Protein Phosphatase 2A Regulatory Subunit B56{alpha} Associates with c-Myc and Negatively Regulates c-Myc Accumulation

Protein phosphatase 2A (PP2A) plays a prominent role in controllingaccumulation of the proto-oncoprotein c-Myc. PP2A mediates itseffects on c-Myc by dephosphorylating a conserved residue thatnormally stabilizes c-Myc, and in this way, PP2A enhances c-Mycubiquitin-mediated degradation. Stringent regulation of c-Myclevels is essential for normal cell function, as c-Myc overexpressioncan lead to cell transformation. Conversely, PP2A has tumorsuppressor activity. Uncovering relevant PP2A holoenzymes fora particular target has been limited by the fact that cellularPP2A represents a large heterogeneous population of trimericholoenzymes, composed of a conserved catalytic subunit and astructural subunit along with a variable regulatory subunitwhich directs the holoenzyme to a specific target. We now reportthe identification of a specific PP2A regulatory subunit, B56 ${alpha}$ ,that selectively associates with the N terminus of c-Myc. B56 ${alpha}$ directs intact PP2A holoenzymes to c-Myc, resulting in a dramaticreduction in c-Myc levels. Inhibition of PP2A-B56 ${alpha}$ holoenzymes,using small hairpin RNA to knock down B56 ${alpha}$ , results in c-Mycoverexpression, elevated levels of c-Myc serine 62 phosphorylation,and increased c-Myc function. These results uncover a new proteininvolved in regulating c-Myc expression and reveal a criticalinterconnection between a potent oncoprotein, c-Myc, and a well-documentedtumor suppressor, PP2A.

INTRODUCTION

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Introduction

c-Myc is a transcription factor responsible for regulating awide array of genes involved in cellular proliferation, growth,apoptosis, and differentiation. A number of experiments havedemonstrated both the requirement for c-Myc and the importanceof tightly regulating c-Myc protein levels for normal cellularfunction. For instance, lymphocytes and fibroblasts deletedfor c-Myc cease to proliferate and exit the cell cycle (12,64). Furthermore, homozygous deletion of the c-myc gene resultsin embryonic lethality in mice (11). On the other hand, sustainedoverexpression of c-Myc in cultured cells blocks differentiation,induces neoplastic transformation, and can initiate apoptosiswhen survival factors are limiting (14). A wide array of naturallyoccurring tumors overexpress c-Myc, due in part to chromosomaltranslocations, amplification, and viral insertions at the c-myclocus (8, 19). Most notably, in mice with inducible c-myc transgenes,expression of c-Myc results in neoplastic premalignant and malignantphenotypes, while withdrawal of c-Myc causes spontaneous regressionof the neoplastic and malignant changes (15, 47). All of thesestudies highlight the importance of understanding the mechanismas well as identifying the players involved in regulating c-Mycprotein levels with respect to normal and neoplastic contexts.

c-Myc expression is controlled at many levels, including genetranscription, mRNA stability, and posttranslational controlof protein stability (17, 26, 29). Posttranslational regulationof c-Myc occurs through several Ras effector pathways that controla series of sequential phosphorylation events on two highlyconserved residues, threonine 58 (T58) and serine 62 (S62) (56,57, 77). These two phosphorylation sites exert opposing affectson c-Myc protein stability, with S62 phosphorylation stabilizingc-Myc and T58 phosphorylation destabilizing c-Myc. Furthermore,T58 phosphorylation requires prior S62 phosphorylation (35,57). Upon exit from quiescence, during early G₁ phase, c-Mycis stabilized by phosphorylation on S62 that can be mediatedby the Ras-activated extracellular regulated kinase. Concurrentactivation of phosphatidylinositol 3-kinase (PI3K) by Ras canlead to inhibition of glycogen synthase kinase-3ß(GSK-3ß), which is a negative regulator of c-Myc proteinlevels. In late G₁, when PI3K activity decreases, c-Myc canbecome phosphorylated on T58 by active GSK-3ß. Thisdually phosphorylated form of c-Myc associates with the phosphorylation-directedprolyl isomerase, Pin1, which can catalyze a cis-to-trans conformationalchange in the phospho-S62-P63 peptidyl bond of c-Myc. This formof c-Myc is then a target for protein phosphatase 2A (PP2A),which dephosphorylates S62, resulting in an unstable, singlyT58-phosphorylated form of c-Myc that is a substrate for ubiquitinationby SCF^Fbw7 and degradation by the 26S proteosome (72, 74, 77).

PP2A is a heterotrimeric protein with two common components,a structural (A) subunit and catalytic (C) subunit forming the"catalytic core," with which a variable regulatory (B) subunitassociates. To date, 25 different B subunits have been identified,which fall into four unrelated families: B, B', B", and B'''.In total, it is estimated that there are 75 to 100 differentPP2A holoenzymes, which are responsible for 30 to 50% of thetotal cellular serine/threonine dephosphorylation activity,depending on cell type. PP2A has been shown to be involved inregulating proliferation, growth, differentiation, and apoptosis(25). Similar to the case for c-Myc, PP2A activity is requiredfor normal cellular function, as shown by a catalytic (C ${alpha}$ ) subunitknockout mouse model that results in death at embryonic day5.5 to 6 (18). However, unlike c-Myc, PP2A is generally regardedas a tumor suppressor. Global inhibition of PP2A activity resultsin increased cellular transformation (55). Despite the importanceof PP2A as a tumor suppressor, relatively few oncogenic PP2Atargets have been identified. Moreover, specific PP2A holoenzymesthat target these oncoproteins have not been well described.

We now report the identification of a specific PP2A holoenzymecontaining the regulatory B subunit, B56 ${alpha}$ , that associates withc-Myc. We demonstrate that the PP2A-B56 ${alpha}$ holoenzyme interactswith the trans-activation domain of c-Myc containing the S62residue, which we previously reported to be dephosphorylatedby PP2A (77). This interaction negatively regulates both c-Mycprotein levels and activity. Given the potent oncogenic natureof c-Myc and the observed tumor suppressor function of PP2A,identification of the PP2A-B56 ${alpha}$ holoenzyme as a c-Myc regulatoryprotein adds to our understanding of two important cell regulatorypathways.

MATERIALS AND METHODS

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Materials and Methods

Plasmids and RNA interference (RNAi). Construction of expression plasmids cytomegalovirus (CMV)-empty,CMV-ßgal, CMV-Myc, pCEP-small-T-antigen, pD40-His/V5-c-Myc,pD40-His/V5-c-Myc^T58A, and pD40-His/V5-c-Myc^S62A, as well asreporter constructs, E2F2-Luc, and E2F2(-E-box)-Luc, have beenpreviously described (58, 77). pD40-His/V5-c-Myc^T58E and pD40-His/V5-c-Myc^S62Dwere generated using mutation primers (see the supplementalmaterial) and TOPO cloning (Invitrogen) into pDEST40 mammalianexpression vector (58, 77). pD40-His/V5-c-Myc^TAD was createdby digesting CMV-Myc with PstI to remove amino acids 40 to 179,containing the transactivation domain, followed by TOPO cloninginto pDEST40. CMV-HA-Myc was made by PCR amplifying the C terminusof c-Myc to include an in-frame hemagglutinin (HA) tag (seethe description of primers in the supplemental material). ThisPCR product was used to replace the existing C terminus of c-Mycin CMV-Myc by restriction cloning using SacII and XbaI sites.pD30-PP2A-FLAG-A, pD30-PP2A-HA-C, pD40-His/V5-B55 ${alpha}$ , and pD40-His/V5-B56 ${alpha}$ were created by PCR amplification of gene coding sequences froma liver cDNA library followed by TOPO cloning into either pDEST30mammalian expression vector (PP2A-FLAG-A and PP2A-HA-C) or pDEST40mammalian expression vector (B55 ${alpha}$ and B56 ${alpha}$ ). Expression vectorsfor pCEP4HA-B56 ${alpha}$ , -ß, - ${gamma}$ 1, - ${gamma}$ 3, - ${delta}$ 1, and ${varepsilon}$ were a generousgift from David Virshup (Huntsman Cancer Institute, Universityof Utah). The pCAN-E4orf4 expression vector was kindly providedto us by Clodagh O'Shea (University of California, San Francisco).

