Bifunctional Properties of Peroxisome Proliferator-Activated Receptor
1 in KDR Gene Regulation Mediated via Interaction With Both Sp1 and Sp3
Yukio Sassa1,
Yasuaki Hata1,
Lloyd Paul Aiello2,3,
Yukio Taniguchi4,
Kimitoshi Kohno5, and
Tatsuro Ishibashi1
1 Department of Ophthalmology, Graduate School of Medical Sciences, Kyushu University, Fukuoka, Japan
2 Department of Ophthalmology, Harvard Medical School, Boston, Massachusetts
3 Research Division and Beetham Eye Institute, Joslin Diabetes Center, Boston, Massachusetts
4 Department of Animal Breeding and Genetics, Graduate School of Agriculture, Kyoto University, Kyoto, Japan
5 Department of Molecular Biology, School of Medicine, University of Occupational and Environmental Health, Kitakyushu, Japan
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ABSTRACT
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Vascular endothelial growth factor receptor 2 (KDR) plays a critical role in mediating a variety of vasculogenic and angiogenic processes, including diabetic retinopathy. We previously demonstrated that the promoter activity of the KDR gene in retinal capillary endothelial cells (RCECs) was regulated in part by the relative concentration of positive/negative transcription factors Sp1/Sp3. We also reported that the peroxisome proliferator-activated receptor (PPAR)
ligand could inhibit intraocular angiogenesis. In the present study, the role of PPAR
1 in KDR gene regulation in RCECs was examined. PPAR
1 protein physically interacted with both Sp1 and Sp3. Transactivation and electrophoretic mobility shift assays clearly demonstrated novel findings that PPAR
1 increased KDR promoter activity by enhancing the interaction between Sp1, but not Sp3, and KDR promoter region without its ligand in RCECs. The ligand-binding site but not the DNA binding site of PPAR
1 enhanced the interaction between Sp1 and KDR promoter region. Conversely, PPAR
1 ligand 15-deoxy
(12,14)-prostaglandin J2 dose-dependently suppressed the binding of KDR promoter region with both Sp1 and Sp3, resulting an inhibition of KDR gene expression. In conclusion, PPAR
1 has bifunctional properties in the regulation of KDR gene expression mediated via interaction with both Sp1 and Sp3.
Among many factors promoting angiogenesis, vascular endothelial growth factor (VEGF) is known to be a key regulator of intraocular angiogenic diseases such as diabetic retinopathy, age-related macular degeneration, and retinopathy of prematurity (1). VEGF acts as an angiogenic and permeability factor through the interaction with its receptors, VEGFR1 (flt-1), VEGFR2 (KDR/flk-1), and VEGFR3 (25). Most of the angiogenic activity of the VEGFs is attributable to VEGF-A (6), which binds to both VEGFR1 and VEGFR2. In contrast, VEGFR3 binds to VEGF-C and -D, which are primarily thought to be lymphangiogenic mediators (5). All of these receptors possess seven extracellular immunoglobulin-like domains and an intracellular tyrosine kinase region containing a kinase insert (3,5,7). In particular, KDR is thought to be mostly concerned with embryonic, neonatal, and pathological angiogenesis (6). Endothelial and hematopoietic cells share a common progenitor (hemangioblast), which expresses KDR very early during development (810). KDR mediates angioblast differentiation (11), whereas flt-1 suppresses hemangioblast commitment (12). Such precursors have been identified in bone marrow, peripheral blood, colonized angiogenic sites, and vascular prostheses in the adult (13,14). These attributes make KDR a therapeutic target to regulate angiogenesis during pathological conditions because of its importance as a mediator of the "angiogenic switch."
We previously demonstrated (15) that specific nuclear protein binding in the KDR to 79/68 with five critical bases between 74 and 70 is important in mediating transcriptional regulation in bovine retinal capillary endothelial cells (RCECs). Moreover, we have demonstrated that Sp1 binding alters both KDR promoter activity and KDR expression using the 5'-flanking region of human KDR gene reporter assay and Sp1 cis element "decoy." Additionally, we have demonstrated that endothelial-selective KDR promoter activity might be partially regulated by alterations in the Sp1-to-Sp3 ratio because Sp1-mediated promoter activation was attenuated by Sp3.
