Selective Cooperation between Fatty Acid Binding Proteins and Peroxisome Proliferator-Activated Receptors in Regulating Transcription

Lipophilic compounds such as retinoic acid and long-chain fattyacids regulate gene transcription by activating nuclear receptorssuch as retinoic acid receptors (RARs) and peroxisome proliferator-activatedreceptors (PPARs). These compounds also bind in cells to membersof the family of intracellular lipid binding proteins, whichincludes cellular retinoic acid-binding proteins (CRABPs) andfatty acid binding proteins (FABPs). We previously reportedthat CRABP-II enhances the transcriptional activity of RAR bydirectly targeting retinoic acid to the receptor. Here, potentialfunctional cooperation between FABPs and PPARs in regulatingthe transcriptional activities of their common ligands was investigated.We show that adipocyte FABP and keratinocyte FABP (A-FABP andK-FABP, respectively) selectively enhance the activities ofPPAR ${gamma}$ and PPARß, respectively, and that these FABPsmassively relocate to the nucleus in response to selective ligandsfor the PPAR isotype which they activate. We show further thatA-FABP and K-FABP interact directly with PPAR ${gamma}$ and PPARßand that they do so in a receptor- and ligand-selective manner.Finally, the data demonstrate that the presence of high levelsof K-FABP in keratinocytes is essential for PPARß-mediatedinduction of differentiation of these cells. Taken together,the data establish that A-FABP and K-FABP govern the transcriptionalactivities of their ligands by targeting them to cognate PPARsin the nucleus, thereby enabling PPARs to exert their biologicalfunctions.

INTRODUCTION

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Introduction

Many small, biologically important lipophilic compounds regulatecellular behavior by modulating the rates of transcription ofvarious target genes. Such compounds include, for example, retinoicacid and long-chain fatty acids (LCFA) and some of their activemetabolites. These molecules activate ligand-inducible transcriptionfactors that belong to the superfamily of nuclear hormone receptors.Retinoic acid activates the retinoic acid receptors (RARs) (9).The transcriptional activities of LCFA and their active derivativesare mediated by several classes of nuclear receptors, the bestcharacterized of which are the peroxisome proliferator-activatedreceptors (PPARs) (reviewed in reference 10). Three isotypesof PPAR ( ${alpha}$ , ß, and ${gamma}$ , also referred to as NR1C1, NR1C2,and NR1C3, respectively [Nuclear Receptor Nomenclature Committee,1999]) that display distinct tissue distributions are knownto exist. PPAR ${alpha}$ is expressed at high levels in the heart, skeletalmuscle, kidney, liver, and intestines. PPARß is widelydistributed, and PPAR ${gamma}$ is expressed at high levels in adiposetissues. The PPARs play a general role in regulating lipid metabolismand energy homeostasis. PPAR ${alpha}$ is involved in the intake of dietaryLCFA in the gut, peroxisomal and mitochondrial ß-oxidationin the liver, and hepatic fatty acid synthesis (10). This isotypehas also been implicated in control of inflammation (11). PPAR ${gamma}$ is a key player in adipocyte differentiation and has been implicatedin modulation of the insulin sensitivity of cells (7, 17, 45)and in regulation of macrophage function (37). While the functionsof PPARß have long remained elusive, we recently foundthat this subtype is involved in wound healing and plays a dualrole in keratinocytes. On the one hand, it mediates keratinocytedifferentiation induced by inflammation-associated agents suchas tumor necrosis factor alpha (TNF- ${alpha}$ ), and on the other, itfunctions in counteracting the apoptotic effects of TNF- ${alpha}$ inthese cells (31, 44). Hence, like the other PPAR isotypes, PPARßappears to regulate differentiation and inflammatory responsesin a cell whose functions involve active lipid metabolism.

PPARs display remarkably broad ligand selectivity (10, 13, 22-24).All three PPARs bind to and are activated by various unsaturatedLCFA. In addition, PPARs are activated by some eicosanoids;15-deoxy- ${Delta}$ 12,14-prostaglandin J2 (PGJ2) is a ligand for PPAR ${gamma}$ ,and hydroxyeicosatetraenoic acid and leukotriene B₄ are ligandsfor PPAR ${alpha}$ . In recent years, a variety of synthetic compoundswith selectivities toward particular PPAR isotypes have beensynthesized, and some of these are used or are in clinical trialsfor a variety of disorders ranging from diabetes to cancer.Like other nonsteroid nuclear receptors, PPARs associate withRXR (NR2B1, NR2B2, and NR2B3) to form heterodimers that bindto particular response elements in the promoter regions of targetgenes and act as ligand-inducible transcription factors (30).The molecular events underlying the transcriptional activitiesof nuclear receptor ligands through their cognate receptorshave become increasingly clear over the past years (14, 51).An important question that has remained elusive, however, relatesto the mechanism by which nuclear receptor ligands, which arepoorly soluble in water, reach the nucleus to bind to theircognate receptors and initiate their transcriptional activities.

In addition to nuclear receptors, many lipophilic compoundsand their metabolites bind in cells to proteins that are membersof the family of intracellular lipid-binding proteins (iLBPs).This family of small (14- to 15-kDa) proteins includes cellularretinol-binding proteins I and II (CRBP-I and -II), cellularretinoic acid-binding proteins (CRABP-I and -II), and nine knownisotypes of fatty acid binding proteins (FABPs) (2). The iLBPshave remarkably similar three-dimensional folds. Reported X-raycrystal structures of these proteins demonstrate that the entranceto the proteins' ligand-binding pockets is flanked by two ${alpha}$ -helicesthat appear to limit access to the binding site. This structuresuggests that marked conformational changes may need to occurprior to exit of the ligand from the binding pocket, raisingthe interesting question of how such rearrangements are inducedto allow ligands to leave the pocket and reach their correctsites of action. The marked evolutionary conservation of iLBPssuggests that they play important roles in the biological activitiesof their ligands, but the precise nature of these roles is notwell understood. It has traditionally been believed that thegeneral function of iLBPs is to solubilize and protect theirligands in aqueous spaces and to facilitate transport acrossthe cytosol (8, 42). However, it has become increasingly clearin recent years that, in addition to these general functions,iLBPs have diverse and specific roles in regulating the metabolismand activities of their ligands (reviewed in reference 35).Our recent studies demonstrated, for example, that CRABP-II(although not CRABP-I) functions by directly delivering retinoicacid to the nuclear receptor that is activated by this hormone,i.e., RAR (4, 5, 12). These studies established that CRABP-IItranslocates to the nucleus upon binding of retinoic acid andthat it associates directly with RAR to mediate ligand channelingto the receptor. The CRABP-II-RAR complex was found to be ashort-lived intermediate which dissociates rapidly followingligand transfer. We showed further that retinoic acid channelingbetween CRABP-II and RAR facilitates the ligation of RAR, therebystimulating the transcriptional activity of the receptor (4,5, 12).

