Protein Phosphatase 2A (PP2A) Regulates Low Density Lipoprotein Uptake through Regulating Sterol Response Element-binding Protein-2 (SREBP-2) DNA Binding*

Background: The sterol response element-binding protein-2 (SREBP-2) regulates LDLR gene expression. Results: Protein phosphatase 2A regulates SREBP-2 binding to an LDLR promoter SRE. Conclusion: PP2A regulates LDL uptake. Significance: A novel pathway regulating LDL uptake has been elucidated. LDL-cholesterol (LDL-C) uptake by Ldlr is regulated at the transcriptional level by the cleavage-dependent activation of membrane-associated sterol response element-binding protein (SREBP-2). Activated SREBP-2 translocates to the nucleus, where it binds to an LDLR promoter sterol response element (SRE), increasing LDLR gene expression and LDL-C uptake. SREBP-2 cleavage and translocation steps are well established. Several SREBP-2 phosphorylation sites have been mapped and functionally characterized. The phosphatases dephosphorylating these sites remain elusive. The phosphatase(s) regulating SREBP-2 represents a novel pharmacological target for treating hypercholesterolemia. Here we show that protein phosphatase 2A (PP2A) promotes SREBP-2 LDLR promoter binding in response to cholesterol depletion. No binding to an LDLR SRE was observed in the presence of the HMG-CoA reductase inhibitor, lovastatin, when PP2A activity was inhibited by okadaic acid or depleted by siRNA methods. SREBP-2 cleavage and nuclear translocation were not affected by loss of PP2A. PP2A activity was required for SREBP-2 DNA binding. In response to cholesterol depletion, PP2A directly interacted with SREBP-2 and altered its phosphorylation state, causing an increase in SREBP-2 binding to an LDLR SRE site. Increased binding resulted in induced LDLR gene expression and increased LDL uptake. We conclude that PP2A activity regulates cholesterol homeostasis and LDL-C uptake.


LDL-cholesterol (LDL-C) uptake by Ldlr is regulated at the transcriptional level by the cleavage-dependent activation of membrane-associated sterol response element-binding protein (SREBP-2). Activated SREBP-2 translocates to the nucleus,
where it binds to an LDLR promoter sterol response element (SRE), increasing LDLR gene expression and LDL-C uptake. SREBP-2 cleavage and translocation steps are well established. Several SREBP-2 phosphorylation sites have been mapped and functionally characterized. The phosphatases dephosphorylating these sites remain elusive. The phosphatase(s) regulating SREBP-2 represents a novel pharmacological target for treating hypercholesterolemia. Here we show that protein phosphatase 2A (PP2A) promotes SREBP-2 LDLR promoter binding in response to cholesterol depletion. No binding to an LDLR SRE was observed in the presence of the HMG-CoA reductase inhibitor, lovastatin, when PP2A activity was inhibited by okadaic acid or depleted by siRNA methods. SREBP-2 cleavage and nuclear translocation were not affected by loss of PP2A. PP2A activity was required for SREBP-2 DNA binding. In response to cholesterol depletion, PP2A directly interacted with SREBP-2 and altered its phosphorylation state, causing an increase in SREBP-2 binding to an LDLR SRE site. Increased binding resulted in induced LDLR gene expression and increased LDL uptake. We conclude that PP2A activity regulates cholesterol homeostasis and LDL-C uptake.
Cholesterol biosynthesis and uptake are important pathways that are required for cell maintenance because cholesterol is an essential lipid and is important for maintaining membrane fluidity, raft formation, and steroid and bile acid syntheses (1)(2)(3)(4). Moreover, proper LDL-C 3 uptake is essential for maintaining normal LDL-C blood level. Cholesterol itself is an important second messenger regulating developmental cell signaling (5)(6)(7). Deregulation of cholesterol metabolism leads to a chronic increase in blood plasma cholesterol level, which is a major risk factor for cardiovascular disease and atherosclerosis.
Current drug therapies (statins) have targeted de novo cholesterol biosynthesis as treatment for cardiovascular disease (8 -10). Although statins are able to reduce blood plasma cholesterol levels by inhibiting HMG-CoA reductase (HMGCR), ϳ10 -20% of patients are unable to tolerate treatment and have irrevocable joint pain and, in some cases, liver toxicity (11)(12)(13)(14)(15). Moreover, statins have a threshold as far as how low they can reduce LDL-C; thus, ϳ55-65% of patients still remain at risk for cardiovascular events (16). These patients may go on a higher dose of statin, which in some cases increases the incidence of side effects (17). Thus, novel therapies treating lipid disorders are needed to help statin-intolerant individuals. One such potential biologic therapy that is in clinical trials targets Pcsk9, which is involved in the degradation of Ldlr (18).
De novo cholesterol biosynthesis requires the induction of genes regulated by the transcription factor known as SREBP-2, one of three SREBPs encoded by mammalian cells. SREBP-2, along with SREBP-1a, activates genes required for cholesterol biosynthesis and LDL-C uptake, whereas SREBP-1c is important for fatty acid synthesis (19).