Peroxisome proliferator-activated receptors (PPARs) are members of the steroid receptor superfamily (16,17). Three subtypes of PPARs,
, ß (
), and
, have been identified and cloned. Like other members of this superfamily, PPARs mediate transcriptional regulation through their central DNA-binding domain, which recognizes response elements (peroxisome proliferator response elements) in the promoters of specific target genes (18,19). Recent evidences in our laboratory and by others (20,21) reveal that PPAR
ligands are capable of inhibiting angiogenesis both in vitro and in vivo. Using real-time quantitative RT-PCR, it was shown that the PPAR ligand 15-deoxy
(12,14)-prostaglandin J2 (15-d PGF2) suppressed KDR gene expression in VEGF-stimulated human umbilical vein endothelial cells grown in three-dimensional collagen gels (20). However, it has not been documented that PPAR
by itself or its ligands actually affect either KDR promoter activity or KDR expression directly. Additionally, there is no consensus peroxisome proliferator response element in the KDR gene promoter at least up to 900 bp. In this study, we evaluated the possibility that PPAR activator-dependent KDR downregulation is mediated by ligand-activated PPAR interaction with other transcriptional factors. We detected a potent and novel inhibitory activity of PPAR
ligands (15-d PGF2 or insulin-sensitizing thiazolidinedione pioglitazone) on KDR gene and protein expression in RCECs mediated by the suppression of both DNA-Sp1 and -Sp3 binding. PPAR
1 was also shown to physically interact with Sp1 and Sp3. The 15-d PGF2 dose-dependently suppressed Sp1- and Sp3-PPAR
interaction. PPAR
1 protein increased KDR promoter activity by the enhancement of the Sp1-KDR promoter region binding in the absence of its ligands. The ligand-binding site (but not the DNA-binding site) of PPAR
1 appeared to be responsible for enhanced Sp1-KDR promoter region binding.
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RESEARCH DESIGN AND METHODS
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The 15-d PGF2, Wy14643, and rabbit polyclonal antibody against PPAR
were purchased from Cayman Chemical (Ann Arbor, MI). Pioglitazone was provided by Takeda Chemical Industries (Osaka, Japan). Pioglitazone and 15-d PGF2 were dissolved in DMSO. [
-32P]dCTP and [
-32P]dATP were purchased from Amersham (Piscataway, NJ). Rabbit polyclonal antibody against Sp1, 2, 3, 4, nuclear factor-
B p65, and PPAR
for supershift assay were purchased from Santa Cruz Biotechnology (Santa Cruz, CA). Goat polyclonal antibody against Sp1 (PEP2), rabbit polyclonal antibodies against Sp3 (D-20), KDR (C-1158), and consensus oligonucleotide of Sp1 were also purchased from Santa Cruz Biotechnology.
Cell cultures.
Primary cultures of bovine RCECs were isolated as previously described (15). RCECs were cultured on type I collagen-coated dishes (Iwaki, Chiba, Japan) in endothelial growth medium (Clonetics, San Diego, CA) at 37°C in 5% CO2, 95% air. RCECs of all experiments were incubated for 6 h in Dulbeccos modified Eagles medium (DMEM; Life Technologies, Grand Island, NY) containing 10% fetal bovine serum (Life Technologies) before stimulation.
Plasmids.
The luciferase reporter vector inserted into the human KDR promoter region used in this work was previously described (17). Plasmid pSV40gal (Promega, Madison, WI) contains the ß-galactosidase gene driven by the SV40 promoter and enhancer. For expression plasmid, full-length cDNA fragments of bovine PPAR
2 were isolated from bovine fat cDNA library (22) using a mouse cDNA fragment amplified by RT-PCR as a probe and cloned into the pGEX-3X (Amersham Pharmacia, Piscataway, NJ). Oligonucleotides used for the mouse cDNA probe are the following: mouse PPAR
2, sense 5'-GCGAGGGCGATCTTGACAGGAA-3' (nt 820841) and antisense 5'-GTGCAATCAATAGAAGGAACACG-3' (nt 1,6041,582).
