Peroxisome Proliferator-Activated Receptor {gamma} Regulates E-Cadherin Expression and Inhibits Growth and Invasion of Prostate Cancer

Peroxisome proliferator-activated receptor ${gamma}$ (PPAR ${gamma}$ ) might notbe permissive to ligand activation in prostate cancer cells.Association of PPAR ${gamma}$ with repressing factors or posttranslationalmodifications in PPAR ${gamma}$ protein could explain the lack of effectof PPAR ${gamma}$ ligands in a recent randomized clinical trial. Usingcells and prostate cancer xenograft mouse models, we demonstratein this study that a combination treatment using the PPAR ${gamma}$ agonistpioglitazone and the histone deacetylase inhibitor valproicacid is more efficient at inhibiting prostate tumor growth thaneach individual therapy. We show that the combination treatmentimpairs the bone-invasive potential of prostate cancer cellsin mice. In addition, we demonstrate that expression of E-cadherin,a protein involved in the control of cell migration and invasion,is highly up-regulated in the presence of valproic acid andpioglitazone. We show that E-cadherin expression responds onlyto the combination treatment and not to single PPAR ${gamma}$ agonists,defining a new class of PPAR ${gamma}$ target genes. These results openup new therapeutic perspectives in the treatment of prostatecancer.

INTRODUCTION

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Introduction

Prostate cancer is the most common form of cancer in men andthe second leading cause of cancer deaths. Tumor growth is originallyandrogen dependent. Androgens exert their effects through activationof the androgen receptor (AR), a member of the hormone nuclearreceptor superfamily. In the mature prostatic gland, the ARregulates the expression of genes involved in cell divisionand proliferation of the epithelial cells (26). The AR is alsoinvolved in several other aspects of prostate cellular metabolism,including lipid biosynthesis, and controls the production ofspecialized secretory proteins with prostate-restricted expression,such as prostate-specific antigen (PSA) (26). When prostatecancer is still hormone dependent, androgen ablation therapycauses regression of the tumor (18), likely through inactivationof the transcription of the AR target genes. However, the durabilityof this response is inadequate and many men develop recurrentandrogen-independent prostate cancer, which has a very poorprognosis (see reference 11 for a review). Other nuclear receptorsor locally produced factors that interact with nuclear receptorsare likely involved in cell proliferation, differentiation,and apoptosis in the prostate. The peroxisome proliferator-activatedreceptor ${gamma}$ (PPAR ${gamma}$ ) is one such factor. PPAR ${gamma}$ is another memberof the hormone nuclear receptor superfamily. As for most ofthe other members of this family, its activity is regulatedby ligands. Prostaglandin J2 and the antidiabetic drugs thiazolidinedioneshave been determined to be natural and synthetic ligands ofPPAR ${gamma}$ , respectively (for a review, see reference 9). PPAR ${gamma}$ ishighly expressed in the adipose tissue and is required for itsdevelopment through regulation of the expression of adipocyte-specificgenes, such as lipoprotein lipase or the fatty acid transportprotein aP2. PPAR ${gamma}$ is expressed in several other tissues in additionto adipose tissue, including gut, macrophages, lung, bladder,breast, and prostate, although its function in these tissuesremains to be elucidated. Interestingly, PPAR ${gamma}$ has been shownto be overexpressed in prostate cancer (15). Whereas the physiologicalfunction of PPAR ${gamma}$ in normal epithelial cells is largely unknown,PPAR ${gamma}$ activation was reported to inhibit the proliferation ofprostate carcinoma cells (4, 21, 25, 34) and also other cancerlineages (7). These observations suggest that induction of differentiationby activation of PPAR ${gamma}$ may represent a promising novel therapeuticapproach for cancer, as already demonstrated with xenograftmodels of prostate (21). In addition, treatment of patientswith advanced prostate cancer with the PPAR ${gamma}$ agonist troglitazoneresulted in the stabilization of prostate-specific antigen levels(25). In contrast, in a large-scale, placebo-controlled, randomizedclinical trial, no effects on the PSA doubling time of prostatecancer patients were observed (35). These results suggest thatPPAR ${gamma}$ is not permissive for activation by ligands in these prostatecancer patients. One interesting hypothesis is that some factorscould prevent activation of PPAR ${gamma}$ by its ligands in cancer cells.One such factor is histone deacetylases (HDAC). Deacetylationof histones has been correlated with a transcriptionally silentstate of chromatin. Inhibition of HDAC activity by natural orsynthetic compounds results in the reversion of the phenotypeof tumoral cells into normal cells or apoptosis of cancer cells(22). Although the precise mechanisms have not yet been elucidated,HDAC inhibition results in the selective induction of endogenousgenes that play roles in either differentiation or cell cyclearrest. We demonstrated in previous studies that HDAC3 is complexedwith PPAR ${gamma}$ in the promoters of PPAR ${gamma}$ target genes and that thisassociation results in the repression of these target genes.HDAC inhibitors, such as valproic acid or sodium butyrate (NaBu),had a synergistic effect with thiazolidinediones in the activationof PPAR ${gamma}$ target genes (8). Therefore, HDAC inhibition could renderPPAR ${gamma}$ permissive to activation by its ligands. We show in thisstudy that a combination treatment of HDAC inhibitors and PPAR ${gamma}$ agonists results in the arrest of proliferation, increases apoptosis,and decreases the invasion potential of prostate cancer cellsboth in vitro and in vivo. Furthermore, we show that PPAR ${gamma}$ agonistsincrease the expression of E-cadherin mRNA only in the presenceof HDAC inhibitors, which defines a new class of PPAR ${gamma}$ targetgenes.

MATERIALS AND METHODS

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Materials and Methods

Materials and oligonucleotides. Pioglitazone was a kind gift of Takeda Pharmaceutical Industries(Osaka, Japan). Rosiglitazone was purchased from VWR-Calbiochem(Fontenay sous Bois, France). All chemicals, except if statedotherwise, were purchased from Sigma (St. Louis, MO). Anti-cyclin-dependentkinase 4 (anti-CDK4) (C-22), anti-PPAR ${gamma}$ (H-100 for chromatinimmunoprecipitation [ChIP] or N-20 for immunohistochemistry[IHC]), anti-HDAC3 (H-99), and anti-PCNA (PC-10) antibodieswere from Santa Cruz Biotechnology (Santa Cruz, CA); anti-acetylH4 (Lys 12) and anti-phospho-retinoblastoma (anti-^ppRb) (Ser807/811) were from Cell Signaling (Beverly, MA); anti-p21 (Ab-1)was from EMD Biosciences (Darmstadt, Germany); anti-p27 wasfrom NeoMarkers (Fremont, CA); and antibromodeoxyuridine (anti-BrdU)and anti-E-cadherin (NCH-38) antibodies were from DAKO (Glostrup,Denmark). The oligonucleotide sequences used for various experimentsdescribed in the manuscript are available upon request.

Cell culture, transient transfections, and siRNA. The LNCaP, DU145, PC3, and luminescent PC3 (30) prostate cancercell lines were derived from stocks routinely maintained inthe laboratory. Monolayer cell cultures were grown in Ham'sF-12 medium supplemented with 10% fetal calf serum (FCS) (Invitrogen,Cergy-Pontoise, France). In all experiments, cells were treatedfor 48 h with the vehicle dimethyl sulfoxide (dilution, 1:2,000),5 x 10^–6 M pioglitazone, 5 x 10^–6 M rosiglitazone,valproic acid (1.5 mM for PC3 cells, 0.75 mM for DU145 cells,and 0.375 mM for LNCaP cells), or both pioglitazone and valproicacid. Transient transfections were performed as described previously(2), and luciferase activity measurements were normalized forß-galactosidase activity to correct for differencesin transfection efficiency. Graph values represent the meansof three independent experiments. For small interfering RNA(siRNA) experiments, smart-pool siRNAs against HDAC3 (Dharmacon,Lafayette, CO) were transfected in PC3 cells by using DharmaFECT2 (Dharmacon) according to the manufacturer's instructions.After 24 h, cells were treated as described above and incubatedfor 24 h. Effects of the siRNA on HDAC3 mRNA and protein levelsare illustrated below (see Fig. 7B and C, respectively).

