). The activation is $~$ 5-foldin the absence of ligand and 11-fold in the presence of 100nM CITCO (Fig. 4a). This concentration of ligand was used becauseinitial experiments verified that it is specific for CAR, whereashigher doses are not specific because they activate anotherreceptor, PXR. Coexpression of NCOA6 did not significantly enhanceCAR-mediated promoter activation, whereas PGC-1 ${alpha}$ , a known CARcoactivator, significantly enhanced activation (p < 0.001).HNF4 ${alpha}$ transactivated CYP2C9 promoter activity ( $~$ 7-fold) (p <0.05) (Fig. 4b), and coexpression of NCOA6 with HNF4 ${alpha}$ modestlyenhanced this activation to $~$ 9-fold (p < 0.001), althoughthe enhancement by NCOA6 was not quite significant (p = 0.09).NCOA6 by itself does not transactivate the CYP2C9 promoter.As a positive control, expression of PGC-1 ${alpha}$ , a known coactivatorof HNF4 ${alpha}$ (which is known to be expressed at low levels in HepG2cells), significantly increased HNF4 ${alpha}$ activation (p < 0.01)to $~$ 12-fold. PGC-1 ${alpha}$ had no effect on the 2C9 promoter activityalone (data not shown). When both CAR and HNF4 ${alpha}$ are coexpressedwith the CYP2C9 promoter in the presence of the CAR ligand CITCO,there is a synergistic 26-fold transactivation of CYP2C9 promoteractivity when compared with 11-fold activation by CAR aloneor 4.8-fold by HNF4 ${alpha}$ alone (Fig. 4c). Cotransfection with NCOA6slightly increased this activation by CAR and HNF4 ${alpha}$ to 35-fold,whereas PGC-1 ${alpha}$ produced no significant increase in this experiment.In summary, there is a synergistic activation of CYP2C9 promoterexpression by the nuclear receptors CAR and HNF4 ${alpha}$ in the presenceof the CAR ligand, CITCO. Exogenous NCOA6 had no effect on CARactivation but modestly enhanced the activation of the CYP2C9promoter by HNF4 ${alpha}$ and the synergistic activation by CAR and HNF4 ${alpha}$ ,showing that it is a coactivator of HNF4 ${alpha}$ .

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Fig. 5. Silencing of NCOA6 abrogates the synergistic effects of HNF4 ${alpha}$ with CAR on CYP2C9 gene expression. a, screening of siRNAs for silencing NCOA6 mRNA in HepG2 cells. Five potential targets for silencing NCOA6 were identified in silico. HepG2 cells were infected with 2.5 x 10⁹ VP/ml for each of the siRNAs for NCOA6 (NC-I to NC-V) individually with scrambled siRNA as control. After 48 h, total RNA was prepared to estimate NCOA6 mRNA levels using qPCR. One target, NC-V, was not effective (data not shown). All of the remaining targets significantly suppressed NCOA6 mRNA, ^***, p < 0.001, although NC-III was the most effective ${dagger}$ ${dagger}$ , p < 0.001. Values represent means ± S.E. of triplicate analyses. b, siNCOA6 (NC-III) dramatically decreases the synergistic effects of CAR and HNF4 ${alpha}$ on CYP2C9 promoter activation. HepG2 cells were cotransfected with the CYP2C9 promoter and CAR alone or in combination with HNF4 ${alpha}$ as in Fig. 3c, and the cells were infected with scrambled or siNCOA6 (NC-III) 2.5 x 10⁹ VP/ml in the presence (+) and absence (-) of 100 nM CITCO. Values represent means ± S.E. of triplicate transfections. Transfection with CAR or CAR+HNF4 ${alpha}$ significantly increased CYP2C9 promoter activity, at ^*, p < 0.05, ^**, p < 0.01, ^***, p < 0.001. ${dagger}$ , ${dagger}$ ${dagger}$ , and ${dagger}$ ${dagger}$ ${dagger}$ indicate synergistic rather than additive response to HNF4 ${alpha}$ and CAR at p < 0.05, p < 0.01, and p < 0.001, respectively (analysis of variance with interaction). NC-III significantly decreases the synergistic action of CAR-HNF4 ${alpha}$ in both the absence and presence of CITCO at #, p < 0.05, and ###, p < 0.001, respectively. c, immunoblots of endogenous NCOA6 and PGC-1a in HepG2 cells infected with nuclear receptors. NE (100 µg) from HepG2 cells infected with lacZ, CAR, HNF4 ${alpha}$ , CAR-HNF4 ${alpha}$ , and CAR-HNF4 ${alpha}$ + siNCOA6 (NC-III) was immunoblotted for NCOA6 and PGC-1 ${alpha}$ . NCOA6 is clearly down-regulated in HepG2 cells infected with siNCOA6 (NC-III), whereas PGC-1 ${alpha}$ expression levels remain unchanged. of NE (10 µg) was blotted for Pol II as a control and its expression level remain unchanged.