SREBP-2 is localized in the ER when cholesterol level is high but is transported to the Golgi and cleaved in response to a decrease in cholesterol sensed by sterol cleavage-activating protein (19). Two cleavage events within the Golgi by site 1 and site 2 protease lead to the generation of a soluble SREBP-2 active fragment transcription factor (SREBP-2af) that is transported to the nucleus (20). Nuclear SREBP-2af binds SREs in the promoters of genes required for de novo cholesterol biosynthesis, resulting in increased gene expression. These include * This work was supported by the Genesis Biotechnology Group.
PP2A is a heterotrimeric serine/threonine protein phosphatase that regulates many cell events, including cell cycle progression and cell signaling pathways (22). PP2A is composed of a core enzyme dimer consisting of a catalytic subunit (C) and an A structural subunit (22). The AC dimer recruits specific B regulatory subunits that confer substrate specificity and/or determine cell location. Four gene families consisting of several genes, many encoding several isoforms, encode for the B regulatory subunits (23). There are several reports indicating that PP2A regulates lipid-dependent events (24 -28). Thus, it seems that PP2A targets multiple factors regulating lipid metabolism, lipid trafficking, and lipid-dependent signaling.
We were interested in identifying novel drug targets to treat cardiovascular disease and atherosclerosis. Here, we uncovered a novel role for PP2A in regulating LDL-C uptake. PP2A is required for SREBP-2-dependent activation of LDLR gene expression in response to cholesterol depletion. PP2A directly binds to SREBP-2, altering its phosphorylation status, which causes an enhanced ability to bind an LDLR SRE promoter site. Increased binding causes increased Ldlr level and increased LDL-C uptake.

EXPERIMENTAL PROCEDURES
Cell Lines, Plasmids, and siRNA Treatment-HepG2 cells were grown in minimum Eagle's medium supplemented with 10% FBS, 1% sodium pyruvate, 1% non-essential amino acids, and 0.1% gentamycin (Invitrogen). THLE-3 cells were grown in BEGM (Clonetics) supplemented with 10% FBS, 5 ng/ml EGF, and 70 ng/ml phosphoethanolamine (Sigma). Rat primary hepatocytes were isolated as described (29). Rats were anesthetized with 60 mg of ketamine/kg of rat and 7.5 mg of xylazine/ kg. 50 kilounits/ml of heparin was injected into the femoral vein, and the primary hepatocytes were seeded at a density of 1 ϫ 10 6 cells in growth medium (Williams E medium supplemented with 1% sodium pyruvate, 2 mM glutamine, 4 l/ml ITS medium supplement (1 mg/ml recombinant human insulin; 0.55 mg/ml human transferrin (iron-free), 0.5 g/ml sodium selenite), 5 g/ml hydrocortisone, 0.01 g/ml EGF, and 25 g/ml gentamicin). After the initial 3-h incubation, the medium was removed and replaced with growth medium (as above, without gentamycin and with 0.1% DMSO). All cells were plated on collagen-coated plates and were incubated at 37°C, 5% CO 2 . Depending on the statin and cell line used, the concentration of statin ranged from 25 to 75 M. 10 nM okadaic acid (OA; Calbiochem) was used for inhibition of PP2A activity. All animal procedures were reviewed and approved by the Drexel University College of Medicine institutional animal care and use committee.
For HepG2 and THLE-3 cells, 100 nM Csi or PPP2CAsi siRNA (Dharmacon) was transfected at 48 and 24 h prior to statin treatment using dharmafect 4 transfection reagent. Cells were then treated with lovastatin (Sigma), atorvastatin, or simvastatin for 24 h. Cells were harvested, washed in 1ϫ PBS (Invitrogen), and stored at Ϫ80°C until processing. Rat primary hepatocytes were treated with Csi or 150 nM PPP2CAsi siRNA after the initial 3-h incubation and again the next morning, prior to the addition of 75 M lovastatin after 8 h. Cells were harvested 24 h later (30,31).
The full-length SREBP-2 was cloned into pEGFP-C1 plasmid (Clontech) via XhoI and SacII restriction enzyme sites. The EGFP is linked to the N terminus of SREBP-2. The construct (EGFP-SREBP-2) was confirmed by sequencing.
To infect HepG2-targeting cells, freshly harvested lentivirus was added to virus-containing medium supplemented with hexadimethrine bromide (Polybrene). 48 h postinfection, the cells were subjected to puromycin selection, and the medium was replaced every other day for more than a week. To assay for the infected cells, control and infected cells were either not treated or treated with 50 M lovastatin for 5-6 h. The cells were then gently rinsed one time with PBS and pelleted for total RNA extraction.
RNA Extraction and qRT-PCR-RNA was extracted from cells using the RNeasy kit (Qiagen) according to the manufacturer's protocol. 50 ng of RNA was used as a template in the one-step RT-PCR (Quanta) according to the suggested protocol. qRT-PCR was completed on an MxPro 3000 (Stratagene), and data were analyzed using MxPro software. Relative expression was determined by normalizing the expression of all genes of interest to GAPDH expression (⌬Ct), and data are represented as -fold change compared with the vehicle-treated sample (⌬⌬Ct).