The elucidation of the function of CRABP-II as a coregulatorof RAR raises the intriguing possibility that other membersof the iLBP family also act in concert with nuclear receptors.In view of the observation that FABPs display ligand selectivitiesthat are quite reminiscent of those of PPARs, (43), it is possiblethat some FABPs cooperate with some PPARs in mediating the transcriptionalactivities of their common ligands. The present study was undertakento explore this possibility. In choosing the particular FABPand PPAR isotypes to be studied, we were guided by the tissueexpression profiles of these proteins. We thus focused on possiblefunctional interactions between adipocyte FABP (A-FABP) andPPAR ${gamma}$ and on those between keratinocyte FABP (K-FABP) and PPARß.(A-FABP and PPAR ${gamma}$ and K-FABP and PPARß are the predominantforms of the two types of proteins in adipocytes and in keratinocytes,respectively.) We show that these FABPs act in concert withthese PPARs and, importantly, that they do so with strict selectivitiesfor both receptor subtypes and ligands. The data indicate furtherthat expression of K-FABP in keratinocytes is critical for theinitiation of proper PPARß-mediated differentiationin these cells.

MATERIALS AND METHODS

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Materials and Methods

Ligands. Wy-14643 was purchased from Cayman Chemical Co. (Ann Arbor,Mich.). Linoleic acid (C18:2) was purchased from Sigma ChemicalCo. (St. Louis, Mo.). Rosiglitazone was purchased from SigmaChemical Co. The PPARß-selective ligand L165041 wasprovided by Parke-Davis. cis-Parinaric acid was purchased fromMolecular Probes, Inc. (Eugene, Oreg.).

Plasmids. rH-FABP in pMON was a gift from David Cistola; mA-FABP in pBluescriptand K-FABP in the bacterial expression vector pRSET-A were providedby David Bernlohr. The PPAR ${gamma}$ ligand-binding domain (PPAR ${gamma}$ -LBD)and PPARß-LBD in pRSET-A were provided by Eric Xu.rH-FABP and mA-FABP were amplified by PCR and subcloned intothe mammalian expression vector pSG5. Bacterial expression vectorsfor glutathione S-transferase (GST)-tagged A-FABP and K-FABPwere constructed by inserting the corresponding coding sequencesinto a pGEX-4T2 vector. mPPAR ${alpha}$ , mPPARß, and mPPAR ${gamma}$ wereexpressed by using the mammalian vector pSG5. Expression vectorsfor green fluorescent protein (GFP)-tagged K-FABP and A-FABPwere constructed by subcloning the corresponding coding sequencesinto pEGFP-N2 in frame with the GFP moiety. All constructs wereconfirmed by sequencing. The (PPRE)₃-luciferase reporter constructwas provided by Ronald Evans (Salk Institute).

K-FABP containing an NES. The nuclear export sequence (NES) MDLCQAFSDVILA was added toK-FABP by PCR using a three-step strategy with the K-FABP cDNAin pSG5 as a template. The NES-K-FABP was then cloned into pSG5and verified by sequencing. The primary sequence of the constructcontained the NES linked to the N terminus of the native K-FABPby 2 residues (EF).

Proteins. GST-tagged and histidine-tagged proteins were expressed in Escherichiacoli BL21. Protein expression was induced with 0.5 mM isopropyl-ß-D-thiogalactopyranoside(IPTG) for 3 h, except for proteins expressed by using the pRSETvector. For these, bacteria were grown at room temperature for20 h without the addition of inducer. Bacteria were pelletedand lysed in 10 ml of HEDK100 (10 mM HEPES, 0.1 mM EDTA, 100mM KCl, and 1 mM dithiothreitol [pH 8.0]) with 0.1% NonidetP-40. Following treatment with DNase I and deoxycholic acid,the slurry was centrifuged and the supernatant was incubatedwith 1 ml of glutathione-agarose beads (for GST-tagged proteins)or Ni-charged beads (for His-tagged proteins) for 2 h at 4°Cwith gentle rocking. Beads were washed with HEDK100 buffer,and protein purity was assessed by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE).

Coprecipitation assays. ³⁵S-labeled mPPAR ${gamma}$ and mPPARß (in pCDNA3.1) were synthesizedby coupled in vitro transcription-translation using the TNTkit (Promega). For coprecipitation experiments, GST-FABP orHis-FABP, immobilized on glutathione-agarose or Ni-charged Sepharosebeads, respectively, were incubated with the appropriate ³⁵S-labeledPPAR for 2 h in 1 ml of HEDK100 at 4°C with gentle rocking.Beads were washed five times in the same buffer containing 0.1%Nonidet P-40. The resulting bound proteins were analyzed bySDS-PAGE and visualized by autoradiography.

Transactivation assays. COS-7 and COS-1 cells were maintained in Dulbecco's modifiedEagle's medium supplemented with 10% charcoal-treated newbornbovine calf serum (Cocalico Biologicals Inc., Reamstown, Pa.).Cells were cultured in six-well plates and were transfectedwith 0.3 or 1 µg of the (PPRE)₃-luciferase reporter vectorand 0.3 µg of pSG5 alone or harboring the cDNA for anappropriate FABP. Each well also received 0.15 or 0.3 µgof pCH110, a ß-galactosidase expression plasmid, asa control for transfection efficiency. In some experiments,50 ng of a pSG5 expression vector encoding the appropriate PPARwas cotransfected. Transfections were carried out by using Fugene(Roche Diagnostics Corporation) according to the protocol ofthe manufacturer. Twenty-four hours following transfection,the medium was replaced by Dulbecco's modified Eagle's mediumwithout serum, and ligands were added from a concentrated dimethylsulfoxide solution. Following 24 h of treatment, cells werelysed and assayed for luciferase activity by using the luciferaseassay system (Promega). Luciferase activity was corrected forß-galactosidase activity, which was measured by standardprocedures. All experiments were carried out in triplicate.

Labeling of PPAR ${gamma}$ -LBD. Purified PPAR ${gamma}$ -LBD was covalently labeled with N-(1-pyrenebutanoyl)cysteicacid succinimidyl ester sodium salt (Molecular Probes, Inc.).Protein was incubated with a fivefold molar excess of probeat 4°C for 2 h. Labeled protein was dialyzed extensivelyto remove free probe. The probe/protein ratio of the labeledprotein was determined from the absorbance of the probe (obtainedby using the equation ${varepsilon}$ ₃₄₁ = 38,000 M^-1 cm^-1) and measurementof the protein concentration by a Bradford assay using bovineserum albumin as a standard. The probe/protein ratio never exceeded0.5.

Fluorescence titrations. Fluorescence titrations were carried out with a Fluorolog 2DMIB spectrofluorometer (SPEX Instruments, Edison, N.J.). Protein(1 µM) was placed in a cuvette and titrated with parinaricacid from a concentrated solution in ethanol. Ligand bindingwas monitored by following the increase in the fluorescenceof the ligand upon binding to the protein (excitation wavelength[ ${lambda}$ _ex], 303 nm; emission wavelength [ ${lambda}$ _em], 416 nm). Ethanol concentrationsnever exceeded 2%. Titration curves were analyzed by fittingthe data to an equation derived from simple binding theory (34)to yield the number of binding sites and the equilibrium dissociationconstants (K_d). Analyses were carried out by using Origin 4.1software (MicroCal Software Inc., Northampton, Mass.).