NCOA6 as the Bridging Coactivator for Nuclear Receptors CARand HNF4 ${alpha}$ . To more definitely test the transcriptional role ofNCOA6 in the synergistic activation of CYP2C9 by CAR and HNF4 ${alpha}$ ,we then expressed siRNA directed against NCOA6 in HepG2 cellsusing adenoviral system to silence endogenous NCOA6 expression.Among five targets tested, NC-V was not effective. Of the remainingfour, NC-III and NC IV reduced the expression of NCOA6 mRNAlevels by 95 and 88%, respectively, as quantified by qPCR (p< 0.001) (Fig. 5a). NC-III produced a significantly lowerexpression than any of the other targets. Western blot analysisconfirmed that NCOA6 protein was markedly decreased in cellsinfected with NC-III (Fig. 5c), whereas PGC-1 ${alpha}$ and Pol II remainunchanged. To test whether silencing of NCOA6 affects the ligand-dependentsynergistic activation of the CYP2C9 promoter by CAR and HNF4 ${alpha}$ ,the CYP2C9-luc promoter construct and CAR, HNF4 ${alpha}$ , or CAR-HNF4 ${alpha}$ were transiently transfected into HepG2 cells; 24 h later, thecells were infected with adenovirus expressing scrambled orsiRNAs for NCOA6. It should be noted that the magnitude of thesynergistic activation is larger than in Fig. 4c, probably becausetransfection efficiencies are different during culture involvingadenoviral infection (serum is absent from the medium but isadded later). Serum is absent from the medium during adenoviraltreatment of the cells, but is added later which would shockthe cells altering transfection efficiency. The synergisticactivation of the CYP2C9 promoter by CAR-HNF4 ${alpha}$ was dramaticallysuppressed by the expression of siRNA (NC-III) for NCOA6 inthe presence and absence of ligand (Fig. 5b).

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Fig. 6. NCOA6 siRNA (III) prevents the synergistic effects of CAR and HNF4 ${alpha}$ on CYP2C9 mRNA in vivo in HepG2 cells. a, SiNCOA6 decreases the endogenous CYP2C9 expression. HepG2 cell were infected with adenovirus containing scrambled or siNCOA6(NC-III) for 48 h. The cells were harvested, and total RNA was prepared to estimate constitutive CYP2C9 mRNA levels using qPCR. NC-III significantly decreases endogenous CYP2C9 mRNA at ^***, p < 0.001. b, silencing of NCOA6 abolishes the synergistic effects of adenoviral expression of CAR and HNF4 ${alpha}$ on CYP2C9 mRNA in HepG2 cells. HepG2 cells were infected with adenovirus expressing lacZ, CAR, HNF4 ${alpha}$ , CAR-HNF4 ${alpha}$ , and CAR-HNF4 ${alpha}$ with siNCOA6(NC-III) for 48 h. The cells were harvested, and total RNA was used to measure CYP2C9 mRNA by qPCR. CAR or HNF4 ${alpha}$ significantly increased CYP2C9 mRNA at ^*, p < 0.05; ^**, p < 0.01; and ^***, p < 0.001. ${dagger}$ ${dagger}$ ${dagger}$ , synergistic rather than additive response to transfection with HNF4 ${alpha}$ and CAR at p < 0.001. ##, NC-III significantly reduced the CYP2C9 mRNA response to HNF4 ${alpha}$ and CAR at p < 0.01. Values represent means ± S.E. of triplicates.