The primers used for qRT-PCR were designed using Beacon Designer software and were ordered from IDT. For the HepG2 loaded onto a 10% denaturing gel, and proteins were then transferred to 0.45-m nitrocellulose (Whatman). Blots were blocked in 5% milk/TBST prior to incubation with primary and secondary antibodies (Amersham Biosciences). Antibodies were detected with the ECL detection kit from Amersham Biosciences. Primary antibodies for SREBP-2, LDLR, FDFT1, PPP2CA (protein phosphatase 2A ␣ catalytic subunit), and GAPDH were purchased from Abcam and were diluted to the suggested concentrations for Western blotting.
Subcellular Fractionation-HepG2 cells were harvested, and pellets were washed in 1ϫ PBS prior to resuspension in Dignam Buffer A (10 mM Tris, pH 7.6, 1.5 mM MgCl 2 , 10 mM KCl, 0.5 mM DTT) and incubation on ice for 15 min. Cells were lysed by passage through a 25-gauge needle and centrifuged. The clear lysate was collected as the non-nuclear fraction (cytoplasm), and the pellet was resuspended in radioimmune precipitation assay buffer ϩ propidium iodide and sonicated. Debris was pelleted by centrifugation and clear supernatant was collected as the nuclear fraction. 25 g of protein lysates was loaded onto 10% SDS-polyacrylamide gels and separated by electrophoresis. SREBP-2, PPP2CA, and GAPDH antibodies were used as described above, and anti-Lamin B (Santa Cruz Biotechnology, Inc.) was used as a nuclear marker. Anti-GAPDH (Rockland) was used as a cytosolic marker.
Immunocytochemistry Staining-48 h after HepG2 cells were transfected with control siRNA or PPP2CA siRNA, they were treated with 60 M lovastatin or DMSO for 6 h. They were then fixed and labeled with rabbit anti-LDLR antibody (Cayman Chemicals, Ann Arbor, MI), followed by incubation of Alexa Fluor 488-conjugated anti-rabbit secondary antibody (Invitrogen). After antibody incubation, cells were mounted with fluorescent mounting medium containing DAPI (Invitrogen) for counterstaining. Fluorescence microscopy was performed using a 20ϫ objective on a Leica DMI6000 confocal microscope, and images were processed using LAS AF software.
GFP-SREBP-2 Fluorescence Microscopy-HepG2 cells were transfected with control siRNA or PPP2CA siRNA, and 24 h later, EGFP-SREBP-2 was transfected into the cells by Lipofectamine 2000 (Invitrogen). The next day, the cells were treated with 40 M lovastatin or DMSO for 1 h. The cells were then fixed and mounted with DAPI-containing mounting buffer to visualize nuclei. The translocation of the SREBP-2 N terminus was examined by fluorescence microscopy (Leica DMI6000B).
LDL Uptake Assay-24 h after HepG2 cells were transfected with control siRNA or PPP2CA siRNA, they were washed with PBS and incubated overnight in lipoprotein-deficient medium to induce the expression of LDLR. The next day, cells were treated with 60 M lovastatin or DMSO for 6 h. LDL uptake was initiated by incubating cells grown in serum-deficient medium with 5 g/ml BODIPY-LDL (Invitrogen). Uptake of BODIPY-LDL was measured after a 30-min incubation at 37°C. Cells were fixed and mounted with fluorescent mounting medium containing DAPI (Invitrogen) for counterstaining. Intercellular BODIPY-LDL was visualized using fluorescence microscopy.
In order to IP PP2A, protein was quantified with the Bradford Assay (Bio-Rad), and 1 mg of whole cell extract was precleared with 40 l of a 50% protein G-agarose slurry (Millipore) for 2 h at 4°C. PP2A was immunoprecipitated overnight with 5 g of rat anti-PP2A (R&D Systems) at 4°C. Immunocomplexes were collected with 20 l of protein G-agarose for 1 h at 4°C. The protein G-agarose was washed two times with 1 ml of wash solution (0.05% Tween 20 in 1ϫ PBS, pH 7.2) at 4°C for 5 min. Proteins were boiled off of the agarose in 2ϫ SDS-PAGE loading buffer at 100°C for 10 min, and total IP lysate was loaded onto 10% polyacrylamide gels for Western analysis. Blots were probed for with anti-PPP2CA, anti-SREBP-2, and anti-GAPDH (Abcam). SREBP-2 was immunoprecipitated using 5 g of a SREBP-2 monoclonal antibody from Millipore. For nuclear coimmunoprecipitation, the nuclear IP kit from Active Motif was used according to the manufacturer's instructions.