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FIG. 7. Effects of HDAC3 overexpression on the E-cadherin promoter and HDAC3 knockdown on E-cadherin mRNA in response to pioglitazone. (A) Activity generated by the E-cadherin luciferase reporter cotransfected with the PPAR ${gamma}$ expression vector and increasing amounts of the HDAC3 expression vector. Experiments were performed without stimulation (vehicle) or in the presence of pioglitazone, valproic acid, or both. (B and C) Q-PCR (B) and Western blot (C) analysis showing knockdown expression of HDAC3 expression in PC3 cells transfected with a control or HDAC3 siRNA. In panel C, levels of induction (n-fold) are indicated. (D) Quantitative real-time PCR showing E-cadherin gene expression in control versus HDAC3 knockdown in PC3 cells treated as indicated. RLU, relative luciferase units; +, presence of agonist or inhibitor; –, absence of agonist or inhibitor (white bar).

Apoptosis and BrdU assays, flow cytometry analysis, and phospho-pRb detection. Proliferating LNCaP, DU145, and PC3 cells were incubated for48 h with the different treatments as described above. For allimmunofluorescence experiments, cells were grown on coverslips.Apoptotic cells were detected using Alexa 568-conjugated annexinV labeling according to the manufacturer's instructions (Roche,Basel, Switzerland). For BrdU incorporation, cells were incubatedfor 4 h (PC3 and DU145 cells) or for 16 h (LNCaP cells) in thepresence of 100 µM BrdU, harvested, and fixed with methanol.An additional treatment of the cells with 1.5 N HCl for 10 minwas performed. Cells were then incubated with the anti-BrdUantibody (dilution, 1:100) for 16 h at 4°C, and BrdU stainingwas revealed using a Texas Red-conjugated anti-mouse immunoglobulinG (IgG). For phospho-pRb (^ppRb) immunofluorescence detection,PC3 cells were harvested after 48 h of treatment, fixed in methanolfor 10 min at 4°C, and incubated for 16 h at 4°C withthe anti-phospho-pRb antibody (dilution, 1:50), and phospho-pRbstaining was revealed using a Texas Red-conjugated anti-rabbitIgG. At least 500 cells were counted. For fluorescence-activatedcell sorter analysis, cells were harvested, fixed with 70% ethylalcohol, and DNA was labeled with propidium iodide. Cells weresorted by fluorescence-activated cell sorter analysis (CoulterElectronics, Hialeah, FL), and cell cycle profiles were determinedusing ModFit software (Becton Dickinson, San Diego, CA).

RNA extraction, RT-PCR, and Q-PCR. RNA extraction and reverse transcription-PCR (RT-PCR) were performedas described previously (3). Quantitative PCR (Q-PCR) was carriedout using a LightCycler and DNA double-strand-specific SYBRgreen I dye for detection (Roche). Q-PCR was performed usinggene-specific oligonucleotides, and results were then normalizedto RS9 levels.

Protein extracts and Western blot analysis. Preparation of protein extracts and sodium dodecyl sulfate-polyacrylamidegel electrophoresis, electrotransfer, and immunoblotting wereperformed as described previously (31).

Kinase assays. CDK4 immunoprecipitation and kinase assays were performed exactlyas previously described (1).

In vivo murine models of prostate cancer. Male Rj:NMRI-nu (nu/nu) (Janvier, Le Genest-St-Isle, France)and CD17-SCID/bg (Harlan, Gannat, France) mice were maintainedaccording to European Union guidelines for use of laboratoryanimals. In vivo experiments were performed in compliance withthe French guidelines for experimental animal studies (agreementno. B-34-172-27). For in vivo proliferation studies, 3 x 10⁶luminescent PC3 cells were laterally injected subcutaneouslyin nude mice at 6 weeks of age. Five days after subcutaneousinjection, cohorts (10 mice/group) were orally administratedvehicle (0.5% carboxymethyl cellulose [CMC]), pioglitazone (30mg/kg of body weight/day in 0.5% CMC), valproic acid (150 mg/kg/dayin 0.5% CMC), or both compounds for a period of 4 weeks. Tumorprogression was determined by measuring the volume of the tumorwith a caliper. Tumor tissues were collected, weighed, fixedin 4% phosphate-buffered formalin, and embedded in paraffinfor immunohistological analyses. For in vivo bone invasion studies,subconfluent monolayers of luminescent PC3 cells were detachedby trypsinization, washed, and resuspended in phosphate-bufferedsaline to the working concentration of 5 x 10⁵ cells/10 µl.All tibia injections were performed on SCID mice (10 mice/group)anesthetized with pentobarbital (50 mg/kg). The proximal endof the left tibial bones was exposed surgically in a flex position,and 10 µl of phosphate-buffered saline containing tumorcells was injected into the bone marrow space with a 26-gaugeneedle. Mice were treated 7 days after intratibial injectionwith vehicle (0.5% CMC), pioglitazone (30 mg/kg/day in 0.5%CMC), valproic acid (300 mg/kg/day in 0.5% CMC), or both compoundsfor a period of 4 weeks and monitored weekly for tumor growthkinetic by use of bioluminescence imaging with a NightOWL LB981charge-coupled-device camera (Berthold Technologies, Bad Wildbad,Germany) and WinLight software (Berthold Technologies). Leftand right legs were harvested and fixed in 4% phosphate-bufferedformalin, X rays of the legs were taken, and invasion potentialwas scored by four blind comparisons of X-ray radiographs. Scoresranged from 0 (no invasion) to 4 (high degree of invasion).For both xenograft mouse models, tumor formation was verifiedby use of bioluminescence imaging 1 day before starting treatment.No failure rate for tumor initiation was observed, and tumorgrowth occurred at the same rate.

IHC and histology. IHC was performed as described previously (2). Briefly, afterantigen retrieval, 5 µm formalin-fixed luminescent PC3tumor sections was incubated with the anti-PCNA (dilution, 1:500),anti-p21 (dilution, 1:20), and anti-E-cadherin (dilution, 1:25)antibodies, and a LandMark prostate tissue microarray (Ambion,Austin, TX) containing 5 µm formalin-fixed, paraffin-embeddedhuman normal and tumor prostate sections was incubated withthe anti-PPAR ${gamma}$ (dilution, 1:25) or the anti-acetyl H4 (dilution,1:25) antibody. Immunostaining was revealed using peroxidase-conjugatedanti-mouse (for PCNA, p21, and E-cadherin; Jackson Immunoresearch,Cambridgeshire, United Kingdom), anti-goat (for PPAR ${gamma}$ ; JacksonImmunoresearch), or anti-rabbit (for acetylated H4 [AcH4]; JacksonImmunoresearch) secondary antibody and diaminobenzidine chromogen(DAKO) as a substrate. Sections were counterstained with hematoxylin.For E-cadherin, immunofluorescence staining was revealed usinga Texas Red-conjugated anti-mouse secondary antibody. Negative-controlexperiments using mouse, rabbit, or goat IgG were performed,and no staining was observed under these conditions. Trainedpathologists analyzed the PPAR ${gamma}$ , acetyl H4, and E-cadherin staining.Immunohistochemical quantification was based on two parameters,the intensity of the staining and the percentage of cells positivelystained, leading to 4 groups: 0, no staining; 1, weak positivestaining; 2, moderate staining; and 3, strong staining.

Invasion assay. A Boyden chamber migration assay was performed as describedpreviously (12). Briefly, polycarbonate filters (12 µmpore size) were coated with 60 µg of Matrigel (BectonDickinson). Cells were harvested in medium containing 3% FCSand ligands (vehicle, 5 µM pioglitazone, 1.5 mM valproicacid, or both compounds) and added to the top chamber (1 x 10⁶cells per chamber). Medium supplemented with 10% FCS and ligandswas used in the bottom compartment as a chemoattractant. Tocorrect for proliferation and/or cell death due to our treatments,cells were cultured in parallel in 12-well plates in mediumcontaining 3% FCS and ligands (control plate corresponding tototal cells). Chambers and plates were incubated for 48 h at37°C, and cells that had traversed the Matrigel and spreadon the bottom surface of the filter as well as cells from controlplates were then quantified using 3(4,5-dimethyl-thiazol- 2-yl)2,5-diphenoltetrazolium bromide and determination of optical density at540 nm. Experiments were performed in triplicate, and resultsare expressed as percentages of invading cells relative to percentagesof total control cells.

