EPAS1 Promotes Adipose Differentiation in 3T3-L1 Cells

doi:10.1074/jbc.M400840200

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EPAS1 Promotes Adipose Differentiation in 3T3-L1 Cells^*

Shigeki Shimba ${ddagger}$ , Taira Wada ${ddagger}$ , Shuntaro Hara $§$ , and Masakatsu Tezuka ${ddagger}$ ¶

From the Department of Health Science, College of Pharmacy, Nihon University, 7-7-1 Narashinodai, Funabashi, Chiba 274-8555, Japan and the Department of Public Health and Molecular Toxicology, School of Pharmaceutical Sciences, Kitasato University, 5-9-1 Shirokane, Minato-ku, Tokyo 108-8641, Japan

Received for publication, January 26, 2004 , and in revised form, June 16, 2004.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Adipose differentiation is regulated by several transcriptionfactors, such as the CAAT/enhancer-binding protein family andperoxisome proliferator activator (PPAR) ${gamma}$ 2. Several recent studieshave shown that the basic helix-loop-helix-PAS superfamily isalso involved in the regulation of adipose differentiation.In this study, we investigated the roles played by EPAS1 (endothelialPAS domain protein 1) in adipogenesis. EPAS1, also referredto as hypoxia-inducible factor 2 ${alpha}$ , is a transcription factorknown to play essential roles in catecholamine homeostasis,vascular remodeling, and the maintenance of reactive oxygenspecies, and so forth. During adipose differentiation in 3T3-L1cells, the level of EPAS1 mRNA began to increase 6 days afterthe induction, and EPAS1 was highly expressed in differentiatedcells. To examine whether EPAS1 is involved in adipogenesis,we first isolated stable clones from 3T3-L1 cells in which wecould induce the expression of an EPAS1 C-terminal deletionmutant (designated EPAS1-(1–485)) with the insect hormone.The induction of EPAS1-(1–485) allowed the cells to accumulateonly minimum amounts of intracellular lipid droplets. Consistentwith the morphological observations, a minimum amount of aP2and PPAR ${gamma}$ 2 mRNA was induced in the EPAS1-(1–485) cells.We then examined whether or not EPAS1 was able to promote adipogenesisin NIH 3T3 cells, a relatively nonadipogenic cell line. Overexpressionof EPAS1 in NIH 3T3 cells induced a significant amount of lipidaccumulation compared with that of the control cells in thepresence of the PPAR ${gamma}$ ligand. The results were also confirmedby measuring the expression of adipocyte-related genes. Adenovirus-mediatedEPAS1-(1–485) expression resulted in the reduction ofbasal and insulin-dependent glucose transport in 3T3-L1 adipocytes.The mechanism involved the transcriptional regulation of GLUT1,GLUT4, and IRS3 expression by EPAS1. Taken together, these resultssuggest that EPAS1 plays several supporting roles in maintainingspecific aspects of adipogenesis and adipocyte function includingregulation of glucose uptake followed by lipid synthesis.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Adipose differentiation is a complex process by which fibroblast-likeundifferentiated cells are converted into cells that accumulatelipid droplets. Recent studies using DNA arrays revealed thatexpression of several hundred genes is altered in this process(1). This complex differentiation process is driven by the coordinatedexpression of various transcription factors, including the CAAT/enhancer-bindingprotein (C/EBP)^¹ family and peroxisome proliferator activator(PPAR) ${gamma}$ 2 (2–4). In pre-adipocytes, the Wnt signaling pathwayis part of the machinery, which maintains the cells in undifferentiatedstates (5). Adipogenesis begins on the treatment of preadipocyteswith fetal calf serum, insulin, dexamethasone, and an inducerof intracellular cyclic AMP such as isobuthylmethylxanthine.A rapid and transient increase in transcription and expressionof C/EBP ${beta}$ and C/EBP ${delta}$ is observed in the early stages of differentiation.These factors have been shown to promote adipogenesis, presumablythrough induction of C/EBP ${alpha}$ and PPAR ${gamma}$ 2 (2–4). The enforcedexpression of PPAR ${gamma}$ 2 or C/EBP ${alpha}$ has been shown to stimulate adipogenesisin NIH 3T3 fibroblasts (6–8), suggesting the essentialroles played by these factors in regulating adipogenesis invitro. Cells lacking PPAR ${gamma}$ 2 had a greatly reduced level of C/EBP ${alpha}$ (9–11). Similarly, cells lacking C/EBP ${alpha}$ have reduced adipogenicpotential and expression of PPAR ${gamma}$ 2 (12). Importantly, addingPPAR ${gamma}$ 2 back to C/EBP ${alpha}$ -null cells has been shown to restore theirability to accumulate lipids and activate markers of adiposedifferentiation (12). Recent studies have demonstrated thatectopic expression of C/EBP ${alpha}$ failed to rescue the ability todifferentiate in PPAR ${gamma}$ -null mouse embryo fibroblasts (13). Therefore,rather than being an equal co-director of the adipogenesis program,PPAR ${gamma}$ 2 plays a leading role in the adipogenic hierarchy. On theother hand, C/EBP ${alpha}$ is critical in the establishment of insulinsensitivity (12). This effect of C/EBP ${alpha}$ is mediated in part bythe direct transcriptional induction of both the insulin receptorand IRS1 (12). Consequently, C/EBP ${alpha}$ is influential in maintainingthe expression of PPAR ${gamma}$ 2 and in promoting full insulin sensitivity.

