Characterization of Eicosanoids Produced by Adipocyte Lipolysis

Excessive adipocyte lipolysis generates lipid mediators and triggers inflammation in adipose tissue. However, the specific roles of lipolysis-generated mediators in adipose inflammation remain to be elucidated. In the present study, cultured 3T3-L1 adipocytes were treated with isoproterenol to activate lipolysis and the fatty acyl lipidome of released lipids was determined by using LC-MS/MS. We observed that β-adrenergic activation elevated levels of approximately fifty lipid species, including metabolites of cyclooxygenases, lipoxygenases, epoxygenases, and other sources. Moreover, we found that β-adrenergic activation induced cyclooxygenase 2 (COX-2), not COX-1, expression in a manner that depended on activation of hormone-sensitive lipase (HSL) in cultured adipocytes and in the epididymal white adipose tissue (EWAT) of C57BL/6 mice. We found that lipolysis activates the JNK/NFκB signaling pathway and inhibition of the JNK/NFκB axis abrogated the lipolysis-stimulated COX-2 expression. In addition, pharmacological inhibition of COX-2 activity diminished levels of COX-2 metabolites during lipolytic activation. Inhibition of COX-2 abrogated the induction of CCL2/MCP-1 expression by β-adrenergic activation and prevented recruitment of macrophage/monocyte to adipose tissue. Collectively, our data indicate that excessive adipocyte lipolysis activates the JNK/NFκB pathway leading to the up-regulation of COX-2 expression and recruitment of inflammatory macrophages.

Obesity is a global epidemic that is associated with numerous morbidities, such as type 2 diabetes, cardiovascular diseases, hypertension, and certain types of cancers (1)(2)(3)(4)(5). There is a growing appreciation that for certain individuals, obesity results in low grade chronic inflammation that largely emanates from the adipose tissue (6,7) and results in systemic insulin resistance (8 -10). Adipose tissue inflammation consists of hypertrophied adipocytes that secrete adipokines and free fatty acids into the circulation. An excess of these free fatty acids increases the likelihood of lipotoxicity and the formation of atherosclerotic plaques. The hypertrophied adipocytes also have impaired functions, including their ability to respond to insulin, which often leads to systemic insulin resistance and eventually, type 2 diabetes.
Adipose tissue is known to produce inflammatory cytokines/ chemokines that regulate local and systemic pro-inflammatory responses (11). For example, adipose-derived pro-inflammatory chemokine (C-C motif) ligand 2/monocyte chemotactic protein 1 (CCL2/MCP-1) plays a critical role in inflammatory cell recruitment to adipose tissue (12,13), which is important in the pathology of metabolic syndrome (13). Also, interleukin-6 (IL-6) 2 produced by inflamed adipose tissue can contribute to hepatic insulin resistance (14). However, the signaling pathways involved in the production of inflammatory cytokines/ chemokines remain elusive. We recently reported that acute activation of ␤ 3 -adrenergic receptors (ADRB3) triggers expression of pro-inflammatory genes, including MCP-1, IL-6, PAI-1, among others (15). ADRB3-mediated inflammation mimics inflammation produced by chronic treatments, like high fat feeding, and thus offers a tractable model for investigating molecular mechanisms of adipose tissue inflammation. Importantly, inflammation induced by ADRB3 agonists depends on activation of hormone-sensitive lipase (HSL), suggesting involvement of lipolytic products as pro-inflammatory mediators. Using this adipose lipolysis model, we recently showed that the adipose ADRB3/HSL signaling pathway activates sphingosine kinase 1, which leads to the production of proinflammatory cytokine IL-6 (16).