EMSA. Electromobility shift assays (EMSA) were performed as describedpreviously (2, 10). Briefly, in vitro-translated PPAR ${gamma}$ and retinoidX receptor ${alpha}$ (RXR ${alpha}$ ) were incubated for 15 min at 21°C in atotal volume of 20 µl binding buffer [10 mM Tris-HCl (pH7.9), 40 mM KCl, 10% glycerol, 0.05% Nonidet P-40, 1 mM dithiothreitol,and 1 µg poly(dI:dC)] in the presence of 2 ng of a T4polynucleotide kinase end-labeled, double-stranded oligonucleotideprobe. For gel supershift assays, 2 µg of IgG or PPAR ${gamma}$ antibody was added to the reaction mixture. DNA-protein complexeswere separated by electrophoresis on a 4% polyacrylamide gelin 0.25% Tris-borate-EDTA at 4°C and 10 V/cm.

Cloning of the E-cadherin and aP2 promoters. The E-cadherin and aP2 promoters were cloned using BD AdvantageGC genomic polymerase mix (BD Biosciences Clontech, Palo Alto,CA) and genomic DNA as a template. PCR amplifications were performedaccording to the manufacturer's instructions and cloned in thepGL3-basic vector (Promega Life Science, Madison, WI). An E-cadherinpromoter deletion mutant devoid of the PPAR ${gamma}$ response element(PPRE) was obtained by PCR using specific primers and clonedas described above. The different pGL3 promoter constructs weresequenced and used in transient transfections.

Coimmunoprecipitation. Immunoprecipitation assays were performed as previously described(8).

ChIP and Re-ChIP. ChIP assays were performed as described previously (3). Chromatinreimmunoprecipitation (Re-ChIP) assays were performed as describedpreviously (23). Briefly, proteins from PC3 cells treated for48 h with different ligands were formaldehyde cross-linked toDNA. After lysis and DNA sonication, proteins were immunoprecipitatedusing an anti-PPAR ${gamma}$ antibody. After being washed, DNA-proteincomplexes were eluted in 10 mM dithiothreitol for 30 min at37°C and reimmunoprecipitated using IgG (negative control)or anti-HDAC3 antibody. Cross-linking was then reversed by heatingthe samples at 65°C for 16 h. DNA was then purified usinga QIAGEN PCR purification kit (QIAGEN, Courtab $oe$ uf, France), andPCR amplification was performed using promoter-specific oligonucleotideprimers.

Statistical analysis. Data are presented as means ± standard errors of themeans, except for tumor measurements (volume and mass), whichare presented as medians. Group means and medians were comparedby factorial analysis of variance. Upon determination of significantinteractions, differences between individual group means andmedians were analyzed by Fisher's protected least-squares differencetest. Differences were considered statistically significantat P of <0.05.

RESULTS

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Results

Synergistic action of PPAR ${gamma}$ agonists and HDAC inhibitors in the control of cell proliferation and apoptosis in prostate cancer cells. We have demonstrated previously that HDAC inhibitors have asynergistic action with PPAR ${gamma}$ agonists in the activation of PPAR ${gamma}$ target genes and adipocyte differentiation (8). Since both PPAR ${gamma}$ agonists and HDAC inhibitors independently arrest proliferationof prostate cancer cells, we wanted to test the synergy of bothagents in the control of prostate cancer cell growth. BrdU incorporationstudies with the androgen-dependent LNCaP (AR mutant, Rb wildtype [wt], p53 wt) cell line indicated that percentages of BrdU-positivecells were significantly decreased upon 48 h of pioglitazoneand rosiglitazone treatments compared to percentages of controlcells (with LNCap, 33.8% ± 0.1% for vehicle-treated cells,26.8% ± 1.4% for pioglitazone-treated cells, and 27.5%± 2.5% for rosiglitazone-treated cells) (Fig. 1A). Moreover,a significant decrease in BrdU incorporation was observed whencells were incubated in the presence of the HDAC inhibitor valproicacid (33.8% ± 0.1% for vehicle-treated cells versus 4.8%± 0.8% for valproic acid-treated cells) (Fig. 1A). Mostinterestingly, the combination treatment of pioglitazone plusvalproic acid or rosiglitazone plus valproic acid decreasedthe proliferation index to 1.5% ± 0.1% or 1.6% ±0.01%, respectively. To further prove that the effect of thecombination treatment was independent of the cell line, twoandrogen-independent prostate cancer cell lines, i.e., DU145(AR^–, Rb^–, p53 mutant) and PC3 (AR^–, Rb wt,p53^–) cells, were subjected to BrdU incorporation (Fig.1B and C). With DU145 cells, PPAR ${gamma}$ agonists and valproic acidalone demonstrated no inhibitory effect on proliferation (Fig.1B), whereas with PC3 cells, a single valproic acid treatmentresulted in a decreased proliferation index (12.6% ±2.1% for vehicle-treated cells versus 6.9% ± 1.6% forvalproic acid-treated cells) (Fig. 1C). Importantly, as observedfor LNCaP cells, moderate and strong inhibitory effects on proliferationwere obtained when using the combination of PPAR ${gamma}$ agonists andvalproic acid with DU145 cells (33.9% ± 4.5% for vehicle-treatedcells versus 24.3% ± 1.8% for pioglitazone plus valproicacid-treated cells and 23.1% ± 2.1% for rosiglitazoneplus valproic acid-treated cells) and PC3 cells (12.6% ±2.1% for vehicle-treated cells versus 2.1% ± 0.8% forpioglitazone plus valproic acid-treated cells and 1.6% ±0.7% for rosiglitazone plus valproic acid-treated cells), respectively.Flow cytometry analysis further demonstrated the antiproliferativeeffect of our treatments on PC3 cells, showing a decrease inthe number of cells in the S phase concomitant to an increasein the proportion of cells in the G₁ phase of the cell cyclecompared to vehicle-treated cells (Fig. 1D). Similarly to BrdUincorporation studies, the combination therapy resulted in thehighest accumulation of cells in the G₁ phase of the cell cycle(Fig. 1D). These results suggest an inhibitory effect of thecombined treatment of PPAR ${gamma}$ agonists and valproic acid on cellularproliferation of several prostate cancer cell lines. Moreover,the effects of the treatment are independent of the AR statusof the cells, since LNCaP and PC3 cells responded similarlyto the combination therapy. Interestingly, the inhibition ofproliferation following treatments was more important for LNCaPand PC3 cells than for DU145 cells. Since LNCaP and PC3 cellsexpress wild-type Rb protein and DU145 cells express mutantRb protein, this suggests that our treatment efficacy coulddepend on Rb status and might involve Rb-dependent pathways.

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FIG. 1. Proliferation of prostate cancer cells in response to PPAR ${gamma}$ agonists and HDAC inhibitor. (A to C) Quantification of BrdU incorporating LNCaP (A), DU145 (B), and PC3 (C) cells treated with vehicle (white bars), pioglitazone, rosiglitazone, valproic acid, or a combination of both PPAR ${gamma}$ agonists and HDAC inhibitor. At least 500 cells were counted under a microscope. Asterisks indicate statistically significant results (analysis of variance; ns, not significant; *, 0.01 $≤$ P < 0.05; **, 0.001 $≤$ P < 0.01; ***, P < 0.001). (D) Flow cytometry analysis of PC3 cells in response to pioglitazone, valproic acid, or both. Fractions of cells in the G₀/G₁, S, or G₂/M phases of the cell cycle are indicated. (E) Quantification of apoptosis of PC3 cells in response to pioglitazone, valproic acid, or both. +, presence of agonist or inhibitor (black bars); –, absence of agonist or inhibitor (white bars).