Phosphorylation Analysis of SREBP-2-Cells were incubated in the absence or presence of lovastatin and either Csi or PPP2CAsi. Cell-free lysates were obtained, and total phosphothreonine-, phosphoserine-, or phosphotyrosine-phosphorylated proteins were immunoprecipitated using polyclonal antibodies against phosphothreonine, phosphoserine, or phosphotyrosine (1:1,000 dilutions) (Sigma). Immunoprecipitates were resolved by SDS-PAGE and transferred to nitrocellulose membranes. The degree of phosphorylated SREBP-2 present was determined by Western analysis, using anti-SREBP-2 polyclonal antibodies (1:250 dilution). For the corollary experiment, SREBP-2 was immunoprecipitated using anti-SREBP-2 antibodies, and the degree of phosphorylation was determined using anti-phosphoantibodies and Western analysis. Densitometry was performed using ImageQuant software.
Chromatin Immunoprecipitation Analysis of the DNA Binding Activity of SREBP-2-Cells grown in the absence or presence of statin were treated with 1% formaldehyde for 15 min at room temperature. Cross-linking was stopped by the addition of 125 mM glycine. Cells were washed, pelleted, and washed with PBS. Cells were then lysed using lysis buffer (50 mM HEPES, pH 7.5, containing 140 mM NaCl, 0.1% Triton X-100, 0.1% sodium deoxycholate, and a protease mixture) and spun down to remove cellular debris. 1 mg of the resulting supernatant was used for immunoprecipitating SREBP-2-bound DNA for 1 day at 4°C, using 5 g of anti-SREBP-2 polyclonal antibodies.
Immunoprecipitated complexes were isolated after 1 h at 4°C using protein A-agarose beads with salmon sperm DNA (Millipore). The beads were washed with lysis buffer containing 500 mM NaCl, and finally with 10 mM Tris-HCl, pH 8.0, containing 0.25 M LiCl, 0.5% Nonidet P-40, 0.5% sodium deoxycholate, followed by a wash with Tris-EDTA, pH 8.0. SREBP-2⅐DNA complexes were eluted from beads using 50 mM Tris-HCl, pH 8.0, containing 10 mM EDTA, and 1% SDS. Crosslinking was reversed using 5 M NaCl at 65°C for 6 h. Samples were then diluted using 500 mM Tris-HCl, pH 8.0, containing 10 mM EDTA and 0.67% SDS. Samples were treated with 250 g of Proteinase K for 1 h at 37°C. DNA was eluted from samples using the DNA Easy kit (Qiagen). Purified DNA was used to PCR-amplify bound DNA. PCR products were resolved by 1.5% agarose gel electrophoresis.
Cells were resuspended in 1ϫ radioimmune precipitation assay buffer and sonicated at 4°C on ice for 10 min (30-s on, 30-s off cycle). Cell debris was pelleted by centrifugation for 10 min, and cell lysates were collected and analyzed for protein content using the Bradford assay. Whole cell extract was boiled at 100°C for 10 min and loaded onto a 15% denaturing gel and run at 100 V for 90 min. Proteins were then transferred to nitrocellulose using the iBlot transfer device (Invitrogen). Blots were blocked in 5% milk-TBST prior to incubation with anti-SREBP-2 (Abcam) and secondary anti-mouse HRP. Antibodies were detected using an ECL detection kit from Millipore and a charge-coupled device camera (GE ImageQuant LAS 4000).
EMSA binding reactions were performed at room temperature for 30 min and consisted of nuclear extract in 1ϫ binding buffer (50% glycerol, 100 mM MgCl 2 , 1 g/l poly(dI-dC), 1% Nonidet P-40, 1 M KCl, 100 mM EDTA, and 5 M DNA probe). The mixture was run on 6% non-denaturing polyacrylamide gels in 1ϫ Tris borate-EDTA buffer. Protein⅐DNA complexes were then transferred to Hybond-N ϩ nylon membrane using the Trans-Blot semidry method (Bio-Rad) and cross-linked using the Spectrolinker XL-1000 UC cross-linker (Spectronics Corp.). Detection of biotin-labeled DNA was performed using the LightShift chemiluminescent EMSA kit (Thermo Scientific) and visualized by exposure to a charge-coupled device camera (GE ImageQuant LAS 4000).
For EMSA competition studies, a 10-fold molar excess of WT non-biotin-labeled forward and reverse oligonucleotides was added to the EMSA reaction mix. For the supershift assay, 6 g of SREBP-2 mouse antibody (Abcam) was added to the reaction mixture. The mixture was fractionated on a 6% non-denaturing polyacrylamide gel. Transfer and detection were performed as described above.

RESULTS
The Protein Phosphatase Inhibitor Okadaic Acid Blocks SREBP-2-dependent LDLR Gene Expression-To determine whether PP2A was required for LDLR gene expression, PP2A activity was chemically reduced using 10 nM OA, and SREBP-2 was indirectly activated using the HMGCR inhibitor, lovastatin. The relative levels of LDLR gene expression and protein were determined. PP2A phosphatase activity was decreased by Ͼ85% at this OA concentration (data not shown). The level of cell cholesterol was decreased by 30% (data not shown).