Several recent studies have shown that the basic helix-loop-helix(bHLH)-PAS superfamily is also involved in regulation of adiposedifferentiation (14–17). The bHLH-PAS proteins are characterizedby the PAS domain, which is composed of two imperfect 50-aminoacid repeats and a bHLH domain. The term "PAS" is derived fromthe first three members of the family: the period gene, thearyl hydrocarbon receptor nuclear translocator gene (ARNT),and the single-minded (SIM) gene. Using the PAS domain and thebHLH domain, proteins of this family form heterodimers thatbind to a target gene through the basic region and govern thefunctions of that gene. The PAS domain is found in a varietyof proteins that play roles in development and adaptation tothe environment, such as neurogenesis (18), circadian rhythms(19), hypoxia (20), and xenobiotic metabolism (21). Thus, membersof bHLH-PAS superfamily are thought to serve as sensors of environmentaland developmental signals. We recently demonstrated that thearyl hydrocarbon receptor, a ligand-dependent transcriptionfactor, is involved in the negative regulation of adipogenesisin 3T3-L1 cells (14). The proposed mechanism of action in thiscase is that the aryl hydrocarbon receptor inhibits the PPAR ${gamma}$ 2activation pathway by stimulating p107 expression and p42/p44mitogen-activated protein kinase, and the inhibition of thePPAR ${gamma}$ 2 signaling pathway results in a lower level of morphologicaldifferentiation in aryl hydrocarbon receptor-activated cells(14). Hypoxia inhibits adipogenesis in a hypoxia-inducible factor(HIF)-1 ${alpha}$ -dependent manner (15). The putative mechanism for thisprocess is that HIF-1 ${alpha}$ -regulated gene Dec 1/Stra 13 repressesPPAR ${gamma}$ 2 promoter activity (15). Clinical studies have shown thatdisruption of the Sim1 gene by a de novo balanced translocationbetween chromosomes results in obesity (16). Also, Sim1 heterozygousmice develop early-onset obesity (17). Consequently, severalbHLH-PAS proteins are thought to participate in the regulationof adipose differentiation.

Among the proteins of bHLH-PAS family, we have focused hereon the roles played by EPAS1 (endothelial PAS domain protein1) in adipogenesis. EPAS1, also referred to as HIF-2 ${alpha}$ , HLF, orMOP2, is a transcription factor predominantly expressed in endothelialcells and the organ of ZuckerlandI (22–25). Studies usingEPAS1-null mice revealed that EPAS1 is essential for catecholaminehomeostasis and vascular remodeling (25, 26). More recently,Scortegagna et al. (27) revealed that EPAS1 plays a role inthe maintenance of reactive oxygen species. In addition to theseroles, a contribution of EPAS1 to the regulation of adipogenesishas been suggested for the following reasons. First, severalgrowth factors, including insulin and insulin-like growth factor,induce and activate EPAS1 activity in a phosphatidylinositol3-kinase-dependent or related manner (28). Also, HIF-1 ${alpha}$ , whichis closely related to EPAS1, mediates insulin signaling in hepatocytes(29). More importantly, EPAS1 is highly expressed in white adiposetissue (this study). We show here that overexpression of a dominantnegative form of EPAS1 in 3T3-L1 preadipocyte cells resultedin the suppression of morphological differentiation, as wellas in the induction of adipocyte-related genes. The mechanisminvolves the direct transcriptional regulation of GLUT1, GLUT4,and IRS3 genes by EPAS1. We also examined here the ability ofEPAS1 to induce adipose differentiation in nonadipogenic cells.Ectopic expression of wild-type EPAS1 in NIH 3T3 cells inducedmorphological differentiation and the expression of adipocyte-relatedgenes. These results suggest that EPAS1 is an important transcriptionfactor in the regulation of adipose differentiation.

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Cell Culture—3T3-L1 cells, obtained from the Human ScienceResearch Resources Bank (Osaka, Japan), were maintained in Dulbecco'smodified Eagle's medium supplemented with 10% calf serum. Forinduction of adipose differentiation, the cells were grown toconfluence. The cells were then fed with differentiation medium(a 3:1 mixture of Dulbecco's modified Eagle's medium and Ham'sF-12 containing 10% fetal bovine serum, 1.6 µM insulin,0.0005% transferrin, 180 µM adenine, 20 pM triiodothyronine,0.25 µM dexamethasone, and 500 µM isobutylmethylxanthine).After 3 days, the cells were refed with fresh differentiationmedium without dexamethasone and isobutylmethylxanthine andmaintained over the following days.