Next, we determined the effect of our treatments on apoptosisof PC3 prostate cancer cells. No effect was observed upon pioglitazonetreatment, whereas a significant proportion of PC3 cells underwentapoptosis when treated with valproic acid or pioglitazone combinedwith valproic acid (Fig. 1E). Altogether, these results demonstratethat the combination treatment decreases cellular proliferationand increases apoptosis.

Regulation of expression of cell cycle regulators and pRb phosphorylation by PPAR ${gamma}$ agonists and HDAC inhibitors in prostate cancer cells. Since pioglitazone and valproic acid treatments impact cellularproliferation of PC3 cells, we next wanted to analyze the expressionof cell cycle regulators. Consistent with the observed cellcycle arrest, mRNA and protein expression of the cell cycleinhibitors p19, p21, and p27 were increased in response to pioglitazone,valproic acid, and (to a higher extent) the combination treatment(Fig. 2A and B). Moreover, cyclin D1 mRNA and protein levelswere decreased upon treatment with pioglitazone alone or incombination with valproic acid (Fig. 2A and B). Previous reportsdemonstrated that PPAR ${gamma}$ agonists regulate p21 expression in pancreaticand lung cancer cells through interaction with sp1 proteinsand binding to sp1 sites on the p21 promoter (13, 16). In addition,it has been demonstrated recently that rosiglitazone posttranscriptionallyinduces p21 in PC3 cells (28). To clarify whether the increasedp21 mRNA and protein expression was mediated by PPAR ${gamma}$ transcriptionalactivity or by indirect mechanisms, chromatin immunoprecipitationassays were performed. Using primers amplifying the sp1 sitesin the human p21 promoter, previously shown to mediate the effectsof PPAR ${gamma}$ through sp1 binding (16), we observed that PPAR ${gamma}$ wasbound to this promoter region in PC3 cells, suggesting a transcriptionalregulation of the p21 promoter by PPAR ${gamma}$ (Fig. 2C; see Fig. S1Ain the supplemental material). Moreover, we observed an increasedacetylation status of histone H4 from vehicle-, pioglitazone-,valproic acid-, and pioglitazone plus valproic acid-treatedcells, suggesting an increased transcriptional activity of thispromoter (Fig. 2C; see Fig. S1A in the supplemental material).Since several cell cycle inhibitors are induced upon treatment,we next wanted to study the effect of our treatments on pRbphosphorylation in PC3 cells. pRb phosphorylation levels weredramatically decreased, as assessed by immunofluorescence assays(Fig. 2D). Moreover, using an anti-pRb antibody detecting unphosphorylatedand phosphorylated pRb proteins and an anti-^ppRb antibody detectingonly the Ser 807/811 phosphorylated form of pRb, we observedby immunoblotting a decrease in ^ppRb in cells treated with pioglitazone,valproic acid, or both and an accumulation of unphosphorylatedpRb from nontreated to pioglitazone plus valproic acid-treatedcells, which was consistent with arrested proliferation (Fig.2E). To further assess the participation of the CDK4/cyclinD complex in pRb phosphorylation upon treatments, kinase activityexperiments were performed. Immunoprecipitated CDK4 from PC3cells treated with vehicle was active in nontreated cells, whereasit was inactive in cells treated with pioglitazone, valproicacid, or both (Fig. 2F). Altogether, these results demonstratethat the observed decreased cellular proliferation of PC3 cellsupon treatments could be the result of an increased expressionof cell cycle inhibitors, leading to reduced pRb phosphorylationlevels.

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FIG. 2. Analysis of cell cycle regulators in response to PPAR ${gamma}$ agonist and HDAC inhibitor. (A) Quantification by Q-PCR of mRNA expression of the indicated genes in PC3 cells in response to pioglitazone, valproic acid, or both. Results were normalized for expression of RS9 mRNA. CcnD1, cyclin D1. (B) Immunoblotting of the indicated proteins in PC3 cells treated as indicated in panel A. The corresponding induction (n-fold) compared to that for nontreated cells is indicated below the image. (C) Results from ChIP assays, showing binding of PPAR ${gamma}$ and HDAC3 to the human p21 promoter in a region containing sp1 sites and the presence of acetylated histone H4 in this region. PC3 cells were treated as indicated in panel A. (D) Quantification of pRb phosphorylation levels in PC3 cells following treatment as indicated (white bar, no treatment). At least 500 cells were counted under a fluorescence microscope for detection of phospho-pRb after use of an anti-phospho-Rb antibody. (E) Western blot analysis of PC3 whole-cell extracts treated as indicated in panel A. The proteins detected with specific antibodies are indicated. (F) CDK4 activity in PC3 cells. Results from sodium dodecyl sulfate-polyacrylamide gel electrophoresis autoradiography show phosphorylated, purified pRb by immunoprecipitated (IP) CDK4 from vehicle-, pioglitazone-, valproic acid-, and pioglitazone plus valproic acid-treated PC3 cells. See the legend for Fig. 1 for definitions of symbols.

Inhibition of tumor progression in a mouse model of prostate cancer in response to pioglitazone and valproic acid combination therapy. To evaluate the in vivo effect of a combined therapy of pioglitazoneand valproic acid on prostate cancer development, we used animmunodeficient mouse model in which luminescent PC3 cells weregrafted subcutaneously, allowing us to follow tumor initiationand progression by using bioluminescent imaging. We observedno failure in tumor initiation, with 100% of grafted cells givingrise to a tumor. No significant differences in tumor volumeand mass were observed for mice treated with either pioglitazoneor valproic acid, whereas a 40% decrease in tumor volume andmass was observed for mice treated with the combination of pioglitazoneand valproic acid compared to mice treated with vehicle (Fig.3A and B). Consistent with the inhibition of tumor growth, adecrease in cell proliferation in tumors of mice treated withthe combination therapy compared to that in tumors of mice treatedwith vehicle was observed, as measured by PCNA staining on histologicalsections of the tumors (Fig. 3C and D). Consistent with thesizes of tumors (Fig. 3A and B), no effect on tumor cell proliferationwas observed when each single agent (pioglitazone or valproicacid) was used in the treatment. Further characterization indicatedthat the expression of p21 was increased in tumors of mice treatedwith the combination therapy compared to expression in tumorsof mice treated with vehicle or single-agent therapy (Fig. 3E and F),consistent with the observed decrease in cell proliferation.Interestingly, when analyzing other markers of tumor aggressivenessin mice treated with the combination therapy we found increasedexpression of E-cadherin, which is important in the controlof invasion and migration of cancer cells (Fig. 3G).

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FIG. 3. In vivo analysis of tumor development in nude mice in response to pioglitazone and valproic acid after PC3 cell graft. (A and B) Volumes (A) and weights (B) of luminescent PC3 tumors in nude mice treated for 4 weeks with vehicle, pioglitazone (Pio), valproic acid (Val), or both (Pio+Val), as described in Materials and Methods. The number of mice used and the median value for each group are indicated. (C) Micrography representative of PCNA staining (red arrow) by IHC of tumor sections in mice treated with vehicle, pioglitazone, valproic acid, or both. (D) Quantification of PCNA staining represented in panel C. Four fields per section were analyzed for PCNA staining indicative of cell proliferation. Sections of tumors of all mice were analyzed. At least 500 cells were counted per tumor. (E) Micrography representative of p21 staining (red arrow) by IHC of tumor sections in mice treated with vehicle, pioglitazone, valproic acid, or both. (F) Quantification of p21 staining represented in panel E was obtained as described for panel D. (G) Micrography representative of E-cadherin staining by immunofluorescence (white arrow) of sections of tumors in mice treated with vehicle, pioglitazone, valproic acid, or both. See legend for Fig. 1 for definitions of other symbols.