Silencing of NCOA6 Down-Regulates Constitutive and SynergisticInduction of CYP2C9 mRNA in HepG2 Cells. We examined the effectof NCOA6 siRNA on CYP2C9 mRNA in HepG2 cells. Cells were infectedwith either adenovirus expressing scrambled or NCOA6 siRNAsfor 48 h with lacZ-infected cells as control. Scrambled siRNAdid not change CYP2C9 mRNA expression significantly in normalHepG2 cells. siNCOA6 (NC-III), on the other hand, down-regulatedendogenous CYP2C9 mRNA expression more than 75% (Fig. 6a). Becausewe have shown previously that CAR and HNF4 ${alpha}$ synergistically activatethe CYP2C9 promoter and that the down-regulation of NCOA6 levelsgreatly inhibits this synergistic activation, we examined whetherthere was any synergistic induction of CYP2C9 mRNA by CAR andHNF4 ${alpha}$ , as well as the effect of siNCOA6 (NC-III) on the synergisticincrease in CYP2C9 mRNA in vivo. We infected AdCAR and AdHNF4 ${alpha}$ individually and in combination in HepG2 cells and simultaneouslydown-regulated NCOA6 levels with siRNA for NCOA6 (NC-III). Adenoviralexpression of CAR and HNF4 ${alpha}$ produces a synergistic rather thanadditive 1000-fold induction of CYP2C9 mRNA in HepG2 cells comparedwith a 100-fold induction by HNF4 ${alpha}$ alone and a 35-fold inductionby CAR alone. The synergistic effects of HNF4 ${alpha}$ and CAR on CYP2C9mRNA in HepG2 cells were abolished by down-regulating NCOA6with adenoviral siRNA (p < 0.01) (Fig. 6b). In contrast,silencing NCOA6 did not affect the induction of CYP2C9 mRNAby CAR alone or HNF4 ${alpha}$ alone (data not shown). Silencing of NCOA6also did not affect the expression of mRNA of other known coactivatorssuch as SRC-1, PBP, or GRIP-1, although siRNA for NCOA6 modestlydecreased mRNA for PGC-1 ${alpha}$ ( $~$ 40%) (data not shown). Taken together,the effects of NCOA6 siRNA on the synergistic transactivationby CAR and HNF4 ${alpha}$ and their mRNAs strongly indicate that NCOA6acts as a bridging partner between CAR and HNF4 ${alpha}$ responsiblefor the synergistic up-regulation of CYP2C9 gene expression.

Recruitment Analysis of CAR, HNF ${alpha}$ , and Cofactors on the CAR ResponseElement and HNF4 ${alpha}$ Response Element of CYP2C9 Promoter. ChIP assayswere performed on the chromatin extracts from the HepG2 cellsdescribed above in Fig. 6b to demonstrate the recruitment ofnuclear receptors CAR and HNF4 ${alpha}$ to their respective binding siteson CYP2C9 promoter and the effect of silencing of NCOA6 on theassociation of coactivators to these nuclear receptors (Fig. 7).The following PCR products were generated by primer pairs forthe CAR-RE (Fig. 7a), HNF4 ${alpha}$ -RE (Fig. 7b), or for a negative controlprimers from glyceraldehyde-3-phosphate dehydrogenase-CNAP-1gene (Fig. 7c). Input chromatin and nonimmune IgG was used asa negative control are shown at the bottom. These ChIP assaysdemonstrate that CAR is recruited robustly to the CAR bindingsite (Fig. 7a) on the promoter region of CYP2C9 in chromatinextracts prepared from HepG2 cells, particularly in cells overexpressingCAR and moderately in cells overexpressing CAR-HNF4 ${alpha}$ with orwithout the siRNA for NCOA6 (NC-III). As expected, HNF4 ${alpha}$ wasrecruited to its binding site (Fig. 7b) on the CYP2C9 promoterin all of the chromatin extracts from cells overexpressing HNF4 ${alpha}$ ,CAR-HNF4 ${alpha}$ , and siRNA for NCOA6 (NC-III) did not affect this recruitment.Antibodies for the coactivator NCOA6 robustly precipitated theHNF4 ${alpha}$ binding sites in chromatin extracts from cells overexpressingCAR, HNF4 ${alpha}$ , and CAR-HNF4 ${alpha}$ , particularly in cells overexpressingboth CAR and HNF4 ${alpha}$ , and also precipitated the CAR binding site,although less robustly. This association of NCOA6 to both theHNF4 ${alpha}$ binding sites and CAR binding site was negligible in chromatinextracts from cells expressing NCOA6 siRNA. The coactivatorPGC-1 ${alpha}$ was robustly associated with both the HNF4 ${alpha}$ binding sitesand CAR binding sites in chromatin extracts from cells overexpressingCAR, HNF4 ${alpha}$ , and CAR-HNF4 ${alpha}$ , whereas PIMT was associated primarilywith the HNF4 ${alpha}$ site. Silencing of NCOA6 with NC-III greatly reducedor abolished the association of CBP, PGC-1 ${alpha}$ , and PIMT to theCYP2C9 promoter, suggesting that NCOA6 is required for the recruitmentof cofactors from the mediator complex. Fig. 7c shows no amplificationof a nontarget gene from immunoprecipitated chromatins. Thus,ChIP assays show that CAR and HNF4 ${alpha}$ interact with their respectivebinding sites on the CYP2C9 promoter in vivo in its native context,NCOA6 interacts with both the nuclear receptors and brings downboth sites by its interaction with the nuclear receptors CARand HNF4 ${alpha}$ , and silencing NCOA6 prevents the recruitment not onlyof NCOA6 but also other coactivators to the HNF4 ${alpha}$ -RE.

