The Molecular Scaffold Kinase Suppressor of Ras 1 (KSR1) Regulates Adipogenesis

Mitogen-activated protein kinase pathways are implicated inthe regulation of cell differentiation, although their preciseroles in many differentiation programs remain elusive. The Raf/MEK/extracellularsignal-regulated kinase (ERK) kinase cascade has been proposedto both promote and inhibit adipogenesis. Here, we titrate expressionof the molecular scaffold kinase suppressor of Ras 1 (KSR1)to regulate signaling through the Raf/MEK/ERK/p90 ribosomalS6 kinase (RSK) kinase cascade and show how it determines adipogenicpotential. Deletion of KSR1 prevents adipogenesis in vitro,which can be rescued by introduction of low levels of KSR1.Appropriate levels of KSR1 coordinate ERK and RSK activationwith C/EBPß synthesis leading to the phosphorylationand stabilization of C/EBPß at the precise momentit is required within the adipogenic program. Elevated levelsof KSR1 expression, previously shown to enhance cell proliferation,promote high, sustained ERK activation that phosphorylates andinhibits peroxisome proliferator-activated receptor gamma, inhibitingadipogenesis. Titration of KSR1 expression reveals how a molecularscaffold can modulate the intensity and duration of signalingemanating from a single pathway to dictate cell fate.

INTRODUCTION

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Introduction

The Raf/MEK/extracellular signal-regulated kinase (ERK) kinasecascade is an evolutionarily conserved pathway involved in thedetermination of cell fate (50, 86). In mammalian cells, signalingthrough the Raf/MEK/ERK kinase cascade has been implicated inmultiple aspects of cell fate determination, including the regulationof senescence, proliferation, transformation, differentiation,and apoptosis (50). While a positive role for ERK signalingis well established in proliferation, transformation, and oncogene-inducedsenescence (29, 47, 79, 90), its role in cell differentiationprograms remains controversial. ERK activation has been shownto play both positive and negative roles in T-cell commitment(2, 5, 12, 32, 64), myogenesis (19, 51), and adipogenesis (17,20, 53, 62, 71), with the results seemingly dependent upon themethodology used to study the Raf/MEK/ERK kinase cascade. Inadipogenic conversion of 3T3-L1 preadipocytes, inhibition ofpathway activity reveals a positive role for ERKs (53, 62, 71),whereas constitutive activation of the pathway suggests a negativerole for ERKs (17, 20).

Preadipocyte differentiation is influenced by endocrine andautocrine factors that promote or constrain adipogenesis byintracellular mechanisms that induce the synthesis and activationof adipogenic transcription factors (58). Upon treatment ofgrowth-arrested fibroblasts with a hormonal cocktail of methylisobutylxanthine,dexamethasone, and insulin (MDI), there is a rapid inductionof C/EBPß and C/EBP ${delta}$ (1 to 2 h) lasting 2 to 3 days(69, 70, 83). With the expression of C/EBPß/ ${delta}$ , postconfluent,growth-arrested preadipocytes reenter the cell cycle and undergomultiple rounds of cellular division, a process termed mitoticclonal expansion (MCE) (70, 71). C/EBPß/ ${delta}$ then inducethe expression of C/EBP ${alpha}$ and peroxisome proliferator-activatedreceptor gamma (PPAR ${gamma}$ ) (56, 82-84). C/EBP ${alpha}$ and PPAR ${gamma}$ terminateMCE and together induce the expression of genes involved intriglyceride storage and metabolism that lead to formation ofa mature adipocyte (56-58, 83, 84).

C/EBPß is necessary for adipogenic conversion of culturedcells. Fibroblasts from C/EBPß^–/– C/EBP ${delta}$ ^–/–or C/EBPß^–/– mice fail to differentiateinto adipocytes (69, 70). C/EBPß is necessary forMCE and induction of C/EBP ${alpha}$ and PPAR ${gamma}$ (70, 82, 85). Expressionof C/EBPß is controlled transcriptionally by CREB(4, 89). Work in multiple cell systems suggests, however, thatC/EBPß activity is controlled posttranslationallyby multiple kinases (8, 27, 42, 52). Phosphorylation of C/EBPßby the Raf/MEK/ERK/p90 ribosomal S6 kinase (RSK) kinase cascaderegulates its stability and activity. Phosphorylation of Thr²¹⁷by RSK inactivates a caspase-inhibitory box on C/EBPß,increasing its stability and thereby enhancing its expressionand activity (8, 35). Phosphorylation of Thr¹⁸⁸ by ERK transactivatesC/EBPß (27, 42, 52).

While the Raf/MEK/ERK kinase cascade is thought to play an importantrole in adipogenic conversion, its precise contribution remainscontroversial. Studies using the specific MEK inhibitor U0126or antisense DNA against ERK indicate that the activation ofERK and CREB is necessary for the induction of C/EBPß/ ${delta}$ ,for MCE, and for the induction of C/EBP ${alpha}$ and PPAR ${gamma}$ (4, 53, 62,71). Conversely, activation of ERK with constitutively activeupstream effectors causes ERK-mediated phosphorylation and inactivationof PPAR ${gamma}$ and blocks terminal differentiation (1, 10, 17, 20,88). These observations have led to disparate conclusions thatERKs function to promote and inhibit adipocyte differentiation.

Kinase suppressor of Ras 1 (KSR1) (25, 68, 73) is a scaffoldfor the Raf/MEK/ERK kinase cascade that regulates the activationof Raf by Ras (36, 74) and the activation of MEK by Raf (34,39). Consistent with the predicted effects of a scaffold onits cognate signaling cassette (9, 28), KSR1 interacts withRaf, MEK, and ERK (22, 26, 36, 61, 66), and its deletion impairsthe activation of ERK by growth factors and serum (26). Experimentalmanipulation of KSR1 expression regulates the degree of ERKactivation with coincident effects on the proliferative rateand oncogenic potential of cells (26). The ability to manipulateKSR1 expression and, in turn, control signal transduction throughthe Raf/MEK/ERK kinase cascade provided the opportunity to examinethe role of ERK activation in regulating cell fate in greaterdetail.