Oil Red O Staining—To judge the state of adipose differentiationby visual inspection, cultures were fixed with 4% formalin inphosphate-buffered saline for 2 h, rinsed three times with distilledwater, and then air-dried. The fixed cells were stained with0.5% Oil Red O solution for 1 h. After staining, the cultureswere rinsed several times with 70% ethanol.

Immunoblot Analysis of EPAS1 Protein—The cells, grownin 60-mm dishes, were rinsed with ice-cold phosphate-bufferedsaline. The rinsed cells were scraped off the dish, placed ina microcentrifuge tube, and centrifuged at 5,000 x g for 1 min.The resulting pellets were suspended in lysis buffer (50 mMHepes-KOH (pH 7.8), 420 mM KCl, 0.1 mM EDTA, 5 mM MgCl₂, 1 mMdithiothreitol, 0.5 mM phenylmethylsulfonyl fluoride, 0.0002%leupeptin, and 20% glycerol), vortex-mixed, and rocked at 4°C for 60 min. The suspensions were centrifuged for 15 minat 10,000 x g, and the resulting supernatants were then frozenuntil further analysis. The protein concentration of the extractswas determined according to the method of Bradford, using bovineserum albumin as the standard (30). Protein samples were denaturedby heating them to 90 °C in SDS-reducing buffer and resolvedby electrophoresis on 10% SDS-polyacrylamide gels. After transferof proteins to nitrocellulose membranes, the filters were probedwith antibodies against EPAS1 (Novous) or the FLAG motif (Stratagene).Color visualization was performed with secondary antibodiesconjugated with alkaline phosphatase and nitroblue tetrazoliumchloride/5-bromo-4-chloro-3-in-dolyl-phosphate substrate solution(Promega).

Ponasterone A (PonA)-inducible EPAS1-(1–485) ExpressionSystem— The PonA-inducible EPAS1-(1–485) expressionsystem was constructed using complete control mammalian expressionsystem (Stratagene) according to the manufacturer's instructions.Briefly, EPAS1-(1–485) cDNA was generated by PCR usingfull-length EPAS1 cDNA (31) and subcloned into expression vectorpEGSH, which is under the control of the PonA-responsive regulatoryplasmid pVgRXR. Cells stably transfected with regulatory plasmidpVgRXR were selected in conventional medium containing G418(450 µg/ml). After selection and isolation, the cellswere also transfected with pEGSH-EPAS1-(1–485) and allowedto grow in nonselective medium for 48 h. The cells were thencultured in medium containing hygromycin B (200 µg/ml).After 2–3 weeks, clones were isolated and expanded individually.

Analysis of RNA—Total RNA was extracted from the cloneswith TRIzol reagent (Invitrogen) according to the manufacturer'sinstructions and analyzed by Northern blotting. Probes wereprepared by reverse transcription-PCR techniques.

Adenovirus Infection—Adenovirus expressing EPAS1-(1–485)tagged with the FLAG motif was prepared according to the protocolsupplied by the manufacturer (Clontech). 3T3-L1 adipocytes wereinfected with the virus at a multiplicity of infection of $~$ 50in OPTI-MEM I (Invitrogen) for 24 h.

Promoter Analysis—The promoter region of GLUT1 gene (-3586to +237), GLUT4 gene (-785 to -1), IRS3 gene (-1787 to +1),PPAR ${gamma}$ 2 gene (-615 to +67), and EPAS1 gene (-1169 to +3) was amplifiedby PCR from genomic DNA isolated from 3T3-L1 cells. The DNAfragments amplified were subcloned into pGL3 basic vector. HEK293 cells were transiently transfected with the appropriateplasmids by lipofection, and the transfected cells were grownin conventional medium for 48 h. The cell lysates were prepared,and luciferase activities were assayed with the Dual LuciferaseReporter Assay System (Promega).

Determination of 2-Deoxyglucose Transport Activity—3T3-L1adipocytes were deprived of insulin by incubation in Dulbecco'smodified Eagle's medium for 24 h. The cells were then stimulatedwith 1 µM insulin in Krebs-Ringer-Hepes buffer (1.36 mMNaCl, 4.7 mM KCl, 1.25 mM MgSO₄, 1.25 mM CaCl₂, 1.2 mM KH₂PO₄,20 mM Hepes-NaOH (pH 7.4), and 0.1% bovine serum albumin) for30 min. The glucose uptake reaction was initiated by the additionof Krebs-Ringer-Hepes buffer containing 2-[¹⁴C]deoxyglucose(1 mCi/mmol) to each well, and after 5 min, the reaction wasterminated by washing the wells three times with ice-cold phosphate-bufferedsaline. The cells were then solubilized in 1 M NaOH, and theradioactivity was measured in a liquid scintillation counter(ALOKA).