Adipocyte lipolysis is known to produce lipid mediators, but it is poorly understood how specific mediators regulate proinflammatory signaling in adipose tissue. We have established LC-MS/MS methods to quantitatively measure more than 600 species of fatty acyl lipids in a single chromatographic run (17)(18)(19). In this study, we characterized the fatty acyl lipidome produced by adipocyte lipolysis using LC-MS/MS lipidomic methods. We observed that adipose lipolysis increases the production of ϳ50 lipid species, which are metabolites of cyclooxygenase (COX), lipoxygenases, epoxygenases, and other sources. Furthermore, our data indicate that adipocyte lipolysis upregulates cyclooxygenases-2 (COX-2), which contributes to adipose pro-inflammatory signaling. Thus, targeting COX-2 may provide a novel means for modulating obesity-induced inflammation.

Results
Lipidomic Characterization of Lipid Mediators Generated by the Adipocyte ADBR3/HSL-mediated Lipolytic Process-Differentiated 3T3-L1 mouse adipocytes were treated with and without isoproterenol (ISO), a nonselective ␤-adrenergic agonist, for 3 h to induce maximal lipolysis (15). Culture medium was collected and analyzed for the levels of fatty acyl lipids by the LC-MS/MS. We have established LC-MS/MS methods to quantitatively measure more than 600 species of fatty acyl lipids in a single chromatographic run (17)(18)(19). We found that approximately sixty lipid species were significantly increased following ISO stimulation (Supplemental Tables 1 and 2), including metabolites of cyclooxygenase (COX), lipoxygenase, and epoxygenase.
Activation of hormone sensitive lipase (HSL) is responsible for ϳ2/3 of the total fatty acids released during ␤-adrenergic receptor activation (15,20,21). We then determined which ISO-increased lipid mediators are regulated by the activation of HSL. Differentiated 3T3-L1 mouse adipocytes were pretreated for 1 h in the presence or absence of BAY 59-9435, a selective HSL inhibitor (15,16), followed by treatment with and without ISO for an additional 3 h (15,16). As shown in Fig. 1 and Supplemental Table 1, pretreatment with BAY 59-9435 largely eliminated the ISO-induced production of cyclooxygenase, lipoxygenase, and epoxygenase metabolites ( Fig. 1, Supplemental Table 1).
HSL-mediated Lipolysis Stimulates COX-2 Expression-We next investigated mechanisms underlying the increased production of cyclooxygenase metabolites during adipocyte lipolysis. As shown in Fig. 2A, isoproterenol up-regulated COX-2 mRNA levels. As expected from the lipidomic data, inhibition of HSL with BAY 59-9435 eliminated the induction of COX-2 gene expression. This result indicates that induction of COX-2 mRNA by ISO involves HSL-mediated lipolysis. In contrast, expression of COX-1 was unaffected by adrenergic activation or HSL inhibition (Fig. 2B). The up-regulated COX-2 gene expression was accompanied by the selective induction of COX-2 protein (Fig. 2C). Furthermore, selective inhibition of COX-2 activity with celecoxib eliminated production of cyclooxygenease metabolites induced by ISO treatment (Fig.  2D, Supplemental Table 2). Our lipidomic analysis identified PGE2 as the most abundant cyclooxygenase metabolite induced by ADRB3/HSL activation (Supplemental Tables 1 and  2). Our previous study showed that culture media, with respect to incubation time, temperature, and composition of the medium, greatly affect the stability of lipid species identified using multiple reaction monitoring (MRM) LC-MS/MS method (17). This may be a reason for the difference in minor lipid species identified in different experiments (e.g. 11dh-TXB3 and TXB2 in Figs. 1 and 2, respectively).
Lastly, we tested whether activation of adipocyte lipolysis in vivo affected COX-2 expression by injecting mice with the selective ␤3-adrenergic receptor (ADRB3) agonist CL 316-243 in the presence and absence of HSL inhibition. As shown in Fig.  2E, administration of CL 316-243 up-regulated levels of COX-2 mRNA in the epididymal white adipose tissue, and this effect was abolished by inhibition of HSL with BAY 59-9435. Collectively, our data suggest that adrenergic activation of lipolysis up-regulates COX-2, not COX-1, in vitro and in vivo, leading to the increased production of lipid metabolites of the cyclooxygenase pathway.