Small interfering RNA (siRNA) SMARTpools for scramble control,PP2A-C ${alpha}$ (PPP2CA), and B55 ${alpha}$ (PPP2R2B), were purchased from Dharmacon(Lafayette, CO). Small hairpin RNA (shRNA) expression vectorswere generated using OligoEngine (Seattle, WA) software to identifytarget sequences to each of PP2A-A, B56 ${alpha}$ , -ß, - ${gamma}$ , - ${delta}$ ,and - ${varepsilon}$ (see the description of target sequences in the supplementalmaterial). Oligonucleotides encoding the sense and antisenseshRNA sequences were cloned into the pSUPER-shRNA expressionvector (OligoEngine) by the manufacturer's protocol.

Cell lines and transfection. HEK-293 cells were maintained in Dulbecco's modified Eagle'smedium (DMEM) supplemented with 10% characterized fetal bovineserum (FBS), L-glutamine, and penicillin-streptomycin at 37°Cand 5% CO₂. Cells were plated to achieve 60 to 80% confluenceat 24 h postsplit for transfection. SMARTpool siRNA transfectionswere carried out as previously described (77). All other transfectionswere performed using Metafectene (Biontex, Germany) accordingto manufacturer's specifications at a 3:1 ratio of transfectionreagent to DNA (75 to 80% efficiency). Total transfected DNA(2 to 6 µg) was held constant by the addition of emptycontrol plasmid. All transfections included 50 ng of CMV-ßgalto assess transfection efficiencies between experimental conditions.Transfected cells were maintained in DMEM supplemented with10% FBS and L-glutamine, except in shRNA experiments, in whichthey were maintained in 2% or 0.2% FBS and L-glutamine for theindicated time periods.

Antibodies. The c-Myc antibodies, N262, and agarose-conjugated C-33 werepurchased from Santa Cruz Biotechnology (Santa Cruz, CA). HA.11and PP2A-A 6F9 antibodies were from Covance (Berkeley, CA).The rabbit polyclonal antibody to HA tag (rabHA) was obtainedfrom Abcam (Cambridge, MA). The PP2A-C ${alpha}$ antibody was purchasedfrom BD Biosciences (San Jose, CA). The V5 antibody was fromInvitrogen (Carlsbad, CA), and the M2-FLAG and ß-tubulinantibodies were from Sigma (St. Louis, MO). The c-Myc serine62 phospho-specific antibody ( ${alpha}$ S62phospho) was generated as previouslydescribed (57). The threonine T58 phospho-specific antibody( ${alpha}$ T58phospho) was purchased from Cell Signaling Technology (Beverly,MA), and specificity is achieved by blocking with milk (see"Western blotting and quantitation" below). The PP2A-B' ${alpha}$ antibodywas obtained from Upstate (Lake Placid, NY).

Western blotting and quantitation. Transfected cells were lysed in 10 volumes 1.5x luciferase bufferfrom Promega (Madison, WI) with protease and phosphatase inhibitors(10 mM sodium fluoride, 100 mM sodium vanadate, 10 mM ß-glycerolphosphatedisodium pentahydrate, 1 µg/ml aprotinin, 1 µg/mlpepstatin, 0.5 µg/ml leupeptin, 0.2 mg/ml AEBSF [4-(2-aminoethyl)benzenenesulfonylfluoride hydrochloride], and 1.6 mg/ml iodoacetamide). Lysateswere freeze-thawed three times, incubated on ice for 20 min,and subjected to ß-galactosidase (ß-gal)activity analysis as described previously (58). Five times sodiumdodecyl sulfate sample buffer was added to a final concentrationof 1.5x. Sample load volumes were adjusted by ß-galactivity to account for transfection efficiency, separated bysodium dodecyl sulfate-polyacrylamide gel electrophoresis, andtransferred to Immobilon-FL (Millipore, Billerica, MA). Membraneswere blocked in Odyssey Block buffer (LI-COR Biosciences, Lincoln,Nebraska), except when probed with anti-threonine 58 phospo-specificantibody, which used 5% nonfat milk in phosphate-buffered saline(PBS) for blocking. Primary antibodies were diluted in 1:1 OdysseyBlock buffer-PBS, 0.05% Tween or 2.5% milk in PBS, or 0.05%Tween (P-T58 antibody) at the indicated dilutions. Primary antibodieswere detected with the secondary anti-mouse and anti-rabbitnear-infrared fluorescent dyes Alexa Fluor 680 (Molecular Probes,Eugene, OR) and IRDye800 (Rockland, Philadelphia, PA) used ata 1:10,000 dilution in 1:1 Odyssey Block buffer-1x PBS, 0.05%Tween or 2.5% nonfat milk in PBS, or 0.05% Tween (P-T58 antibody).Immunoblots were scanned using a LI-COR (Lincoln, Nebraska)Odyssey Infrared Imager to visualize proteins, which also allowsfor simultaneous anti-rabbit and anti-mouse dual-wavelengthdetection.

Antibody signals were quantified using LI-COR Odyssey InfraredImager software version 1.2, which allows for linear signalquantitation over four orders of magnitude. Quantitated proteinlevels were normalized to control protein levels, which wereset to onefold or 100% as indicated. Average protein levelsand error bars representing two standard deviations were calculatedfrom three separate experiments using Excel (Microsoft, Redmond,WA). Significant differences were also calculated from threeseparate experiments by t-test analysis (two-tailed distributionand two-sample unequal variance) using Excel.

Reverse transcription-PCR (RT-PCR) analysis. Transfected HEK-293 cells were collected in 1x PBS with 1 mMEDTA, and 5% of the cells were reserved for ß-galassay and Western analysis. RNA was isolated from cells exhibitingtransfection efficiencies within 5% of each other using TRIzolreagent from Invitrogen (Carlsbad, CA). cDNA was made usingMoloney murine leukemia virus reverse transcriptase accordingto manufacturer's protocol (Invitrogen). Two times ImmunomixRed from BIOLINE (Randolph, MA) was used for PCR analysis ofcDNA (see the supplemental material for the primer sequenceand thermocycler setup).

Cycloheximide half-life. One-hundred-millimeter dishes of HEK-293 cells were cotransfectedwith 50 ng CMV-ßgal, 0.5 µg pD40-His/V5-c-Myc,and 4 µg pSUPER-empty or B56 ${alpha}$ under 10% FBS conditionsfor 24 h. Each transfection mixture was split into six 60-mmdishes, maintained for 24 h in DMEM supplemented with 10% FBSand L-glutamine, and then starved in DMEM supplemented with0.2% FBS and L-glutamine for 48 h. Cells were treated with 100µg/ml cycloheximide 5 min prior to starting the indicatedtime course, and cells were collected at the indicated points.

