Human dendritic cell activities are modulated by the omega-3 fatty acid, docosahexaenoic acid, mainly through PPAR{gamma}:RXR heterodimers: comparison with other polyunsaturated fatty acids

There is accumulating evidence that omega-3 fatty acids maymodulate immune responses. When monocytes were differentiatedto dendritic cells (DCs) in the presence of docosahexaenoicacid (DHA), the expression of costimulatory and antigen presentationmarkers was altered in a concentration-dependent way, positivelyor negatively, depending on the markers tested and the maturationstage of the DCs. Changes induced by eicosapentaenoic acid andlinoleic acid were similar but less intense than those of DHA,whereas oleic acid had almost no effect. DHA-treated, matureDCs showed inhibition of IL-6 expression and IL-10 and IL-12secretion, and their lymphoproliferative stimulation capacitywas impaired. The phenotypic alterations of DCs induced by DHAwere similar to those already reported for Rosiglitazone (Rosi),a peroxisome proliferator-activated receptor ${gamma}$ (PPAR ${gamma}$ ) activator,and the retinoid 9-cis-retinoic acid (9cRA), a retinoid X receptor(RXR) activator. Moreover, DHA induced the expression of PPAR ${gamma}$ target genes pyruvate dehydrogenase kinase-4 and aP-2 in immatureDCs. The combination of DHA with Rosi or 9cRA produced additiveeffects. Furthermore, when DCs were cultured in the presenceof a specific PPAR ${gamma}$ inhibitor, all of the changes induced byDHA were blocked. Together, these results strongly suggest thatthe PPAR ${gamma}$ :RXR heterodimer is the pathway component activatedby DHA to induce its immunomodulatory effect on DCs.

Key Words: lymphocyte proliferation • immunological regulation • nuclear receptors • dentritic cell maturation

INTRODUCTION

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INTRODUCTION

Omega-3 fatty acids (FAs), reportedly having beneficial effectson cardiovascular diseases, atherosclerosis, and cancer [¹ ,² ], fulfill significant roles as regulators of the immune response[² , ³ ] as a result of their properties as anti-inflammatoryagents. The deficit in omega-3 FA ingestion in Western countriesmight act unfavorably in the increasing rate of diseases withan immunological basis, such as autoimmune and chronic inflammatorydisorders [⁴ ]. In this sense, some amelioration has been describedfor docosahexaenoic acid (DHA) treatment in rheumatoid arthritis,autoimmune nephritis, systemic lupus erythematosus, septic shock,asthma, psoriasis, and colitis [¹ , ⁵ ], which has motivatedmore intensive study on different cell types of the immune system.As a consequence, it has been found that DHA and eicosapentaenoicacid (EPA) alter lymphocyte, monocyte, macrophage, and NK phenotypeand function, primarily affecting cytokine secretion [² , ³ ,⁶ , ⁷ ]. Although all of these regulatory effects have beenwidely demonstrated, the underlying mechanism remains obscurein many cases. Polyunsaturated FAs (PUFAs), in general, altermembrane properties [⁸ ], modify signal transduction [⁹ ], transactivatesome genes, and serve as a source for the production of differentsecond messengers: eicosanoids, PGs, resolvins, and other lipidmediators [¹⁰ ¹¹ ¹² ¹³ ].

Dendritic cells (DCs) are professional APCs capable of migratingto lymph nodes and inducing potent primary responses [¹⁴ ¹⁵ ¹⁶ ].DCs play a pivotal role in the immune response, balancing betweentolerance and immunity and connecting innate and adaptive responses[¹⁴ , ¹⁶ ¹⁷ ¹⁸ ].

Despite the large number of studies already describing the effectsof fish oils and omega-3 PUFAs on many immune cell types, therehas recently been increasing interest in the action of DHA onDCs. In this sense, some of the effects of DHA, as well as EPAand arachidonic acid, on DCs have been reported [¹⁹ ²⁰ ²¹ ].However, the precise mechanism of the action of DHA and relatedFAs on the regulation of DC activities remains unknown.