Decreased in vitro and in vivo invasion potential of prostate cancer cells treated with pioglitazone and valproic acid. Increased expression of E-cadherin suggested that the combinationtreatment could have an impact on the invasion and migrationpotential of prostate cancer cells. We therefore evaluated theeffect of the combination of pioglitazone and valproic acidon the invasiveness of LNCaP and PC3 cells by using a Matrigelassay. Treatments of LNCaP cells with pioglitazone, valproicacid, or both had no effect on the invasive potential of thesecells (Fig. 4A), probably due to the low metastatic potentialof this cell line (17, 27) and a weak percentage of cells invadingthe Matrigel membrane under basal conditions (Fig. 4A). In PC3cells, which have a high metastatic potential (20, 27), pioglitazonetreatment showed no significant effect on invasiveness of thecells compared to that of the control vehicle-treated cells(41.9% ± 2.0% for control-treated cells versus 32.2%± 8.6% for pioglitazone-treated cells), whereas decreasedinvasion was observed when PC3 cells were treated with valproicacid (24.0% ± 2.3%). Strikingly, a synergistic effecton the inhibition of invasion was observed when a combinationof pioglitazone and valproic acid was used (11.4% ± 3.1%).These results suggested that the invasion potential of highlymetastatic prostate cancer cells was inhibited in the presenceof the combination treatment.

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FIG. 4. Analysis of invasive potential of prostate cancer cells both in vitro and in vivo in response to valproic acid and pioglitazone treatments. (A) Invasive capacity of LNCaP and PC3 cells in Matrigel-coated membrane in response to pioglitazone, valproic acid, or both, as indicated. Percent invasion represents the proportion of plated cells that migrated through the membrane. White bars, no treatment. (B) Representative X-ray analysis and scores of the PC3-engrafted tibiae of SCID mice after 21 days of treatment with vehicle, pioglitazone, valproic acid, or a combination of pioglitazone and valproic acid. Xenografted tibiae were scored from 0 to 4 depending on the invasion degree: 0, no invasion; 1, weak and localized sign of invasion (asterisk); 2, regular features of invasion (arrowhead); 3, strong marks of bone destruction (bracket); 4, complete bone destruction (inside the white dotted line). Locations of femur and tibia bone structures are indicated. (C) Qualitative in vivo invasion analysis of X ray. X-ray radiographs were blindly scored for bone invasion potential, and results are presented as relative percentages of scores of >3. (D) Hematoxylin and eosin staining of intratibial tumors, demonstrating invasion of tumor cells from mice treated with vehicle in the join (large arrowhead) and in the skeletal muscle (small arrowheads), whereas PC3 tumors from pioglitazone plus valproic acid (Pio+Val)-treated mice remained in the bone cavity (asterisks). See legend for Fig. 1 for definitions of other symbols.

These data prompted us to study the effect of pioglitazone andvalproic acid on the inhibition of invasion in vivo. Prostatecancer cells preferentially invade bone. We therefore used abone invasion model by intratibially injecting luminescent PC3cells in immunodeficient mice. Mice were treated thereafterfor 30 days with the combination therapy pioglitazone and valproicacid. In vivo imaging techniques using a charge-coupled-devicecamera facilitated the follow-up of tumor initiation and growthin these animals by quantification of the luciferase signalafter intraperitoneal luciferin injection. As described forsubcutaneous xenograft, no failure in tumor initiation was observed.To characterize the in vivo bone invasion potential of our xenograftedPC3 cells, X-ray analysis of the legs was performed and bonedestruction was scored from 0 (no destruction and thus no invasion)to 4 (high degree of bone destruction, demonstrating a highinvasion potential) (Fig. 4B). X-ray analysis of treated miceshowed preservation of bone structure and density, whereas massivebone destruction was observed for nontreated mice (Fig. 4C).Moreover, histological analysis of the tibiae demonstrated thattumor cells engrafted in mice treated with vehicle destroyedthe tibial bone and spread both in the join and in the skeletalmuscle, whereas PC3 cells from pioglitazone plus valproic acid-treatedmice remained inside the central bone cavity (Fig. 4D), reinforcingthe scoring data presented in Fig. 4C. These results demonstratethat the combination of pioglitazone and valproic acid is effectivein the inhibition of invasion of prostate cancer cells in bone.

Increased expression of E-cadherin mRNA in prostate cancer cells in response to pioglitazone and valproic acid treatment. Inhibition of invasion of prostate cancer cells was likely theresult, at least in part, of increased expression of E-cadherin.Since PPAR ${gamma}$ and HDAC are key regulators of gene transcription,we tested the hypothesis that E-cadherin expression could beregulated at the transcriptional level by pioglitazone and valproicacid. With LNCaP cells, we failed to induce E-cadherin mRNAexpression upon addition of pioglitazone, valproic acid, orboth, suggesting that in this cell line PPAR ${gamma}$ might have no transcriptionaleffect on genes involved in migration processes (Fig. 5A, LNCaP).This idea is reinforced by the invasion results showing thatmigration of LNCaP cells is not modified upon treatment withPPAR ${gamma}$ agonists or HDAC inhibitor (Fig. 4A). In the androgen-independentand highly metastatic PC3 cell line, no significant inductionof E-cadherin mRNA levels was observed after pioglitazone treatmentof PC3 cells. In contrast, valproic acid significantly inducedE-cadherin mRNA up to 10-fold compared to results with vehicle-treatedcells (Fig. 5A and B). Interestingly, the combination of pioglitazoneand valproic acid further increased E-cadherin mRNA expression(70-fold induction) (Q-PCR [Fig. 5A] and semiquantitative RT-PCR[Fig. 5B]). Consistent with the mRNA data, the association ofpioglitazone and valproic acid resulted in an increase in E-cadherinprotein levels compared to results with vehicle-treated PC3cells (Fig. 5C).

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FIG. 5. E-cadherin expression, in vitro binding by PPAR ${gamma}$ /RXR ${alpha}$ , and transactivation assays in response to pioglitazone and/or valproic acid treatments. (A) Quantification of mRNA expression by Q-PCR of the E-cadherin gene in LNCaP and PC3 cells in response to pioglitazone, valproic acid, or both. Results were normalized for expression of RS9 mRNA. (B) Semiquantitative RT-PCR imaging showing expression of the E-cadherin mRNA in PC3 cells in response to pioglitazone, valproic acid, or both. (C) Western blot analysis of PC3 whole-cell extracts treated as indicated in panel A. The proteins detected with specific antibodies and the levels of induction (n-fold) are indicated. (D) Computational analysis of the regulatory region of the human E-cadherin gene demonstrating the presence of a potential PPRE. Comparison of this PPRE with the PPREs of classical PPAR ${gamma}$ target genes is illustrated. (E) In vitro binding of the PPAR ${gamma}$ /RXR ${alpha}$ heterodimer to the E-cadherin promoter. EMSA analysis of the radiolabeled PPRE of the E-cadherin promoter incubated with unprogrammed reticulocyte lysate (lane 1), in vitro-translated RXR ${alpha}$ (lane 2), PPAR ${gamma}$ (lane 3), or both (lane 4 to 11). Double-stranded cold oligonucleotides, representing the E-cadherin PPRE (PPRE_E-cad), the consensus PPRE (PPRE_cons), or the mutated E-cadherin PPRE (PPRE_mut), were included in the competition assays (lanes 5 to 8). Incubation of an anti-PPAR ${gamma}$ antibody resulted in a supershifted band (lane 10, black arrowhead), whereas no modification in PPAR ${gamma}$ /RXR ${alpha}$ binding was observed with IgG (lane 9). No binding was observed when a radiolabeled mutated E-cadherin PPRE (PPRE_mut) was used as a probe (lane 11). ns, nonspecific binding; fp, free probe. (F) Pioglitazone and valproic acid treatments modulate E-cadherin promoter activity. Shown are relative luciferase activities as determined after cotransfection of COS cells with the PPAR ${gamma}$ expression vector and the empty construct, the E-cadherin promoter construct, or the E-cadherin promoter deletion mutant reporter construct. Cells were treated as indicated. Luc, luciferase; HMG-CoA synthetase, 3-hydroxy-3-methylglutaryl coenzyme A synthetase; LPL, lipoprotein lipase; RLU, relative luciferase units; Ecad-Luc, E-cadherin luciferase reporter. See legend for Fig. 1 for definitions of symbols.