OA treatment had little effect on basal LDLR expression as determined by qRT-PCR (Fig. 1A, Control versus OA). In the presence of lovastatin, LDLR gene expression increased by ϳ2.5-fold (Fig. 1A, Control versus Lov). This -fold increase is in good agreement with previous data (32,33). No increase in expression was seen in cells treated with lovastatin and OA (Fig.  1A, Lov versus Lov OA). OA treatment had no effect on lovastatin-induced expressions of HMGCR and SREBP-2 (Fig. 1, B and C). Ldlr protein level increased ϳ3.0-fold in response to lovastatin treatment, whereas there was no increase when PP2A activity was abolished (Fig. 1, B and C). Treatment with the cholesterol-depleting agent hydroxypropyl-␤-cyclodextrin or simvastatin/atorvastatin gave similar results (not shown).
PP2A Is Required for SREBP-2-dependent Sterol Gene Expression-Because OA (Ͼ10 nM) can inhibit other protein phosphatases, PP2A activity was reduced using siRNA methods. siRNA against the ␣ catalytic subunit of PP2A was used to reduce activity (PPP2CAsi).
Overexpression of the Protein Phosphatase 2A Methylesterase Results in the Loss of PP2A-dependent LDLR Gene Expression-The catalytic subunit of PP2A is demethylated on Lys-309 by the Pme-1 demethylase (PPME1), causing a reduction in phosphatase activity (34).  To further substantiate the requirement of PP2A for LDLR expression, PPME1 or the PPP2CA catalytic subunit of PP2A was overexpressed, and LDLR expression and protein were determined. Ectopic overexpression of PPME1 resulted in ϳ7-fold overexpression of protein (Fig. 3A), whereas Ppp2ca was overexpressed by ϳ5-fold (Fig. 3B).

PP2A Is Not Required for Lovastatin-induced SREBP-2 Processing and Nuclear
Translocation-When the level of cholesterol is high, full-length SREBP-2 localizes to the endoplasmic reticulum as an inactive protein. When the level of cholesterol becomes decreased, it traffics to the Golgi (20,35), where it is proteolytically cleaved, releasing a soluble active transcription factor (SREBP-2af) that translocates to the nucleus, where it induces cholesterol gene expression by binding to SREs.
To begin to determine the step where PP2A regulates SREBP-2 activity, SREBP-2 proteolytic processing and nuclear translocation were examined in Ppp2ca-depleted cells. A nuclear fraction was used for these experiments and was purified by subcellular fractionation and ultracentrifugation. Fraction purity was assessed by Western analysis using antibodies directed against nuclear Lamin B and cytosolic Gapdh (Fig. 4).
SREBP-2af accumulated in the nucleus in response to lovastatin treatment (Fig. 4, Csi, Con versus Lov). Similar results were seen when Ppp2ca was depleted (Fig. 4, Csi Lov versus PPP2CAsi Lov). A higher basal level of SREBP-2af was observed in the nucleus in the absence of Ppp2ca and lovastatin (Fig. 4, PPP2CAsi versus Csi). Based on this result, we cannot definitively rule out the possibility that PP2A does not have a negative role in proteolytic processing. However, there was an additional increase in SREBP-2af nuclear localization in the presence of lovastatin and absence of Ppp2ca. Moreover, LDLR gene expression was not increased in the absence of lovastatin in Ppp2ca-depleted cells (Fig. 2).
To further show that SREBP-2af translocates to the nucleus in the absence of Ppp2ca, the localization of a N-terminal fulllength GFP-SREBP-2 was visualized by fluorescence microscopy, in the absence and presence of Ppp2ca and lovastatin. SREBP-2 nuclear translocation and function was also assessed indirectly by determining the degree of LDL-C uptake using fluorescence microscopy. HepG2 cells were grown in the absence (Con) or presence of lovastatin (Lov). Cells were treated with 100 nM non-targeting siRNA (Csi) or siRNA directed against the catalytic subunit of PP2A (PPP2CAsi) at 48 and 24 h prior to lovastatin treatment. 75 M lovastatin was added for 24 h, and cells were harvested. Cells were lysed and centrifuged as described under "Experimental Procedures" in order to obtain nuclear fractions. Cell protein was resolved by SDS-PAGE, and proteins were detected using Western analysis. Lamin was used as a nuclear marker. Gapdh was used as a non-nuclear marker. SREBP-2af, cleaved SREBP-2. A, non-nuclear fraction. B, nuclear fraction. In untreated control cells, GFP-SREBP-2 localized to a perinuclear organelle (Fig. 5, control) that co-stained with the ER marker, PDI (not shown). Upon the addition of lovastatin, fulllength GFP-SREBP-2 was cleaved, and GFP-SREBPaf translocated to the nucleus (Fig. 5, Control ϩ Lov). Similar results were obtained using cells transfected with a control siRNA (Fig. 5, Csi versus Csi ϩLov). The loss of the Ppp2ca had no effect on SREBP-2af translocation in the presence of lovastatin (Fig. 5, PPP2CAsi versus PPP2Asi ϩ Lov). Greater than 90% of transfected cells had the localization patterns shown.