Fluorescence competition titrations. Protein was complexed with parinaric acid at a molar ratio of1. The complex was then titrated with the appropriate liganduntil a plateau was reached. Binding of ligand was monitoredby following the decrease in the fluorescence of parinaric acidthat accompanies its dissociation from the protein. The K_d forthe nonfluorescent ligand was obtained from the 50% effectiveconcentration (EC₅₀) of the competition curve and the previouslydetermined K_d for parinaric acid.

Kinetics of transfer of ligands from FABP to PPAR ${gamma}$ -LBD. The appropriate binding protein was complexed with ligand ata molar ratio corresponding to the number of functional bindingsites (determined by fluorescence titrations as described above).The holoprotein was mixed with labeled PPAR ${gamma}$ -LBD by using a rapidmixing apparatus (HiTech, Salisbury, United Kingdom). The progressof the transfer reaction from the binding protein to the receptorwas monitored by following the time-dependent decrease in thefluorescence of the probe ( ${lambda}$ _ex = 342 nm; ${lambda}$ _em = 377 nm) which accompaniedligand binding by the labeled PPAR ${gamma}$ -LBD. Data were fit to a singlefirst-order reaction equation to yield the pseudo-first-orderrate constant of the transfer reaction.

Primary keratinocyte culture. Mouse keratinocytes were isolated from epidermis as reportedby Hager et al. (16) with the following modifications. The epidermiswas separated from the dermis following overnight incubationat 4°C in 2.5 U of Dispase/ml. The epidermis was placedin a 50-ml centrifuge tube with 10 ml of keratinocyte serum-freeculture medium (KSFM), and the tube was given 50 firm shakes.Keratinocytes were resuspended in KSFM containing 0.05 mM Ca²⁺and 0.1 ng of epidermal growth factor/ml and were seeded at5 x 10⁴ cells per cm². Keratinocytes were used after 2 to 3passages.

Direct lysate RPA. Gene-specific probes corresponding to cyclin A and involucrinwere subcloned into pGEM3Zf(+) (Promega). Gene-specific antisenseriboprobes were synthesized by in vitro transcription with eitherT7 or Sp6 RNA polymerase (Ambion). The L27 probe has been describedpreviously (26). For all riboprobes except L27, a 1:1 ratioof [ ${alpha}$ ³²P]UTP to cold UTP was used; for probe L27, a 1:10 ratiowas used. An RNase protection assay (RPA) was carried out asdescribed by the manufacturer (Ambion) with the following modifications:1 x 10⁶ to 2 x 10⁶ keratinocytes were lysed in 200 µlof lysis/denaturation buffer and clarified by centrifugationthrough a Qiashredder (Qiagen). A 45-µl volume of lysatewas hybridized to 1 ng of specific cyclin A and involucrin (10⁹cpm/µg) and 10 ng of L27 probe (10⁷ cpm/µg). RNasedigestion (10 U of RNase A/ml and 400 U of RNase T1/ml) wascarried out at 37°C for 20 to 30 min. RPA products wereresolved in a 6% electrolyte-gradient denaturing polyacrylamidegel. Gels were dried and exposed to X-ray film or to a Phosphorscreen. Gene-specific mRNA expressions were normalized to thespecific activity of the probe and to L27 mRNA expression.

Transfection of keratinocytes with antisense K-FABP. The expression level of K-FABP in keratinocytes was decreasedby expression of an antisense construct composed of the full-lengthK-FABP coding sequences inserted in the reverse orientationinto a pCDNA3.1 expression vector. The vector was transfectedinto the cells by using Superfect (Qiagen) 12 h prior to inductionof differentiation.

RESULTS

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Results

FABPs enhance the transcriptional activities of PPARs. To examine whether FABPs functionally interact with PPARs, theeffects of expression of some of these binding proteins in cellson the transcriptional activities of PPARs were examined. Inthese experiments, the FABP and PPAR isotypes to be tested wereselected based on their coexpression in different tissues. HeartFABP (H-FABP) was matched with PPAR ${alpha}$ , A-FABP was matched withPPAR ${gamma}$ , and K-FABP was tested for possible effects on PPARß.A luciferase reporter construct under the control of a consensusPPAR response element was cotransfected into COS-7 cells togetherwith expression vectors for a particular PPAR isotype and foran FABP. The cells were then treated with appropriate ligands,and the expression of the reporter was examined.

In studying the activity of PPAR ${alpha}$ , two ligands were used: linoleicacid, a naturally occurring pan-PPAR ligand, and Wy-14643, asynthetic PPAR ${alpha}$ -selective ligand (Fig. 1A). As expected, treatmentwith each of these ligands activated transcription of the reporter.The activation, however, was significantly enhanced upon cotransfectionof H-FABP. Expression of H-FABP augmented the transcriptionalactivity of PPAR ${alpha}$ under all the conditions used and led to a>3-fold enhancement in the presence of 1 µM Wy-14643.The transcriptional activity of PPAR ${gamma}$ was examined in the presenceof linoleic acid as well as the natural PPAR ${gamma}$ ligand PGJ2 (Fig.1B). Like H-FABP for PPAR ${alpha}$ , A-FABP markedly enhanced the transcriptionalactivity of PPAR ${gamma}$ both in the absence and in the presence ofan exogenous ligand. As discussed in the introduction, PPARsrespond to a wide variety of ligands, including naturally occurringfatty acids that are present in cells even without additionof exogenous ligands. The enhancement of transcriptional activityby the FABPs observed in the absence of added ligand (Fig. 1)most likely reflects the effect of the binding proteins on PPARactivities induced by the endogenous ligands.

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FIG. 1. H-FABP and A-FABP enhance the transcriptional activities of PPAR ${alpha}$ and PPAR ${gamma}$ , respectively. Transactivation assays were carried out by using COS-7 cells as described in Materials and Methods. (A) PPAR ${alpha}$ was cotransfected into cells with either an empty vector or an expression vector for H-FABP. The ability of the receptor to activate expression of the luciferase reporter was examined in the absence of ligand or in the presence of either the naturally occurring pan-PPAR ligand linoleic acid (18:2) or the PPAR ${alpha}$ -selective ligand Wy-14643 (WY). (B) PPAR ${gamma}$ was cotransfected into cells with either an empty vector or an expression vector for A-FABP. The transcriptional activity of the receptor was examined in the absence of ligand or in the presence of either linoleic acid (18:2) or the naturally occurring PPAR ${gamma}$ ligand PGJ2. Luciferase activity was normalized to the activity of ß-galactosidase.

The selectivity of FABP function was further investigated byexamining the effects of A-FABP and K-FABP on the transcriptionalactivities of PPARß and PPAR ${gamma}$ . In this series of experiments,synthetic ligands that are selective for PPARß (L165041)or PPAR ${gamma}$ (troglitazone) were used (Fig. 2). Addition of 0.2 µMtroglitazone to cells overexpressing PPAR ${gamma}$ resulted in $~$ 3-foldactivation of the reporter. Coexpression of A-FABP in thesecells markedly augmented the ability of the ligand to inducePPAR ${gamma}$ -mediated transactivation and did so in a dose-dependentfashion (Fig. 2A). In contrast, overexpression of K-FABP hadlittle effect on the transcriptional activity of PPAR ${gamma}$ . On theother hand, K-FABP markedly activated PPARß in a dose-dependentmanner, while A-FABP had no effect on the activity of this receptor(Fig. 2B). Hence, A-FABP and K-FABP selectively enhance theactivities of PPAR ${gamma}$ and PPARß, respectively.