Computational analysis of the E-cadherin promoter identifieda PPRE, located at nucleotides –2476 to –2464 fromthe transcription initiation start site, that was highly conservedcompared to the PPRE found in PPAR ${gamma}$ target genes, such as the3-hydroxy-3-methylglutaryl coenzyme A synthetase, the aP2, andthe lipoprotein lipase promoters (Fig. 5D). EMSA analysis usingthe PPRE found in the E-cadherin gene as a probe indicated thatthe in vitro-translated PPAR ${gamma}$ /RXR ${alpha}$ heterodimer specifically boundto this element, as demonstrated by the use of a competitorprobe containing a consensus PPRE and the use of a PPAR ${gamma}$ antibody,which supershifted the retarded PPAR ${gamma}$ -containing band (Fig. 5E).No binding was observed when the reticulocyte lysate or thein vitro-translated PPAR ${gamma}$ or RXR ${alpha}$ was used alone (Fig. 5E, lanes1, 2, and 3). These results suggested that the PPAR ${gamma}$ /RXRa heterodimercould regulate the expression of E-cadherin through direct bindingto its promoter.

To determine whether PPAR ${gamma}$ /RXR ${alpha}$ could activate the human E-cadherinpromoter in vitro, COS cells were cotransfected with a PPAR ${gamma}$ expression vector and with the full-length E-cadherin promotercontaining the PPRE driving the expression of the luciferasegene or a deletion mutant devoid of this PPRE. No effect ofpioglitazone on E-cadherin promoter activity was observed inthe presence of PPAR ${gamma}$ expression vectors, whereas valproic acidinduced up to threefold E-cadherin promoter activity. Consistentwith increased E-cadherin mRNA expression (Fig. 5A and B), thecombination of pioglitazone and valproic acid had synergisticeffects and induced up to fivefold the activity of the full-lengthE-cadherin promoter in COS cells (Fig. 5F). This synergisticeffect was abrogated when the PPRE of the E-cadherin promoterwas deleted (Fig. 5F), suggesting that PPAR ${gamma}$ was mediating thesynergistic effects. The same results were obtained when PC3cells were transiently transfected (data not shown). Interestingly,the E-cadherin gene contains a functional PPRE that is responsiveto PPAR ${gamma}$ but only in the presence of HDAC inhibitors.

Regulation of E-cadherin expression defines a new class of PPAR ${gamma}$ target genes responding only to the combination treatment. To further elucidate the molecular mechanisms underlying theeffect of PPAR ${gamma}$ on the expression of E-cadherin discussed above,we first tested the presence of the HDAC3 repressor proteinin the PPAR ${gamma}$ complex in PC3 cells by coimmunoprecipitation studies.We first verified that our treatments had no impact on PPAR ${gamma}$ and HDAC3 protein levels, as demonstrated by immunoblotting(Fig. 6A). When protein extracts from PC3 cells were immunoprecipitatedusing an anti-HDAC3 antibody, endogenous PPAR ${gamma}$ protein was associatedwith HDAC3 in the control-, pioglitazone-, and valproic acid-treatedcells and was minimally detected in cells cotreated with pioglitazoneand valproic acid (Fig. 6B). To further prove that HDAC3 isassociated with PPAR ${gamma}$ and represses its transcriptional activity,chromatin immunoprecipitation studies of the E-cadherin promoterwere performed. A 414-bp fragment of the human E-cadherin promotercontaining the binding site of PPAR ${gamma}$ was amplified by PCR whenanti-PPAR ${gamma}$ was used to immunoprecipitate chromatin from vehicle-,pioglitazone-, valproic acid-, and pioglitazone plus valproicacid-treated cells (Fig. 6C, PPRE, and Fig. S1B in the supplementalmaterial). Interestingly, a PCR amplification product was observedwhen anti-HDAC3 was used to immunoprecipitate chromatin fromvehicle-, pioglitazone-, or valproic acid-treated cells, whereasno amplification was observed when immunoprecipitated chromatinfrom cells treated with the combination of pioglitazone andvalproic acid was used as a template or when nonspecific IgGswere used to immunoprecipitate the chromatin (Fig. 6C, PPRE,and Fig. S1B in the supplemental material). Moreover, when ananti-acetylated histone H4 antibody was used, the E-cadherinpromoter could be amplified in valproic acid-treated and pioglitazoneplus valproic acid-treated cells, indicating that, under theseconditions, the E-cadherin promoter was activated (Fig. 6C,PPRE, and Fig. S1B in the supplemental material). Binding ofPPAR ${gamma}$ and HDAC3 was specific to the PPAR ${gamma}$ binding site of theE-cadherin promoter, since no amplification of a promoter regionlocated outside the PPRE was observed (Fig. 6C, non PPRE). However,when chromatin was immunoprecipitated using an anti-acetylatedhistone H4, we observed amplification of the region devoid ofthe PPRE after treatments of the cells with valproic acid andpioglitazone plus valproic acid and, to a much lesser extent,after treatment with pioglitazone, suggesting that this regionis also transcriptionally active (Fig. 6C, non PPRE). To furtherprove the direct association of HDAC3 with PPAR ${gamma}$ on the E-cadherinpromoter, we performed Re-ChIP experiments. After a first chromatinimmunoprecipitation using an anti-PPAR ${gamma}$ antibody, we performeda second immunoprecipitation using an anti-HDAC3 antibody ornonspecific IgGs. As observed for ChIP experiments, the samefragment of the human E-cadherin promoter was amplified by PCRwhen anti-HDAC3 was used to immunoprecipitate chromatin fromvehicle-, pioglitazone-, or valproic acid-treated cells (Fig.6D and Fig. S1C in the supplemental material), demonstratingthat HDAC3 forms a complex with PPAR ${gamma}$ in PC3 cells on the E-cadherinpromoter even in the presence of valproic acid. No associationof PPAR ${gamma}$ and HDAC3 with the E-cadherin promoter was observedwhen chromatin from cells treated with a combination of pioglitazoneand valproic acid was used (Fig. 6D and Fig. S1C in the supplementalmaterial).

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FIG. 6. Differential HDAC3 recruitment and in vivo binding of PPAR ${gamma}$ to the E-cadherin and aP2 promoters in response to pioglitazone and/or valproic acid treatments. (A) Western blot showing PPAR ${gamma}$ and HDAC3 expression in PC3 cells treated with pioglitazone, valproic acid, or both. Induction (n-fold) is indicated. (B) Immunoprecipitation (IP) assays showing interaction between PPAR ${gamma}$ and HDAC3. Extracts from PC3 cells treated with vehicle, pioglitazone, valproic acid, or both were immunoprecipitated with IgG or anti-HDAC3 or directly analyzed for the presence of PPAR ${gamma}$ (Input). Western blot analysis revealed the presence of PPAR ${gamma}$ in HDAC3 immunoprecipitates. (C) ChIP demonstrating binding of PPAR ${gamma}$ and HDAC3 to the E-cadherin promoter. Cross-linked chromatin from PC3 cells treated with vehicle, pioglitazone, valproic acid, or both was incubated with antibodies against PPAR ${gamma}$ , HDAC3, acetylated H4, or IgG. Immunoprecipitates were analyzed by PCR using specific primers for the PPRE present in the E-cadherin promoter (PPRE) or primers amplifying a region outside the PPRE (non PPRE). As a control, a sample representing 10% of the total chromatin was included in the PCR (Input). (D) Re-ChIP assays demonstrating interaction between HDAC3 and PPAR ${gamma}$ on the E-cadherin promoter. Chromatin prepared from PC3 cells treated with vehicle, pioglitazone, valproic acid, or both was subjected to the ChIP procedure with the antibody against PPAR ${gamma}$ and reimmunoprecipitated using IgG or anti-HDAC3 antibody. Immunoprecipitates were analyzed as described for panel C. (E) Quantification of mRNA expression by Q-PCR of the aP2 gene in PC3 cells in response to pioglitazone, valproic acid, or both. Results were normalized for expression of RS9 mRNA. (F) Activity generated by the aP2 luciferase (aP2-Luc) reporter cotransfected with the PPAR ${gamma}$ expression vector. Experiments were performed either without stimulation (vehicle) or in the presence of pioglitazone, valproic acid, or both. (G) Re-ChIP assays demonstrating interaction between HDAC3 and PPAR ${gamma}$ on the aP2 promoter. Chromatin was prepared and subjected to the Re-ChIP procedure as described for panel D. Immunoprecipitates were analyzed using primers specific for the aP2 promoter. WB, Western blot; RLU, relative luciferase units. See the legend for Fig. 1 for definitions of symbols.