Adipose Lipolysis Activates the JNK/NFB Pro-inflammatory Signaling Axis, Leading to COX-2 Up-regulation-We next characterized the mechanism by which lipolysis regulates COX-2 activity and expression. We previously reported that adipose ADRB3-triggered lipolysis activates stress kinases such as c-Jun N-terminal kinase (JNK) (15,16). As shown in Fig. 3A, pharmacological inhibition of JNK significantly abolished the up-regulation of COX-2 by isoproterenol. NFB is a known downstream molecular target that is activated in response to JNK activation (22)(23)(24), and NFB has been found to induce COX-2 gene expression (25)(26)(27)(28). Therefore, we examined whether adipocyte lipolysis activates NFB. Treatment of 3T3-L1 adipocyes with isoproterenol led to the progressive translocation of NFB into the cell nucleus (arrows, Fig. 3B), indicating NFB activation. Moreover, the ISO-induced COX-2 up-regulation was significantly attenuated by pharmacological inhibition of NFB with BAY 11-7082 (Fig. 3C). These data suggest that induction of COX-2 gene expression depends on activation of the JNK/NFB signaling pathway.
Next, we investigated the HSL-mediated signaling pathways which contribute to the activation of JNK/NFB pathway, leading to COX-2 up-regulation. Activation of HSL generates free fatty acids including palmitic and oleic acids from triglyceride. Treatment of 3T3-L1 adipocytes with palmitic acid rapidly activated JNK kinases, as indicated by the phosphorylation status of p54 JNK and p46 JNK (Fig. 3D). In addition, palmitate treatment resulted in the parallel phosphorylation of IB␣ and elevation of COX-2 protein levels (Fig. 3D). The rapid phosphorylation of IB␣ and expression of COX-2 protein suggests substantial amplification of signals generated by JNK activation (i.e. pp56 JNK and pp46 JNK ). Collectively, these data suggest that free fatty acids produced by HSL activation stimulate the JNK/ NFB/COX-2 signaling axis in adipocytes.
COX-2 inhibition significantly suppressed the ISO-stimulated NFB activation (Fig. 3E), indicating that COX-2 activity is required for NFB activation. In contrast, celecoxib did not affect ISO-stimulated phosphorylation of HSL (Fig. 3E), indicating that the effect of COX-2 inhibition is downstream of HSL activity.
To determine whether expression of COX-2 is sufficient to induce expression of CCL2 in the absence of isoproterenol, we acutely transduced 3T3-L1-CAR cells with COX-2 expressing adenoviruses (16). As shown in Fig. 4E, expression of COX-2 rapidly stimulated the production of CCL2 without affecting the expression of IL-6. These results suggest that CCL2/ MCP-1, but not IL-6, is a downstream target of the lipolysisactivated JNK/NFB/COX-2 signaling pathway.
COX-2 Regulates Adipose Macrophage/Monocyte Infiltration Induced by Lipolysis-CCL2/MCP-1 is known to be a critical pro-inflammatory chemokine which promotes the recruitment of macrophages/monocytes to the site of inflammation (29 -31). Therefore, we examined whether lipolysis stimulates the recruitment of macrophages/monocytes into the adipose tissue, and whether the macrophage/monocyte recruitment is mediated by COX-2 activity. Hematoxylin and eosin staining of gonadal WAT suggested that ADRB3 activation leads to tissue extravasation and immune cell infiltration (data not shown). As shown in Fig. 6, administration of CL 316-243 significantly increased the infiltration of macrophages/monocytes into the epididymal white adipose tissue, as determined by immunohistochemistry for F4/80. Moreover, the increased macrophage/ monocyte infiltration was completed abrogated by COX-2 inhibition. The immunohistochemical observation of COX-2-dependent macrophage recruitment was further supported by qPCR analysis for levels of Mac-2 (Fig. 6C), a macrophage cell surface protein (32).