Two important questions arise when the role of the Raf/MEK/ERKcascade in cell fate determination is considered: (i) how canactivation of this pathway both activate and inhibit the samecellular program and (ii) how can a single kinase cascade giverise to multiple cell fates? We examine these questions by titratingexpression of the molecular scaffold KSR1 and examining itseffect on signal transduction through the Raf/MEK/ERK kinasecascade to regulate adipogenesis. We show that moderate levelsof KSR1 are required to coordinate Raf/MEK/ERK/RSK signalingwith C/EBPß expression and ensure progression of theadipogenic program. Titration of KSR1 to higher levels prolongsERK activation and enhances mitogenesis (26) but inhibits adipogenesisby promoting ERK-mediated inactivation of the antiproliferativetranscription factor PPAR ${gamma}$ . Thus, the intensity and durationof Raf/MEK/ERK signaling determine the biologic consequenceof pathway activity to affect adipogenic potential. ManipulatingKSR1 directs pathway activity and cell fate.

MATERIALS AND METHODS

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Materials and Methods

Mice. DBA1/LacJ KSR1^–/– mice were previously described(43). Male KSR1^–/– and KSR1^+/+ mice were fed a chowdiet (4% fat) ad libitum, and weights were recorded every 4weeks until 20 weeks of age. Mice were then sacrificed, andepididymal, inguinal, visceral, and brown adipose fat pads weredissected and weighed (n = 6 mice in each group).

Analysis of adipocyte size. Sections were obtained from epididymal fat pads of 20-week-oldmale KSR1^–/– and KSR1^+/+ mice (n = 6 mice in eachgroup). The fat pads were fixed and stained with hematoxylinand eosin. For each mouse, x20 photomicrographs from three independentfields containing 50 to 100 adipocytes were analyzed using IPLabsoftware (Scanalytics Inc., Fairfax, VA).

Plasmids. KSR1 plasmids were described previously (26). MSCV-IRES-YFPwas created by substitution of yellow fluorescent protein (YFP)for green fluorescent protein (GFP) in MSCV-IRES-GFP (a giftfrom Eric Gosner, St. Jude's Children's Hospital, Memphis, TN).Wild-type PPAR ${gamma}$ (a gift from Bruce Spiegelman, Harvard MedicalSchool, Boston, MA) was subcloned into MSCV-IRES-YFP. PPAR ${gamma}$ S112A-IRES-YFPwas produced by site-directed mutagenesis of PPAR ${gamma}$ -IRES-YFP.pLXSN C/EBP ${alpha}$ was a gift from Ormond MacDougald (University ofMichigan, Ann Arbor, MI). C/EBPß was subcloned intothe pWZL retroviral vector containing blasticidin S resistance(a gift from Gary Nolan, Stanford University, Palo Alto, CA).

Cell lines. Primary mouse embryo fibroblasts (MEFs) were derived from KSR1^+/+and KSR1^–/– embryos at embryonic day 13.5, as describedpreviously (43). Immortalized MEFs were derived by passagingprimary KSR1^–/– and KSR1^+/+ MEFs under a 3T9 protocol(75). KSR1^–/– and KSR1^+/+ MEFs and KSR1^–/–MEFs expressing ectopic KSR1 were described previously (26,43). KSR1^–/– and KSR1^+/+ MEFs expressing C/EBPßwere produced by retroviral infection and selection using 10µg/ml blasticidin S for 7 days. KSR1^–/– cellsexpressing both KSR1 and PPAR ${gamma}$ were produced by infection withbicistronic retroviruses encoding KSR1-IRES-GFP and PPAR ${gamma}$ -IRES-YPFor control viruses and sorted for green and yellow fluorescenceby fluorescence-activated cell sorter analysis. Cells were excitedat 488 nm, and GFP and YFP signals were discriminated with a525-nm short-pass dichroic filter. Cells demonstrating appropriatelevels of fluorescence through both 530/30-nm and 550/30-nmfilters were collected.

Cell culture and retroviral infection. Cells were maintained in Dulbecco's modified Eagle's mediumsupplemented with 10% fetal bovine serum, 2 mM L-glutamine,0.1 mM minimal essential medium nonessential amino acids, 100U/ml penicillin, and 100 µg/ml streptomycin and incubatedat 37°C in 5% CO₂. To produce recombinant retroviruses,retroviral vectors were cotransfected with an ecotropic packagingvector (a gift from Tom Smithgall, University of PittsburghSchool of Medicine, Pittsburgh, PA) into 293T cells, and supernatantswere collected 48 to 72 h posttransfection. Retroviral infectionof MEFs was performed using 8 µg/ml polybrene.

Preparation of cell extracts and Western blotting. Cells were lysed in Triton-sodium dodecyl sulfate (SDS) lysisbuffer (40 mM Tris [pH 7.4], 120 mM NaCl, 0.5% Triton X-100,0.3% SDS, 10 mM sodium pyrophosphate, 2 mM EGTA, 2 mM EDTA,1 mM phenylmethylsulfonyl fluoride, 10 mg/ml leupeptin, 5 mg/mlaprotinin). Twenty-five micrograms of total protein was loadedper well, and lysates were subjected to SDS-polyacrylamide gelelectrophoresis and Western blotting. Antibodies were from SantaCruz unless otherwise noted: anti-PPAR ${gamma}$ (Upstate), anti-RSK (TransductionLaboratories), anti-phospho-RSK (Ser³⁸⁰) (Cell Signaling), anti-phospho-ERK1/2antibodies (Cell Signaling), anti-KSR1 (Transduction Laboratories),anti-Foxo1 (Cell Signaling), anti-phospho-Foxo1 (Ser²⁵⁶) (CellSignaling), anti-STAT5 (Cell Signaling), and anti-actin (Sigma).Anti-mouse, anti-rabbit, and anti-goat secondary antibodiesconjugated to Alexa Fluor 680 (1:3,000; Molecular Probes) andIRDye800 (1:3,000; Rockland) were used to probe primary antibodies.Protein bands were detected and quantified on a Li-Cor Odysseyinfrared imaging system. To assess PPAR ${gamma}$ phosphorylation, sampleswere run on an 11% acrylamide-bis (100:1) gel containing 5 Murea (20).