Finally, we asked whether other known PPAR ${gamma}$ target genes, suchas aP2, responded to the treatments similarly to E-cadherin.In contrast to what we observed for the E-cadherin gene, aP2mRNA expression was induced more than 100-fold in PC3 cellstreated with pioglitazone compared to cells treated with vehicle(Fig. 6E). Surprisingly, only minor effects on aP2 mRNA expressionwere observed upon treatment with valproic acid (Fig. 6E). Furthermore,combination treatment of pioglitazone and valproic acid inducedaP2 mRNA expression at levels similar to those observed forpioglitazone treatment alone (Fig. 6E). These results suggestedthat PPAR ${gamma}$ differentially regulated transcription in the contextsof the E-cadherin and the aP2 genes. Transient-transfectionassays with COS and PC3 (data not shown) cells using the aP2luciferase-based promoter construct were consistent with thishypothesis. As observed for the aP2 mRNA expression, pioglitazoneinduced the aP2 promoter activity, whereas no effect on luciferaseactivity was observed upon valproic acid treatment (Fig. 6F).Moreover, no additive effect of the association of pioglitazoneand valproic acid on luciferase activity was observed for thispromoter (Fig. 6F). To elucidate the molecular mechanism underlyingthe observed effects, Re-ChIP experiments were performed withthe aP2 gene as described above. A 567-bp fragment of the humanaP2 promoter containing the PPRE was amplified by PCR when anti-HDAC3was used to reimmunoprecipitate PPAR ${gamma}$ -immunoprecipitated chromatinfrom vehicle-treated PC3 cells (Fig. 6G and Fig. S1D in thesupplemental material). In contrast to the E-cadherin gene promoter,HDAC3 was not present on the aP2 promoter of PC3 cells treatedwith pioglitazone, valproic acid, or both, suggesting that HDAC3is not associated with PPAR ${gamma}$ under these conditions on the aP2promoter (Fig. 6G and Fig. S1D in the supplemental material).Altogether, our data suggest that the E-cadherin and aP2 genesare differentially transcriptionally regulated by PPAR ${gamma}$ . Regulationof E-cadherin expression by PPAR ${gamma}$ requires inhibition of HDACregardless of the presence of PPAR ${gamma}$ ligands, whereas in the contextof the aP2 promoter, PPAR ${gamma}$ ligands are sufficient to induce expression.

HDAC3 mediates repressive effects on PPAR ${gamma}$ -mediated E-cadherin promoter activity. We observed by ChIP experiments that HDAC3 is recruited on theE-cadherin promoter upon pioglitazone or valproic acid treatment.To further prove that HDAC3 mediates repressive effects on theE-cadherin promoter, we first evaluated the effect of the transientoverexpression of HDAC3 on PPAR ${gamma}$ -mediated E-cadherin promoteractivity. COS cells were transiently cotransfected with thePPAR ${gamma}$ expression vector, the full-length E-cadherin promoterdriving the expression of the luciferase gene, and increasingamounts of the HDAC3 expression vector (Fig. 7A). The combinationof pioglitazone and valproic acid induced the E-cadherin promoteractivity in the absence of HDAC3 (Fig. 5E and 7A). Interestingly,when increasing amounts of HDAC3 were cotransfected with PPAR ${gamma}$ ,a strong decrease in the E-cadherin promoter activity was obtained,suggesting a repressive role for HDAC3 on the E-cadherin gene(Fig. 7A). To specifically evaluate the consequence of lossof HDAC3 expression, siRNA experiments were performed. Transfectionof validated HDAC3 siRNA in PC3 cells resulted in an 80% reductionin endogenous HDAC3 mRNA and protein levels, as demonstratedby Q-PCR and immunoblotting (Fig. 7B and C, respectively). siRNA-mediatedHDAC3 knockdown increased endogenous E-cadherin mRNA expressionin PC3 cells treated with pioglitazone (twofold induction) (Fig.7D), whereas no effect of pioglitazone was observed with thecontrol siRNA (Fig. 7D). These results suggest that HDAC3 repressesPPAR ${gamma}$ transcriptional activity on the E-cadherin gene in PC3cells upon pioglitazone treatment.

E-cadherin expression is decreased whereas PPAR ${gamma}$ expression and deacetylated histone H4 are increased in human prostate cancer. One important requirement in order to ensure a successful therapyusing a combination of PPAR ${gamma}$ agonists and HDAC inhibitors isthat PPAR ${gamma}$ is expressed in prostate cancer and that histonesare deacetylated. Consistent with previous studies (32), wefound by IHC studies that PPAR ${gamma}$ was mainly not expressed in normalprostate (Fig. 8A). PPAR ${gamma}$ expression was absent in 42.9% and65.5% of normal prostate and benign prostate hyperplasia tissues,respectively, and 42.9% of normal prostate tissues expressedlow levels of PPAR ${gamma}$ (Fig. 8A and Table 1). However, strong expressionwas found in prostate cancer, with 100% of prostate cancersexpressing PPAR ${gamma}$ at different levels (Fig. 8A and Table 1). Furthermore,a gradual increase in PPAR ${gamma}$ staining was observed from differentiated(Gleason score of <7, 62.5% of cancers expressed PPAR ${gamma}$ ) toundifferentiated (Gleason score of $≥$ 7, more than 80% of cancersare positive for PPAR ${gamma}$ protein) adenocarcinomas (Table 1). Incontrast to PPAR ${gamma}$ expression, acetylation status of histone H4was found to be inversely correlated with the aggressivenessof prostate cancer. In the normal prostate, histone H4 was oftenacetylated (Fig. 8B and Table 2). Eighty-one percent of normalprostate biopsy samples were positively stained (Table 2, scores1 and 2), whereas acetylated histone H4 was mostly not detectedin aggressive prostate cancer (Table 2, scores 0 and 1) (87.5%,60%, and 78.6% of prostate cancer tissues with Gleason scoresof <7, 7, and >7 have negative or weak acetylated H4,respectively), indicating high histone deacetylase activityin prostate cancer. Furthermore, we correlated the expressionof PPAR ${gamma}$ with acetylated histone H4 in each individual tumorwith different Gleason scores (Table 3). Interestingly, we foundthat tissues that were positively stained for both PPAR ${gamma}$ andacetylated H4 were tumor prostates with Gleason scores of $≤$ 7(Table 3). In these tissues, we also observed positive stainingfor PPAR ${gamma}$ and negative staining for acetylated H4 (25% of cancerswith Gleason scores of <7 and 50% with Gleason scores of7 were PPAR ${gamma}$ ⁺ and AcH4^–, respectively) (Table 3). Aggressiveprostate cancers were mostly positive for PPAR ${gamma}$ and negativefor acetylated H4 (64.3% of cancers with Gleason scores of >7were PPAR ${gamma}$ ⁺ and AcH4^–) (Table 3). Most of the normal prostatetissues were negatively and positively stained for PPAR ${gamma}$ andacetylated H4, respectively (47.6% of normal prostate were PPAR ${gamma}$ ^–and AcH4⁺) (Table 3). These data demonstrate that PPAR ${gamma}$ expressionand acetylation status of histone H4 are often inversely correlatedin aggressive prostate cancer. Importantly, these results supportthe use of HDAC inhibitors and PPAR ${gamma}$ agonists in the treatmentof prostate cancer. Finally, consistent with previous results(19, 29), we showed that E-cadherin expression is lost in mostof prostate adenocarcinoma samples (Fig. 8C), suggesting thatthe association of PPAR ${gamma}$ agonists and HDAC inhibitors might beof interest to reinduce E-cadherin expression and subsequentlyinhibit invasion.