One of the important regulators in lipid metabolism is peroxisomeproliferator-activated receptor ${gamma}$ (PPAR ${gamma}$ ), which regulates genesresponsible for lipid uptake, accumulation, and storage [²² ].Besides its role in adipocytes, it was also reported that PPAR ${gamma}$ is expressed in cells of monocytic origin such as macrophagesand DCs, where it plays an anti-inflammatory role by blockingthe induction of several proinflammatory cytokines [²³ ²⁴ ²⁵ ]and regulates lipid metabolism. PPAR ${gamma}$ forms a heterodimer withretinoic X receptors (RXR), subsequently regulating many targetgenes upon activation. PPAR ${gamma}$ are expressed at high levels inDCs, and DHA derivatives have been found to act as potent PPAR ${gamma}$ agonists [²⁶ ]. Furthermore, DHA itself has been reported tobe a natural ligand of RXR [²⁷ , ²⁸ ]. This fact together withthe similar effects of the specific PPAR ${gamma}$ and RXR activators[i.e., Rosiglitazone (Rosi) and 9cis Retinoic acid (9cRA)] onDCs to those reported here suggest to us the possibility thatthese nuclear receptors are involved in the mechanism of actionof DHA on DCs.

In this paper, we show that DHA acts on DCs by inhibiting theexpression of some costimulatory markers and the secretion ofimportant regulatory cytokines, as well as by limiting the lymphocytestimulatory capacity of DCs, and we confirm an impairment ofDC maturation described previously [²¹ ]. Furthermore, additiveeffects of DHA with other specific activators of PPAR ${gamma}$ or RXRare also described. The effects induced by DHA action on DCsare more intense than those induced by any other monounsaturatedFA or PUFA studied.

The DHA-induced expression of PPAR ${gamma}$ target genes in DCs togetherwith the phenotypic and functional alterations and the blockingeffects of specific PPAR ${gamma}$ :RXR inhibitors on the DHA-induced activitysuggest a mechanism of action for DHA involving activation ofthe heterodimer PPAR ${gamma}$ :RXR. These results point toward the potentialimplications for immunological function of a DHA-rich diet andthe possible usefulness of these FAs in reducing or complementingtreatments with agonists of PPAR ${gamma}$ :RXR receptors and suggest apossible participation of this FA and its putative receptorsin the physiological mechanisms of control of DC differentiationand maturation.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Cell isolation and generation of DCs
Human monocytes were purified from PBMCs isolated from freshbuffy coats (kindly provided by the Blood and Tissue Bank ofCatalonia, Spain) by Ficoll-Paque gradient centrifugation (AmershamBioscience, Uppsala, Sweden) and plastic adherence on gelatine-coatedflasks, as described previously [²⁹ ]. Lymphocytes obtainedby this process were resuspended in human autologous serum with10% DMSO and frozen until use.

When required, a negative selection purification method usingmonocyte-negative isolation kit II, according to the instructionsof the manufacturer, was also used (Dynal Biotech ASA, Oslo,Norway). After magnetic retention of Dynabead-attached cells,the supernatant fraction contained more than 85% CD14⁺ cells.

Monocytes were seeded (1x10⁶ cells/well) in six-well plates(Costar, Cambridge, MA, USA) and differentiated to immatureDCs by adding IL-4 (750 U/ml; Sigma-Aldrich, St. Louis, MO,USA) and GM-CSF (100 ng/ml; Leucomax 400, Novartis, Barcelona,Spain) in RPMI medium (Sigma-Aldrich). Cultures were fed withcytokines every 2–3 days. At Day 6, DCs showed phenotypiccharacteristics of immature DCs (CD14^neg, CD83^low, CD1a^high,HLA-DR^high, CD80^low, CD86^low). When mature DCs were needed,LPS (500 ng/ml, Sigma-Aldrich, EC 055:B5), TNF- ${alpha}$ (Sigma-Aldrich),or polyinosinic:polycytidylic acid (Sigma-Aldrich) was addedat Day 6, and DCs were cultured for 2 additional days.

DC treatment
Prior to addition of DC-differentiating cytokines, the indicatedconcentrations of DHA, EPA, oleic acid (OA), linoleic acid (LA),9cRA (Sigma-Aldrich), and Rosi (GlaxoSmithKline, Mississauga,Ontario, Canada) were added alone or in combinations. When necessary,10 µM GW9662 (Sigma-Aldrich) was added to cultures andincubated for 90 min at 37°C, 5% CO₂, prior to any othertreatment. The GW9662 addition was repeated on Day 3.

Flow cytometry
DCs were collected, and mAb, directly conjugated to FITC orPE, were subsequently used. The FITC-conjugated mouse mAb wereanti-CD1a, anti-CD83, anti-HLA-DR, and anti-CD36, and the PE-conjugatedmouse mAb were anti-CD14, anti-CD80, and anti-CD86 (BD PharMingen,San Diego, CA, USA). Data for at least 5 x 10³ DC regions/samplewere acquired and analyzed on a FACScan flow cytometer usingCellQuest (BD Biosciences, Mountain View, CA, USA), FlowJo (TreeStar, Inc., Ashland, OR, USA), and WinMDI software.