Coimmunoprecipitation. Cells were resuspended in 10 cell pellet volumes of PP2A-CoIPbuffer (20 mM Tris, pH 7.5, 12.5% glycerol, 0.2% NP-40, 200mM NaCl, 1 mM EDTA, 1 mM EGTA, and 1 mM DTT plus protease andphosphatase inhibitors). Cellular lysates were incubated onice for 20 min and cleared by centrifugation at 20,000 x g for10 min at 4°C. Cleared lysate volumes were adjusted fortransfection efficiency by ß-gal assay and incubatedwith either a 1:150 dilution of agarose-conjugated C-33, a 1:500dilution of HA.11, or a 1:750 dilution of V5 antibody. Immunoprecipitateswere washed three times with 10 volumes PP2A-CoIP buffer. Wherespecified, immunoprecipitates were more stringently washed threetimes with 10 volumes PP2A-CoIP buffer with 300 mM NaCl.

His-Myc-Ni-NTA columns. Cells transfected with 6 µg pD40-His/V5-conrol, -Myc,or -Myc^TAD were resuspended in 10 cell pellet volumes Ni-nitrilotriaceticacid (Ni-NTA) lysis buffer (see the supplemental material).Cell lysates were then sonicated using a Branson Sonifier 450sonicator (10 1-s pulses at 20% duty and output of 2), incubatedon ice for 20 min, and cleared by centrifugation at 14,000 rpmfor 10 min at 4°C. Cleared lysate volumes were adjustedfor transfection efficiency according to ß-gal activity.QIAGEN (Valencia, CA) Ni-NTA beads were added to cleared lysatesand rotated for 4 hours at 4°C. Ni-NTA columns were washedthree times with 10 volumes Ni-NTA CoIP buffer (see the supplementalmaterial). Cells transfected with 6 µg pD30-PP2A-HA-Cwere resuspended in 10 cell pellet volumes Ni-NTA CoIP buffer,incubated on ice for 20 min, and cleared by centrifugation.Ni-NTA columns were incubated with PP2A-HA-C cleared lysatefor 4 hours at 4°C and then washed three times with 10 volumesNi-NTA wash buffer (see the supplemental material). Column-boundproteins were released by three 0.5-volume elutions with Ni-NTAelution buffer (see the supplemental material).

Luciferase assay. Cell pellets were resuspended in 10 volumes 1.5x luciferasebuffer with protease and phosphatase inhibitors, freeze-thawedthree times, incubated on ice for 20 min, and cleared by centrifugationat 14,000 rpm for 10 min at 4°C. Samples were subjectedto ß-gal activity analysis. Luciferase activity wasdetected using a Promega luciferase assay kit and Berthold luminometer(Bundoora, Australia). Luciferase activity was adjusted forß-gal activity.

RESULTS

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Results

Increased PP2A activity downregulates c-Myc protein levels, dependent upon PP2A holoenzyme formation. We previously demonstrated that global inhibition of PP2A stronglystabilizes c-Myc protein, allowing it to accumulate to highlevels (77). These experiments relied on a variety of mechanismsfor inhibiting PP2A activity, including chemical inhibitionwith okadaic acid, which inhibits the catalytic C subunit ofPP2A (16); expression of simian virus 40 (SV40) small T antigen,which competitively inhibits regulatory B subunit binding tothe structural A subunit (7, 41, 45, 62); and RNAi knockdownof the catalytic C subunit (77). To further characterize therole of PP2A in regulating c-Myc protein levels, we examinedthe effects of increasing cellular PP2A activity on c-Myc proteinlevels. We coexpressed c-Myc with increasing amounts of a stable,functional, N-terminally HA-tagged PP2A catalytic (PP2A-HA-C)subunit (2, 69). As shown in Fig. 1A and B, increasing amountsof PP2A-HA-C partially reduced c-Myc protein levels. Interestingly,the reduction was initially dose dependent (up to twofold moretransfected PP2A-HA-C subunit relative to c-Myc), but no furthersignificant decrease in c-Myc protein levels was seen with higherconcentrations of PP2A-HA-C (compares lanes 1 to 3 with lanes4 to 5 and graph).

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FIG. 1. c-Myc protein levels are negatively regulated by PP2A holoenzyme activity. (A) Increased cellular PP2A activity decreases c-Myc protein levels. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 0.5 µg pD40-His/V5-c-Myc, and increasing amounts from 0.5 µg to 2.5 µg of pD30-PP2A-HA-C, as indicated. Whole-cell lysates were collected at 36 h posttransfection, normalized for transfection efficiency by ß-gal activity, and visualized by Western blot analysis with anti-V5 for c-Myc, anti-PP2A-C ${alpha}$ for total endogenous and ectopic PP2A-C, and anti-HA.11 for ectopic PP2A-HA-C. (B) Limited reduction of c-Myc protein levels by increased expression of PP2A-C subunit. c-Myc and PP2A-HA-C protein levels were quantified from panel A and two repeat experiments using LI-COR software (see "Western blotting and quantitation" in Materials and Methods). Average protein levels and error bars were calculated and graphed relative to the maximum level seen for c-Myc or PP2A-HA-C. (C) PP2A holoenzyme formation is required to negatively regulate c-Myc protein levels. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 0.5 µg CMV-Myc, or 0.5 µg pCEP-SV40 small T antigen, plus either 1.5 µg or 2.5 µg of pD30-PP2A-HA-C, as indicated. Whole-cell lysates were prepared and normalized as for panel A. Immunoblots were probed for c-Myc with anti-N262 and for PP2A-HA-C with anti-HA.11. (D) Adenovirus E4orf4 expression causes an increase in c-Myc protein levels. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 0.5 µg CMV-Myc and increasing amounts from 0.5 µg to 2.5 µg of pCAN-E4orf4, as indicated. Lysates were prepared and normalized as for panel A, and c-Myc protein was visualized by Western blot analysis with anti-N262.

The limited capacity of PP2A-HA-C activity to reduce c-Myc proteinlevels suggests that some aspect of PP2A biology is limiting.Most likely this limiting factor is related to PP2A holoenzymeformation, which involves association of the PP2A-A and -C subunitswith a variable regulatory B subunit that specifies substraterecognition. This hypothesis prompted us to determine whetherformation of the heterotrimeric PP2A holoenzyme was requiredto negatively regulate c-Myc protein levels. To test this, weinhibited PP2A holoenzyme formation by expressing SV40 smallT antigen. We then coexpressed increasing amounts of PP2A-HA-Cto determine whether the uncomplexed PP2A-HA-C subunit couldnegatively regulate c-Myc protein levels. Consistent with ourresults with murine fibroblasts (77), SV40 small T antigen expressionincreased c-Myc protein levels in human HEK-293 cells (Fig.1C, compare lanes 1 and 2). However, addition of PP2A-HA-C nolonger reduced c-Myc protein expression, at levels previouslyshown to maximally reduce c-Myc (Fig. 1C, lanes 3 and 4, comparedto A). It is important to note that SV40 small T antigen expressionreportedly does not affect PP2A-C subunit catalytic activity(76). These results strongly suggest that the PP2A-HA-C subunitmust incorporate into a PP2A holoenzyme in order to negativelyregulate c-Myc protein levels. Consequently, identifying theregulatory B subunit(s) that directs PP2A activity towards c-Mycis critically important to further understand the mechanismby which PP2A regulates c-Myc protein levels.