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Fig. 7. Analysis of recruitment of the nuclear receptors CAR, HNF4 ${alpha}$ , and coactivators to the CYP2C9 promoter by chromatin immunoprecipitation analysis. ChIP analysis for CAR-HNF4 ${alpha}$ mediated recruitment of nuclear receptor cofactors to the CYP2C9 gene promoter. Chromatin extracts isolated from HepG2 cells infected individually with adenovirus expressing lacZ, CAR, HNF4 ${alpha}$ , CAR-HNF4 ${alpha}$ , and CAR-HNF4 ${alpha}$ with siNCOA6 (NC-III) were precleared as described under Materials and Methods and immunoprecipitated with antibodies for CAR, HNF4 ${alpha}$ , NCOA6, PIMT, CBP, and PGC-1 ${alpha}$ . PCR was used to analyze the CYP2C9 promoter at the CAR binding sites (a), HNF4 ${alpha}$ binding sites (b), and control negative primers (c). Expression of CAR and HNF4 ${alpha}$ increased their recruitment to their respective sites. Immunoprecipitation with NCOA6, PIMT, CBP, and PGC-1 ${alpha}$ showed their association with both CAR and HNF4 ${alpha}$ binding sites on CYP2C9 promoter. Silencing of NCOA6 essentially abolishes the recruitment of NCOA6, PIMT, CBP, and PGC-1 ${alpha}$ to the HNF4 ${alpha}$ sites as well as many of the cofactors to the CAR and HNF4 ${alpha}$ binding sites.

Discussion

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Abstract
Materials and Methods
Results
Discussion
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In the present study, we address the mechanism of the synergisticactivation of the human CYP2C9 promoter by CAR and HNF4 ${alpha}$ . Itis noteworthy that we identify NCOA6 as a new HNF4 ${alpha}$ -interactingprotein using the HNF4 ${alpha}$ as the bait in yeast two-hybrid screening.To identify the proteins that interact with full-length HNF4 ${alpha}$ ,we used a GST pull-down approach using nuclear extracts fromHepG2 cells expressing CAR. Both CAR and CYP2C9 are expressedat very low levels in HepG2 cells (Ferguson et al., 2002), butoverexpression of CAR (by infection with AdCAR) induces CYP2C9mRNA expression in these cells. Therefore, we used nuclear extractsfrom HepG2 cells infected with AdCAR to identify binding proteinpartners in the CAR-HNF4 ${alpha}$ complex. Mass spectral analysis identifiedCAR, and immunoblotting identified NCOA6 and CAR as well asCBP, PGC-1 ${alpha}$ , and PIMT in this mega complex. As discussed earlier,nuclear receptor coactivators exist in subcomplexes (McKennaet al., 1999). Although there are two schools of thought regardingwhether these subcomplexes form sequentially or combinatorially,recent evidence points to proteins that facilitate such linkageof these subcomplexes, even for a transient period (Misra etal., 2002). Examples of such proteins include NCOA6, linkingCBP to a PBP complex, and PIMT, directly linking CBP with PBP.Consistent with this bridging function, we found proteins belongingto the known CBP subcomplex and mediator subcomplex in the isolatedCAR-HNF4 ${alpha}$ complex from HepG2 cells. The synergistic activationof HNF4 ${alpha}$ and CAR on CYP2C9 promoter activity, the effects ofsilencing NCOA6 on this synergism, and the results of ChIP assayssuggest that after recruitment of CAR and HNF4 ${alpha}$ to their respectivebinding sites, a set of coactivators are recruited to form abridge between the receptors initiating the observed surge intranscriptional activity. siRNA studies suggest that NCOA6 isnecessary for the formation of this bridge between HNF4 ${alpha}$ andCAR and for recruitment of other coactivators to the proximalHNF4 ${alpha}$ sites.