Chemotaxis assay
Immature DCs (5x10⁵) were seeded into a transwell chamber (5µm, Millipore, Billerica, MA, USA) in a 12-well plate,and migration to MIP-1 ${alpha}$ (10 ng/ml; R&D Systems, Wiesbaden,Germany) was analyzed after 1 h, counting the migrated cellsby gating DCs in a FACSCalibur cytometer for 4 min. After DCmaturation with LPS, as described above, migration to MIP-3β(10 ng/ml; PeproTech, Rocky Hill, NJ, USA) was performed undersimilar conditions as for MIP-1 ${alpha}$ .

Analysis of endocytic capacity
For the analysis of endocytic activity, 2 x 10⁵ DCs were incubatedwith FITC-Dextran (Sigma-Aldrich) for 30 min at 37°C. Asa control, 2 x 10⁵ DCs were precooled to 4°C prior to incubationwith dextran at 4°C for 30 min. The cells were washed fourtimes and analyzed on a FACSCalibur cytometer.

Carboxyfluorescein diacetate-succinimidyl ester (CFDA-SE) staining
To determine proliferation, lymphocytes obtained as describedabove were thawed and washed immediately with PBS to eliminateDMSO. Cells were incubated for 15 min at 4–8°C withDNase and MgCl₂ to avoid DNA debris and stained with 5 µMCFDA-SE (Molecular Probes, Leiden, Netherlands) for 10 min at37°C, followed by two steps of incubation (10 min at 37°C)and washing.

DC autologous stimulation of lymphocytes
Primary DCs were pulsed with Staphylococcal enterotoxin B (SEB;Sigma-Aldrich) antigen (1 µg/mL) for 4 h at 37°C ina humid atmosphere of 5% CO₂ and then irradiated prior to coincubationwith lymphocytes. Autologous stimulation was conducted in 96-wellculture plates in 200 µL RPMI 1640 containing 10% inactivatedFCS and antibiotics. DCs were mixed with 1 x 10⁵ autologousCFSE-labeled lymphocytes at a DC:lymphocyte ratio between 1:10and 1:160. Cells were allowed to proliferate for 96 h and werethen collected and analyzed in a FACScan flow cytometer usingappropriate software. The percent divided cells (%DvC; the initialnumber of lymphocytes that become activated by DCs) and theproliferation index (PI; the average number of divisions inthe lymphocyte population) were calculated using the FlowJoproliferation platform. Comparison between %DvC from samplesand controls at different ratios of DC:lymphocyte permits anapproximated calculation of the stimulatory capacity of theDCs.

RNA isolation and quantitative real-time RT-PCR analysis of PPAR ${gamma}$ target genes
Total RNA was prepared from $~$ 10⁶ DCs, differentiated and subjectedto the treatments described above. After extraction with a guanidiniumHCl/phenol mixture and isopropanol precipitation following theRoche Tripure isolation reagent protocol [³⁰ ], RNA was dissolvedin diethyl pyrocarbonate-treated water, and the integrity ofthe RNA samples was checked by electrophoresis in agarose geland the concentrations estimated spectrophotometrically. Typically,6–10 µg total RNA was obtained from one extraction.RNA was treated with RNase-free DNase for 1 h at 37°C. QuantitativemRNA expression analysis was performed using TaqMan real-timeRT-PCR (Applied Biosystems, Foster City, CA, USA). The RT reactionwas performed on 0.5 µg RNA using TaqMan standardizedreagents, and the real-time PCR reaction was performed usingTaqMan Universal PCR Master Mix and the following standardizedgene expression primer probes ("Assay-on-Demand"): FA-bindingprotein 4 (FABP4/aP2; Hs99699791_m1) and pyruvate dehydrogenasekinase-4 (PDK4; Hs00176875_m1). Samples were run in duplicateon the ABI-PRISM 7700HT sequence detection system (Applied Biosystems),and the mean value of the duplicate was used to calculate themRNA expression of the gene of interest, which was normalizedto that of the reference control [hypoxanthine guanine phosphoribosyltransferase (HPRT); Hs99999909_m1] using the 2- ${Delta}$ -comparativethreshold method, following the manufacturer’s instructions.