LDL-C Uptake Requires PP2A-LDL-C uptake was assayed using the fluorescence-labeled lipid, BODIPY-LDL. In the absence of lovastatin, control cells had little BODIPY-LDL staining (Fig. 6, Csi ϪLov). Upon the addition of lovastatin, a drastic increase was seen in intercellular BODIPY-LDL staining, indicative of increased LDL-C uptake (Fig. 6, Csi ϩLov). Loss of Ppp2ca resulted in loss of BODIPY-LDL uptake in the presence of lovastatin (Fig. 6, PPP2CAsi ϪLov versus PPP2CAsi ϩLov).
PP2A Is Required for SREBP-2 DNA Binding to a LDLR SRE in Response to Lovastatin Treatment-The fact that SREBP-2af translocated to the nucleus in the absence of Ppp2ca indicated that its function was regulated at a point downstream of transport and nuclear entry, quite possibly at the point of promoter binding. Thus, SREBP-2af SRE promoter binding was assayed in the absence and presence of Ppp2ca and lovastatin using ChIP and EMSA.
ChIP analyses revealed that under basal conditions, Ppp2ca depletion slightly altered SREBP-2af binding to a LDLR promoter SRE in the absence of lovastatin, when compared with untreated cells (Fig. 7, A and B

, Csi ϪLov versus PPP2CAsi
ϪLov). Whereas a 5-fold increase in binding was seen in the presence of both lovastatin and Ppp2ca (Fig. 7, A and B
EMSA analysis was next performed using wild type and mutant LDLR SREs. Under cholesterol-rich conditions in the presence of Ppp2ca, SREBP-2af displayed a low basal level of binding to the WT SRE (Fig. 8A, Con Ppp2ca, lane 3). Binding was seen as a doublet. The binding was specific because no FIGURE 6. LDL-C uptake is defective in cells lacking Ppp2ca. HepG2 cells were transfected with control siRNA (Csi) or siRNA directed against the catalytic subunit of PP2A (PPP2CAsi) and were incubated for 16 h in lipoprotein-deficient medium to induce the expression of Ldlr. Cells were treated with 60 M lovastatin or DMSO for 6 h. LDL-C uptake was initiated by incubating cells with 5 g/ml BODIPY-LDL. Uptake of BODIPY-LDL was measured after 30 min at 37°C. Cells were fixed and mounted with fluorescent mounting medium containing DAPI for counterstaining. Intercellular BODIPY-LDL was visualized using fluorescence microscopy. FIGURE 7. Loss of Ppp2ca causes a reduction in SREBP-2 LDLR SRE binding. Cells transfected with control siRNA (Csi) or siRNA directed against the catalytic subunit of PP2A (PPP2CAsi) were grown for 6 h in the absence (ϪLov) or presence (ϩLov) of lovastatin. Cells were then treated with 1% formaldehyde to cross-link SREBP-2 to DNA. The cross-linking reaction was terminated, and SREBP-2⅐DNA complexes were isolated using anti-SREBP-2 polyclonal antibodies. SREBP-2⅐DNA cross-links were disrupted using 5 M NaCl. A, amount of SREBP-2-bound DNA determined by PCR amplification and agarose gel electrophoresis. B, relative densitometry unit ratio of SREBP-2 SRE binding versus IgG binding. 10% of input, loading control; IgG, negative control. Error bars, S.E.
binding was seen to a mutated SRE (mutant) (Fig. 8A, Con  Ppp2ca, lane 4). The addition of excess unlabeled probe eliminated binding to the wild type SRE (Fig. 8A, Con Ppp2ca, lane  5). The addition of anti-SREBP-2 antibodies to the reaction caused an increase in band intensity (Fig. 8A, Con Ppp2ca, lane  7). This type of result, where the addition of antibody does not result in a supershift, still indicates specific binding and has been previously observed (36,37). Binding was specific because no binding was observed to a mutated SRE in the presence of antibody (Fig. 8A, Con Ppp2ca, lane 8). Finally, the addition of anti-GAPDH antibodies to the labeled probe did not result in the appearance of bands (Fig. 8A, Con Ppp2ca, lane 9).
Loss of PP2A Does Not Alter the Half-life of SREBP-2-One possibility to explain the loss of SRE binding is that SREBP-2 is degraded much faster in the absence of Ppp2ca. To address this question, the half-lives of nuclear SREBP-2 were determined in the presence and absence of lovastatin and Ppp2ca. In the absence of lovastatin and presence of Ppp2ca, SREBP-2af was degraded over a period of 8 h, with a half-life of ϳ4 h (Fig. 9, A and B, Con, ϪLov). In contrast, SREBP-2 accumulated in the presence of both lovastatin and Ppp2ca (Fig. 9, A and B, Con, ϩ Lov). Similar results were observed in the absence of Ppp2ca (Fig. 9, A and C, PPP2si, ϮLov). Thus, the loss of SRE binding seen in the ChIP and EMSA studies was not due to increased degradation of SREBP-2 protein.