Adenovirus E4orf4 expression results in increased c-Myc protein levels. To limit the number of potential regulatory B subunits underinvestigation, we made use of another viral protein, E4orf4,from adenovirus. Unlike SV40 small T antigen, E4orf4 interactswith a subset of intact PP2A holoenzymes that contain eitherB55 ${alpha}$ (30, 60) or B56 family members (27, 61). E4orf4 effectivelyinhibits these PP2A holoenzymes by redirecting their activitytoward targets important for viral production (27, 60). As shownin Fig. 1D, increasing amounts of E4orf4 resulted in a dose-dependentincrease in c-Myc protein levels, similar to that seen withincreasing amounts of SV40 small T antigen (77). Based on thisresult, we narrowed our focus to B55 ${alpha}$ and B56 family membersto see if any had a role in regulating c-Myc protein levels.

RNAi knockdown of the PP2A regulatory B56 ${alpha}$ subunit results in increased c-Myc protein levels. We used an RNA interference screen to individually knock downexpression of B55 ${alpha}$ and B56 family regulatory subunits to assesswhether they are involved in negatively regulating c-Myc proteinlevels. We first examined B55 ${alpha}$ by using small interfering RNA.As shown in Fig. 2A, knockdown of B55 ${alpha}$ did not cause a significantchange in c-Myc protein levels compared to scramble controlsiRNA (compare lanes 1 and 3). In contrast, knockdown of PP2A-Cresulted in a substantial increase in c-Myc protein levels (lane2), consistent with our previous results (77). In both cases,PP2A-C and B55 ${alpha}$ were knocked down by their siRNAs (90% and 75%,respectively) (Fig. 2A, middle and bottom panels, lanes 2 and3). We therefore concluded that B55 ${alpha}$ is not involved in negativelyregulating c-Myc protein levels.

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FIG. 2. Increasing knockdown of B56 ${alpha}$ results in a robust linear increase in c-Myc protein levels. (A) siRNA knockdown of B55 ${alpha}$ does not affect c-Myc protein levels. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 0.5 µg CMV-HA-c-Myc, 0.5 µg pD40-His/V5-B55 ${alpha}$ , and siRNA (100 nM final concentration) targeted to either PP2A-C, B55 ${alpha}$ , or scramble control. Whole-cell lysates were collected at 48 h posttransfection and normalized for transfection efficiency by ß-gal activity, and c-Myc, PP2A-C, and B55 ${alpha}$ proteins were visualized by Western blot (WB) analysis with anti-HA.11, anti-PP2A-C ${alpha}$ , and anti-V5, respectively. (B) Vector-expressed shRNAs targeted to PP2A-A and B56 family members specifically knock down intended targets. HEK-293 cells were cotransfected with 50 ng CMV-ßgal; 0.5 µg of either pD30-PP2A-FLAG-A or pCEP4HA-B56 ${alpha}$ , -ß, - ${gamma}$ 1, - ${gamma}$ 3, - ${delta}$ 1, or - ${varepsilon}$ (targets); and 2 µg pSUPER-shRNA expression vector [empty (–) or targeted to PP2A-A or B56 ${alpha}$ , -ß, - ${gamma}$ 1, - ${delta}$ 1, or - ${varepsilon}$ , as indicated]. Cells were maintained in DMEM supplemented with 2% FBS and L-glutamine for 72 h. Lysates were prepared and normalized as for panel A. Immunoblots were probed for PP2A-A with anti-M2-FLAG or for the indicated B56 family members with anti-HA.11. (C) Increasing knockdown of B56 ${alpha}$ results in increased c-Myc expression. HEK-293 cells were transfected with 50 ng CMV-ßgal, 0.5 µg CMV-HA-c-Myc, and increasing amounts from 0.25 µg to 1.5 µg of pSUPER-shRNA expression vector [empty (–) or targeted to PP2A-A or B56 ${alpha}$ , -ß, - ${gamma}$ 1, - ${delta}$ 1, or - ${varepsilon}$ , as indicated]. Cells were maintained and lysates prepared and normalized as for panel B. c-Myc was visualized with anti-HA.11 by Western blot analysis. (D) Knockdown of PP2A-A or B56 ${alpha}$ results in a linear increase in c-Myc protein levels. c-Myc protein levels were quantified from panel C and two repeat experiments, and average c-Myc expression and error bars were calculated (see "Western blotting and quantitation" in Materials and Methods). Changes in c-Myc protein levels were then graphed as change relative to the shRNA control (panel C, lane 1). (E) Schematic of B56 family members. The B56 family of PP2A regulatory subunits share 71% and 73% amino acid sequence homology in the A subunit binding domains 1 and 2 (ASBD1 and -2), respectively, but significantly lower homology, less than 39% and 34%, in the N and C termini, respectively, which are believed to dictate substrate specificity (33, 39, 79). RNAi target sites used in the shRNA expression vectors are indicated by underlined regions for each B56 member. Splice variations in B56 ${gamma}$ and B56 ${delta}$ are shown.

Next we examined knockdown of the B56 family of regulatory Bsubunits, which are encoded by five distinct genes: B56 ${alpha}$ , -ß,- ${gamma}$ , - ${delta}$ , and - ${varepsilon}$ (38, 40). B56 ${alpha}$ , -ß, and - ${varepsilon}$ each expressa single isoform, whereas B56 ${gamma}$ and - ${delta}$ express multiple isoformsdue to alternative splicing, with four encoded by B56 ${gamma}$ and threeencoded by B56 ${delta}$ (9, 38, 40) (see Fig. 2E for a summary). We designedvector-expressed small hairpin RNAs to knock down the PP2A structuralA ${alpha}$ (predominant adult form) and B56 ${alpha}$ , -ß, - ${gamma}$ , - ${delta}$ , and- ${varepsilon}$ subunits. In the case of B56 ${gamma}$ and - ${delta}$ , the constructed shRNAsare designed to knock down all splice variants (Fig. 2E). Wetested the specificities of these shRNAs by cotransfecting eachshRNA construct with expression constructs for each of the targets:PP2A-A and B56 ${alpha}$ , -ß, - ${gamma}$ 1, - ${gamma}$ 3, - ${delta}$ 1, or - ${varepsilon}$ . Each shRNA specificallyreduced expression of its intended target by 70 to 90% but didnot affect expression of unintended targets (Fig. 2B).

We cotransfected c-Myc with increasing amounts of each shRNAconstruct. As expected, increasing knockdown of the structuralA ${alpha}$ subunit, which should result in near-global inhibition ofall PP2A holoenzymes, caused a robust linear increase in c-Mycprotein levels (Fig. 2C, top panel, and D). In a similar manner,increasing knockdown of B56 ${alpha}$ resulted in a linear increase inc-Myc protein levels (Fig. 2C, second panel, and 2D). In contrast,increasing knockdown of the remaining B56 subunits did not showa significant effect on c-Myc protein levels (Fig. 2C, bottomfour panels, and D). Results from the E4orf4 experiment andthe RNAi screen strongly suggest that B56 ${alpha}$ is likely the regulatoryB subunit responsible for targeting PP2A activity towards c-Myc.