Akt Phosphorylation—3T3-L1 adipocytes were stimulatedwith 1 µM insulin in serum-free Dulbecco's modified Eagle'smedium for 30 min. Cell lysates were prepared in extractionbuffer (20 mM Tris-HCl (pH 7.5), 150 mM NaCl, 1 mM EDTA, 1 mMEGTA, 1% Triton X-100, 2.5 mM sodium pyrophosphate, 1 mM glycerophosphate,1 mM Na₃VO₄, 1 µg of leupeptin, and 1 mM phenylmethylsulfonylfluoride). The amount of phosphorylated Akt in cell lysateswas determined by enzyme-linked immunosorbent assay accordingto the manufacturer's instructions (Cell Signaling Technology).

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The Level of EPAS1 Increased during Adipose Differentiationin 3T3-L1 Cells—In the first set of experiments, we examinedthe expression level of EPAS1 in mice adipose tissue. In whiteadipose tissue isolated from C57BL/6J mice, EPAS1 was predominantlyexpressed in fractions containing adipocytes, as compared withstromal-vascular fractions (Fig. 1A). Also, white adipose tissuein mice fed a high-fat diet expressed a much higher level ofEPAS1 mRNA compared with that in control mice (Fig. 1B). Theseresults suggest that the expression of EPAS1 is increased duringadipose differentiation in vivo. EPAS1 was originally identifiedas the transcriptional factor abundantly expressed in endothelialcells (22–24). Thus we compared the expression level ofEPAS1 in adipocytes with that in endothelial cells. The levelof EPAS1 mRNA expression in adipocytes is as high as that inendothelial cells (Fig. 1C). Then, in the next set of experiments,preadipose 3T3-L1 cells were differentiated to adipocytes bythe addition of dexamethasone, isobutylmethylxanthine, insulin,and fetal bovine serum, and the expression of EPAS1 during adipogenesiswas analyzed by Western blotting (Fig. 1D). The adipose differentiationstatus was confirmed by staining with Oil Red O and by measurementof glyceraldehyde-3-phosphate dehydrogenase activity 8 daysafter induction (data not shown). The level of EPAS1 proteinbegan to increase 6 days after induction and was markedly expressedin the differentiated cells (8 days after induction). Similarto the protein expression levels, EPAS1 mRNA levels increasedduring adipose differentiation (Fig. 1E). Conversely, expressionof HIF-1 ${alpha}$ was detected only at the early stage and declinedduring adipose differentiation (Fig. 1E). To characterize theexpression of EPAS1 during adipogenesis, the effects of adipocyte-relatedtranscription factors such as C/EBPs and PPAR ${gamma}$ s on EPAS1 promoteractivity were examined (Fig. 1F). Luciferase activity drivenby the EPAS1 promoter was increased by C/EBP ${beta}$ or C/EBP ${delta}$ , whereasC/EBP ${alpha}$ and PPAR ${gamma}$ s had little or no effect on this activity (Fig.1F).

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FIG. 1.
Expression of EPAS1 during adipose differentiation. A, white adipose tissue was excised from two male C57BL/6J mice (6 weeks old), and the tissue was fractionated into adipocytes and a stromal-vascular (S.-V.) fraction. Total RNA was isolated, and the expression of EPAS1 mRNA was determined by Northern blot analysis. Lanes 1 and 2 were run using samples from two distinct mice, respectively. B, obese C57BL/6J mice were generated by feeding the mice a high-fat diet for 4 weeks. White adipose tissue was excised from control mice and obese mice, and the expression of EPAS1 mRNA was determined by Northern blot analysis. C, expression of EPAS1 mRNA in human venous endothelial cells (Cell Systems) and white adipose cells (ZEN-BIO, Inc.) was determined by Northern blot analysis. D, 3T3-L1 cells were induced to differentiate by the standard protocol. Western blot analysis of EPAS1 and actin was performed on whole cell extracts (10 µg for EPAS1 and 5 µg for actin). E, expression of EPAS1 mRNA during adipose differentiation in 3T3-L1 cells was determined by Northern blot analysis. F, expression plasmids of adipogenesis-related transcription factors were transfected into HEK 293 cells with the reporter plasmid carrying the mouse EPAS1 promoter region. For all constructs, phRL-SV40 vector (Promega) was co-transfected to correct for differences in transfection efficiency, and the normalized luciferase activity was represented as arbitrary units. The averages of three independent experiments are shown.