PP2A Binds SREBP-2-Co-immunoprecipitation was next used to determine whether Ppp2ca directly bound to SREBP-2af. Ppp2ca was immunoprecipitated, interacting proteins were resolved by SDS-PAGE, and Western analysis was used to detect SREBP-2af association. 10% inputs used in the co-immunoprecipitation experiments are shown in Fig. 9, A and D.
SREBP-2af was efficiently pulled down by Ppp2ca antibodies (Fig. 10B) but not the IgG antibody control. The Ppp2ca-SREBP-2af interaction was detected at all time points and in control and lovastatin-treated samples (not shown). Identical results were obtained when SREBP-2 antibodies were used to pull down Ppp2ca (Fig. 10C). SREBP-2af was also able to pull down the A subunit of PP2A, Ppp2r1a (not shown). If Ppp2ca directly regulates nuclear SREBP-2af DNA binding, then it should associate with SREBP-2af in the nucleus. Nuclear SREBP-2af was efficiently co-immunoprecipitated in the absence or presence of lovastatin using Ppp2ca antibodies (Fig. 10E). SREBP-2 antibodies were able to pull down nuclear Ppp2ca (Fig. 10F).
Loss of PP2A Alters the Phosphorylation State of SREBP-2af-The direct interaction between Ppp2ca and SREBP-2af suggests that PP2A may modulate SREBP-2af phosphorylation status, causing changes in DNA binding. If this is the case, then the phosphorylation status of SREBP-2af should be altered in cells lacking Ppp2ca. Phosphorylated proteins were immunoprecipitated using phosphospecific antibodies, and SREBP-2af phosphorylation was determined by Western analysis using anti-SREBP-2 antibodies.
For all experiments, 1) an equal level of SREBP-2af was used, 2) PPP2CAsi knockdown efficiency was Ͼ90%, 3) IgG immunoprecipitation experiments were used to demonstrate specificity, and 4) the specificity of each phosphoantibody was validated using phosphospecific blockers. 4 In the absence of lovastatin, cells had a basal level of serine phosphorylation in the absence of lovastatin, which decreased 10-fold upon the addition of drug (Fig. 10A, Csi versus Csi ϩ Lov). Threonine phosphorylation was absent in untreated cells but increased 3-fold in lovastatin-treated cells (Fig. 10B, Csi versus Csi ϩLov).
In cells lacking Ppp2ca, the basal levels of SREBP-2af serine and threonine phosphorylation were increased in the absence of lovastatin (Fig. 11, A and B, PP2Asi ϪLov), whereas both serine (12-fold) and threonine (7-fold) phosphorylation increased in Ppp2ca-depleted drug-treated cells (Fig. 11, A and B, PPP2CAsi, ϪLov versus PPP2CAsi ϩLov). No tyrosine phosphorylation was seen under all conditions (Fig. 11C). Similar results were obtained when SREBP-2 antibodies were used and Western analysis was performed using phosphospecific antibodies (not shown). Thus, the loss of Ppp2ca activity resulted in changes in the phosphorylation status of SREBP-2af that correlate with a loss of DNA binding and reduced LDL uptake.

DISCUSSION
The data show that PP2A regulates SREBP-2 activity and LDL-C uptake. Depletion of Ppp2ca resulted in the loss of 4 M. Villasmil and J. T. Nickels, unpublished data. FIGURE 9. Loss of Ppp2ca has no effect on SREBP-2 half-life. HepG2 cells were transfected with 100 nM control siRNA (Con) or siRNA directed against the catalytic subunit of PP2A (PPP2CAsi) at Ϫ48 and Ϫ24 h in the absence (ϪLov) and presence (ϩLov) of lovastatin treatment. Cells were treated with 75 M lovastatin for 24 h. Cells were treated with 5 g/ml cyclohexamide for the indicated times, harvested, and stored at Ϫ80°C until processing. Whole cell extracts were resolved using a 15% denaturing SDS-PAGE gel. Proteins were transferred to nitrocellulose and incubated with SREBP-2 antibodies. Protein was detected using ECL chemiluminescence. Actin, loading control.  Nuclear extracts were obtained as described under "Experimental Procedures." Ppp2ca was immunoprecipitated (IP) using rat anti-Ppp2ca polyclonal antibodies. SREBP-2 was immunoprecipitated using SREBP-2 antibodies. Immunoprecipitated proteins were resolved by SDS-PAGE, and proteins were detected using Western analysis (WB). A, 10% of the whole cell extract used. B, immunoprecipitation of SREBP-2 using anti-Ppp2ca antibodies. C, immunoprecipitation of Ppp2ca using SREBP-2 antibodies. D, 10% of the nuclear extract used. E, immunoprecipitation of SREBP-2 using anti-Ppp2ca antibodies. F, immunoprecipitation of Ppp2ca using SREBP-2 antibodies. IgG, negative control.