Adipogenesis. Primary or immortalized MEFs were seeded in 35-mm dishes andgrown to 2 days postconfluence (day 0). Cells were then stimulatedwith insulin (4 µg/ml; Sigma), dexamethasone (10 ng/ml;Sigma), and methylisobutylxanthine (115 µg/ml; Sigma)in 10% fetal bovine serum (FBS) for 2 days and insulin in 10%FBS for an additional 2 days before being transferred into 10%FBS for the remainder of the treatment (67). For primary MEFs,cells were also stimulated with pioglitazone (5 µM; Sigma)for 4 days. MCE was assessed at day 0 and day 3 by trypan bluecell counting. Samples were lysed at various times throughoutMDI stimulation for Western blot analysis. For C/EBPßstability, 2-day postconfluent cells were treated with MDI for4 hours in 10% FBS and then shifted to 10% FBS containing 50µg/ml cycloheximide for the indicated times. To inhibitERK activity in KSR1-expressing MEFs, U0126 (Cell Signaling)was added at various concentrations to the differentiation medium4 h following MDI stimulation and was maintained in the culturemedium for 8 days.

In situ ERK activation assay. Cells were seeded at 1.5 x 10⁴ cells/well in a 96-well plate24 h prior to analysis and subjected to an in situ plate assayusing the Li-Cor Odyssey infrared imaging system to quantifyERK activation. Cells at 70% confluence were deprived of serumfor 4 hours and treated with 25 ng/ml platelet-derived growthfactor (PDGF) in Dulbecco's modified Eagle's medium plus 1%bovine serum albumin for 5 min. Anti-phospho-ERK1/2 (1:100;Cell Signaling) and anti-ERK1 (1:100; Santa Cruz) primary antibodiesand anti-mouse Alexa Fluor 680 (1:100; Molecular Probes) andanti-rabbit IRDye800 (1:100; Rockland) secondary antibodieswere used to detect and quantify phosphorylated and total ERKprotein levels.

RT-PCR. Total RNA was prepared from cells or tissues with TRI reagent(Molecular Research Center) according to the manufacturer'sinstructions. Five micrograms of total RNA was reverse transcribedwith Superscript II reverse transcriptase (Invitrogen), and1/20 of the reverse transcription (RT) reaction was used forPCR. The sequences of primers were as follows: KSR-1 forward,5'-GGCAAAGCTGGTGAAATAC-3'; KSR-1 reverse, 5'-AGCTACTGTCTCGAGCATCT-3';KSR-2 forward, 5'-CTGTCCTGCAAGAAGAAGGTG-3'; KSR-2 reverse, 5'-GCACGTCTGAGACATCCAGTA-3';GAPDH forward, 5'-CCCTTCATTGACCTCAACTAC-3'; GAPDH reverse, 5'-TACTCCTTGGAGGCCATGT-3'.

Northern blot analysis. RNA was isolated with TRI reagent (Molecular Research Center)according to the manufacturer's protocol. Total RNA (20 µg)was separated in 1% agarose-formaldehyde gels, transferred toZeta-Probe GT membrane (Bio-Rad), and probed with [³²P]dCTP-radiolabeledDNA. A full-length C/EBPß vector, a 600-bp mouse KSR1,and a 700-bp ß-2-microglobulin cDNA fragment wererandomly primed with the DECAprime II kit (Ambion) accordingto the manufacturer's specifications. The blots were hybridizedwith ULTRAhyb solution (Ambion) at 50°C overnight. Followinghybridization, Northern blots were washed twice with 2x SSC(1x SSC is 0.15 M NaCl plus 0.015 M sodium citrate)-0.1% SDSat room temperature for 10 min and twice again with 0.1x SSC-0.1%SDS at 50°C for 15 min. Hybridized Northern blots were analyzedby storage phosphor technology (Molecular Dynamics).

Statistical analysis. All values are means ± standard deviations (SD) unlessotherwise stated. Statistical analyses were carried out usinga two-tailed Student's t test. Significance was rejected ata P value of $≥$ 0.05.

RESULTS

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Results

KSR1^–/– mice have enlarged adipocytes. KSR1^–/– mice are overtly normal and fertile andgrow at the same rate as their wild-type littermates (Fig. 1A),although cells from these mice show diminished ERK activation(30, 43). The masses of fat depots in KSR1^–/– miceand their wild-type littermates were also indistinguishable(Fig. 1B). However, histological examination of epididymal adiposetissue revealed a marked increase in the cross-sectional areaof adipocytes in KSR1^–/– mice compared to KSR1^+/+mice. (Fig. 1C and D). Analysis of size distribution of epididymaladipocytes demonstrated that while KSR1^+/+ mice had significantlymore of the smallest detectable cells, KSR1^–/– micehad more cells that were 2 to 10 times larger in the cross-sectionalarea (Fig. 1E). Considering the identical fat pad weights forKSR1^–/– and KSR1^+/+ mice, these data imply thatKSR1^–/– mice have fewer, but larger, adipocytes.

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FIG. 1. KSR1^–/– mice have enlarged adipocytes. (A) Weights of KSR1^–/– (open diamonds) and KSR1^+/+ (closed squares) mice fed a standard chow diet ad libitum. Values are the means ± SD (n = 6 mice). (B) Weights of different fat depots from 20-week-old KSR1^–/– (gray) and KSR1^+/+ (black) mice as described above (A). Values are the means ± SD (n = 6 mice). (C) Representative photomicrographs (x20) of epididymal fat pads as described above (B). (D) Average cross-sectional area of epididymal adipocytes from fat pads dissected as described above (B). Three independent fields from six KSR1^–/– and six KSR1^+/+ mice were analyzed as described in Materials and Methods. Values are the means ± SD. ** denotes a P value of $≤$ 0.01. (E) Distribution curve of adipocyte size analyzed as described above (D). Values are the means ± SD. * denotes a P value of $≤$ 0.05; ** denotes a P value of $≤$ 0.01. (F) Oil Red O staining of primary KSR1^–/– and KSR1^+/+ MEFs 8 days following treatment with differentiation medium to induce adipogenesis as described in Materials and Methods. (G) Ethidium bromide-stained gel of RT-PCR products showing expression of KSR1, KSR2, and GAPDH (glyceraldehyde-3-phosphate dehydrogenase) transcripts in white adipose tissue (WAT) or MEFs from KSR1^–/– and KSR1^+/+ mice.