Knockdown of B56 ${alpha}$ increases c-Myc protein stability. PP2A activity has been shown to regulate transcription (3, 42,70), mRNA stability (28), and translation (4, 32). However,our previous data show that PP2A activity affects c-Myc proteinstability (77). To determine whether PP2A-B56 ${alpha}$ might regulatec-myc transcription or mRNA stability, we examined endogenousc-myc mRNA levels by RT-PCR upon shRNA knockdown of B56 ${alpha}$ in 293cells. c-myc mRNA levels did not change when B56 ${alpha}$ was knockeddown, compared to the control (Fig. 3A, top panel). However,in the same experiment, endogenous c-Myc protein levels didincrease 4.1-fold with B56 ${alpha}$ knockdown (Fig. 3A, second panelfrom bottom), consistent with our results from Fig. 2C and D.We next assessed whether knockdown of B56 ${alpha}$ affects c-Myc proteinstability. As shown in Fig. 3B, knockdown of B56 ${alpha}$ significantlydecreases the rate of c-Myc protein degradation following inhibitionof protein synthesis with cycloheximide (compare middle andtop panels). The quantitated increase in c-Myc half-life withB56 ${alpha}$ inhibition, from 25 min to greater than 2 h (Fig. 3B, graph),is consistent with our previous data showing a five- to sixfoldincrease in c-Myc stability upon global inhibition of PP2A activity(77). These results demonstrate that the increase in c-Myc proteinlevels upon knockdown of B56 ${alpha}$ is due to increased c-Myc proteinstability rather than to increased levels or stability of c-mycmRNA.

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FIG. 3. PP2A-B56 ${alpha}$ regulates c-Myc protein stability. (A) Knockdown of B56 ${alpha}$ does not affect endogenous c-myc mRNA levels. HEK-293 cells were cotransfected with 50 ng CMV-ßgal and 3 µg pSUPER-shRNA-empty (–) or pSUPER-shRNA-B56 ${alpha}$ under 10% FBS conditions for 24 h and then starved in 0.2% FBS for 48 h. Cells exhibiting transfection efficiencies by ß-gal assay within 5% of each other were used for RT-PCR analysis of endogenous c-myc and GAPDH (glyceraldehyde-3-phosphate dehydrogenase gene) mRNA levels. Endogenous c-Myc and ß-tubulin protein levels were also examined in the same experiment by Western blotting (WB) with anti-N262 and anti-ß-tubulin, respectively. (B) c-Myc protein stability is increased upon B56 ${alpha}$ knockdown. One-hundred-millimeter dishes of HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 0.5 µg pD40-His/V5-c-Myc, and 4 µg pSUPER-empty or p-SUPER-B56 ${alpha}$ under 10% FBS conditions for 24 h. Each transfection mixture was split into six 60-mm dishes with 10% FBS and then starved in 0.2% FBS for 48 h. Cells were treated with 100 µg/ml cycloheximide (CHX), and cell lysates were prepared at the indicated time points after treatment. c-Myc and ß-tubulin were visualized from samples at each time point with anti-V5 and anti-ß-tubulin by Western analysis. c-Myc protein levels were quantified relative to ß-tubulin levels and graphed as percent c-Myc protein remaining after cycloheximide treatment. Protein half-life was calculated using the Excel (Microsoft) graphing function.

B56 ${alpha}$ associates with c-Myc. Although previous experiments presented here and elsewhere (77)have demonstrated that manipulating PP2A function can affectc-Myc protein levels, nobody has experimentally demonstratedan association between c-Myc and PP2A. We therefore initiallycharacterized the general interaction between PP2A and c-Myc.Cells were cotransfected with an expression vector for c-Mycand either PP2A-HA-C or empty control. As shown in Fig. 4A,c-Myc coimmunoprecipitated with anti-HA antibody only in thepresence of the PP2A-HA-C subunit (upper panel, compare lanes1 and 2). We also coimmunoprecipitated PP2A-HA-C with c-Myc.His₆-tagged c-Myc, c-Myc^TAD (deleted for the transactivationdomain), or control Ni-NTA columns were generated and incubatedwith cellular lysates containing PP2A-HA-C. As shown in Fig.4B, the PP2A-HA-C subunit was pulled out by the c-Myc column(top panel, lane 2) but not by either the control or c-Myc^TADcolumn (lanes 1 and 3, respectively). This not only confirmsthat PP2A and c-Myc associate but also shows that the interactionoccurs through the N-terminal transactivation domain of c-Myc.Importantly, the transactivation domain of c-Myc contains thehighly conserved S62 residue that we have previously shown tobe dephosphorylated by PP2A (77).

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FIG. 4. c-Myc specifically associates with B56 ${alpha}$ . (A) c-Myc complexes with PP2A-HA-C subunit. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 3 µg CMV-Myc, and 3 µg of either pD30-PP2A-HA-C (+) or CMV-empty (–), as indicated. Cleared lysate volumes were normalized by ß-gal activity and subjected to immunoprecipitation (IP) with anti-HA.11. Ten percent input volumes and 50% IP samples were analyzed by Western blotting (WB) for c-Myc with anti-N262 and for PP2A-HA-C with anti-HA.11. (B) PP2A-HA-C associates with the transactivation domain of c-Myc. HEK-293 cells cotransfected with 50 ng CMV-ßgal and 3 µg either pD40-His/V5-control, -c-Myc, or -c-Myc^TAD (input shown in lanes 1 to 3 of the lower panel) were used to generate Ni-NTA-control, -c-Myc, or -c-Myc^TAD columns (see "Ni-NTA columns" in Materials and Methods). Ni-NTA columns were incubated with cleared lysates from HEK-293 cells transfected with 3 µg pD30-PP2A-HA-C (input shown in lane 4). Column-bound proteins were eluted, and 50% eluate and 10% input samples were subjected to Western blot analysis with anti-V5 for c-Myc and anti-HA.11 for PP2A-HA-C. (C) PP2A-B56 ${alpha}$ interacts with c-Myc. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 3 µg pD40-His/V5-c-Myc, and 3 µg either CMV-empty (–) or pCEP4HA-B56 ${alpha}$ , -B56ß, -B56 ${gamma}$ 1, -B56 ${gamma}$ 3, -B56 ${delta}$ 1, or -B56 ${varepsilon}$ , as indicated. Anti-HA.11 immunoprecipitations were carried out on cleared lysates adjusted for ß-gal activity. Two percent input and 50% IP samples were analyzed by Western blotting with anti-V5 for c-Myc, anti-rabHA for B56 family members, and anti-PP2A-C ${alpha}$ for endogenous PP2A-C. (D) Endogenous PP2A-B56 ${alpha}$ holoenzymes associate with endogenous c-Myc. Endogenous c-Myc was immunoprecipitated from HEK-293cells with agarose-conjugated C-33 antibody. Control immunoprecipitation was done using agarose A+G beads. Two percent input and 50% IP samples were subjected to Western blot analysis with anti-PP2A-B' ${alpha}$ for endogenous B56 ${alpha}$ , anti-N262 for endogenous c-Myc, and anti-PP2A-C ${alpha}$ for endogenous PP2A-C subunit.