Expression of the Dominant Negative Form of EPAS1 Inhibits AdiposeDifferentiation in 3T3-L1 Cells—To examine whether EPAS1exerts an influence on adipogenesis, we first constructed anEPAS1 C-terminal deletion mutant (designated EPAS 1-(1–485))that lacked a transactivation domain. EPAS1-(1–485) formsa heterodimer with ARNT and binds to the hypoxia-responsiveelement sequence (32). However, this mutated EPAS1 lacks theability to transactivate HRE-driven transcription (Fig. 2A;Ref. 32). Co-expression of EPAS1-(1–485) suppressed theinduction of HRE-driven transcription by full-length EPAS1 ina dose-dependent manner (Fig. 2A), indicating that EPAS1-(1–485)functioned as a dominant negative mutant. Although EPAS1-(1–485)also inhibits HIF-1 ${alpha}$ -dependent transcriptional activity in vitro(data not shown), the expression pattern of EPAS1 is distinctfrom that of HIF-1 ${alpha}$ during adipogenesis (Fig. 1E). Furthermore,HIF-1 ${alpha}$ protein is unstable due to oxygen-dependent ubiquitinationunder normoxia conditions, whereas EPAS1 protein is expressedat constant levels regardless of oxygenation (33, 34). Therefore,the effects of EPAS1-(1–485) observed in this study aremost likely on EPAS1 activity, but not HIF-1 ${alpha}$ activity. We thenisolated stable clones from 3T3-L1 cells in which we could inducethe expression of EPAS1-(1–485) with insect hormone (Pon.A)(Fig. 2B). This system allows us to directly examine the rolesof EPAS1 without relying on pharmacological agents or hypoxiaconditions that might regulate other signaling pathways andtranscriptional activities. Treatment of the control 3T3-L1cells with Pon.A had no effect on the differentiation states,as judged by Oil Red O staining (Fig. 2C). Conversely, the inductionof EPAS1-(1–485) allowed cells to accumulate only minimumamounts of intracellular lipid droplets (Fig. 2, C and D). Theseresults were confirmed by measuring the expression of adipocyte-relatedgenes, such as PPAR ${gamma}$ 2 and the C/EBP family. As expected, theexpression of these genes was strongly induced in the controlcells during differentiation (Fig. 2D). In contrast, consistentwith the morphological observations, minimum amounts of PPAR ${gamma}$ 2and C/EBP family were induced in the EPAS1-(1–485)-expressingcells. Consequently, these results indicated that EPAS1 playsa role for execution of the adipose differentiation programin 3T3-L1 cells.

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FIG. 2.
Dominant negative effects of EPAS1-(1–485) on adipose differentiation in 3T3-L1 cells. A, dominant negative effects of EPAS1-(1–485) on HRE-driven luciferase activity by full-length EPAS1. The indicated amounts of EPAS1-(1–485) and/or full-length EPAS1 expression plasmid and ARNT expression plasmid were co-transfected into HEK 293 cells with the reporter plasmid pGL3-HRE. For all constructs, pRL-SV40 vector (Promega) was co-transfected to correct for differences in transfection efficiency, and the normalized luciferase activity was represented as arbitrary units. The averages of three independent experiments are shown. B, 3T3-L1 preadipocytes stably transfected with pVgRXR and pEGSH-EPAS1-(1–485) were treated with Pon.A for 18 h. Western blot analysis of EPAS1-(1–485) and actin was performed on whole cell extracts (10 µg for EPAS1 and 5 µg for actin). C, 3T3-L1 preadipocytes stably transfected with inducible EPAS1-(1–485) or empty vector (Vector) were induced to differentiate for 7 days in the presence or absence of Pon.A. Cells were fixed and stained with Oil Red O. Similar results were obtained with three independent clones. D, the cell clones were induced to differentiate in the presence or absence of PonA. Total RNA was extracted at the indicated time points, and the expression of adipocyte-related genes was determined by Northern blot analysis.

The Combination of the PPAR ${gamma}$ Activator and a Conventional DifferentiationMixture Restores the Ability of EPAS1-(1–485)-expressingCells to Differentiate—Activation of PPAR ${gamma}$ with ligandssuch as thiazolidinediones can promote adipose differentiation.Therefore, we chose to examine whether or not the activationof PPAR ${gamma}$ would be able to restore the differentiation potentialof EPAS1-(1–485)-expressing cells. Consistent with theresults shown in Fig. 2, the induction of EPAS1-(1–485)with PonA resulted in a lower differentiation morphology (Fig. 3,middle row). However, treatment with troglitazone allowedthe EPAS1-(1–485)-expressing cells to accumulate lipiddroplets to the same extent as that of the control cells inthe presence of PonA (Fig. 3, bottom row). Similarly, co-treatmentwith the conventional differentiation mixture containing ciglitazoneor indomethacin restored the ability of the cells to differentiate(data not shown).

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FIG. 3.
Restoration of the differentiation potential of cells expressing EPAS1-(1–485) by treatment with PPAR ${gamma}$ 2 ligand. 3T3-L1 preadipocytes stably transfected with inducible EPAS1-(1–485) expression vector (EPAS1-(1–485)) or empty inducible vector (Vector) were treated with differentiation medium containing the indicated reagents. On day 7, the cells were fixed and stained with Oil Red O. Similar results were obtained with independent clones.