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FIG. 2. A-FABP and K-FABP selectively enhance the transcriptional activities of PPAR ${gamma}$ and PPARß. Transactivation assays were carried out by using COS-7 cells as described in Materials and Methods. (A) Cells were cotransfected with PPAR ${gamma}$ and either an empty vector (vec) or an expression vector for either K-FABP (K) or A-FABP (A). The transcriptional activity of PPAR ${gamma}$ was examined in the absence or presence of the PPAR ${gamma}$ -selective ligand troglitazone (TZD). (B) Cells were cotransfected with PPARß and either an empty vector or an expression vector for either K-FABP or A-FABP. The transcriptional activity of PPARß was examined in the absence or presence of the PPARß-selective ligand L165041.

Ligand selectivities of FABPs and PPARs. The data in Fig. 2 demonstrate that the transcriptional activitiesof PPAR ${gamma}$ and PPARß are selectively enhanced by A-FABPand K-FABP, respectively. It is possible that this behaviorstems from a specific response of the FABPs to the selectivePPAR isotype ligands or is mediated through selective A-FABP-PPAR ${gamma}$ and K-FABP-PPARß interactions. Alternatively, A-FABPmay fail to augment PPARß activity simply becauseit does not bind the ligand for this receptor. Similarly, K-FABPmay not associate with the ligand for PPAR ${gamma}$ . Hence, the bindingaffinities of K-FABP and A-FABP for the PPAR ligands used inthis study were measured. K_d characterizing the interactionsof the FABPs with these ligands were measured by fluorescencecompetition assays by using the synthetic fluorescent LCFA parinaricacid as a probe. The method requires two steps (27). In thefirst step, the K_d for the association of parinaric acid witha protein is measured by fluorescence titrations. Parinaricacid associates with PPARs and FABPs with high affinity, andits fluorescence is significantly enhanced upon binding to theseproteins (27). The association of the probe with a protein canthus be followed by monitoring the increase in probe fluorescenceupon binding. Representative titrations of A-FABP and K-FABPwith parinaric acid are shown in Fig. 3A and B, respectively.Fluorescence increased in a saturable fashion upon titrationwith parinaric acid. Continuing addition of the probe followingsaturation resulted in additional increases which had a linearappearance. This linear increase stemmed from the fluorescenceof unbound parinaric acid added to the mixtures (27). Titrationcurves were corrected for the nonspecific linear increase influorescence. Corrected curves (Fig. 3A and B) were analyzedby fitting to a equation derived from simple binding theory(34) to yield the number of binding sites and the K_d for theassociation of parinaric acid with the respective proteins.In the second step, K_d for binding of nonfluorescent ligandswere measured by monitoring their abilities to compete withparinaric acid for binding. Protein was precomplexed with parinaricacid and titrated with the nonfluorescent ligand. The bindingof the nonfluorescent ligand was monitored by following thedecrease in the fluorescence of parinaric acid that accompaniedits displacement from the ligand binding pocket (Fig. 3C to F).The K_d for the nonfluorescent ligand was extracted fromthe EC₅₀ of the competition curve and the measured K_d for parinaricacid. By this method, the K_d for the association of K-FABP,A-FABP, PPARß, and PPAR ${gamma}$ with troglitazone and withL165041 were measured. The values (Table 1) reveal that theligands associate with K-FABP and A-FABP with similar affinities.Hence, the selectivity of the effects of the binding proteinson the transcriptional activities of the receptors does notsimply originate from differential ligand binding properties.

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FIG. 3. Determination of the ligand binding affinities of A-FABP and K-FABP. The K_d for the association of A-FABP (A) or K-FABP (B) with parinaric acid was measured by fluorescence titration. Protein (1 µM) was titrated with parinaric acid from a concentrated ethanolic solution. Fluorescence ( ${lambda}$ _ex = 303 nm; ${lambda}$ _em = 413 nm) was measured after each addition. Representative curves are shown. Titration curves were corrected for nonspecific increases in fluorescence due to addition of free parinaric acid. Corrected data (solid circles) were analyzed by fitting to an equation derived from binding theory to obtain the K_d and the number of ligand binding sites (solid lines through data points). The Kd for the association of troglitazone (C and D) and L165041 (E and F) with A-FABP (C and E) and K-FABP (D and F) were measured by competition fluorescence titrations. Protein was complexed with parinaric acid at a molar ratio corresponding to the measured number of binding sites. FABP-parinaric acid complexes were titrated with the appropriate ligand until a plateau was reached. K_d for the nonfluorescent ligands were calculated by using the EC₅₀ of the competition curves and the measured K_d for parinaric acid.

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TABLE 1. K_d characterizing the interactions of PPARß-LBD PPAR ${gamma}$ -LBD, A-FABP, and K-FABP with ligands

K-FABP and A-FABP undergo nuclear localization in response to ligands for PPARß and PPAR ${gamma}$ , respectively. PPARs are nuclear proteins, while FABPs are usually describedas cytosolic. The observations that some FABPs enhance the transcriptionalactivities of selected PPARs thus raise the question whetherthese effects are exerted directly, which would require thepresence of the FABPs in the nucleus, or whether they stem fromindirect activities such as classical functions of FABPs inenhancing the influx of ligands into the cells or facilitatingligand transport in the cytosol. To examine the subcellularlocation of FABP, constructs harboring either K-FABP or A-FABPfused with GFP were generated and transfected into COS-1 cells.The locations of the GFP-FABPs in the cells were then studiedby confocal microscopy. In the absence of ligand, A-FABP waspredominantly cytosolic and appeared to be excluded from thenucleus (Fig. 4A). Addition of the PPAR ${gamma}$ ligand rosiglitazoneresulted in a dramatic redistribution of A-FABP into the nucleus(Fig. 4B). Similarly, this protein localized to the nucleusin response to the natural pan-PPAR agonist linolenic acid (Fig.4C). In contrast, A-FABP remained cytosolic following additionof the PPARß ligand L165041 (data not shown). LikeA-FABP, K-FABP was predominantly cytosolic in the absence ofligand (Fig. 4D). The cellular distribution of K-FABP did notchange upon addition of the PPAR ${gamma}$ ligand rosiglitazone (datanot shown), but this binding protein located into the nucleusfollowing addition of either the PPARß ligand L165041or the pan-ligand linolenic acid (Fig. 4E and F, respectively).Hence, A-FABP and K-FABP move to the nucleus in specific responseto ligands for PPAR ${gamma}$ and PPARß, respectively.

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FIG. 4. A-FABP and K-FABP translocate into the nucleus in response to ligands for PPAR ${gamma}$ and PPARß, respectively. Expression vectors harboring either A-FABP (A through C) or K-FABP (D through F) tagged with GFP were transfected into COS-1 cells, and the subcellular locations of the proteins were examined by confocal microscopy. Images represent superpositions of the fluorescence and bright-field images of the same field. Ligands were added 3 to 4 h prior to imaging as follows: none (A and D), 1 µM troglitazone (PPAR ${gamma}$ ligand) (B), 5 µM linolenic acid (C and F), and 1 µM L165041 (PPARß ligand) (E).