Given that c-Myc associates with PP2A, we asked whether theinteraction is mediated by one or more specific regulatory Bsubunits. We focused on the B56 family of regulatory subunitsas suggested by the E4orf4 and RNAi experiments. We coexpressedc-Myc with B56 ${alpha}$ , -ß, - ${gamma}$ 1, - ${gamma}$ 3, - ${delta}$ 1, - ${varepsilon}$ , or -empty controland then immunoprecipitated the different B56 subunits. As shownin Fig. 4C, c-Myc clearly coimmunoprecipitated with B56 ${alpha}$ (upperpanels, lane 2), but not with B56ß, - ${gamma}$ 1, - ${gamma}$ 3, - ${delta}$ 1, or- ${varepsilon}$ (lanes 4, 6, 8, 10, and 12). Furthermore, endogenous PP2AC subunit coimmunoprecipitated with each of the B56 subunits,suggesting that PP2A holoenzymes are pulled down in each case(Fig. 4C, 2nd panel from top, even lanes). We also immunoprecipitatedendogenous c-Myc from 293 cells and showed association withendogenous B56 ${alpha}$ (Fig. 4D, lane 3). Moreover, endogenous PP2A-Csubunit also coimmunoprecipitated with endogenous c-Myc (middlepanel, lane 3). Studies have shown that association betweenthe regulatory B and catalytic C subunits is mediated throughthe structural A subunit (31, 49, 52, 63). Therefore, it islikely that intact trimeric PP2A-B56 ${alpha}$ holoenzymes associate withc-Myc through the B56 ${alpha}$ regulatory subunit.

PP2A-B56 ${alpha}$ association with the transactivation domain of c-Myc is enhanced when serine 62 dephosphorylation is inhibited. To determine whether B56 ${alpha}$ interacts with c-Myc near the serine62 phosphorylation site, we immunoprecipitated wild-type c-Myc(c-Myc^WT) and c-Myc^TAD from 293 cells cotransfected with B56 ${alpha}$ .As shown in Fig. 5A, both B56 ${alpha}$ and endogenous PP2A-C subunitcoimmunoprecipitated with c-Myc^WT (top two panels, lane 5) butnot with c-Myc^TAD, compared to the control (lanes 4 and 6).These results demonstrate that B56 ${alpha}$ targets PP2A holoenzymesto the transactivation domain of c-Myc.

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FIG. 5. PP2A-B56 ${alpha}$ holoenzyme associates with the transactivation domain of c-Myc. (A) PP2A-B56 ${alpha}$ requires the transactivation domain of c-Myc for association. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 3 µg pCEP4HA-B56 ${alpha}$ , and 3 µg of either pD40-His/V5-contol, -c-Myc^WT, or -c-Myc^TAD, as indicated. Cleared lysates were collected at 36 h posttransfection and normalized for transfection efficiency by ß-gal activity, and immunoprecipitations (IP) were performed with anti-V5. Five percent input and 50% IP samples were subjected to Western blot (WB) analysis with anti-V5 for c-Myc, anti-rabHA for B56 ${alpha}$ , and anti-PP2A-C ${alpha}$ for endogenous PP2A-C. (B) PP2A-B56 ${alpha}$ shows a stronger association with c-Myc T58A and S62D point mutants. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 3 µg of either CMV-control (–) or pCEP-4HAB56 ${alpha}$ (+), and 3 µg pD40-His/V5-c-Myc^WT or pD40-His/V5-c-Myc point mutants (T58A, S62A, T58E, and S62D, as indicated). Lysates were prepared and normalized as for panel A and subjected to immunoprecipitation with anti-HA.11. Immunoprecipitates were washed with a stringent buffer (see "Coimmunoprecipitation" in Materials and Methods). Ten percent input and 50% IP samples were analyzed by Western analysis with anti-V5 for c-Myc, anti-rabHA for B56 ${alpha}$ , and anti-PP2A-C ${alpha}$ for endogenous PP2A-C.

The transactivation domain of c-Myc contains the T58 and S62residues, which coordinately regulate c-Myc degradation, andPP2A dephosphorylates S62. Therefore, we tested whether thephosphorylation status of T58 or S62 could affect the interactionbetween PP2A-B56 ${alpha}$ and c-Myc. B56 ${alpha}$ was immunoprecipitated from293 cells coexpressing c-Myc^WT or c-Myc point mutants (T58A,S62A, T58E, or S62D). Immunoprecipitates were washed under stringentconditions to challenge the interaction. As shown in Fig. 5B, c-Myc^WTand all four point mutants coimmunoprecipitated with B56 ${alpha}$ tovarious degrees (top panel, even lanes). Since the S62A mutantlacks phosphorylation at both T58 and S62 (57), this resultsuggests that phosphorylation at T58 and/or S62 is not essentialfor PP2A-B56 ${alpha}$ association with c-Myc. On the other hand, bothc-Myc^T58A and the S62 phosphorylation mimic, c-Myc^S62D, showeda stronger association with B56 ${alpha}$ (Fig. 5B, top panel, lanes 4and 10, respectively). Previous studies have demonstrated thatc-Myc^T58A shows substantially higher S62 phosphorylation levelsthan c-Myc^WT, and in vitro assays show that PP2A fails to dephosphorylatec-Myc^T58A (35, 57, 77). Thus, the inability of PP2A to dephosphorylateS62, as occurs with c-Myc^T58A and the phosphorylation mimicc-Myc^S62D mutants, appears to create a "substrate trap" whererelatively more P-S62 c-Myc remains bound to PP2A-B56 ${alpha}$ holoenzymes.

Combined expression of the catalytic and B56 ${alpha}$ subunits dramatically reduces c-Myc protein levels. In Fig. 1, we demonstrated that increasing PP2A activity byexpressing PP2A-HA-C had limited activity toward reducing c-Mycprotein levels. Now that we had identified a specific PP2A holoenzyme,PP2A-B56 ${alpha}$ , that associates with c-Myc, we assessed the effectsof increasing expression of this holoenzyme on c-Myc proteinlevels. As shown in Fig. 6, expression of either B56 ${alpha}$ or PP2A-HA-Calone showed only a slight, but consistent, reduction in c-Mycprotein levels compared to the control (top panel, lanes 1 to3, and graph). Expression of the PP2A-A subunit alone generallyresulted in increased c-Myc protein levels (lane 4). Other reportshave also described aberrant affects from overexpressing PP2A-A,which could explain our results (73). However, the combinationof B56 ${alpha}$ with PP2A-HA-C dramatically reduced c-Myc protein levelsto about 20% of that for the control (compare lanes 1 and 5and graph). Coexpression of all three B56 ${alpha}$ , HA-tagged C, andPP2A-A subunits together also significantly reduced c-Myc proteinlevels to 45% (data not shown). Taken together, these resultsdemonstrate that increasing PP2A-B56 ${alpha}$ holoenzyme levels can substantiallyreduce c-Myc protein expression.

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FIG. 6. Increased PP2A-B56 ${alpha}$ activity reduces c-Myc protein levels. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 1 µg CMV-Myc and 1 µg of pD30-PP2A-FLAG-A, pD30-PP2A-HA-C, and/or pD40-His/V5-B56 ${alpha}$ , as indicated. Whole-cell lysates were collected at 48 h posttransfection and normalized for transfection efficiency by ß-gal activity, and samples were subjected to Western blot (WB) analysis with anti-N262 for c-Myc, anti-M2-FLAG for PP2A-A, anti-HA.11 for PP2A-C, and anti-V5 for B56 ${alpha}$ . c-Myc protein levels were quantified from three separate experiments, and average protein levels with error bars were graphed relative to control protein levels (see "Western blotting and quantitation" in Materials and Methods).