PPAR
1 cDNA were constructed from PPAR
2 cDNA and cloned into pcDNA3.1 (Invitrogen, Carlsbad, CA) and pGEX-3X. GST-PPAR
1 fusion proteins containing partial deletions of the receptor were constructed using the BamHI restriction enzyme-recognition site and cloned into pGEX-3X. PPAR
2 cDNA was cloned into pcDNA3.1 in reverse (reverse PPAR
2). The human Sp1 and Sp3 cDNA expression vectors used in this work have been described previously (23).
Transfection and luciferase assay.
Plasmid DNA was introduced into RCECs with the Lipofect Amine reagent (Invitrogen) as instructed by the manufacturer. The appropriate luciferase reporter construct (1.2 µg) was always cotransfected with 0.8 µg of pSV40gal to normalize the transfection efficiency in the 1.53.0 x 105 cells used. Cells were harvested 48 h after transfection, and luciferase activity was measured using the luciferase assay system (Promega, San Luis Obispo, CA). Galactosidase activity was assayed as described previously (15). For each transfection, luciferase activity was divided by galactosidase activity to obtain normalized luciferase activity. Results were normalized to the activity of 101/296-luc in the absence of a ligand.
Northern blot analysis.
Total RNA samples were isolated from cells using the acid guanidinium thiocyanate-phenol-chloroform-extraction method and subjected to Northern blot analysis as described previously (15). mRNA levels were quantified by densitometry with a Fujix BAS 2500 bioimage analyzer (Fuji, Tokyo, Japan).
MTT cell viability assays.
Confluent RCECs were incubated in DMEM with 10% serum for 48 h and then treated with 15-d PGF2 or pioglitazone. After 24 h of stimulation, the MTT assay (Chemicon, Temecula, CA) was performed per the manufacturers instructions.
Preparation of protein samples and Western blotting.
Whole-cell lysates or cytosolic or nuclear extracts were isolated from RCECs as previously described and subjected directly to Western blotting or after immunoprecipitation (15). Protein samples were separated by SDS-PAGE, followed by electrophoretic transfer to nitrocellulose membranes. After blocking with skim milk, the blots were incubated overnight at 4°C with antibodies against Sp3 (1:1,000), PPAR
(1:500), or KDR (1:500). After washing, membranes were incubated with horseradish peroxidase-labeled second antibodies (BioRad, Hercules, CA) (1:3,000) for 1 h at room temperature. Visualization was performed using the Amersham enhanced chemiluminescence detection system per the manufacturers instructions.
Electrophoretic mobility shift assay.
In vitro transcription/translation of human Sp1 and Sp3 cDNA clones were performed using the TNT kit (Promega, San Luis Obispo, CA). The unprogrammed reticlocyte was also simultaneously generated. For the electrophoretic mobility shift assay (EMSA), 3 µg of nuclear protein or each volume of in vitro transcription/translation of human Sp1 or Sp3 was incubated with radioactively labeled oligonucleotide equal to 105 cpm in binding buffer (20 mmol/l Tris, pH 7.5, 50 mmol/l KCl, 1 mmol/l MgCl2, 0.01% Triton X-100, 5% glycerol, and 1 mmol/l DTT) and 2 µg poly(dI/dC) (Boehringer Mannheim, Mannheim, Germany), giving a total volume of 15 µl, for 30 min at room temperature. The sequence of the probe used was the KDR promoter region 85/56 (15). The protein DNA complex was resolved by native 5% PAGE in 0.5x Tris-borate EDTA buffer. The gel was dried and exposed to imaging plates and analyzed with a Fujix BAS 2500 bioimage analyzer.
Glutathione S-transferase pull-down assay.