SREBP-2-dependent gene expression and SREBP-2af binding to an LDLR SRE promoter element. Ppp2ca regulation was specific to LDLR because the expressions of several other SREBP-2af genes were not affected. Loss of SREBP-2af binding was not due to increased degradation because the half-life of SREBP-2af was equivalent in the absence or presence of Ppp2ca. Ppp2ca regulated SREBP-2af SRE binding through a direct interaction that caused the dephosphorylation of several phosphoresidues required for function. Based on these data, we conclude that PP2A directly regulates SREBP-2af by regulating the phosphorylation status of serine/threonine residues required for DNA binding, LDLR gene expression, and LDL-C uptake.
Several phosphorylation events regulate SREBP function, where activity is stimulated or inhibited depending on the targeting kinase (38 -47). For instance, ERK1/2-dependent SREBP-2 phosphorylation of Ser-455 increases its activity by blocking a sumoylation event inhibiting binding to the co-repressor, HDAC3. Glycogen synthase kinase-3␤ phosphorylation of SREBP-1a on Thr-426 and Ser-430 initiates its degradation when bound to promoter regions of sterol-responsive genes, through targeting it for ubiquitin-dependent SCF-mediated degradation. AMP-activated protein kinase kinase inhibits SREBP-1c activity by phosphorylating Ser-372 within the soluble active fragment (48). Ser-117 on SREBP-1a is a major phosphorylation site for MAPK signaling (41). Thus, multiple phosphorylation events fine tune the activity of SREBPs. Which of these sites represent PP2A substrates needs to be elucidated to fully understand the depth of SREBP-2 regulation.
It is interesting that PP2A may only regulate SREBP-2. Differential specificities in the promoters of many sterol-responsive genes exist, including the LDLR, HMGCR, and HMGS promoters (49). All display heterogeneity in their response to SREBP-1/SREBP-2 activity, by varying the number or sequence of various SREs or specific co-factor binding sites (50 -54). The LDLR promoter responds to various signals based on the presence of multiple binding elements (55,56), which includes the serum response, Sp1, repeat 3, Egr1, and C/EBP␤ elements (56,57). Thus, PP2A may have a specific role in regulating cholesterol homeostasis through specific regulation of LDLR expression and LDL-C uptake.
PP2A regulates several metabolic processes. For example, it targets the basic helix-loop-helix leucine zipper carbohydrate-binding element-binding protein transcription factor (ChREBP). ChREBP target genes include those activating glycolysis, lipogenesis, and glucogenesis pathways (58), which contribute to the onset of metabolic syndrome (59). Although PP2A does activate ChREBP, possibly increasing the severity of metabolic syndrome, it has also been demonstrated that loss of PP2A through FoxO transcription factor inhibition may contribute to the onset of metabolic syndrome (60). These results indicate that PP2A activity is fine tuned in response to changes in global metabolism because those individuals with metabolic syndrome present with multiple maladies, including glucose intolerance or full-blown diabetes, high blood cholesterol level, obesity, and hypertension.
The PP2A AC dimer may always be bound to SREBP-2. Differential regulation may arise from the binding and release of different B subunits. It is unlikely that a single heterotrimeric species regulates nuclear transport, DNA binding, and transactivation. We have observed several B subunits accumulating in response to cholesterol depletion. 5 It also makes sense that the expression of various B subunits be regulated through changes in cholesterol level. If multiple PP2A subpopulations are generated, depending on metabolic state, they can be turned on or off, depending on cholesterol level. A recent report showed that multiple PP2A subunits were regulated at the transcriptional, translational, and post-translational levels in myocytes (61).
Another possibility to explain phosphatase specificity is based on an emerging model suggesting that PP2A B subunits can act as "scaffolds" that enable AC dimer binding to a substrate under specific physiological conditions (62,63). The B subunit is associated with a substrate alone and recruits the AC dimer at the appropriate time. The B56␤ subunit complexes with Akt in the absence of the AC dimer and then recruits it to AKT upon insulin signaling (63). In the yeast Saccharomyces cerevisiae, the PP2A B subunit, ScCdc55, possesses an activity that may be separate from its association with a PP2A holoenzyme (64 -66). We have recently found that a single B subunit is associated with SREBP-2 in mouse liver independent of the AC dimer. 6 The "scaffold" model is still highly speculative and awaits further validation.
Finally, PP2A binding altered the phosphorylation status of SREBP-2af. Although most phosphorylation events regulating 5 L. Rice and J. T. Nickels, unpublished data. 6 B. Joseph, D. Pandya, and J. Nickels, manuscript in preparation. SREBP activity cause increased protein degradation or induce the transactivation activity of promoter-bound protein, some exceptions exist. Very recently, AMP kinase was found to phosphorylate nuclear SREBP-2af, causing a decrease in SREBP-2dependent gene expression (48). Moreover, it was shown that PKA phosphorylation of SREBP-1a/SREBP-1c reduces DNA binding (42). Whether these sites are PP2A targets remains to be elucidated.