PBP (Zhu et al., 1997) and PRIP/NCOA6 (Zhu et al., 2000) areknown to regulate individually the expression of the ap2 gene,which is involved in adipogenesis (Qi et al., 2003). GRIP-1and PBP have also been shown to function as coactivators fora CAR-mediated increase in Cyp2b10 gene expression (Min et al.,2002; Jia et al., 2005). Although NCOA6 has shown to be a coactivatorfor CAR (Choi et al., 2005), CAR-mediated gene expression ofCyp2b10 was not affected in NCOA6-null mice (Guo et al., 2006;Sarkar et al., 2007). GRIP-1 belongs to the p160 family of coactivators(Leo and Chen, 2000). Although GRIP-1 could interact with CARand HNF4 ${alpha}$ individually, GRIP-1 is not a major player in bridgingfunction. Deletion of the SRC-1, steroid receptor coactivator-2/GRIP-1,and SRC-3/pCIP genes in knockout mice have no effect on CAR-regulatedgene transcription (Xia et al., 2007). PBP, on the other hand,acts as a coactivator for CAR, and studies in PBP-null miceindicate that PBP is necessary for the translocation of CARto the nucleus, and PBP regulates the hepatic expression ofCAR (Jia et al., 2005). In the present study, we show that NCOA6acts as an interacting partner for HNF4 ${alpha}$ (Fig. 2). Because invitro data show that PBP can bind to CAR, and HNF4 ${alpha}$ binds toNCOA6 (Fig. 2), we considered the possibility of a bridge formationeither directly or through PIMT (Zhu et al., 2001). PIMT hasbeen reported to form a bridge between NCOA6 and PBP (Misraet al., 2002).

Although there is also a possibility of an indirect interaction/mechanismbetween CAR and HNF4 ${alpha}$ with PIMT or PIMT-like methyl transferases,one likely scenario for the CAR-HNF4 ${alpha}$ bridge formation is bythe direct interaction of NCOA6 with both of the receptors simultaneously.The nuclear receptor interacting box containing the first LXXLLmotif is found to interact with CAR alone (Fig. 5b), whereasHNF4 ${alpha}$ interacted with the NR boxes coding for both the firstLXXLL and the second LXXLL motifs (Fig. 5c). This opens thepossibility that the nuclear receptor interacting box bindsto CAR and the NR-2 box binds to HNF4 ${alpha}$ , thereby directly bridgingCAR and HNF4 ${alpha}$ to bring about the synergistic activation of theCYP2C9 promoter and the induction of CYP2C9 mRNA. Nonredundantcoactivators like CBP and its binding proteins (histone acetylatingproteins) are known to interact with both CAR and HNF4 ${alpha}$ ; likewise,the redundant coactivator PGC-1 ${alpha}$ (a member of the PGC-1 familyknown to be involved in splicing) interacts with both CAR andHNF4 ${alpha}$ . Although these coactivators are probably part of the CAR-HNF4 ${alpha}$ transcription complex, our data suggest that it is unlikelythat they are required for the bridge between CAR and HNF4 ${alpha}$ .For example, the redundant coactivator PGC-1 could rescue notthe silencing effect of NCOA6 in CYP2C9 transactivation assays.