Measurement of cytokines
On Day 7, LPS was added to the DC cultures, and supernatantswere harvested 24 h later. Samples were then frozen at –80°Cuntil use. The human IL-10 and IL-12 levels were determinedusing the human IL-12 (p70) subunit and IL-10 BD OptEIA ELISAset, according to the instructions of the manufacturer (BectonDickinson, Franklin Lakes, NJ, USA). IL-6 gene expression wasanalyzed following the method described in the previous section.The primers and probe used were an Hs00174131_m1, Assay-on-Demandcombination from Applied Biosystems. Results were normalizedto that of the reference control (HPRT, Hs99999909_m1)

Statistics
Statistical analysis was performed using the SPSS 12.0 statisticalpackage (SPSS Inc., Chicago, IL, USA), and the nonparametricWilcoxon signed rank test was used for comparisons between controland experimental groups [³¹ ]. The significance level was placedat P < 0.05.

RESULTS

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RESULTS

DHA modulates differentiation of immature DCs from monocytes
Monocytes differentiated to DCs in the presence of GM-CSF andIL-4 over 6–8 days displayed low CD86 and CD80 and noCD83 or CD14 expression and were CD36⁺, HLA-DR⁺, and CD1a⁺⁺(Fig. 1 and Table 1 ). However, when this process was performedin the presence of DHA, a rise in the DC markers CD36, HLA-DR,CD83, and CD86 was observed, and CD86 showed the most strikingincrease (up to fivefold). Contrary to this, CD80 showed onlya slight decrease, and CD1a, expressed at high levels in untreatedcells, was inhibited with DHA treatment (a reduction of morethan 66% of CD1a+ cells; Fig. 1 and Table 1 ). The action ofDHA treatment was concentration-dependent, reaching its maximumeffect at 50 µM. Despite these phenotypic changes, inhibitionof the differentiation process from monocyte to immature DCwas ruled out from the functional characteristics of the cellsas well as the CD14^– phenotype.

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Figure 1. Changes in the differentiation process from monocyte to immature and mature DCs in the presence or absence of 50 µM DHA. Adherent monocytes were differentiated to DCs by 6 days culture in the presence of GM-CSF and IL-4. Maturation of DCs was induced by 2 additional days of culture with 500 ng/mL LPS. The surface expression level is indicated as mean fluorescence intensity (MFI) in each histogram.

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Table 1. Impact of DHA Concentration on the Immature and LPS-Matured DC Phenotype^a

DHA also alters the mature DC phenotype
LPS-matured DCs displayed a phenotype characterized by beingCD86++, HLA-DR++, CD83+, CD80+, CD1a+, with CD36 expressed atlow levels (Fig. 1 and Table 1 ). Surprisingly and contrastingwith the effects displayed in some markers on immature DCs,when DHA-treated DCs were matured with LPS, the costimulationand antigen presentation markers were down-regulated in a concentration-dependentmanner relative to the untreated DCs in number of positive cellsand MFI, except for the twofold up-regulation of CD36 (P<0.05;Fig. 1 and Table 1 ). TLR4 was not modulated significantlyby DHA, suggesting that FA effects were independent of thisreceptor (data not shown).

Effect of DHA on chemotaxis and uptake capacity in DCs
As phenotypic changes induced by DHA suggested differences inthe immature and mature characteristics of the treated DCs,the migration to MIP-1 ${alpha}$ in immature DCs and to MIP-3β inmature DCs was examined. As can be observed in Figure 2 , DHAincreases MIP-1 ${alpha}$ chemotaxis in immature DCs, whereas GW9662 blocksthe process (P<0.05). Contrarily, for MIP-3β, the chemotacticcapacity of the DHA-treated, mature DCs was decreased significantly(P<0.05) and the effect inhibited by GW9662 (Fig. 2) .

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Figure 2. Chemotaxis induced by MIP-1 ${alpha}$ and MIP-3β on immature and mature DCs, respectively. Mean of 10 different assays. Results are expressed as mean of the MFIs of the different flow cytometry assays. Statistical analysis was performed using the Wilcoxon signed rank test; *, P < 0.05 (different from untreated).

The FITC-dextran uptake capacity of treated, immature DCs wasalso tested. Treatment with DHA of up to 50 µM did notinduce statistically significant variations in the endocyticcapacity (data not shown). These results were coincident withthose for 9cRA and Rosi presented elsewhere [²⁹ ].