Ectopic Expression of EPAS1 in NIH 3T3 Cells Stimulates AdiposeDifferentiation—The results described above demonstratedthat EPAS1 plays a role in adipogenesis in 3T3-L1 cells. Then,we wished to examine whether EPAS1 has the ability to promoteadipogenesis in NIH 3T3 cells, a relatively nonadipogenic cellline. NIH 3T3 cells were stably transfected with either a controlvector or a vector expressing high levels of full-length EPAS1mRNA. After the selection and expansion of stable clones, thelevel of the EPAS1 protein was examined by Western blot analysis.As shown in Fig. 4A, the cells transfected with the vector expressingEPAS1 mRNA produced more EPAS1 protein than did the controlvector-transfected cells. To evaluate the differentiation potencyof the clones, the cells were cultured to confluence and thentreated with a standard differentiation medium containing PPAR ${gamma}$ 2ligand (troglitazone or 5,8,11,14-eicosatetraynoic acid). Theextent of differentiation was estimated by adipose stainingwith Oil Red O. Neither the EPAS1-expressing cell clones northe control cells showed signs of lipid accumulation when culturedin the absence of differentiation-inducing agents (data notshown). Treatment with adipose differentiation medium containingPPAR ${gamma}$ 2 ligands enabled the wild-type NIH 3T3 cells and the cellsexpressing vector mRNA to exhibit only a minimum degree of lipidaccumulation (Fig. 4, B and C). However, the cells overexpressingEPAS1 showed more lipid accumulation than was observed in thecontrol cells 10 days after induction of differentiation (Fig.4, B and C). The expression of adipocyte-related genes, suchas PPAR ${gamma}$ 2 and aP2, was greatly induced in the EPAS1-expressingcells, whereas these genes were poorly expressed in the controlcells (Fig. 4D).

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FIG. 4.
Ectopic expression of full-length EPAS1 in NIH 3T3 cells stimulates adipose differentiation. A, NIH 3T3 cells were stably transfected with full-length EPAS1 expression plasmid (EPAS1) or pcDNA 3.1 plasmid (Vector). Western blot analysis of EPAS1 and actin was performed on whole cell extracts (10 µg for EPAS1 and 5 µg for actin). B, cell clones were treated with differentiation medium containing either troglitazone (10 µM) or ETYA (50 µM) for 10 days. Cells were fixed and stained with Oil Red O. C, microscopic view of dishes shown in B at x100 original magnification. D, the cell clones were induced to differentiate with differentiation medium containing ETYA. Total RNA was extracted at the indicated time points, and the expression of adipocyte-related genes was determined by Northern blot analysis. The results shown in A-D are representative of three to five independent clones with similar results.

EPAS1 Regulates Glucose Uptake in Adipocytes—In additionto PPAR ${gamma}$ 2, insulin plays pivotal roles in adipose differentiation.Previous studies have shown that insulin-like growth factoractivates EPAS1 in osteoblast-like cells (28). Thus, to understandthe molecular basis by which EPAS1 promotes adipose differentiation,we next examined the effects of EPAS1-(1–485) on the expressionof genes for insulin signaling and glucose transport. As describedin Fig. 2, the induction of EPAS1-(1–485) in preadipocytesresulted in failure of differentiation, and therefore it isnot clear whether alterations of gene expression in EPAS1-(1–485)-expressingcells during adipose differentiation reflect direct effectsof EPAS1-(1–485) or are an indirect result of the lowerlevel of differentiation of EPAS1-(1–485) cells. Thus,in these experiments, 3T3-L1 cells were induced to differentiate,and mature adipocytes were infected with adenovirus expressingeither LacZ or EPAS1-(1–485). As shown in Fig. 5 (-),infection with adenovirus carrying LacZ had no effect on expressionof the genes examined. Overexpression of EPAS1-(1–485)in 3T3-L1 adipocytes dramatically suppressed the expressionof GLUT1, GLUT4, and IRS3, whereas the expression of other genessuch as PPAR ${gamma}$ 2, aP2, insulin receptor (IR), IRS1, and GLUT8 wasnot significantly altered (Fig. 5). We then examined the abilityof EPAS1 to directly regulate the transcriptional activity ofthese genes. The luciferase reporter gene driven by the promoter/enhancerof GLUT1, GLUT4, IRS3, and PPAR ${gamma}$ 2 was constructed and transfectedinto 293 cells with different amount of EPAS1 expression vector.As shown in Fig. 6A-C, EPAS1 enhanced the promoter/enhanceractivity of GLUT1, GLUT4, and IRS3 genes in a dose-dependentmanner. Also, consistent with the mRNA expression results (Fig. 5),EPAS1/ARNT was found to have no effect on PPAR ${gamma}$ 2 promoteractivity (Fig. 6D). To evaluate whether these changes in geneexpression had an effect on the biological activity of adipocytes,glucose transport activity in EPAS1-(1–485)-expressingadipocytes was determined. In the absence of insulin, the amountof glucose transported into EPAS1-(1–485)-expressing cellswas <50% of that in the control cells (Fig. 7A). Althoughthe addition of insulin increased the amount of glucose transportedinto the cells, the glucose transport activity of the EPAS1-(1–485)-expressingcells was still significantly lower than that of the controlcells (Fig. 7A). In contrast to glucose transport activity,the degree of Akt phosphorylation was the same in EPAS1-(1–485)-expressingcells and control cells (Fig. 7B).