The reduced number of adipocytes in fat depots of KSR1^–/–mice could be due to a reduction in the adipogenic capacityof KSR1^–/– preadipocytes to differentiate. To testtheir adipogenic potential, primary MEFs from KSR1^–/–and KSR1^+/+ mice were treated with an adipogenic cocktail ofMDI with or without the synthetic PPAR ${gamma}$ ligand pioglitazone.Scattered adipocytes were detected by Oil Red O staining inonly KSR1^+/+ MEFs treated with the adipogenic cocktail and pioglitazone(Fig. 1F). The absence of detectable differentiation in KSR1^–/–MEFs suggested a role for KSR1 in adipogenesis of MEFs. However,this defect was relatively severe in comparison to the decreasein adipocyte number and increase in adipocyte size caused byKSR1 deletion in vivo. A related gene, KSR2, has been recentlyidentified in Caenorhabditis elegans (45) and humans (11). Weexamined white adipose tissue and MEFs from KSR1^–/–and KSR1^+/+ mice for the expression of KSR1 and KSR2. KSR2 wasdetected in both adipocytes from KSR1^–/– and KSR1^+/+mice but was undetected in KSR1^–/– or KSR1^+/+ MEFs(Fig. 1G). Thus, KSR2 expression may minimize the effect ofKSR1 deletion in vivo, while its absence in KSR1^–/–MEFs may deprive cells in culture of a family of effectors necessaryfor hormonally induced adipogenesis.

KSR1 is necessary for adipogenic progression. To determine the contribution of KSR1-scaffolded signaling toadipogenesis, postconfluent, immortalized KSR1^–/–and KSR1^+/+ MEFs were treated with MDI to induce differentiation.KSR1 was necessary for adipogenic conversion of fibroblasts,as MDI-treated KSR1^+/+ but not KSR1^–/– MEFs showedsubstantial triglyceride accumulation following 8 days of treatment(Fig. 2A and B). An increase in KSR1 expression coincides withthe differentiation of HL-60 cells (78) and PC12 cells (66).We examined whether KSR1 expression was altered similarly duringadipogenesis. When either 3T3-L1 preadipocytes or wild-typemouse embryo fibroblasts were treated with MDI, the level ofKSR1 protein increased throughout the first 4 days of adipogenicinduction (Fig. 2C). Ectopic expression of KSR1 in KSR1^–/–MEFs elevates ERK activity and enhances cell proliferation ina dose-dependent manner (26).

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FIG. 2. KSR1 is necessary for C/EBPß induction and adipogenesis. (A) Oil Red O staining of immortalized KSR1^–/– and KSR1^+/+ MEFs 8 days following treatment with differentiation medium to induce adipogenesis as described in Materials and Methods. (B) Analysis of triglyceridelevels in immortalized KSR1^–/– and KSR1^+/+ MEFs 0 and 8 days after treatment with differentiation medium. Values are the means ± SD of four independent experiments. (C) Western blot analysis of whole-cell extracts prepared at different times during differentiation of 3T3-L1 preadipocytes and immortalized KSR1^+/+ MEFs. Lysates were probed with an anti-KSR1 antibody to detect induction of KSR1 during adipogenesis. ß/2 microglobulin (ß/2 M) was used to demonstrate equal loading of each sample. (D) Analysis of MCE in KSR1^–/– and KSR1^+/+ MEFs by counting cell number 0 and 3 days after treatment with differentiation medium. Values are the means ± SD of four independent experiments. (E to I) Western blot analysis of whole-cell extracts prepared at different times during differentiation of KSR1^–/– and KSR1^+/+ MEFs. Lysates were probed with the indicated antibodies to detect induction and activation of each protein during adipogenesis. ß/2 microglobulin (ß/2 M) was used to demonstrate equal loading of each sample.

We tested whether deletion of KSR1 would affect the MCE of preadipocytesthat accompanies adipocyte differentiation in vitro. Thoughcontroversial (15, 54), MCE of preadipocytes has been suggestedas a precursor to acquisition of the terminal adipogenic program(31, 49). MCE was assessed in wild-type and KSR1^–/–MEFs 3 days after MDI treatment, and Western blotting was performedfor C/EBPß, C/EBP ${delta}$ , C/EBP ${alpha}$ , and PPAR ${gamma}$ from 0 to 8 days.KSR1 was necessary for induction of MCE (Fig. 2D), consistentwith data implicating MEK activation in this process (71). Westernblot analysis revealed that deletion of KSR1 inhibited maximalinduction of C/EBPß and completely eliminated inductionof its downstream effectors C/EBP ${alpha}$ and PPAR ${gamma}$ . Induction of C/EBP ${delta}$ was unaffected by KSR1 deletion (Fig. 2E). C/EBPßexpression is dependent upon the coordinated action of the Raf/MEK/ERK/RSKand CREB pathways (4, 89). CREB phosphorylation was unaffectedin MDI-treated KSR1^–/– MEFs (Fig. 2H), indicatingthat CREB does not play a critical role in regulating the effectof KSR1 on adipogenesis. Although ERK and RSK were both phosphorylatedin MDI-treated KSR1^–/– MEFs, sustained activationof each kinase was abrogated (Fig. 2F and G). Adipogenesis isalso regulated by the action of a number of additional effectors,including E2F-1, Wnt10b, Foxo1, and STAT5 (16, 41, 59, 65).However, expression and/or phosphorylation of these effectorsin the adipogenic program is unaltered by the deletion of KSR1(Fig. 2I), suggesting that these proteins and the pathways theyregulate function independently of KSR1 and the Raf/MEK/ERKkinase cascade.