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FIG. 8. Analysis of PPAR ${gamma}$ , histone H4 acetylation, and E-cadherin expression in human normal and neoplastic prostates. (A) Micrography representative of human PPAR ${gamma}$ staining (red arrows) by IHC of sections of normal prostate, prostatic intraepithelial neoplasia (PIN), and prostatic adenocarcinoma. Weak to no staining (black arrows) was observed in normal prostatic gland. (B) Micrography representative of acetylated histone H4 staining (red arrow) by IHC of sections of normal prostatic gland and prostatic adenocarcinoma. No immunostaining (black arrow) was observed in prostatic adenocarcinoma. (C) Micrography representative of human E-cadherin staining by IHC of tissue microarray sections of normal prostate and prostatic adenocarcinoma obtained after radical prostatectomy. Strong staining was observed in normal prostate (red arrow), whereas no staining (black arrow) was observed in adenocarcinoma.

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TABLE 1. PPAR ${gamma}$ expression in normal, benign prostate hypertrophy (BPH), and prostate cancer tissues

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TABLE 2. Acetylation status of histone H4 in normal, benign prostate hypertrophy (BPH), and prostate cancer tissues

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TABLE 3. Correlation between PPAR ${gamma}$ expression and acetylated H4 in normal, benign prostate hypertrophy (BPH), and prostate cancer tissues

DISCUSSION

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Discussion

PPAR ${gamma}$ is overexpressed in prostate cancer (15). Whereas the physiologicalfunction of PPAR ${gamma}$ in normal epithelial cells is largely unknown,PPAR ${gamma}$ activation inhibits the proliferation of malignant cellsfrom prostate carcinoma (4, 21, 25, 34), among others. Theseobservations suggest that induction of differentiation by activationof PPAR ${gamma}$ may represent a promising novel therapeutic approachfor cancer, as already demonstrated for liposarcoma (6) andin xenograft models of prostate (21). In addition, treatmentof patients with advanced prostate cancer with the PPAR ${gamma}$ agonisttroglitazone resulted in a high incidence of stabilization ofprostate-specific antigen levels (25). These studies were, however,limited to a reduced number of patients. A larger prospective,randomized, placebo-controlled clinical trial analyzed the effectsof rosiglitazone on the PSA doubling time in patients with biochemicaldisease progression after radical prostatectomy and/or radiationtherapy. In this study, no effects of rosiglitazone on diseaseprogression were observed for these patients (35). Despite technicalcaveats in the interpretation of PSA doubling time measurements,this study showed that PPAR ${gamma}$ ligands are not efficient in thissubset of patients. One interesting hypothesis is that PPAR ${gamma}$ could be insensitive to ligand activation in prostate cancerbecause its activity is repressed by the action of upstreamevents. This was demonstrated in a study showing that sustainedactivation of PPAR ${gamma}$ by the new PPAR ${gamma}$ activator R-etodolac requiredthe presence of HER2 inhibitors, suggesting that the HER2 pathway,likely through mitogen-activated protein kinase phosphorylationof PPAR ${gamma}$ , abrogated the effects of PPAR ${gamma}$ activity through degradationof this nuclear receptor (14). In this scenario, PPAR ${gamma}$ ligandscannot activate PPAR ${gamma}$ as a result of its degradation. We showin our study that, similarly to what is observed for the HER2-PPAR ${gamma}$ axis, inhibition of HDAC activity is required to achieve maximalPPAR ${gamma}$ activation in prostate cancer cells. We have shown previouslythat PPAR ${gamma}$ is part of an HDAC3-containing repressor complex inthe presence of PPAR ${gamma}$ ligands and we characterized a PPAR ${gamma}$ -HDAC3direct interaction (8). We believe that in prostate cancer cellsHDAC are fully active (Fig. 8) and therefore PPAR ${gamma}$ activity isrepressed in these cells even in the presence of ligands. HDACinhibition has been shown to result in decreased proliferationof several cancer cells (22). We found that histone H4 acetylationlevels were decreased in prostate cancer tumors, although theprecise correlation between histone acetylation level and tumorstage is more complex (33).

We found that PPAR ${gamma}$ might control tumor growth at two differentlevels. First, this nuclear receptor might exert antiproliferativeeffects through regulation of the expression of cell cycle regulators.This is consistent with previous studies showing decreased expressionof cyclin D1 upon PPAR ${gamma}$ agonist treatment in cancer cell lines(38). Second, we found that the combination treatment abrogatedthe invasive potential of prostate cancer cells. It is knownthat E-cadherin is one of the major factors that inhibit metastasisand invasion of prostate cancer cells through maintenance ofthe adherens junctions important for epithelial cell-cell adhesionand inhibition of epithelial-to-mesenchymal transition, whichis a required event in cancer progression. Downregulation ofE-cadherin expression contributes to certain aspects of oncogenesis(5), and it has been observed to occur in 50% of prostate cancers(24, 36, 37). We consistently found increased expression ofE-cadherin in PC3 cells treated with the combination therapy.Furthermore, we show that E-cadherin is a bona fide PPAR ${gamma}$ targetgene. In contrast to classical PPAR ${gamma}$ target genes, regulationof E-cadherin expression in response to PPAR ${gamma}$ ligands both atthe promoter and at the RNA level requires, however, the presenceof HDAC inhibitors to fully achieve maximal stimulation. Thisis consistent with our hypothesis that PPAR ${gamma}$ is not permissivefor activation by ligands when complexed with HDAC. This isdemonstrated by our ChIP experiments, which show that despitePPAR ${gamma}$ being bound to the promoter of the E-cadherin gene in thepresence of ligand, the promoter is not active, as shown bytransient-expression experiments and E-cadherin mRNA quantification.The lack of activity is most likely the result of the presenceof HDAC3 in this PPAR ${gamma}$ complex on the PPAR binding site of theE-cadherin promoter, a phenomenon that we cannot explain andare currently investigating. However, in the presence of HDACinhibitors and PPAR ${gamma}$ ligands, HDAC3 is absent from the PPAR ${gamma}$ complexin the E-cadherin gene promoter, and consequently the promoteris active, as suggested by the activity of the E-cadherin promoter.The finding that E-cadherin expression responds to PPAR ${gamma}$ agonistsonly in the presence of HDAC inhibitors defines a new classof PPAR ${gamma}$ target genes.

In support of this, we show that classical PPAR ${gamma}$ target genes,such as aP2, responded to PPAR ${gamma}$ with a sixfold activation inthe absence of HDAC inhibitors (Fig. 6). This suggests thatthe sensitivities of PPAR ${gamma}$ repression to HDAC are different dependingon the context of the promoter of the PPAR ${gamma}$ target gene. We canconclude from our results that a combination therapy using PPAR ${gamma}$ agonists and HDAC inhibitors might be considered for the treatmentof prostate cancer.

ACKNOWLEDGMENTS

Jacques Teyssier, Imâde Ait-Arsa, Michel Brissac, andMichelle Turmo are acknowledged for their excellent technicalassistance. Members of the Equipe AVENIR and INSERM U540 areacknowledged for support and discussions.

This work was supported by grants from INSERM (Avenir), CHUde Montpellier, Association pour la Recherche contre le Cancer,Alfediam, Ligue contre le Cancer, and Fondation pour la RechercheMédicale. I.I. was supported by a grant from Ligue Nationalecontre le Cancer, D.S. by the Boehringer Ingelheim Fonds Ph.D.scholarship program, and A.A. by a grant of INSERM poste vert.

FOOTNOTES

* Corresponding author. Mailing address: Equipe Avenir, INSERM U540, 60 rue de Navacelles, F-34090 Montpellier, France. Phone: 0033 467 043 082. Fax: 0033 467 540 598. E-mail: fajas{at}montp.inserm.fr.

Supplemental material for this article may be found at http://mcb.asm.org/.

These authors contributed equally to this work.

REFERENCES

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