Nuclear localization of K-FABP is essential for its ability to enhance the transcriptional activity of PPARß. In view of the above observations, we sought to further dissectpossible contributions of extranuclear versus nuclear activitiesof an FABP on the transcriptional activity of its cognate PPAR.To this end, a K-FABP construct that contains the NES DLCQAFSDVILAat its amino terminus was generated. NESs of this type are usedby a variety of proteins to facilitate their export from thenucleus into the cytoplasm (33, 43). Hence, fusing the sequenceto K-FABP will result in a shift in its subcellular distributionto the cytosol. If K-FABP modulates the activity of PPARßthrough cytosolic activities such as facilitation of influxor cytosolic transport of ligands, it can be expected that similarenhancements will be observed when either native K-FABP or K-FABPcontaining an NES is overexpressed in cells. On the other hand,if the ability of K-FABP to augment PPARß activitydepends on nuclear function, this ability will be impaired whenthe protein is excluded from the nucleus. The ability of NES-K-FABPto enhance the transcriptional activity of PPARß wasexamined by transactivation assays (Fig. 5). The data showedthat while expression of K-FABP markedly augmented the abilityof PPARß to activate transcription of the reportergene, overexpression of NES-K-FABP had no effect on the receptor'stranscriptional activity. Thus, ligand-induced movement of K-FABPinto the nucleus is essential for enabling the protein to enhanceligand-induced PPARß-mediated transcriptional activation.

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FIG. 5. K-FABP harboring an NES (NES-K-FABP) does not enhance the transcriptional activity of PPARß. Transactivation assays were carried out using COS-1 cells as described in Materials and Methods. Cells were cotransfected with PPARß and either an empty vector (vec) or an expression vector for either K-FABP (K) or NES-K-FABP (NES-K). The transcriptional activity of PPARß was examined in the absence or presence of the PPARß ligand L165041.

A-FABP and K-FABP selectively interact with PPAR ${gamma}$ and PPARß, respectively, and do so in a ligand-dependent fashion. Movement of A-FABP and K-FABP into the nucleus in the presenceof a cognate ligand for the "correct" PPAR colocalizes thesebinding proteins and receptors to the same cellular compartmentunder conditions where the PPARs become activated. Hence, enhancementof the transcriptional activity of PPAR by FABP may be mediatedby direct interactions between the two proteins. In order toexamine this possibility, coprecipitation experiments were carriedout. FABPs tagged with either GST or hexahistidines were expressedin E. coli and purified by affinity chromatography. ³⁵S-labeledPPARß and PPAR ${gamma}$ were synthesized by a coupled in vitrotranscription-translation system. The tagged FABPs, immobilizedon appropriate Sepharose beads, were incubated with ³⁵S-labeledPPARs in the presence or absence of appropriate ligands, andthe beads were centrifuged, washed, and resolved by SDS-PAGE.PPAR that coprecipitated with the FABP was then visualized byautoradiography. A weak association was observed between PPAR ${gamma}$ and the GST-tagged or histidine-tagged A-FABP in the absenceof ligand, but the interaction was significantly stabilizedin the presence of the PPAR ${gamma}$ ligand troglitazone (Fig. 6A andB). In contrast, A-FABP did not form an observable complex withPPARß in the absence of ligand or in the presenceof either troglitazone or the PPARß-selective ligandL165041 (Fig. 6B). K-FABP associated with PPARß inthe presence of the PPARß ligand L165041, albeit withan apparent affinity which seems to be weaker than that of theA-FABP-PPAR ${gamma}$ association (Fig. 6C). K-FABP did not associatewith PPAR ${gamma}$ in the absence of ligand or in the presence of eithertroglitazone, L165041, or palmitic acid (data not shown).

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FIG. 6. A-FABP and K-FABP interact with PPAR ${gamma}$ and PPARß selectively and in a ligand-dependent fashion. Coprecipitation assays were carried out by using bacterially expressed FABPs and ³⁵S-labeled in vitro transcribed-translated PPARs as described in Materials and Methods. (A) GST-tagged A-FABP was immobilized on glutathione-agarose and incubated with ³⁵S-labeled PPAR ${gamma}$ in the absence or presence of the indicated concentration of the PPAR ${gamma}$ ligand troglitazone (TZD). (B) Histidine-tagged A-FABP was immobilized on Ni²⁺-Sepharose and incubated either with ³⁵S-labeled PPAR ${gamma}$ in the absence or presence of troglitazone or with PPARß in the absence or presence of either troglitazone or the PPARß ligand L165041 (L). (C) GST or GST-tagged K-FABP was immobilized on glutathione-agarose and incubated with ³⁵S-labeled PPARß in the absence or presence of L165041.

A-FABP channels troglitazone to PPAR ${gamma}$ , but K-FABP does not. The data in Fig. 6 suggest that A-FABP and K-FABP interact withPPAR ${gamma}$ and PPARß, respectively, and that they do soonly in the presence of a ligand that is selective for the PPARisotype with which they interact. The interactions, however,appear to be exceedingly weak (Fig. 6). We note that this isreminiscent of the characteristics of the complex that formsbetween CRABP-II and RAR in the presence of retinoic acid. Thiscomplex was found to be a short-lived intermediate and couldnot be visualized by using a variety of methodologies aimedat demonstrating protein-protein interactions, including coprecipitationassays (5, 12). We thus sought to further examine whether anFABP directly interacts with a PPAR and to explore the functionalconsequences of these putative interactions. We hypothesizedthat, like the function of CRABP-II in activating RAR, interactionsbetween FABPs and PPARs may serve to facilitate the ligationof the PPAR by direct channeling of ligands between cognatebinding proteins and receptors. We thus investigated the mechanismby which ligands move from either A-FABP or K-FABP to PPAR ${gamma}$ .

Theoretically, transfer of a ligand from a donor protein (FABP)to an acceptor protein (PPAR) may occur by one of two possiblemechanisms. In one scenario, the ligand dissociates from thedonor into the aqueous phase (donor-ligand ${leftrightarrow}$ donor + ligand),followed by association with the acceptor (ligand + acceptor ${leftrightarrow}$ acceptor-ligand). In this case, the rate-limiting step forthe transfer reaction will be the dissociation of the donor-ligandcomplex (12). Hence, the rate constant of the transfer reactionwill be independent of the concentrations of the proteins.

In a second scenario, the ligand moves from the donor to theacceptor by channeling, i.e., by a process that involves directprotein-protein interactions and that bypasses the aqueous phase(donor-ligand + acceptor $->$ acceptor-ligand + donor). In thiscase, the rate of the reaction will be limited by the frequencyof productive collisions between the donor and the acceptor,and it will increase as the donor/acceptor ratio is increased.

The mechanism by which a ligand moves from an FABP to a PPARmay thus be studied by examining the dependence of the rateconstant of the transfer reaction on the donor/acceptor ratio.