Ectopic C/EBPß expression restores adipogenic potential to KSR1^–/– MEFs. Deletion of C/EBPß, C/EBP ${alpha}$ , or PPAR ${gamma}$ blocks adipogenicconversion of fibroblasts (56, 57, 69, 70, 84). To determinewhether the impaired adipogenesis of KSR1^–/– MEFswas due to the loss of transcription factor expression, C/EBPß,C/EBP ${alpha}$ , or PPAR ${gamma}$ was introduced to KSR1^–/– MEFs. Introductionof C/EBP ${alpha}$ or PPAR ${gamma}$ rescued adipogenesis in KSR1^–/–MEFs as assessed by Oil Red O staining (Fig. 3A). PPAR ${gamma}$ permittedMDI-independent differentiation and C/EBP ${alpha}$ allowed MDI-dependentdifferentiation, consistent with PPAR ${gamma}$ expression being downstreamof C/EBP ${alpha}$ during adipogenesis (56, 84). These data demonstratethat KSR1^–/– MEFs retain the molecular machineryneeded to produce mature adipocytes. Furthermore, introductionof C/EBPß into KSR1^–/– MEFs rescued adipogenesis.C/EBPß expression in KSR1^–/– MEFs rescuedMDI-induced triglyceride accumulation (Fig. 3B), MCE (Fig. 3C),and expression of C/EBP ${alpha}$ and PPAR ${gamma}$ (Fig. 3D) compared to controlvector expression (Fig. 3B to D and data not shown). C/EBPßexists as alternate translation products in both an activatingform known as liver activating protein (LAP) and an inhibitoryform known as liver inhibitory protein (LIP), which lacks theN-terminal transcriptional activation domain found in LAP (13,14). Constitutive expression of LAP, but not LIP, also promotedadipogenesis in KSR1^–/– MEFs and showed the abilityto promote adipogenesis in the absence of the hormonal inducers(Fig. 3B), suggesting that KSR1 contributes to adipogenesisby enhancing the function of C/EBPß.

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FIG. 3. Expression of C/EBPß, C/EBP ${alpha}$ , or PPAR ${gamma}$ restores adipogenic conversion in KSR1^–/– MEFs. (A and B) Oil Red O staining of KSR1^–/– MEFs expressing (A) C/EBP ${alpha}$ and/or PPAR ${gamma}$ or (B) C/EBPß (wild type, LAP, or LIP) untreated or following 8 days of treatment with differentiation medium to induce adipogenesis as described in Materials and Methods. (C) Analysis of MCE in KSR1^–/– MEFs expressing C/EBPß or vector control by counting cell numbers 0 and 3 days after treatment with differentiation medium. Values are the means of four independent experiments. (D) Western blot analysis of whole-cell extracts prepared at different times during differentiation of KSR1^–/– MEFs expressing C/EBPß. Lysates were probed with the indicated antibodies to detect induction of each protein during adipogenesis.

KSR1 coordinates RSK activation with C/EBPß synthesis. C/EBPß transcription is controlled by CREB, whereasC/EBPß stability and activation are modulated by theRaf/MEK/ERK/RSK kinase cascade (4, 8, 27, 42, 48, 52, 89). Northernblot analysis revealed that MDI-stimulated C/EBPßtranscription was similar in both KSR1^–/– and KSR1^+/+MEFs (Fig. 4A). These data are consistent with the normal phosphorylationof CREB observed in KSR1^–/– MEFs (Fig. 2H).

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FIG. 4. KSR1 is required for C/EBPß phosphorylation and stabilization during adipogenesis. (A) MDI-induced C/EBPß transcription is independent of KSR1 expression. Shown is Northern blot analysis of C/EBPß, KSR1, and ß/2 M at different times after induction of differentiation in KSR1^–/– and KSR1^+/+ MEFs. (B) KSR1 enhances C/EBPß phosphorylation during adipogenesis. Shown is Western blot analysis of whole-cell extracts prepared at different times during differentiation of KSR1^–/– and KSR1^+/+ MEFs. Lysates were probed with the indicated antibodies to detect induction and activation of C/EBPß during adipogenesis. (C and D) Total and phosphorylated C/EBPß expression was quantified from the Western blots described above (B) at each time point and normalized to ß/2 M levels, and the resulting data were plotted as fold stimulation following induction of differentiation. Data for Thr²¹⁷ phosphorylation are shown in C, and data for Thr¹⁸⁸ phosphorylation are shown in D. KSR1^+/+, black line; KSR1^–/–, gray line; phospho-C/EBPß, solid line; total C/EBPß, dashed line. Data shown in each panel are the averages of three independent experiments. (E and F) Effect of KSR1 on C/EBPß stability. Shown is Western blot analysis of whole-cell extracts prepared from KSR1^–/– and KSR1^+/+ MEFs after 4 h of induction with differentiation medium followed by 0 to 2 h of treatment with cycloheximide (CHX). Lysates were probed for C/EBPß and ß/2 M. C/EBPß expression at each time point was quantified and normalized to ß/2 M levels, and the resulting data were plotted in F. Maximal expression was set arbitrarily to 1. Values are the means of two independent experiments.