DHA effects are partially reproduced by other FAs
To determine whether the effects observed with DHA on DCs arerestricted to this FA or are a general feature of PUFAs, theactivities of other PUFAs: EPA, LA, and OA, belonging to theomega-3, omega-6, and omega-9 FA families, respectively—werealso tested. Immature DCs treated with the different PUFAs (Fig. 3A )displayed similar, although less intense, phenotypic alterationsto those obtained with DHA, except for EPA and LA, which incontrast to DHA, reduced CD36 expression. OA induced no phenotypicchanges except the up-regulation of CD80. The weak effects shownfor LA and OA could be incremented with higher concentrationsof these FAs but without reaching the intensities shown forDHA and EPA. When the other FAs were tested on mature DCs, theresults paralleled those obtained with DHA but again, to a lesserdegree (Fig. 3B) . The only difference was again in the expressionof CD36, which was not up-regulated with these FAs. OA onceagain produced no effects in the mature stage, in comparisonwith those using DHA.

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Figure 3. Changes in the differentiation process from monocytes cultured with GM-CSF and IL-4 to produce immature DCs (A) and LPS-matured DCs (B) induced by the presence 50 µM DHA, EPA, LA, or OA.

DHA and other PUFAs inhibit IL-12 and IL-10 secretion in DCs
IL-12 and IL-10 were evaluated in supernatants of DCs culturedfor 24 h with LPS in the absence or presence of DHA at increasingconcentrations. Secretion of IL-12p70 and IL-10 was diminishedin DHA-treated DCs relative to the untreated DCs, in a concentration-dependentmanner (Fig. 4 A and B ), reaching more than 60% inhibitionfor IL-12 and IL-10 secretions at 50 µM DHA. EPA, LA,and OA displayed the same pattern but with reduced inhibitoryeffects, and OA was the least active.

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Figure 4. Cytokine secretion of LPS-matured DCs in the presence of PUFAs. ELISA displaying IL-12 (A) and IL-10 (B) secretion at different FA concentrations normalized to control (100%). (C) Effect of DHA on the expression of the IL-6 gene studied by real-time RT-PCR. Statistical analysis was performed using the Wilcoxon signed rank test; *, P < 0.05 (relative to untreated). C+, positive control (matured DCs without any additional treatment).

DHA inhibits IL-6 expression in DCs
When DCs were cultured in the presence of 50 µM DHA, markedinhibition of IL-6 expression was observed (0.2±0.13that of control). This inhibition was greater when DHA was combinedwith RXR agonists 9cRA or HX630 (Fig. 4C) .

DHA down-regulates DC stimulation of autologous lymphocytes
DCs, differentiated in the presence of 50 µM of the followingFAs: DHA, EPA, LA, or OA, were loaded with the SEB antigen,irradiated, and cocultured with CFSE-labeled lymphocytes ata ratio of 1:10 DC:lymphocyte. Analysis of proliferation usingthe FlowJo proliferation platform confirmed the results observedin the histograms, being 43.4 ± 11.1%DvC (for untreatedDCs) and 16.3 ± 6.8% for DHA-treated DCs (P<0.05;Table 2 ), which indicates a proliferation decrease of 69% withrespect to the untreated DCs. EPA- and LA-treated DCs induceda less-pronounced decrease in lymphoproliferation. Finally,OA-treated DCs did not reduce lymphoproliferation (46.2±9.2;Table 2 ). DHA did not induce changes in CD4, CD8 T cell subpopulationsunder the culture conditions of this work nor were there significantvariations in CD62 ligand and CD25 high regulatory T cell (Treg)-relatedmarkers.

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Table 2. Impact of FA Treatment on Lymphocyte Activation

DHA exerts similar and additive effects on DCs to those induced by 9cRA and Rosi
It has been described that DHA serves as a precursor for metabolitesthat are potent PPAR ${gamma}$ activators, and additionally, this FA isable to bind to RA receptor RXR [²⁷ , ²⁸ ]. Treatment of DCswith DHA yielded similar results to those reported by Nencioniet al. [³² ] and us [²⁹ ], obtained using the PPAR ${gamma}$ and RXR ligandsRosi and 9cRA, respectively. In this sense, Rosi, 9cRA, andDHA induced the same phenotypic variations (Fig. 5 ). Rosi andDHA down-regulated IL-10 and IL-12 secretion in mature DCs,and all three compounds also inhibited autologous lymphocyteproliferation stimulated by DCs. Furthermore, PPAR ${gamma}$ and RXR ligandsproduced additive or synergic effects when combined in cultureswith complementary activators of both sides of the PPAR ${gamma}$ :RXRheterodimer. These additive effects have been demonstrated inmany different cell types [³³ ³⁴ ³⁵ ], including DCs [²⁹ ].To test whether DHA could mimic these effects, combination studiesof DHA with the previously mentioned, specific, strong agonistsfor PPAR ${gamma}$ and RXR were performed. At concentrations for whichagonists alone produced scarcely any effect in DCs, additiveeffects were seen in combination with DHA. Thus, in immatureDCs, additive effects of DHA with Rosi or 9cRA coincubationwere observed for CD86, CD36, HLA-DR, CD1a, and CD80 (Fig. 5A) .In mature DCs, once again, the additive effects observed inthe combination of DHA with Rosi or 9cRA were the down-regulationof CD86, CD80, CD83, CD1a, and HLA-DR and the up-regulationof CD36 (Fig. 5B) . When using higher concentrations of theseligands, the additive effects were increased in immature andmature DCs (Fig. 5 A and B) .