To monitor the transfer of ligand between FABP and PPAR, a fluorescence-basedsystem was developed. The PPAR ${gamma}$ -LBD was bacterially expressedand purified. The PPAR ${gamma}$ -LBD was used because of technical difficultiesencountered in bacterial expression of full-length PPAR. However,the question being addressed is whether the putative FABP-PPARinteractions mediate ligand channeling. If such interactionsoccur, they are likely to involve regions of the donor and acceptorproteins that are near the corresponding ligand binding sites;for PPAR, these would be within LBD. The report that the CRABP-IIinteraction domain of RAR, a protein which is homologous toPPAR, is present within the receptor's LBD (5) further supportsthe suitability of using the PPAR-LBD for these studies. PurifiedPPAR ${gamma}$ -LBD was covalently labeled with the fluorescent probe N-(1-pyrenebutanoyl)cysteicacid succinimidyl ester (see Materials and Methods). Pyreneis an environmentally sensitive probe, i.e., its fluorescenceproperties respond to conformational alterations in its vicinity,such as those that accompany ligand binding by a protein. Thecovalent labeling did not alter the affinity of PPAR ${gamma}$ -LBD forparinaric acid, verifying that it did not result in proteindenaturation or misfolding. The ability of the protein-boundprobe to serve as a readout for the movement of ligand fromA-FABP to the receptor was then examined. In this control experiment,we also wanted to verify that a ligand which is initially boundto an FABP will indeed transfer to the PPAR upon mixing of thetwo proteins. Pyrene-labeled PPAR ${gamma}$ -LBD was titrated with A-FABPprecomplexed with troglitazone. As shown in Fig. 7A, the fluorescenceof pyrene-labeled PPAR ${gamma}$ decreased upon titration with the A-FABP-troglitazonecomplex to reach a plateau upon saturation. These observationsindicate that the PPAR-bound pyrene moiety properly sensed movementof the ligand from the FABP to the receptor and can be usedas a readout for the transfer reaction.

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FIG. 7. A-FABP directly channels troglitazone to PPAR ${gamma}$ -LBD, while K-FABP does not. The dependence of the rate of transfer of troglitazone (TZD) from FABP to PPAR ${gamma}$ was examined. PPAR ${gamma}$ -LBD was covalently labeled with a pyrene moiety. (A) The labeled protein (1 µM) was titrated with A-FABP precomplexed with troglitazone. Fluorescence ( ${lambda}$ _ex = 342 nm; ${lambda}$ _em = 377 nm) decreased upon titration until a plateau was reached at saturation. (B and C) To determine the rate constants for ligand transfer from FABP to PPARß-LBD, pyrene-labeled PPARß-LBD was mixed with A-FABP (B) or K-FABP (C) precomplexed with troglitazone. Mixing was accomplished using a stopped-flow apparatus. Final protein concentrations for the representative traces shown were 1 µM PPARß-LBD and 5 µM FABP-ligand complexes. Traces were analyzed by fitting to a single first-order reaction (solid line through data points) to obtain the pseudo-first-order rate constant of the reaction. (D) t_1/2 for transfer of troglitazone from A-FABP (solid circles) or K-FABP (open circles) to PPARß-LBD as a function of the FABP/PPAR molar ratio.

A-FABP or K-FABP was precomplexed with troglitazone and mixedwith pyrene-labeled PPAR ${gamma}$ . Mixing was accomplished by using astopped-flow apparatus which allowed for monitoring reactionrates in the subsecond range. Transfer of troglitazone fromthe FABP to PPAR ${gamma}$ was then monitored by following the time-dependentdecrease in the fluorescence of pyrene-labeled PPAR which accompaniedmovement of the ligand from the binding protein to the receptor(Fig. 7B and C). Traces were fit to a single first-order reactionin order to obtain the apparent rate constant of the transferreaction. To determine the mechanisms of transfer of troglitazonefrom the binding proteins to PPAR ${gamma}$ , rate constants were determinedat different FABP/PPAR ${gamma}$ molar ratios (Fig. 7D). The data clearlyshow that the half-life (t_1/2) for transfer of troglitazonefrom K-FABP to PPAR ${gamma}$ was independent of the donor/acceptor ratio,indicating that it requires prior dissociation of the ligandfrom this binding protein, followed by association with thereceptor. In contrast, the t_1/2 for movement of troglitazonefrom A-FABP to PPAR ${gamma}$ strongly depended on the donor/acceptorratio. This behavior indicates that ligand transfer from A-FABPto PPAR ${gamma}$ is mediated by direct protein-protein interactions betweenthis binding protein and the receptor. These data establishthat while K-FABP acts as a passive vehicle which binds andreleases this ligand in response to concentration gradientsand shifts in equilibrium conditions, A-FABP delivers troglitazoneto PPAR ${gamma}$ by channeling between the two proteins. These observationsshow further that the direct A-FABP-PPAR ${gamma}$ interactions resultin significant facilitation of the formation of the PPAR ${gamma}$ -troglitazonecomplex and thus may be the basis for the enhancing effect ofA-FABP on PPAR ${gamma}$ -mediated transactivation (Fig. 2).

To further examine factors that control these interactions,the mechanism of transfer of two other ligands from A-FABP toPPAR ${gamma}$ was determined. These ligands, the fluorescent probes parinaricacid and 8-anilino-1-naphthalenesulfonate, bind to both A-FABPand PPAR ${gamma}$ with K_d of 30 to 40 nM (Table 1; also data not shown).The t_1/2 values for transfer of parinaric acid at A-FABP/PPAR ${gamma}$ molar ratios of 1, 10, and 20 were found to be 8.7 ±0.3, 8.9 ± 0.6, and 8.8 ± 0.7 s, respectively.The t_1/2 values for movement of ANS at A-FABP/PPAR ${gamma}$ molar ratiosof 0.5, 5, and 10 were 0.04 ± 0.004, 0.04 ± 0.001,and 0.038 ± 0.002 s, respectively. Hence, movement ofthese ligands from the binding protein to the receptor displayedsimilar rate constants across a wide range of donor/acceptorratios. The observations that, unlike troglitazone, these ligandsdo not induce productive interactions between A-FABP and PPAR ${gamma}$ reveal that the selectivity of FABP-PPAR interactions is governednot only by the nature of the particular proteins but also bythe presence of specific agonists.

In the absence of ectopic PPARß, K-FABP augments the receptor's transcriptional activity only when the level of ligand is limiting. An important question that arises from the observations thatFABPs potentiate PPAR-mediated transcriptional activation relatesto the physiological conditions under which this activity becomesimportant. To address this question, the effect of K-FABP onthe activity of PPARß was investigated by transactivationassays carried out in the absence of ectopic expression of PPAR,i.e., relying on the (limiting) endogenous level of the receptorin the cells. The range of ligand doses for which the activitiesof PPARß are responsive to the presence of K-FABPwas studied (Fig. 8). The data revealed that expression of K-FABPmarkedly enhanced the transcriptional activity of PPARßat low concentrations of the PPARß ligand L165041.However, the ability of the binding protein to augment transcriptionalrates was rapidly lost when the concentration of the ligandwas raised. It could be argued that, at high ligand concentrations,K-FABP did not affect transcriptional rates because the reportervector became saturated. However, the observations indicatedthat K-FABP lost its potentiating activity upon elevation ofligand concentrations even under conditions that are far fromthe observed maximal activity (Fig. 8, inset). Hence, K-FABPis efficacious in enhancing PPARß activity, but onlyat very low ligand concentrations.