Full-length glutathione S-transferase (GST)-PPAR
1 fusion protein was synthesized from pGEX-PPAR
1 using the GST Gene Fusion system (Amersham). The proteins were loaded onto glutathione-Sepharose beads, which were washed and resuspended in binding buffer (20 mmol/l HEPES, pH 7.7, 75 mmol/l KCl, 0.1 mmol/l EDTA, 2.5 mmol/l MgCl2, 0.05% Nonidet P-40, 2 mmol/l dithiothreitol, and 10% glycerol) in the presence or absence of 10 µmol/l 15-d PGF2. The beads were incubated with 5 µl of in vitro translated 35S-labeled Sp1 or nuclear extract (400 µl) for 3 h at 4°C in the presence or absence of 1 or 10 µmol/l 15-d PGF2, followed by washing six times with binding buffer in the presence or absence of 1 or 10 µmol/l 15-d PGF2. They were then resuspended in 30 µl of SDS sample buffer and analyzed by SDS-PAGE.
Statistical analysis.
The experimental data are expressed as means ± SD. Statistical significance was assumed when was P < 0.05 using the Students t test in normally distributed populations.
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RESULTS
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PPAR
ligands downregulate KDR protein expression.
To examine the effect of PPAR
ligands on KDR protein expression, Western blotting was performed. RCECs were cultured for 24 h with 15-d PGF2 at the concentration of 10 µmol/l or with pioglitazone at a concentration of 20 µmol/l. Both 15-d PGF2 (40%, P = 0.019) and pioglitazone (36%, P = 0.023) significantly reduced KDR protein expression as compared with control (Fig. 1).

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FIG. 1. Suppression of KDR protein expression by PPAR ligands. Whole-cell lysate extracted from RCECs treated with 10 µmol/l 15-d PGF2 or 20 µmol/l pioglitazone for 24 h were subjected to Western blotting. The lower graph represents KDR protein expression as the percentage of control for three experiments (mean ± SD). *P < 0.05 vs. control.
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PPAR ligands downregulate KDR mRNA.
We have previously shown that the 5.7-kb KDR mRNA is expressed constitutively in RCECs (15). Treatment of RCECs with 15-d PGF2 (10 µmol/l) resulted in a decrease in the message level that was evident after 4 h and persisted for up to 24 h. mRNA levels reached 23% (P = 0.004) of 0-h values for KDR after 4 h of treatment (Fig. 2A). Both PPAR
and PPAR
are expressed in RCECs, as we have previously reported (21). To examine whether the downregulation of KDR by 15-d PGF2 is mediated through PPAR
, we determined the effect of pioglitazone, a PPAR
ligand, and Wy14643, a PPAR
ligand, on KDR mRNA expression. Pioglitazone (20 µmol/l) suppressed the KDR mRNA expression after 4 h of treatment (Fig. 2B), whereas Wy14643 (200 µmol/l) did not affect the expression of KDR mRNA (Fig. 2C). Because PPAR
ligands were reported (24) to have an apoptotic effect in endothelial cells, we also evaluated the viability of RCECs with MTT assay. Treatments of RCECs with 15-d PGF2 (10 µmol/l) or pioglitazone (20 µmol/l) for 24 h did not show any statistically significant changes in cell viability as compared with control (percentage of viable cells: control, 100%; 15-d PGF2, 97 ± 3.3; and pioglitazone, 96 ± 3.5; n = 6) (online appendix Fig. 1 [available at http://diabetes.diabetesjournals.org]).

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FIG. 2. Suppression of KDR mRNA expression by PPAR ligands. Total RNAs extracted from RCECs treated with 10 µmol/l 15-d PGF2 (A), 20 µmol/l pioglitazone (B), or 200 µmol/l Wy14643 (C) for the indicated time were subjected to Northern blotting. The lower graph represents KDR mRNA expression normalized to 36B4 (mean ± SD) (n = 4). *P < 0.05, **P < 0.01 compared with the control value.
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Effect of PPAR
ligands on KDR gene promoter activity.