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FIG. 5.
Dominant negative effects of EPAS1-(1–485) on the expression of insulin signaling- and glucose transport-related genes in 3T3-L1 adipocytes. 3T3-L1 adipocytes were infected with the adenovirus carrying EPAS1-(1–485) (E(1–485)) or LacZ (Z) at a multiplicity of infection of $~$ 50 for 24 h. Total RNA was extracted, and the expression of glucose transport-related genes was determined by Northern blot analysis. The results shown are representative of three to five independent virus preparations with similar results.

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FIG. 6.
EPAS1 activates the promoter activity of GLUT1 (A), GLUT4 (B), and IRS3 (C), but not that of PPAR ${gamma}$ 2(D). Full-length EPAS1 and ARNT expression plasmids were transfected into HEK 293 cells with the reporter plasmid (0.15 µg) carrying the promoter region of the indicated genes. In D, the PPAR ${gamma}$ 2 promoter-driven luciferase plasmid (0.15 µg) was transfected with a pair of full-length EPAS1 (0.15 µg) and ARNT expression plasmids (0.15 µg) or C/EBP ${delta}$ expression plasmid (0.15 µg) as a positive control. For all constructs, pRL-SV40 vector (Promega) was co-transfected to correct for differences in transfection efficiency, and the normalized luciferase activity was represented as arbitrary units. The averages of three independent experiments are shown.

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FIG. 7.
Dominant negative effects of EPAS1-(1–485) on glucose transport in 3T3-L1 adipocytes. 3T3-L1 adipocytes were infected with adenovirus carrying EPAS1-(1–485) or LacZ at a multiplicity of infection of $~$ 50 for 24 h. The glucose transport activity (A) and Akt phosphorylation status (B) of the cells were determined as described under "Experimental Procedures." The results shown are averages of three independent experiments.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

EPAS1 was originally identified as a transcription factor responseto hypoxia conditions (21–23). Although EPAS1 and HIF-1 ${alpha}$ share high amino acid homology, they may have distinct functionsbecause of differences in tissue distribution and in the developmentalexpression profiles of these proteins (21–23, 35, 36).A recent study has revealed that the target genes of EPAS1 are,at least in part, distinct from those of HIF-1 ${alpha}$ (37). More interestingly,oxygen-dependent protein degradation is restricted to HIF-1 ${alpha}$ (33). In many cell lines such as mouse embryo fibroblasts, EPAS1escapes oxygen-dependent protein degradation and is no longera hypoxia-inducible factor (34). Together with the results fromknockout mice studies, these results strongly suggest that EPAS1plays a critical role in embryonic development and homeostasisunder normoxia conditions (25–27). In this study, we demonstratedthat EPAS1 is highly induced during adipose differentiationin vivo and in vitro (Fig. 1). Also, the C/EBP family can activateEPAS1 promoter activity in vitro (Fig. 1D). Although littlehas been known about the role of this factor in adipose differentiation,the present observations suggest that EPAS1 may play a rolein adipogenesis. The expression of a dominant negative formof EPAS1 suppressed the morphological differentiation of 3T3-L1cells, as well as induction of adipocyte-related genes (Fig. 2).Conversely, overexpression of full-length EPAS1 in nonadipogenicNIH 3T3 cells facilitated lipid droplet accumulation in thecells (Fig. 4), although the presence of the PPAR ${gamma}$ ligand isrequired for adipose differentiation of EPAS1-expressing NIH3T3 cells (data not shown). The morphological differentiationin EPAS1-expressing NIH 3T3 cells was accompanied by the inductionof adipogenic markers such as PPAR ${gamma}$ 2 and aP2 (Fig. 4). Finally,DEXA scan analysis revealed that adipose tissues in EPAS1 knockoutmice are smaller than those in control mice.^² Consequently,EPAS1 appears to play a role in promotion of adipose differentiation.

In this study, the results obtained using the luciferase reporterassay indicate that the EPAS1 promoter is differentially regulatedby different C/EBPs (Fig. 1F). A number of other studies showdifferential action of C/EBP ${alpha}$ and C/EBP ${beta}$ in activating variouspromoters including PPAR ${gamma}$ 2 (38–42). Although precise analysison the EPAS1 promoter has not yet been performed, computer analysisrevealed that the putative binding sites of C/EBPs on the EPAS1promoter region are not identical to those found in PPAR ${gamma}$ 2 (datanot shown). These results, taken together, support idea thatthe action of C/EBPs involves context-specific effects and dependson promoter composition as reported previously (43).