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FIG. 8. K-FABP enhances the transcriptional activity of PPARß only under limiting ligand concentrations. Transactivation assays were carried out by using COS-7 cells as described in Materials and Methods. Cells were cotransfected either with an empty vector or with an expression vector for K-FABP. The transcriptional activity of PPARß was examined at various concentrations of the PPARß-selective ligand L165041. (Inset) Fold activation observed upon cotransfection of K-FABP relative to fold activation in the absence of ectopic binding protein.

K-FABP plays an important role in PPARß-mediated keratinocyte differentiation. Taken together, the results reported above suggest that someFABPs function to activate specific PPARs by transporting PPARligands to the nucleus and directly delivering them to the receptors.Such an activity will facilitate the formation of the activatedform of PPARs, i.e., the liganded receptors, thereby enhancingthe efficacy of PPAR action. This hypothesis implies that thepresence of a particular FABP in cells may be essential forthe activities of the specific PPAR with which it interacts.We thus set out to examine whether K-FABP is involved in a biologicalactivity that is mediated by PPARß.

We recently demonstrated that PPARß is critical fordifferentiation of keratinocytes induced by the inflammation-associatedsignal TNF- ${alpha}$ (44). We showed further that, in addition to up-regulatingthe expression of PPARß, treatment of keratinocyteswith TNF- ${alpha}$ also induces synthesis of a PPARß ligandby these cells (44). In view of the observations that the activityof K-FABP is especially important at low ligand concentrations(Fig. 8), exploring the potential involvement of this proteinin PPARß activities requires a model system in whichligand levels are low (i.e., physiological). TNF- ${alpha}$ -induced keratinocytedifferentiation, a process that is mediated by PPARßunder conditions where activating ligands are generated intracellularly,is thus a particularly suitable model system for investigatingpossible functional interactions between K-FABP and this receptor.Primary keratinocytes were isolated and cultured. Cells werethen transiently transfected with an expression vector harboringa K-FABP antisense construct 12 h prior to treatment with TNF- ${alpha}$ .Western blot analysis demonstrated that transfection of theantisense construct significantly reduced the expression levelof K-FABP, although it did not abolish it completely. The reducedexpression level was maintained longer than 12 h following additionof TNF- ${alpha}$ , the critical time frame for differentiation inductionin these cells (Fig. 9A). Treatment of the keratinocytes withTNF- ${alpha}$ induced growth arrest and differentiation, as could beseen by an increase in the expression of the mRNA of the differentiationmarker involucrin and a concomitant decrease in levels of thecell cycle protein cyclin A beginning at 12 h posttreatment(Fig. 9B, left panels, and 9C). Cells expressing the K-FABPantisense construct underwent growth arrest following TNF- ${alpha}$ treatment,as could be seen by the decrease in cyclin A expression (Fig.9B, right, and 9C). However, these cells displayed a significantdecrease in the expression of involucrin, indicating that differentiationwas markedly inhibited (Fig. 9B, right, and 9C). This inhibitionor delay of differentiation was observed despite the incompleteinhibition of K-FABP expression in the cells (Fig. 9A).

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FIG. 9. TNF- ${alpha}$ -induced differentiation is inhibited or delayed in keratinocytes expressing a K-FABP antisense construct. Primary mouse prekeratinocytes were cultured, and their differentiation was induced by addition of TNF- ${alpha}$ as described in Materials and Methods. (A) Expression of K-FABP in keratinocytes (control) or keratinocytes transfected with a vector harboring antisense (AS) K-FABP was examined by Western blotting using antibodies against K-FABP. Cells were transfected 12 h prior to treatment with TNF- ${alpha}$ , and the expression level of K-FABP was monitored up to 48 h posttreatment. (B) Expression of the differentiation marker involucrin and the cell cycle protein cyclin A in primary keratinocytes and in keratinocytes expressing a K-FABP antisense construct was monitored by an RPA as described in Materials and Methods. (C) Relative expression levels of involucrin and cyclin A in TNF- ${alpha}$ -treated primary keratinocytes or keratinocytes expressing a K-FABP antisense construct were measured by quantitation of the bands shown in Fig. 9B and normalization for the expression of L27.

The conclusion that reduction in the expression level of K-FABPresults in a marked inhibition of keratinocyte differentiationwas further emphasized by examining the phenotype of the cells.Noninduced keratinocytes displayed a polygonal shape with distinctintercellular spaces, giving the cell sheet a paving stone-likeappearance when cells were confluent (Fig. 10A). Upon induction,distinct spaces between cells became much less apparent. Asindividual cell borders became indistinct, i.e., squamous, stratificationbegan. The differentiated cells became larger and developedphase-dense outlines (Fig. 10B). In contrast, in keratinocytesexpressing a K-FABP antisense construct, intercellular spaceswere retained and fewer focal areas of stratification were observed15 h after TNF- ${alpha}$ treatment (Fig. 10C). These observations thusdemonstrate that the presence of high levels of K-FABP is essentialfor proper TNF- ${alpha}$ -induced, PPARß-mediated keratinocytedifferentiation.

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FIG. 10. Expression of a K-FABP antisense construct inhibits or delays TNF- ${alpha}$ -induced differentiation of keratinocytes. Primary mouse prekeratinocytes were cultured as described in Materials and Methods and were visualized by direct bright-field microscopy. (A) Cultured prekeratinocytes; (B) keratinocytes 15 h post-TNF- ${alpha}$ -treatment; (C) keratinocytes expressing a K-FABP antisense construct 15 h post-TNF- ${alpha}$ -treatment.

DISCUSSION

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Discussion

The specific roles that the multiple FABP isotypes play in thebiology of their ligands is not well understood. It is usuallybelieved that these proteins serve a general function in solubilizationand trafficking of their ligands and that they affect lipidmetabolism through their transport function (3, 6, 15, 36, 50).Support for the involvement of FABPs in fatty acid transporthas been provided by reports that diffusion of these ligandsboth in vitro and in cells is facilitated in the presence ofFABP (46-48). The nonspecific nature of this activity has beenemphasized by the observation that bovine serum albumin couldreplace FABP in establishing intracellular diffusive flux offatty acids (29). Other roles for FABPs have been implied bysome studies. It has been suggested that I-FABP, H-FABP, andA-FABP may facilitate the dissociation of fatty acid from membranes(19, 21, 28, 40). It has also been reported that H-FABP associateswith the scavenger receptor CD36 (41), although the functionalsignificance of this observation remains unclear. Recently,the possibility that a connection exists between the activitiesof FABPs and PPARs has been explored. It was reported that L-FABPassociates with specific nuclear membrane proteins in the presenceof long-chain fatty acids or synthetic PPAR ligands (25). Overexpressionof A-FABP and K-FABP was reported to inhibit the transcriptionalactivities of all three PPAR subtypes both in the absence andin the presence of exogenous ligand (18). It was also recentlyshown that L-FABP interacts with PPAR ${alpha}$ and PPAR ${gamma}$ both in the absenceand in the presence of ligands and that decreased expressionof L-FABP in cells results in down-regulation of the transcriptionalactivities of ligands for all three PPAR isotypes (49). Themechanism by which L-FABP may exert these seemingly nonselectiveeffects has not been clarified. We note as well that the basisof the inconsistency between the report that A-FABP and K-FABPinhibit PPAR activity nonselectively (18) and the data in thepresent report is not clear to us.