Using luciferase reporter constructs created from human KDR promoter regions 101/296, both 15-d PGF2 (40% reduction, P < 0.05) and pioglitazone (40% reduction, P < 0.05) attenuated KDR promoter activity as shown in Fig. 3. In contrast, Wy14643, a PPAR
ligand, did not inhibit KDR promoter activity.

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FIG. 3. Transcriptional suppression of KDR gene by PPAR ligands. RCECs transfected with 101/296-luc construct were treated with the indicated concentrations of 15-d PGF2, pioglitazone, or Wy14643 for 24 h and harvested for measuring luciferase activities. Bar graphs represent the mean ± SD of luciferase activity (n = 3). *P < 0.05 compared with the control value.
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PPAR
ligands reduced Sp1/Sp3-KDR promoter binding.
To determine whether 15-d PGF2 could affect KDR promoter binding affinity, EMSA was performed using nuclear extract from RCECs and radiolabeled human KDR promoter region (85/64) containing Sp1 and nuclear factor-
B binding sites as a probe (Fig. 4). Specific DNA-protein binding complexes were evident as a major slower migrating band (complex I) and a faster migrating band (complex II) in control (Fig. 4, lane 4). These bands were competed by 100-fold molar excess of unlabeled Sp1 consensus oligonucleotides (Fig. 4, lane 2). This result suggested that these bands were DNA Sp family-binding complexes. Supershift assay using Sp1 or Sp3 antibodies suggested that both Sp1 and Sp3 comprise complex I, whereas complex II is comprised of only Sp3 (Fig. 4, lanes 57). In addition, the nuclear factor-
B and PPAR
antibodies could not supershift any bands (Fig. 4, lanes 89). One-hour treatment with 15-d PGF2 reduced both complex I and II (Fig. 4, lane 3). Moreover, incubation with anti-Sp2 and anti-Sp4 antibodies did not affect either complex, and no new bands were observed (data not shown).
Interaction between PPAR
1 and Sp1/Sp3 proteins in vitro.
We next explored whether PPAR
1 and Sp1 could directly interact. Figure 5A shows the results of immunoprecipitation using nuclear extract. PPAR
1 was coprecipitated with anti-Sp1 antibody in the absence of 15-d PGF2, suggesting a physical interaction between PPAR
1 and Sp1. This interaction was reduced in the presence of 15-d PGF2 (Fig. 5A). The immobilized PPAR
1-GST fusion protein bound in vitro translated Sp1 protein (Fig. 5C). The 15-d PGF2 dose-dependently suppressed the physical interaction between PPAR
1 and Sp1 (Fig. 5C) (60% reduction with 10 µmol/l 15-d PGF2; P < 0.05). Virtually identical results were obtained using Sp3 (Fig. 5B and D).
PPAR
1 overexpression enhances KDR promoter activity.
Using luciferase reporter constructs created from human KDR promoter regions 101/296, we transfected either PPAR
1 expression vector, reverse PPAR
2 expression vector, or empty vector into RCECs and examined the effect of PPAR
1 on KDR promoter activity. PPAR
1 overexpression enhanced KDR promoter activity (36% increase; P = 0.026), whereas reverse PPAR
2 overexpression did not (Fig. 6).
PPAR
1 protein enhances complex I formation.
To determine whether PPAR
1 by itself could affect Sp family KDR promoter region binding affinity, EMSA was performed using nuclear extract from RCECs with or without bacterially expressed GST-PPAR
1 fusion protein. The GST-PPAR
1 protein dose-dependently enhanced complex I formation (Fig. 7A).
PPAR
1 enhances Sp1- but not Sp3-binding to the KDR promoter.
To determine which Sp family protein (Sp1 or Sp3) KDR promoter region binding complex was enhanced by the GST-PPAR
1 fusion protein, we performed EMSA using either in vitro translated Sp1 or Sp3 with GST-PPAR
1 fusion protein (Fig. 7BD). Both in vitro translated Sp1 and Sp3 could bind the KDR promoter region (81/64). Intensity of the retarded band on EMSA was directly proportional to the concentration of Sp1 in the presence of a small amount of reticulocyte lysate solution (Fig. 7B, lanes 14). Sp1-DNA binding was enhanced by GST-PPAR
1 fusion protein (Fig. 7B, lanes 14, 69). In fact, GST PPAR
1 could enhance Sp1-KDR promoter region binding dose dependently (Fig. 7C, lanes 13), but could not enhance Sp3-KDR promoter region binding (Fig. 7D, lanes 14).