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Figure 5. Phenotypic, additive effects of DHA when combined with 9cRA or Rosi. MFI from immature (A) and LPS-matured (B) DCs belonging to four healthy individuals. In low concentrations (LC), DCs were incubated with 5 µM DHA and/or 100 nM Rosi or 1 nM 9cRA. In high concentrations (HC), DCs were incubated with 25 µM DHA and/or 1 µM Rosi or 10 nM 9cRA.

To confirm these phenotypic results, expression of the well-knownPPAR ${gamma}$ target genes in DC cells [²⁵ ], FABP4 (aP2) and PDK4, wasstudied by real-time RT-PCR. When DCs were treated with DHA,an increase in the expression of these two genes (12-fold forFABP4; 18-fold for PDK4) also induced by Rosi (53-fold for FABP4;sixfold for PDK4) was observed (Fig. 6 ). When DCs were treatedwith combinations of DHA and Rosi, additive effects in the expressionof both genes were observed (Fig. 6) . Additive effects, butin a lower range, were also observed when DCs were treated withcombinations of DHA plus HX630 (a RXR-specific agonist) or 9cRA(Fig. 6) .

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Figure 6. Effect of DHA on the expression of PPAR ${gamma}$ target genes FABP4 (aP2; A) and PDK4 (B) studied by real-time RT-PCR. DCs were treated with combinations of DHA and/or PPAR ${gamma}$ or RXR agonists or GW9662, a specific inhibitor of PPAR ${gamma}$ . Statistical analysis was performed using the Wilcoxon signed rank test; *, P < 0.05 (relative to untreated). C–, positive control (matured DCs without any additional treatment).

GW9662, a covalent PPAR ${gamma}$ inhibitor, blocks DC changes induced by DHA
GW9662, already tested on DCs [³⁶ ], selectively inhibits PPAR ${gamma}$ activation but not that of PPAR ${alpha}$ or -β and also blocks heterodimerformation [³⁷ ]. Therefore, in the presence of GW9662, no activationis possible through the RXR or the PPAR ${gamma}$ component of the heterodimer.To further determine if changes observed in DHA-treated DCswere produced through the PPAR ${gamma}$ :RXR heterodimer pathway, GW9662was added to the monocyte cultures 90 min prior to treatmentwith DHA and the addition of the differentiating cytokines.In GW9662-treated, immature DCs as well as in mature DCs, allof the markers studied were inhibited, except CD36, which wasup-regulated, blocking the effects of DHA and strongly suggestingthat this FA is acting through the PPAR ${gamma}$ :RXR heterodimer (Fig. 7 A and B ).In the same way, GW9662 was able to inhibit the DHA inductionof PPAR ${gamma}$ target gene expression (Fig. 6) . Two particular caseswere CD1a, with GW9662 partially blocking DHA inhibition, andCD36, which is up-regulated by DHA and surprisingly, GW9662in an additive manner (Fig. 7 A and B) . When cytokine productionwas studied, GW9662 blocked the effects of DHA-treated DCs onthe secretion of IL-12 (Fig. 8C ), but production of IL-10 wasinhibited, whether or not DHA was present (Fig. 8D) . In thesame way, GW9662 blocks the effects of DHA-treated DCs on thestimulation of lymphoproliferation. Control DCs loaded with1 µg SEB induced a lymphocyte proliferation of 43% of%DvC and a PI of 4.71 (Fig. 8A , shaded) in comparison withthe cells treated with GW9662, which induced a slight increase(%DvC, 55%; PI, 6.41; Fig. 8A , dashed line). Previous treatmentof DCs with 50 µM DHA reduced induction of lymphocyteproliferation (%DvC, 15%; PI, 2.02; Fig. 8B , shaded), whereasGW9662 treatment reversed the DHA-induced inhibition (%DvC,36%; PI, 4.26; Fig. 8B , dashed line).