Studies in cultured adipocytes, hepatocytes, and neurons haveshown that phosphorylation of C/EBPß on Thr²¹⁷ byRSK and Thr¹⁸⁸ by ERK enhances its stability and transcriptionalactivity, respectively (8, 27, 35, 42, 48, 52). Upon MDI treatment,newly translated C/EBPß is phosphorylated on bothThr²¹⁷ and Thr¹⁸⁸ in KSR1^+/+ MEFs (Fig. 4B and data not shown),thereby enhancing the stability and transcriptional activityof C/EBPß. Western blot analyses reveal that bothexpression and phosphorylation of C/EBPß are markedlydiminished in KSR1^–/– MEFs (Fig. 4B and data notshown). Quantitative analysis of total and phosphorylated formsof C/EBPß reveals that KSR1^–/– MEFs aredefective in both RSK- and ERK-mediated phosphorylation of C/EBPß(Fig. 4C and D). Phosphorylation of C/EBPß at Thr²¹⁷peaked within 8 h of MDI treatment in KSR1^+/+ MEFs, leadingto an increase in C/EBPß expression (Fig. 4C). Althoughthere was a rapid decline in C/EBPß phosphorylationafter 8 hours, total C/EBPß levels increased further,most likely due to the ability of C/EBPß to stimulateits own expression via binding to its promoter in an autoregulatorypositive feedback loop (44). RSK-mediated phosphorylation ofC/EBPß on Thr²¹⁷ was almost absent in KSR1^–/–MEFs (Fig. 4B and C and data not shown), which could accountfor the reduced expression of C/EBPß (Fig. 2E and4B and C and data not shown) and the impaired adipogenic potential(Fig. 2A and B) of KSR1^–/– MEFs. Phosphorylationof C/EBPß on Thr¹⁸⁸ was also diminished in KSR1^–/–MEFs (Fig. 4B and D and data not shown). The reduced phosphorylationand transcriptional activity of C/EBPß likely contributedto the absence of adipogenesis seen in KSR1^–/– MEFs(Fig. 2A and B) despite the low level of delayed C/EBPßexpression (Fig. 2E).

Phosphorylation of C/EBPß by RSK on Thr²¹⁷ increasesC/EBPß stability by creating a functional caspase-inhibitorybox (8). To examine whether C/EBPß stability was decreasedby KSR1 deletion, KSR1^–/– and KSR1^+/+ MEFs weretreated with MDI for 4 hours and then shifted to medium containing50 µg/ml cycloheximide for 0 to 2 h. In comparison toKSR1^+/+ MEFs, C/EBPß protein stability was markedlydiminished in KSR1^–/– MEFs during adipogenic conversion.Two hours after cycloheximide treatment, C/EBPß expressiondeclined by 15% in MDI-stimulated KSR1^+/+ MEFs but by 70% inKSR1^–/– MEFs (Fig. 4E and F). These data indicatethat KSR1^–/– MEFs cannot differentiate into adipocytesdue to a lack of sustained RSK activation, the consequence beingdefective RSK-mediated phosphorylation and stabilization ofC/EBPß.

Levels of KSR1 that enhance mitogenesis inhibit adipogenesis. Molecular scaffolds are predicted to affect signaling throughtheir cognate cascades in a concentration-dependent manner (9,26, 28). Consistent with this concept, growth factor-inducedERK activation and the rate of cell proliferation are dependentupon the amount of KSR1 expressed in cells (26). Induction ofadipogenesis in 3T3-L1 preadipocytes and MEFs causes an increasein KSR1 expression (Fig. 2C). To assess the role of KSR1 expressionon adipogenic conversion, KSR1^–/– MEFs expressingincreasing levels of KSR1 (26) were assessed for ERK activationand adipogenic conversion. Introduction of KSR1 into KSR1^–/–MEFs rescued adipogenesis in a dose-dependent manner disproportionateto its ability to enhance ERK activation and cell proliferation(26). KSR1 promotes a dose-dependent increase in ERK activation,with maximal ERK activation occurring at 14 times the levelof KSR1 expressed in KSR1^+/+ MEFs (Fig. 5A). If KSR1 is expressedat higher levels, ERK activation is inhibited via titrationof members of the Raf/MEK/ERK kinase cascade (26).

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FIG. 5. Physiologic levels of KSR1 promote adipogenesis. (A) KSR1^–/– MEFs expressing increasing levels of KSR1 were serum starved for 4 hours and stimulated with PDGF (25 ng/ml) for 5 min. ERK phosphorylation was assessed by in situ Western blotting as described in Materials and Methods. Data are the means of four independent experiments. (B) Oil Red O staining and Western blot analysis of KSR1^–/– MEFs expressing increasing levels of KSR1 8 days following treatment with differentiation medium to induce adipogenesis as described in Materials and Methods. Whole-cell lysates were probed at 0 and 8 days following induction with differentiation medium with the indicated antibodies. KSR1 level compared to KSR1^+/+ MEFs is indicated. (C) Analysis of MCE in KSR1^–/– MEFs expressing increasing levels of KSR1 by counting cell numbers 0 and 3 days after treatment with differentiation medium. Values are the means of four independent experiments. (D) Oil Red O staining and Western blot analysis of clonal cell populations isolated from the pool of KSR1^–/– MEFs averaging three times the KSR1 levels shown in B. Whole-cell lysates were probed with the indicated antibodies at 0 and 8 days following induction with differentiation medium with the indicated antibodies. KSR1 level compared to KSR1^+/+ MEFs is indicated.

Expression of KSR1 at three times the level expressed in KSR1^+/+MEFs maximally restored MDI-induced triglyceride accumulation,MCE, and C/EBP ${alpha}$ expression (Fig. 5B and C). Higher levels ofKSR1 expression, previously shown to enhance proliferation ofKSR1^–/– MEFs (26), inhibited adipogenesis (Fig.5B and C). To determine the level of KSR1 expression optimalfor adipogenic conversion, clonal cell lines expressing variouslevels of ectopic KSR1 were isolated from the 3x pool of KSR1-expressingMEFs by single-cell sorting. Analysis of cell lines expressingectopic KSR1 at 0.8 to 5.3 times wild-type levels revealed thatoptimal MDI-induced triglyceride accumulation, C/EBP ${alpha}$ and PPAR ${gamma}$ expression, and MCE occur at two to three times wild-type KSR1expression levels (Fig. 5D and data not shown).