The COOH-terminus of PPAR
1 enhances Sp1-KDR promoter region (85/64) binding.
To delineate the PPAR
1 domains required for enhancement of Sp1-KDR promoter region binding, we constructed GST-PPAR
1 fusion proteins containing partial deletions of the receptor (Fig. 8A) and used them in EMSA (Fig. 8B). GST fusion protein comprising either the COOH-terminus of PPAR
1 (4541,329; ligand-binding domain L) or the whole PPAR
1 molecule (D/L) enhanced Sp1-KDR promoter region binding. In contrast, the effect of the NH2-terminus of PPAR
1 (1453; DNA-binding domain D) on Sp1-KDR promoter region binding was not apparent. To determine which domains of PPAR
1 interact with Sp1, we performed pull-down assays with nuclear extract and GST fusion proteins containing PPAR
1 or partial PPAR
1 deletions. Immobilized GST fusion proteins comprising the COOH-terminus of PPAR
1 (L) bound to Sp1. In contrast, Sp1 scarcely interacted with the NH2-terminus of PPAR
1 (D) or GST alone (Fig. 8C). The 15-d PGF2 inhibited the interaction between Sp1 and L but not between D.
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DISCUSSION
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In the present study, we demonstrated that PPAR
ligands reduced the expression of KDR in cultured RCECs through the suppression of both Sp1- and Sp3-DNA binding activity. Additionally, we demonstrated that Sp1-KDR promoter region (85 to 64) binding was enhanced by PPAR
1 itself, whereas Sp3-KDR promoter binding was not. Moreover, we confirmed that this property is distributed over the COOH-terminal region of PPAR
1, which contains a ligand-binding domain.
Mechanisms for antiangiogenetic property of PPAR
ligands.
We previously demonstrated (21) that PPAR
ligands could inhibit intraocular angiogenesis, whereas the detailed mechanisms of this effect have not been clearly determined. Recent studies (25,26) revealed that PPAR
ligands upregulated VEGF gene expression in several cell types including smooth muscle cells and monocytes/macrophages. We also examined the effect of PPAR
ligands on VEGF gene expression in RCECs. Treatment of RCECs with pioglitazone (20 µmol/l) resulted in an increase of VEGF mRNA that was evident after 10 h, whereas 15-d PGF2 (10 µmol/l) did not affect up to 24 h (data not shown). Although VEGF is known to play a prominent role in the regulation of ocular and tumor angiogenesis, it is possible that decreased KDR expression might be one of the key effects of PPAR
ligands as an antiangiogenic agent because KDR predominantly mediates the angiogenic effect of VEGF.
Possible mechanisms of KDR gene suppression by PPAR ligands
PPAR
1 enhances Sp1-KDR promoter region binding.
PPAR
1 protein might have bifunctional properties in KDR gene regulation. PPAR
1 by itself can enhance Sp1-DNA binding in the absence of its ligands, whereas PPAR
1 suppresses Sp1-DNA binding in the presence of its ligands. The interaction between PPAR
1 and either Sp1 or Sp3 might be mediated by Sp family DNA binding since 15-d PGF2, which could suppress the interaction between PPAR
1 and Sp1/Sp3, also inhibited both Sp1- and Sp3-DNA binding (Figs. 4 and 5AD). In vitro translated Sp1-KDR promoter region binding was specifically enhanced by PPAR
1 by itself (Fig. 7B). This result was in agreement with other studies (27,28), in which nuclear receptors including retinoic acid receptor and vitamin D3 receptor enhanced Sp1 binding to its cognate DNA sequence. In addition, PPAR
1 might effectively associate with Sp1 and this interaction could promote Sp1-DNA binding formation. In contrast, PPAR
1 could not enhance Sp3-KDR promoter region binding. Although this differentiation between Sp1 and Sp3 is not explained from the present study, PPAR
1 might promote KDR gene expression in RCECs by alterations in the Sp1-to-Sp3 ratio (15).