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Figure 7. Modulation of DHA effects on DC phenotype by GW9662. MFI from eight healthy individuals in immature DCs at Day 6 (A) and in LPS-matured DCs (B). DCs were incubated with or without 25 µM DHA in the presence or not of 10 µM GW9662. All of these compounds were present in culture medium from the 1st day of differentiation from monocytes to DCs. GW9662 was added to cultures, and incubation was for 90 min at 37°C, 5% CO₂, before any other treatment; this addition was repeated on Day 3 and only in LPS maturation on Day 6.

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Figure 8. Lymphoproliferation and cytokine secretion in the presence of GW9662. Representative lymphoproliferations from three different, healthy individuals triggered by DCs loaded with 1 µg SEB, with (A, dashed line) or without (A, shaded histogram) GW9662. The same experiment was performed in the presence of 50 µM DHA alone (B, shaded histogram) or with GW9662 (B, dashed line). FL1-H, Fluorescence 1-height. The DC:lymphocyte ratio was 1:10. ELISA displaying IL-12 (C) and IL-10 (D) secretion from 10 µM GW9662-treated DCs and untreated in the presence or not of 50 µM DHA. GW9662 was present in culture medium from the 1st day of differentiation from monocyte to DC. The results are shown normalized to the controls. Statistical analysis was performed using the Wilcoxon signed rank test; *, P < 0.05 (relative to untreated).

The effects of GW9662 on many hallmarks of DC maturation suggesta role for PPAR ${gamma}$ :RXR in the physiological maturation processof these cells [²⁹ ], which could also be modulated by dietaryPUFAs.

DISCUSSION

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DISCUSSION

From the 1990s to the present, there has been a large accumulationof literature about the anti-inflammatory properties of omega-3FAs and particularly, of EPA and DHA or their metabolic mediators(docosatrienes, resolvins, and protectins) [³⁸ ³⁹ ⁴⁰ ⁴¹ ]. Adown-regulation has been reported in the production of proinflammatorycytokines in monocytes, macrophages, and DCs [²¹ , ⁴² ⁴³ ⁴⁴ ⁴⁵ ],as well as a fall in lymphocyte response in animals and humansas a consequence of treatment with EPA and DHA [⁴² , ⁴⁶ ]. However,few studies about the effects of these FAs on DCs have beenperformed, and comparative studies about their differentialactivities are also scarce [²⁰ , ⁴⁷ ]. Furthermore, some contradictoryresults have been published [⁴⁸ ⁴⁹ ⁵⁰ ]. Finally, although theactivation mechanisms of these FAs have been suggested in somesystems [¹⁹ , ²⁵ , ²⁶ , ³⁵ , ⁵¹ ⁵² ⁵³ ⁵⁴ ⁵⁵ ⁵⁶ ], despite yearsof study, the details of these mechanisms remain as yet unknown.

In the present report, we have addressed the effects that DHAand other unsaturated FAs exert on human monocyte-derived DCs.DHA, as well as EPA and LA, although to a lesser degree, leadto induction or inhibition in the expression of some costimulationand antigen-presentation markers, depending on the DC maturationstage. CD36, which was always up-regulated, is implicated innoninflammatory antigen apoptotic cell capture [⁵⁷ ]. TheseFAs also diminished secretion of the cytokines IL-10 and IL-12and the DC stimulatory capacity for T cells. IL-10 and IL-12play a central role in the regulation of the lymphocyte activityinduced by DCs; IL-10 is able to commit T lymphocytes to a TH₂activity and in some circumstances, to Treg, whereas IL-12 directslymphocytes to TH₁ activity. OA, the fourth FA studied, didnot alter the DC phenotype, except for an unexpected increasein CD80 surface expression.

The results obtained here could help to explain the abundantbenefits reported for DHA and EPA in chronic inflammatory andautoimmune diseases [⁵⁸ ]. In any case, the potent down-regulationof CD1a expression in DCs treated with DHA and EPA is particularlyinteresting. CD1a is implicated in the activation of the subpopulationof cytolytic T cells restricted for CD1 that can be stimulatedby immature and mature DCs through CD1 presentation. It is knownthat at least one parasite, Leishmania donovani, is able todown-regulate CD1 in DCs to avoid activation of these T cells[⁵⁹ ]. Moreover, it has been demonstrated recently that group1 CD1 (CD1a,b,c) but not group 2 (CD1d) is crucial for the presentationof Mycobacterium tuberculosis antigens [⁶⁰ ]. As a consequence,a diet primarily based on omega-3 FAs could potentially inhibitgroup 1 CD1 presentation by APCs. It could be worthwhile tostudy its possible relation to the high incidence of the infectioustuberculosis disease observed in the Eskimo population (whofollow omega-3-enriched diets and present a 10–20 timeshigher tuberculosis incidence than other populations, despitetheir low population density [⁶¹ ]).