Adipose differentiation is a complex process accompanied bythe alteration of expression of several hundred genes (1). Thecoordination of this complex process is driven mainly by PPAR ${gamma}$ 2(4). Although the induction of a dominant negative form of EPAS1in 3T3-L1 preadipocytes reduced the expression level of PPAR ${gamma}$ 2(Fig. 2D), this may be an indirect result of the lower levelof differentiation of EPAS1-(1–485) cells because of thefollowing reasons. First, in mature adipocytes, dominant negativeEPAS1 had no effect on PPAR ${gamma}$ 2 expression (Fig. 5). Second, theearly expression level of PPAR ${gamma}$ 2 in EPAS1-expressing NIH 3T3cells was not substantially different from that in the controlcells (Fig. 4D). Moreover, EPAS1 had no effect on PPAR ${gamma}$ 2 promoteractivity (Fig. 6D). Therefore, it is unlikely that PPAR ${gamma}$ 2 isa direct target of EPAS1.

We demonstrated in this study that EPAS1 regulates both basaland insulin-dependent glucose transport into cells (Fig. 7A).EPAS1-(1–485) had no effects on phosphorylation of Akt(Fig. 7B), suggesting that EPAS1 is not likely to be involvedin regulation of the Akt signaling pathway. Therefore, the mechanismby which EPAS1 regulates glucose uptake may be the direct transcriptionalregulation of several factors including GLUT1 and GLUT4 (Figs.5 and 6), although we cannot exclude the possibility that EPAS1-(1–485)suppressed the translocation activity of the glucose transporter.Several lines of evidence have suggested that these factorsplay pivotal roles in the promotion of adipose differentiation.A previous study using transgenic mice revealed that GLUT4 regulatesthe number of fat cells as well as insulin sensitivity (44).GLUT4-null mice exhibit decreased longevity associated withcardiac hypertrophy and severely reduced adipose tissue deposits(45). GLUT1 expression and GLUT4 translocation can be regulatedby PPAR (46), suggesting that restoration of the ability ofEPAS1-(1–485) cells to differentiate (Fig. 3) by troglitazoneis likely due to the recovery of these factors. If this is indeedthe case, the present results support the notion that the reducedexpression of GLUT1 and GLUT4 is partly responsible for thereduced differentiation potency of EPAS1-(1–485) cells.The promotion of glucose flux and subsequent glycolysis by thesefactors are known to contribute to an increase in lipid synthesisin adipocytes (47, 48). In addition to GLUT1 and GLUT4, IRS3could be the target gene of EPAS1 (Figs. 5 and 6). White adiposetissue of Irs1^-/-/Irs3^-/- double knockout mice was reduced by $~$ 80% as compared with Irs1^-/- mice, suggesting that IRS3 maybe at least partly involved in the formation of white adiposetissue (49). Taken together, the results suggest that the transcriptionalregulation of these factors, followed by enhanced glucose uptake,may account in part for a putative mechanism by which EPAS1promotes adipose differentiation.

Scortegagna et al. (27) reported an alteration of serum acylcarnitinprofiles in EPAS1-null mice. The markedly high C16:C2 ratioand the spectrum of intermediate acyl-fatty acids species inEPAS1-null mice suggest that EPAS1 participates in the regulationof lipid metabolism (27). Consequently, we are led to concludethat EPAS1 plays several supporting roles in maintaining specificaspects of adipogenesis and adipocyte function, such as regulationof glucose uptake followed by lipid synthesis, despite not beingdirectly responsible for the induction of adipogenesis per se.

FOOTNOTES

^* This work was supported in part by a grant from the Ministryof Education, Sciences, Sports, and Culture of Japan (to S.S. and M. T.); a General Individual Research Grant from NihonUniversity (to S. S.); a grant from the Ministry of Education,Culture, Sports, Science, and Technology to promote multidisciplinaryresearch projects; and an Interdisciplinary General Joint ResearchGrant from Nihon University (to M. T.). The costs of publicationof this article were defrayed in part by the payment of pagecharges. This article must therefore be hereby marked "advertisement"in accordance with 18 U.S.C. Section 1734 solely to indicatethis fact.

^¶ To whom correspondence should be addressed. Tel.: 81-47-465-5694; Fax: 81-47-465-5637; E-mail: tezukam{at}pha.nihon-u.ac.jp.

¹ The abbreviations used are: C/EBP, CAAT/enhancer-binding protein;PPAR, peroxisome proliferator activator; bHLH, basic helix-loop-helix;HIF, hypoxia-inducible factor; PonA, ponasterone A.

² J. A. Garcia, personal communication.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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