Promoter regions of genes have binding sites for numerous nuclearproteins and nuclear receptors. Therefore, the possibility ofcross-talk between binding partners is not only feasible butessential to transduce complex and sometimes contradictory signalsfor the regulation of a gene. Such a cross-talk between glucocorticoidreceptor and peroxisome proliferator-activated receptor- ${gamma}$ hasbeen documented on ap2 gene expression and between the coactivatorsPBP and NCOA6 (Qi et al., 2003). CAR also cross-talks with thefork-head transcription factor FOXO1 to repress its activationof an insulin response sequence in the glucose-6-phosphatasegene (Kodama et al., 2004). PXR also cross-talks with the insulinresponse transcription factor FoxA2 to repress the transcriptionof genes involved in lipid metabolism in the mouse (Nakamuraet al., 2007), and PXR represses glucagon activation of theglucose-6-phosphatase gene by binding to CREB, the cAMP responseelement binding protein, inhibiting CREB interaction with itsDNA binding elements (Kodama et al., 2007). Several examplesof either inhibitory cross-talk or potentiation between HNF4 ${alpha}$ and PXR or CAR have been reported. PXR seems to interfere withHNF4 ${alpha}$ -up-regulation of CYP7A1 and the regulation of cholesterolmetabolism (Bhalla et al., 2004; Li et al., 2007b). HNF4 ${alpha}$ haslong been suggested to have a positive role in the PXR-mediatedinduction of CYP3A4. Possible potentiation between HNF4 ${alpha}$ andCAR has also been reported recently in the regulation of CYP3A4(Li and Chiang, 2006) and steroid and bile acid sulfotransferase(SULT2A1) (Echchgadda et al., 2007).

Our study provides evidence for a new mechanism for the synergisticeffect of HNF4 ${alpha}$ with CAR on expression of the human CYP2C9 gene,wherein cofactors are proposed to bridge distant receptor sitesin the promoter, resulting in a synergistic effect on gene expression.In particular, NCOA6 seems to be an essential factor, possiblyproviding a platform for the recruitment of cofactors to thisbridge.

Acknowledgements

We thank Drs. Georges Frech and Karen Heichman for their oversightof the two-hybrid project at Myriad Genetics (Salt Lake City,UT). We acknowledge and thank Dr. Jason Williams, Protein Microcharacterizationfacility, National Institute of Environmental Health Sciences,for mass spectrometric analysis, and Dr. Grace Kissling, Biostatisticsbranch, National Institute of Environmental Health Sciences,for statistical analysis. We also thank Joyce Blais-dell andSherry Coulter, NIEHS, for their assistance in this work.

Footnotes

This research was supported by the Intramural Research Programof the National Institutes of Health and National Instituteof Environmental Health Sciences (to S.S., R.R., and J.A.G.)and in part by National Institutes of Health grant CA104578(to J.K.R.).

ABBREVIATIONS: CAR, constitutive activate/androstane receptor;HNF4 ${alpha}$ , hepatocyte nuclear factor 4 ${alpha}$ ; RE, response element; NCOA6,Nuclear receptor coactivator 6 (PRIP/RAP250/ASC-2); PBP, peroxisomeproliferator-activated receptor binding protein (TRAP220/MED-1/DRIP205);CBP, cAMP response element-binding protein binding protein;PCR, polymerase chain reaction; SRC-1, steroid receptor coactivator-1;PGC-1 ${alpha}$ , peroxisome proliferator-activated receptor ${gamma}$ coactivator-1;PIMT, PRIP-interacting protein with methyltransferase domain;GRIP-1, glucocorticoid receptor interacting protein; ChIP, chromatinimmunoprecipitation; qPCR, quantitative polymerase chain reaction;CITCO, 6-(4-chlorophenyl)imidazo[2,1-b][1,3]thiazole-5-carbaldehydeO-(3,4-dichlorobenzyl)oxime; PXR, pregnane X receptor; CREB,cAMP response element-binding protein; aa, amino acid; siRNA,small interfering RNA; bp, base pair(s); TEGN, Tris, EDTA, glycerol,and Nonidet P-40; PAGE, polyacrylamide gel electrophoresis;NIEHS, National Institute of Environmental Health Sciences;VP, virus particles; Ad, adenovirus; MS/MS, tandem mass spectrometry.

Address correspondence to: Dr. Joyce A. Goldstein, Laboratory of Pharmacology (A3-02), NIEHS, P.O. Box 12233, Research Triangle Park, NC 27709. E-mail: goldste1{at}niehs.nih.gov

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