PPAR ${gamma}$ is an important regulator of many immunogenic functionsin monocytes, macrophages, lymphocytes, and DCs [³⁶ , ⁶² ⁶³ ⁶⁴ ⁶⁵ ⁶⁶ ⁶⁷ ⁶⁸ ].Many reports have independently described the same effects inthese cells and NK cells for DHA treatment [² , ³ , ⁶ , ⁶⁹ ⁷⁰ ⁷¹ ⁷² ⁷³ ⁷⁴ ]and PPAR ${gamma}$ activators [³² , ³⁶ , ⁶² ⁶³ ⁶⁴ ⁶⁵ ⁶⁶ ⁶⁷ ⁶⁸ , ⁷⁵ ].The actions of DHA and PPAR ${gamma}$ ligands are also significant indiabetes and cardiovascular diseases such as atherosclerosisand hypertension [⁷⁵ ⁷⁶ ⁷⁷ ]. The PPAR ${gamma}$ :RXR heterodimer can beactivated independently by RXR or PPAR ligands [³⁵ , ⁷⁸ , ⁷⁹ ].In fact, DHA derivatives have been found to act as potent PPAR ${gamma}$ agonists [²⁶ ], and DHA itself has been reported to be a naturalligand of RXR [²⁷ , ²⁸ ]. All of these lines of evidence suggesta likely relationship between this nuclear receptor and themechanism of action of DHA, which despite years of study, remainsobscure. On the other hand, it has been reported that combinationsof RXR and PPAR ${gamma}$ activators exert additive or synergistic effectson glucose and lipid metabolism and also on the expression ofsome genes, through the simultaneous activation of both heterodimerpartners [³³ , ⁸⁰ ⁸¹ ⁸² ]. We have already demonstrated theseadditive effects in DCs combining Rosi and 9cRA [²⁹ ]. As expected,if the DHA mechanism of action was dependent on PPAR ${gamma}$ , when DHAwas combined with Rosi, 9cRA, or HX630 (a RXR-specific agonist),it induced additive effects on the DC phenotype (Fig. 5) andon the expression of the PPAR ${gamma}$ target genes FABP4 (aP2) and PDK4(Fig. 6) . Both combinations showed similar effects, althoughthat of DHA with Rosi was more pronounced, suggesting that althoughDHA is a promiscuous activator of both sides of the PPAR ${gamma}$ :RXRheterodimer, it is more prone to RXR.

To further investigate this mechanism, we added the selectivePPAR ${gamma}$ inhibitor GW9662 to the DC cultures, prior to additionof DHA. In the case whereby RXR:RXR homodimers or other heterodimerswere responsible for the effects induced by DHA, then the inhibitorwould not interfere with DHA function. However, our resultsindicated that GW9662 blocked DHA effects, suggesting the PPAR ${gamma}$ :RXRheterodimer pathway as the main site of action.

The lack of toxicity in humans of DHA treatment and the additiveeffects observed in this work with other PPAR ${gamma}$ or RXR activators,which could show toxicity or side-effects at the therapeuticallyeffective dosage, point to DHA as a potential candidate fortherapeutic use. DHA used as a complementary adjuvant with otherPPAR ${gamma}$ and RXR agonists could increase their activity and/or reducetheir required dose without loss of effectiveness. This couldhave important implications in the treatment of diabetes, inflammatorydisorders, and cardiovascular diseases such as atherosclerosisand hypertension. Finally, the effects of fish oil-rich dietson CD1 presentation in vivo require more intensive researchto clarify a possible role in the spread of M. tuberculosisin certain populations.

ACKNOWLEDGEMENTS

This work was supported by Instituto de Salud Carlos III, Ministeriode Sanidad y Consumo FISS01/0880. F. Z-G. was the recipientof a fellowship from the University of Barcelona. We thank theBlood and Tissue Bank from Catalonia for providing the buffycoats used in this work and Drs. Mariona Mestres and FrancescMartí for their expertise advice about the Treg study.

Received October 10, 2007; revised May 30, 2008; accepted June 17, 2008.

REFERENCES

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