Elevated levels of KSR1 facilitate phosphorylation and inhibition of PPAR ${gamma}$ . Prolonged ERK activation can cause PPAR ${gamma}$ phosphorylation on Ser¹¹²,leading to its inactivation and blocking adipogenesis (1, 10,20, 88). Overexpression of KSR1 promotes sustained ERK activation(26). To determine whether impaired adipogenesis by overexpressingKSR1 was due to the phosphorylation and inactivation of PPAR ${gamma}$ ,wild-type PPAR ${gamma}$ and PPAR ${gamma}$ ^S112A, which cannot be phosphorylatedby ERK, were introduced into KSR1-expressing MEFs. The resultingcells were then evaluated for spontaneous differentiation followingseveral days of postconfluent culture. Low levels of KSR1 permitteddifferentiation in MEFs expressing PPAR ${gamma}$ or PPAR ${gamma}$ ^S112A. However,when KSR was expressed at 14 times the level found in KSR1^+/+MEFs, adipogenesis occurred only in cells expressing PPAR ${gamma}$ ^S112A(Fig. 6A). Phosphorylation on Ser¹¹² retards the electrophoreticmobility of PPAR ${gamma}$ (20). An MDI-induced shift in PPAR ${gamma}$ mobilitywas observed in KSR1^–/– MEFs expressing 14 times,but not 3 times, the levels of KSR1 (Fig. 6B). These data demonstratethat KSR1 expression levels that maximize ERK activation inhibitadipogenesis by inactivating PPAR ${gamma}$ via its phosphorylation onSer¹¹². Consistent with that interpretation, the MEK inhibitorU0126 reverses the inhibitory effects of elevated KSR1 expressionin a dose-dependent manner (Fig. 6C). These data implicate ERKactivation as the inhibitory signal preventing adipogenesisin cells with high levels of KSR1 expression.

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FIG. 6. Elevated KSR1 expression promotes PPAR ${gamma}$ phosphorylation to inhibit adipogenesis. (A) Oil Red O staining of KSR1-expressing MEFs from Fig. 5B infected with retroviruses encoding wild-type PPAR ${gamma}$ or PPAR ${gamma}$ _S112A. (B) Western blot analysis of whole-cell extracts of cells from A prepared at days 0 and 8 of differentiation. Lysates were run on a 5 M urea gel (acrylamide-bis; 100:1) and probed with anti-PPAR ${gamma}$ antibody to discriminate phosphorylated and nonphosphorylated forms of PPAR ${gamma}$ . (C) Oil Red O staining of KSR1-expressing MEFs (14 times the endogenous KSR1 levels) stimulated with MDI and then treated with increasing concentrations of U0126 4 hours following MDI stimulation to inhibit prolonged ERK activation.

DISCUSSION

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Discussion

Adipogenesis requires the temporal coordination of multiplesignaling cascades. Here, we show that expression of KSR1, amolecular scaffold for the Raf/MEK/ERK kinase cascade, ensuresan appropriate level of ERK activity for progression throughthe adipogenic program. Deletion of KSR1 prevents the phosphorylationand stable expression of the transcription factor C/EBPß,which is necessary for subsequent expression of C/EBP ${alpha}$ and PPAR ${gamma}$ and completion of the adipogenic program. However, KSR1 expressionlevels that promote maximal ERK activation inhibit the adipogenicprogram by promoting the phosphorylation of PPAR ${gamma}$ on a site thatinhibits its activity. These data provide an explanation forthe conflicting observations of previous reports concludingthat ERK activation promotes (4, 53, 62, 71) or inhibits (17,20) adipogenesis. Adipogenesis requires appropriately timedERK activation of a measured intensity. Too much, or too little,ERK activation disrupts the efficient activation of transcriptionfactors critical to the adipogenic program (Fig. 7).

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FIG. 7. Distinct KSR1 concentrations promote the proliferative and adipogenic potential of cells. (A) Growth factor-induced ERK activation (closed squares), cell proliferation (gray triangles), and adipogenic response (open diamonds) were plotted as a percent response versus KSR1 expression level. (B) Relationship between KSR1 level, ERK activation, and adipogenic progression. Deletion of KSR1 blocks early steps in adipogenesis by blocking MDI-stimulated ERK activation. Low levels of KSR1 expression (1-4X) promote ERK- and RSK-mediated C/EBPß phosphorylation, promoting adipogenesis. Higher levels of KSR1 expression (5-14X) inhibit adipogenic progression by ERK-mediated phosphorylation of PPAR ${gamma}$ .

These studies demonstrate that KSR1 can coordinate ERK activitywith other signaling pathways to regulate the biologic responseto ERK activation. We propose that KSR1 provides a mechanismfor fine control of ERK signal duration to affect cell fate.KSR1 expression is elevated upon induction of adipogenesis in3T3-L1 preadipocytes and MEFs (Fig. 2C). Based on previous analysesin KSR1^–/– MEFs (26), the induction of endogenousKSR1 in KSR1^+/+ MEFs follows a time course that would enhancethe duration of ERK signaling during MCE but suppress ERK activationafterward. Recent observations indicate that KSR1 may be regulatedby cellular mechanisms affecting its stability or activity.Combined mutation of phosphorylation sites Thr²⁷⁴ and Ser³⁹²in KSR1 enhances its stability and amplifies growth factor-inducedERK activation (55). IMP, a novel E3 ligase, targets KSR1 toa Triton X-100-insoluble fraction to impede the activation ofMEK by Raf (34). Although ubiquitination of KSR1 has not beendetected, it is reasonable to postulate cellular mechanismsthat regulate signaling through the Raf/MEK/ERK signaling cassetteby manipulating the stability of a cognate molecular scaffold.

The distribution of KSR1 to different subcellular locationsmay also regulate signaling through ERK. Phosphorylation bythe kinase C-TAK1 and dephosphorylation by protein phosphatase2A regulate KSR1 translocation to the plasma membrane to facilitatethe activation of MEK by Raf (39, 46). KSR1 also translocatesto the nucleus in a manner dependent upon its interaction withMEK (7). These observations suggest that KSR1 is dynamicallyregulated by multiple afferent mechanisms to control signalingthrough ERK.