Reduced expression of B56 ${alpha}$ increases the level of serine 62-phosphorylated c-Myc. We have previously observed that global inhibition of PP2A activityby expression of SV40 small T antigen causes an increase inS62-phosphorylated c-Myc (unpublished data). We investigatedwhether knockdown of B56 ${alpha}$ alone could affect the phosphorylationstatus of c-Myc at S62. Consistent with our previous findings,knockdown of B56 ${alpha}$ resulted in higher total c-Myc protein levelscompared to the control (Fig. 7A, bottom panel, compare lanes1 and 2). Using phospho-specific antibodies, we also observeda significant increase in both S62- and T58-phosphorylated c-Myc(top and middle panels). In contrast, knockdown of the otherB56 family members did not significantly affect total c-Myclevels or S62 and T58 phosphorylation levels (Fig. 7A, lanes3 to 6). The concurrent increase of c-Myc T58 phosphorylationwith B56 ${alpha}$ knockdown is not surprising, since we are blockingthe degradation of c-Myc prior to dephosphorylation on S62 byPP2A but after GSK-3ß phosphorylates c-Myc on T58,and thus we are accumulating doubly phosphorylated c-Myc. Bysimultaneously probing for total and phospho-c-Myc, we wereable to quantitate the relative increases in S62 and T58 phosphorylationwith respect to total c-Myc. As shown in Fig. 7B, we observeda significant enrichment in both S62- and T58-phosphorylatedc-Myc species relative to total c-Myc, with average increasesof 1.8- and 1.4-fold, respectively, upon B56 ${alpha}$ knockdown. A neardoubling in the population of c-Myc that is S62 phosphorylatedcould significantly affect c-Myc function.

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FIG. 7. Knockdown of PP2A-B56 ${alpha}$ increases S62- and T58-phosphorylated c-Myc as well as c-Myc-driven transcription. (A) c-Myc S62 and T58 phosphorylation increases upon PP2A-B56 ${alpha}$ knockdown. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 0.5 µg CMV-Myc-HA-WT, and 1.5 µg of pSUPER-shRNA expression vector [empty (–) or targeted to B56 ${alpha}$ , B56ß, B56 ${gamma}$ , B56 ${delta}$ , or B56 ${varepsilon}$ , as indicated]. Whole-cell lysates were collected at 72 h posttransfection. Samples were normalized for ß-gal activity and analyzed by Western blots (WB) simultaneously probed with anti-HA.11 for total c-Myc and either anti-T58phospho for T58 phosphorylation or anti-S62phospho for S62 phosphorylation. Anti-HA.11 was detected with secondary anti-mouse Alexa Fluor 680, and anti-T58phospho and anti-S62phospho were detected with secondary anti-rabbit IRDye800. The Western blots shown are representative of S62 phosphorylation, T58 phosphorylation, and total c-Myc protein levels from three separate experiments. (B) S62- and T58-phosphorylated c-Myc is enriched upon B56 ${alpha}$ knockdown. S62 or T58 phosphorylation levels along with total c-Myc levels, from simultaneously probed Western blots, were quantitated using LI-COR software (see "Western blotting and quantitation" in Materials and Methods). Ratios of S62-phosphorylation/total c-Myc and T58-phosphorylation/total c-Myc were calculated. Average ratios with error bars from the experiment shown in panel A and two repeat experiments were graphed relative to control (–) levels, and statistically significant differences are indicated (*). (C) B56 ${alpha}$ knockdown selectively increases c-Myc-driven transcription. HEK-293 cells were cotransfected with 50 ng CMV-ßgal, 0.5 µg CMV-HA-c-Myc, and 10 ng of either E2F2-Luc or E2F2(-E-box)-Luc, along with 1.5 µg pSUPER-shRNA expression vector [empty (–) or targeted to B56 ${alpha}$ B56ß, B56 ${gamma}$ , B56 ${delta}$ , or B56 ${varepsilon}$ , as indicated]. Whole-cell lysates were collected at 72 h posttransfection. c-Myc protein levels are shown by Western analysis with anti-HA.11. Luciferase activity was measured and corrected for transfection efficiency based on ß-gal activity. Average corrected luciferase activity from three separate experiments was graphed with error bars, and statistically significant differences are indicated (*). (D) Knockdown of B56 ${alpha}$ increases endogenous E2F2 mRNA levels. HEK-293 cells were cotransfected with 50 ng CMV-ßgal and 3 µg pSUPER-empty, pSUPER-B56 ${alpha}$ , or pSUPER-PP2A-A under 10% FBS conditions for 24 h and then starved in 0.2% FBS for 48 h. Cells exhibiting transfection efficiencies by ß-gal assay within 5% of each other were used for RT-PCR analysis of endogenous E2F2, c-myc, and GAPDH mRNA levels.

Knockdown of PP2A-B56 ${alpha}$ enhances c-Myc-dependent transcriptional activity. c-Myc is a transcription factor that positively regulates thetranscription of a number of target genes that are criticalfor cellular proliferation, growth, and differentiation (10).Consequently, we asked whether the increase in c-Myc expressionobserved upon knockdown of B56 ${alpha}$ has functional significance.To asses c-Myc-driven transcription, we used two luciferasereporter plasmids that contain the E2F2 promoter, which eitherhave consensus E-box c-Myc binding sites (E2F2-Luc) or havepoint mutations in these binding sites that prevent c-Myc binding[E2F2(-E-box)-Luc] (58). As shown in Fig. 7C, knockdown of B56 ${alpha}$ again resulted in significantly increased c-Myc protein levels(lane 2) compared to knockdown of the other B56 family membersand the shRNA control (lanes 1 and 3 to 6). Importantly, thisincreased accumulation of c-Myc was accompanied by a statisticallysignificant increase in E2F2-Luc reporter activity over thatseen with c-Myc when B56 ${alpha}$ is not knocked down [Fig. 7C, graph,E2F2-Luc, B56 ${alpha}$ compared to (–)]. In contrast, the negativecontrol E2F2(-E-box)-Luc reporter plasmid, which does not supportc-Myc binding, did not show a statistically significant changein activity when B56 ${alpha}$ was knocked down [Fig. 7C, E2F2(-E-box)-Luc,B56 ${alpha}$ compared to (–)]. These results demonstrate that theB56 ${alpha}$ effect on E2F2 promoter activity is c-Myc dependent. Incontrast, knockdown of the remaining B56 family members showedonly minor changes in the activity of either E2F2-Luc or E2F2(-E-box)-Luc(Fig. 7C, B56ß, - ${gamma}$ , - ${delta}$ , and - ${varepsilon}$ ). We also examined theeffect of knocking down B56 ${alpha}$ on endogenous c-Myc-driven transcriptionof the E2F2 gene. Figure 7D shows a 1.9-fold increase in E2F2mRNA levels when B56 ${alpha}$ (lane 2) is knocked down compared to thecontrol (lane 1). As a positive control, knockdown of PP2A-A(lane 3) resulted in a 2.1-fold increase in E2F2 mRNA levelscompared to the control. The $~$ 2-fold increase in c-Myc-dependentE2F2 promoter activation with B56 ${alpha}$ knockdown is consistent withincreases seen in c-Myc-driven transcription when c-Myc is stabilizedby inhibition of PP2A activity with SV40 small T antigen (77).Based on these results, we conclude that PP2A-B56 ${alpha}$ negativelyregulates c-Myc protein levels, and this level of control isimportant for regulating c-Myc activity. In the absence of thiscontrol, aberrant expression of functional c-Myc can occur.