Here, we provide evidence that some FABPs act in concert withPPARs and that this activity is highly selective for particularFABP-PPAR pairs: A-FABP specifically enhances the activity ofPPAR ${gamma}$ , while K-FABP activates PPARß. The data demonstratefurther that A-FABP and K-FABP relocate from the cytosol tothe nucleus in response to particular PPAR ligands and thatthe nuclear localization of K-FABP is critical for allowingthis protein to augment the activity of its cognate receptor.Interestingly, we found that both the ligand-induced nuclearlocalization of the FABPs and their ability to enhance transcriptionalactivity are highly selective for the ligand of a particularPPAR isotype. This is so despite the apparent lack of selectivityin ligand binding by the FABPs (Table 1). These observationssuggest that FABPs employ different modes of binding towarddifferent ligands. In other words, they suggest that some ligandsinduce correct alterations in the FABP structure, leading toactivation of the proteins, while others do not.

In addition to their functional interactions, A-FABP and K-FABPwere found to physically associate with PPAR ${gamma}$ and PPARß,respectively. These interactions were specific for particularprotein pairs and depended on the presence of particular ligands.The observed FABP-PPAR interactions were found to be weak, suggestingthat the resulting complex is transient in nature, i.e., itcomprises a short-lived intermediate which dissociates rapidlyfollowing transfer of the ligand. Nevertheless, examinationof the mechanism by which a ligand moves from FABPs to PPAR ${gamma}$ established that direct and selective FABP-PPAR interactionsdo occur and are functionally important. These studies revealedthat A-FABP delivers troglitazone to PPAR ${gamma}$ through direct associationbetween the binding protein and the receptor. The selectivityof these interactions was confirmed by the observations that,unlike A-FABP, K-FABP does not interact with PPAR ${gamma}$ , i.e., movementof troglitazone from K-FABP to the receptor proceeds throughsimple diffusion. A-FABP-mediated channeling of ligands to PPAR ${gamma}$ significantly facilitated the ligation of the receptor, providinga rationale for understanding the ability of this binding protein(which is not shared by K-FABP) to enhance PPAR ${gamma}$ transcriptionalactivity. A-FABP and K-FABP thus appear to function in a mannersimilar to that of CRABP-II in regulating the activity of nuclearhormone receptors, i.e., their association with particular ligandsin the cytosol leads to translocalization into the nucleus,where they form a short-lived complex with a cognate PPAR. Thiscomplex mediates ligand channeling to the receptor, therebyfacilitating its activation and enhancing its transcriptionalactivity. The importance of FABPs for biological activitiesmediated by PPARs is demonstrated by the observation that thepresence of K-FABP is essential for the ability of PPARßto properly induce differentiation of keratinocytes. Taken together,the data reveal that the A-FABP-PPAR ${gamma}$ and K-FABP-PPARßpairs cooperate tightly in regulating transcription in adipocytesand keratinocytes, respectively. Hence, the tissue-specificfunctions of PPARs are found to be closely supported by thetissue-specific expression of particular FABPs.

Functional interactions between FABPs and PPARs are also suggestedby examination of mice and cells that are deficient in FABPexpression. It has recently been reported that PPARßplays a central role in neuronal differentiation (39) and thatreduction in K-FABP expression in the neuronal cell line PC12results in inhibition of differentiation of these cells (1).Taken together with our data demonstrating the importance ofK-FABP and its cognate receptor, PPARß, in inducingdifferentiation in keratinocytes, these observations raise theintriguing possibility that the same FABP-PPAR pair plays asimilar role in mediating neuronal differentiation. RegardingA-FABP, it has been reported that mice in whom expression ofthis protein has been inhibited, like their wild-type counterparts,develop obesity when fed with a high-fat diet. However, unlikecontrol mice, A-FABP^-/- animals do not become insulin resistantor diabetic. This striking phenotype was observed despite thefact that disruption of A-FABP in the null mice is compensatedfor by up-regulation of K-FABP in their adipose tissues (20).Interestingly, mice that are heterozygous for PPAR ${gamma}$ , like A-FABP-nullmice, display increased insulin sensitivity compared to wild-typeanimals (32). Although the exact role of PPAR ${gamma}$ in regulatinginsulin sensitivity is not clear at present, the similarityof the phenotypes of A-FABP^-/- mice and mice deficient in PPAR ${gamma}$ expression suggests that the two proteins act in concert. Inview of the present study, the observation that up-regulationof K-FABP expression does not functionally compensate for theloss of A-FABP in A-FABP^-/- mice appears to reflect the PPARselectivity of these FABPs. It should also be noted that PPAR ${gamma}$ has been reported to be essential for adipocyte differentiationboth in vitro and in vivo (38), while A-FABP-null mice do notdisplay an adipose tissue deficit (20). This apparent conflictis resolved by considering that the hypothesis put forward heredoes not propose that FABPs are absolutely essential for PPARactivity under all conditions. Clearly, PPARs can be activatedby ligands in the absence of a binding protein, most likelydue to the ability of these small ligands to enter the nucleusby free diffusion. Our data indicate, however, that FABPs functionby facilitating ligand delivery, i.e., they act to enhance transcriptionalactivation by providing increased fluxes. Indeed, we show thatthe potentiating activity of FABP is especially significantwhen cellular levels of ligands are limiting, i.e., under conditionsthat necessitate enhanced efficiency of ligand delivery. Theseobservations suggest that while FABPs are dispensable at highligand concentrations, they become essential at low concentrations.A prediction that can be derived from these observations isthat mice lacking A-FABP will display a more severe phenotypeunder conditions of ligand deficiency.

While the present study establishes that some FABPs physicallyand functionally cooperate with specific PPARs, several importantquestions remain to be explored. For example, the mechanismsthrough which FABPs locate to the nucleus in response to correctligands is not understood at present. Similarly, consideringthe close similarities of the overall folding of FABPs, thespecific structural features that allow them to discriminatebetween particular PPAR isotypes remain to be elucidated. Finally,it is worth noting that the existence of at least nine isotypesof FABP suggest that some of these proteins may have roles thatare different from the functions of A-FABP and K-FABP describedhere. The complete scope of the biological functions of FABPshas thus only begun to be elucidated.

ACKNOWLEDGMENTS

We thank David Cistola and Eric Xu for FABP and PPAR constructs,and we thank David Bernlohr for constructs and antibodies.

N.-S. Tan, N. S. Shaw, N. Vinckenbosch, and P. Liu contributedequally to this work.

This work was supported by grants from the NIH (grant CA68150to N.N.), and from the Swiss National Science Foundation andEtat de Vaud (to W.W. and B.D.). The assistance of the NovartisFoundation in supporting N.N.'s sabbatical leave in Lausanneis gratefully acknowledged.

FOOTNOTES

* Corresponding author. Mailing address: 225 Savage Hall, Cornell University, Ithaca, NY 14853. Phone: (607) 255-2490. Fax: (607) 255-1033. E-mail: nn14{at}cornell.edu.

REFERENCES

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