The duration of ERK activity can be influenced by external stimulito regulate differentiation and proliferation (3, 33). Epidermalgrowth factor (EGF) treatment of PC12 cells causes transientERK activation and stimulates proliferation, whereas nerve growthfactor treatment causes sustained ERK activation, the nucleartranslocation of ERK, and neurite outgrowth (21, 76). Ectopicexpression of B-KSR1 can modulate the response of PC12 cellsto growth factor treatment, promoting higher levels of ERK activityand enhancing neurite development (38). Furthermore, the expressionof ectopic B-KSR1 in PC12 cells converts the cellular responseto EGF from proliferation to differentiation (38). In fibroblasts,transient ERK activation by EGF is insufficient to stimulatecell proliferation, whereas sustained ERK activation by PDGFpromotes proliferation (24, 40). KSR1 expression is necessaryfor PDGF to promote sustained ERK activation and induce DNAsynthesis (26). Furthermore, increasing the level of KSR1 expressionconverts the cell's response to EGF into a PDGF-like responsethat promotes proliferation (26). In preadipocytes, endogenouslevels of KSR1 facilitate ERK activation at levels sufficientfor adipogenic progression. Higher levels of KSR1 expressioncause prolonged ERK activation, promoting proliferation at theexpense of adipogenesis.

KSR1 may play a similar role in ERK-mediated effects on otherdifferentiation pathways. ERK-mediated phosphorylation of C/EBP ${alpha}$ on Ser²¹ actively inhibits granulopoesis, suggesting that phosphorylationof C/EBP ${alpha}$ may be important for directing monocyte versus granulocytedifferentiation (60). The effects of allosteric MEK inhibitorsor constitutively activated pathway components suggest a potentialrole for KSR or other scaffolds in regulating ERK signalingin myogenesis (19, 51) and thymocyte maturation (2, 5, 12, 32,64). Treatment of myoblasts with the MEK inhibitor PD98059 blocksMyoD expression and early proliferative responses necessaryfor myogenesis (19). In contrast, constitutively active, nuclearMEK can bind directly to MyoD and inhibit its myogenic action(51). In immature thymocytes, high levels of ERK activity arerequired for clonal deletion of CD4⁺ CD8⁺ thymocytes (negativeselection), whereas low levels of ERK activity are necessaryfor maturation of CD4⁺ CD8⁺ thymocytes into functional CD4⁺or CD8⁺ T cells (32). Analysis and manipulation of KSR1 or otherscaffolds in these cells may reveal novel information aboutthe way in which the Raf/MEK/ERK kinase cascade integrates intoother complex differentiation programs.

KSR1^–/– mice show a mild phenotype in comparisonto the embryonic lethality seen in MEK1 and ERK2 null backgrounds(18, 43, 87). These differences may result from expression ofKSR2 (Fig. 1G), a recently identified KSR family member (11,45). In C. elegans, KSR1 and KSR2 have both overlapping andnonoverlapping functions in response to let60 Ras activation(45). Deletion of KSR1 in MEFs prevents MCE and adipogenesis(Fig. 2) while maintaining proliferative capacity equal to thatof KSR1^+/+ MEFs (26). The adipose depots of KSR1^–/–mice are identical in mass to those of KSR1^+/+ mice. This likelyreflects the compensatory effects of KSR2 in white adipose tissue(Fig. 1G). Despite the expression of KSR2, deletion of KSR1limits the number of cells that comprise each depot and causesan increase in average adipocyte size (Fig. 1C to E). This observationmay be in vivo evidence of impaired MCE. Consistent with a rolefor KSR1 in adipogenesis in vivo, ERK1^–/– mice havedecreased adiposity and fewer adipocytes than wild-type mice(6). Combined deletion of KSR1 and KSR2 should amplify the effectsof the scaffold on adipogenesis in vivo. However, deletion ofKSR1 and KSR2 in C. elegans is lethal (45) and would be predictedto be so in mice.

Molecular scaffolds are thought to organize kinase cascadesto ensure signaling specificity (37). If they reside in specificsubcellular compartments, scaffolds may direct a subset of signalsemanating from a given signaling cassette. This scaffold-mediatedsignaling specificity would allow a cell fine control of outputfrom a kinase cascade and provide a point for therapeutic controlof one physiological response mediated by an effector withoutdisruption of other responses. Analysis of other scaffolds formitogen-activated protein (MAP) kinase pathways supports thisidea. MP1 and its binding partner, p14, specifically organizeMEK1 and ERK1 to coordinate signaling through early endosomes(63, 72). JIP-1, a scaffold for the Jun N-terminal kinase (JNK)pathway, interacts specifically with a subset of MAP kinasekinases and MAP kinase kinase kinases known to activate JNK(80). This specificity of interaction, coupled with the limitedtissue distribution of JIP-1 in mice, demonstrates that JIP-1is not globally required for signals traversing the JNK signalingpathway. Rather, JIP-1 functions specifically in the brain andadipose tissue to mediate JNK responses to ischemic injury (81)and diet-induced obesity (23). OSM, a recently identified scaffoldfor p38-mediated responses to high osmolarity, provides similarspecificity to the p38 pathway for specific stimuli. OSM isnecessary for p38 activation by sorbitol but not by other p38activators such as anisomycin. OSM forms a signaling modulewith Rac, MEKK3, and MKK3, allowing for stimulus-specific controlof p38 activity (77). Although KSR1 binds to both MEK1/2 andERK1/2, our data suggest that KSR family members regulate asubset of cellular responses to MEK and ERK, specifically thosethat require precise control of the intensity and duration oftheir activity, such as proliferation (26), Ras-mediated oncogenesis(26, 30, 43), and adipogenesis (Fig. 1 and 2). Further analysisof KSR family scaffold proteins will define the extent to whichthey direct cell fate in response to ERK activation.

ACKNOWLEDGMENTS

We thank Charles A. Kuszynski and Linda M. Wilkie in the UNMCCell Analysis Facility for their technical expertise in thegeneration of GFP- and YFP-expressing cell lines. We thank MichaelWhite and Thomas Smithgall for critical review of the manuscriptand helpful advice and encouragement.

This research was supported by NIH grants CA90400 and DK52809(R.E.L.), the Charlotte Geyer Foundation (R.E.L.), and the AmericanDiabetes Association (R.L.K.).

FOOTNOTES

* Corresponding author. Mailing address: University of Nebraska Medical Center, Eppley Institute for Research in Cancer and Allied Diseases, 987696 Nebraska Medical Center, Omaha, NE 68198-7696. Phone: (402) 559-8290. Fax: (402) 559-3739. E-mail: rlewis{at}unmc.edu.

REFERENCES

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