The enhanced effect of PPAR
1 is located within its COOH-terminal ligand-binding domain.
Our results demonstrated that the ligand-binding site of PPAR
1, which is thought to be essential for its interaction with Sp1, could enhance Sp1-DNA binding. This suggests that the ligand-binding domain of PPAR
1 cannot interact with Sp1 while occupied by its ligands. Ligand binding leads to a significant conformational change within the ligand-binding domain, which results in the creation of a recognition surface for transcription cofactors (29,30). A chain of these events within the ligand-binding domain might suppress the interaction between PPAR
1 and Sp1. Reduced interaction between PPAR
1 and Sp1 also inhibited Sp1-DNA binding.
PPAR
1 might indirectly enhance Sp1-DNA binding.
We could not detect a supershifted complex using a PPAR
-specific antibody on nuclear extracts (Fig. 4), suggesting that PPAR
1 is neither directly bound to this region of the KDR promoter nor tightly bound to either Sp1 or Sp3, whereas Sp1 and Sp3 are bound to the promoter. Based on our data, we suggest that PPAR
1 might act to promote Sp1-DNA association with other cofactors or through other mechanisms. One of these possible mechanisms may be the phosphorylation of Sp1 by PPAR
1 (31,32). However, we could not demonstrate that PPAR
1 by itself promoted phosphorylation of Sp1 (data not shown).
Recently, the inhibitory effect of PPAR
1 on Sp1-DNA complex by its ligands in other systems has been reported (33,34); however, PPAR
1 itself also suppressed the Sp1-DNA complex in vascular smooth muscle cells. In addition, interaction between PPAR
1 and Sp1 was enhanced by incubation with troglitazone belonging to thiazolidinediones. The reason for the discrepancy with our results is unclear. Several studies (35) showed that PPAR
ligands have ligand type-specific effects. We confirmed that pioglitazone, belonging to thiazolidinediones, also suppressed the interaction between PPAR
1 and Sp1/Sp3 in RCECs (online appendix Fig. 2). This discrepancy might not be explained from PPAR
ligand type-specific effects. Potential explanations might include differential expression of cofactors by the different cell types evaluated.
Although more precise investigation concerning the interaction between nuclear factors is necessary, PPAR
1 enhances KDR gene expression at the transcriptional level via the enhancement of Sp1-KDR promoter binding in the absence of its ligands in RCECs. PPAR
ligands, however, suppress KDR gene expression via a decreased interaction between PPAR
and Sp1/Sp3. PPAR
1 appears to have bifunctional properties in the regulation of KDR gene expression mediated via interaction with both Sp1 and Sp3 in RCECs.
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ACKNOWLEDGMENTS
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This study was supported in part by grants from the Ministry of Education, Science, Sports and Culture, Japan (Grant-in-Aid for Scientific Research nos. 15591861 and 15209057).
The authors thank K. Matsui for his financial support and A. Takeda, S. Nakao, R. Kohno, and Y. Nakamura for the technical support.
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FOOTNOTES
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Additional information for this article can be found in an online appendix at http://diabetes.diabetesjournals.org.
Address correspondence and reprint requests to Tatsuro Ishibashi, MD, PhD, Department of Ophthalmology, Graduate School of Medical Sciences, Kyushu University, 3-1-1, Maidashi, Higashi-ku, Fukuoka, 812-8582, Japan. E-mail: ishi{at}med.kyushu-u.ac.jp
Received for publication August 13, 2003
and accepted in revised form February 11, 2004
15-d PGJ2, 15-deoxy
(12,14)-prostaglandin J2; EMSA, electrophoretic mobility shift assay; GST, glutathione S-transferase; PPAR, peroxisome proliferator-activated receptor; RCEC, retinal capillary endothelial cell; VEGF, vascular endothelial growth factor
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