DISCUSSION

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Discussion

Our previous work demonstrated a prominent role for PP2A inregulating c-Myc protein levels and activity (77). Given thesignificant number of regulatory roles assigned to PP2A, identifyingthe specific PP2A holoenzyme involved in regulating c-Myc givesus valuable insight into the control of c-Myc oncogenicity,as well as further understanding of how PP2A can function asa tumor suppressor. In this report, we present data identifyinga specific PP2A holoenzyme containing the regulatory B subunit,B56 ${alpha}$ , that interacts with the transactivation domain of c-Myccontaining the S62 residue we previously demonstrated to bedephosphorylated by PP2A. Furthermore, we show that the PP2A-B56 ${alpha}$ holoenzyme negatively regulates c-Myc protein stability andfunction, demonstrating the importance of this interaction withrespect to c-Myc biology.

PP2A function toward c-Myc is regulated by trimeric holoenzyme formation. It has previously been shown that ectopic expression of thePP2A-HA-C subunit in HEK-293 cells increases cellular PP2A activity(2). However, whether PP2A-HA-C requires trimeric PP2A holoenzymeformation to function has not been fully elucidated. Some studieshave demonstrated that free PP2A-C and the dimeric catalyticcore, PP2A-A/C, can dephosphorylate known PP2A targets in vitro(65, 76). However, other reports show that the regulatory Bsubunit is required for PP2A substrate specificity and greatlyincreases PP2A activity towards known targets (1, 6, 37, 66,68, 75). Our findings show that in order to affect c-Myc accumulation,ectopically expressed PP2A-HA-C must incorporate into PP2A holoenzymes.Moreover, our results suggest that holoenzyme formation directedtoward c-Myc is limited, presumably due to low levels or limitedaccessibility of the specific regulatory B subunit, B56 ${alpha}$ . Accordingly,we show that manipulation of B56 ${alpha}$ expression levels can dramaticallyaffect c-Myc accumulation.

PP2A holoenzyme formation has been strongly implicated in cellulartumor suppressor activity. For example, there are a number ofPP2A-A subunit mutations reported to occur in a variety of cancersthat disrupt PP2A holoenzyme formation (50, 51, 71). Additionally,inhibition of PP2A holoenzyme assembly by expression of SV40small T antigen has been shown to be a critical step in theexperimental conversion of primary human cells to a transformedtumorigenic state (20, 45, 53, 78). Interestingly, the requirementfor PP2A inhibition in this assay can be circumvented by expressionof the stable c-Myc^T58A mutant, which is resistant to PP2A-mediateddephosphorylation and degradation (77). These findings highlightthe importance of PP2A holoenzyme formation for tumor suppressoractivity and reveal the critical nature of PP2A regulation ofc-Myc for normal cellular function.

B56 ${alpha}$ targets c-Myc and is a key regulator of PP2A tumor suppressor activity. The B56 family of PP2A regulatory B subunits is diverse, witheach member displaying distinct tissue expression, developmentalexpression, and subcellular localization patterns (36, 40).In general, the B56 family members have been regarded as tumorsuppressors (67). To date, a great deal of attention has focusedon the B56 ${gamma}$ isoforms. An N-terminal deletion mutant of B56 ${gamma}$ 1,found in a mouse melanoma cell line, has been shown to resultin increased metastasis by deregulation of paxillin (23) andinhibition of the gamma irradiation cell cycle check point,contributing to genomic instability (23, 24). B56 ${gamma}$ 3 is reportedto regulate Chk2 and p300 protein levels (6, 13), as well asto be involved in cell cycle control by regulating Mdm2 andp53, through its association with cyclin G (43, 44).

Although the B56 ${gamma}$ subunits are clearly tumor suppressors, knockdownof the B56 ${gamma}$ subunits recapitulates the requirement for SV40 smallT antigen in cellular transformation of primary human cellsonly after a significantly longer period of time (7). This resultsuggests that other PP2A holoenzymes targeted by SV40 smallT antigen play an essential role in the transformation of humancells. In this regard, our results showing that c-Myc is a targetof PP2A-B56 ${alpha}$ identify another such PP2A holoenzyme targeted bySV40 small T antigen with tumor suppressor function.

The B56 ${alpha}$ regulatory subunit is reported to be the most ubiquitouslyexpressed isoform of the B56 family (36, 40), making it an idealregulatory B subunit to target PP2A activity towards c-Myc,since c-Myc is also ubiquitously expressed. Although there areno known mutations in B56 ${alpha}$ in human cancers, two mutations identifiedin the PP2A-A subunit from human tumors have been shown to specificallydisrupt the binding of B56 ${alpha}$ to PP2A-A, selectively inhibitingPP2A-B56 ${alpha}$ holoenzyme formation (51). In addition, several otherimportant cellular regulatory proteins have been shown to betargeted by B56 ${alpha}$ . The antiapoptotic protein Bcl2 has been shownto be inactivated by B56 ${alpha}$ (54), and B56 ${alpha}$ plays a crucial rolein negatively regulating protein levels of the Wnt-signalingtranscription factor ß-catenin (34, 59). The discoverythat c-Myc is a B56 ${alpha}$ target places B56 ${alpha}$ at a critical junctionpoint for regulating multiple potent oncoproteins.

Interplay between the oncogenic activity of c-Myc and the tumor suppressor function of PP2A-B56 ${alpha}$ . Despite its critical role in regulating multiple oncoproteins,B56 ${alpha}$ transcript levels are found to be relatively low in mosttissues, and data presented here suggest that B56 ${alpha}$ protein islimiting toward c-Myc (36). Presumably, under normal or quiescentcellular conditions, when c-Myc and ß-catenin proteinslevels are low and Bcl2 is not activated, these low levels ofB56 ${alpha}$ are sufficient. However, aberrant deregulation of any oneof these oncoproteins could sequester the majority of B56 ${alpha}$ andthereby cause deregulation of the other oncoproteins regulatedby PP2A-B56 ${alpha}$ . In fact, ${Delta}$ Np63 ${alpha}$ , an oncogenic form of the p53 familymember p63, which is overexpressed in squamous cell carcinomas,has been reported to associate with B56 ${alpha}$ , and this results inthe accumulation of ß-catenin (46). Our finding thatc-Myc^T58A has a stronger association with PP2A-B56 ${alpha}$ than wild-typec-Myc could mean that it acts in a manner similar to that of ${Delta}$ Np63, explaining in part the increased oncogenicity of c-Myc^T58Aversus c-Myc^WT (22, 48, 57). Furthermore, c-Myc^T58A shows reducedapoptosis compared to c-Myc^WT, which could be facilitated bythe efficient sequestering of PP2A-B56 ${alpha}$ by c-Myc^T58A, thus preventingB56 ${alpha}$ -mediated inactivation of the antiapoptotic Bcl2 (5, 21).

ACKNOWLEDGMENTS

We thank David Virshup for the HA-tagged B56 family expressionvectors and Clodagh O'Shea for the E4orf4 expression vector.

Funding for this work was provided by NIH Training Grant 5-T32-GM08617and OHSU TL Tartar Trust Research Fellowship AMEDG0063 to HughK. Arnold and by NIH grants RO1-CA100855 and KO1-CA086957 toRosalie C. Sears.

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular and Medical Genetics, Oregon Health & Sciences University, 3181 S.W. Sam Jackson Park Rd., L103A, Portland, OR 97239. Phone: (503) 494-6885. Fax: (503) 494-4411. E-mail: searsr{at}ohsu.edu.

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

REFERENCES

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