Collectively, our results indicate that free fatty acids generated from HSL-mediated lipolysis activate the JNK/NFB/ COX-2 signaling axis in adipose tissue (Fig. 6D). Subsequently, COX-2 activation stimulates CCL2 expression, leading to the infiltration of immune cells in adipose tissue.

Discussion
Previous work has shown that excessive lipolysis is associated with adipose tissue inflammation and immune cell infiltration (15,16,33). However, pro-inflammatory lipid mediators produced by adipocyte lipolysis remain to be defined. The present study utilized the LC-MS/MS to profile the fatty acid lipidome generated during adipocyte lipolysis. Our data suggest that COX-2 is responsible for elevating levels of prostaglandins, prostacyclins, and thromboxanes from arachidonic acid in response to adrenergic activation of lipolysis. COX-2 was shown to be a critical inflammatory molecule which is induced in various tissues and in obese individuals (34 -36). Therefore, we decided to focus on characterizing the involvement of  Table 2). E, C57BL/6 mice were intraperitoneally (i.p.) injected with BAY 59-9435 (30 mg/kg) for 1 h, followed by i.p. injection with CL 316-243 (10 nmol). 3 h later, the EWAT was analyzed for COX-2 mRNA levels by qPCR analysis. Data represent mean Ϯ S.D. of triplicate determinations. Each panel was repeated at least two times with similar result. *, p Ͻ 0.05, t test.
COX-2 in lipolysis-triggered adipose inflammation in the present study. Our results show that COX-2 expression is significantly induced and activated in cultured adipocytes and adipose tissue upon ␤-adrenergic activation. The up-regulation of COX-2 was inhibited by selective pharmacological inhibition of HSL, indicating that the lipolysis-increased COX-2 expression is dependent on HSL activity. Furthermore, our study suggests that COX-2 up-regulation of CCL2 production may play an important role in immune cell infiltration into adipose tissue.
Previously, we reported that adipose lipolysis activates JNK and p38 stress kinases, which play important roles in lipolysisstimulated production of pro-inflammatory cytokines/chemo-kines (15,16). In the present study, we observed that ␤-adrenergic activation induced nuclear translocation of NFB, a key inflammatory regulator. Moreover, pharmacological inhibition of either JNK or NFB suppressed the lipolysis-induced COX-2 up-regulation. Lipolysis is known to generate free fatty acids by hydrolyzing triglycerides. Direct treatment of adipocytes with palmitate, a free fatty acid, activates the JNK/NFB/COX-2 signaling pathway. These results together suggest that free fatty acids produced by adipose lipolysis activate the JNK/NFB pathway, leading to COX-2 up-regulation. Also, we showed that lipolysis-induced expression of IL-6 is mediated by JNK activation (15). However, unlike CCL2, pharmacological inhi-

COX-2 Activation in Lipolysis-triggered Adipose Inflammation
bition of NFB or COX-2 had no effect on the lipolysis-stimulated IL-6 expression. In this regard, we recently reported that the lipolysis-induced up-regulation of IL-6 is mediated by production of sphingosine-1-phosphate, and this pathway requires the up-regulation of sphingosine kinase 1 (SphK1) via the JNK/ AP-1 pathway (16). Collectively, these results indicate that the regulation of CCL2 and IL-6 both involve the generation of lipid mediators, but the specific pathways (COX-2 and SphK1) diverge following JNK activation.
In the present study, we found that lipolysis triggers an acute infiltration of macrophages/monocytes into the adipose tissue, which is mediated by the JNK/NFB/COX-2 signaling axis. The physiological or patho-physiological significance of the lipolysis-driven macrophage/monocyte infiltration awaits future investigation. Our previous studies suggest that lipolysis-driven infiltration of macrophages/monocytes regulates inflammation, apoptosis, and remodeling of adipose tissues (15,16,21,37). In addition, it has been suggested that adipose macrophages can buffer local fatty acid concentrations by the uptake of fatty acids and suppression of adipocyte lipolysis (33).
How COX-2 could potentially regulate the expression of CCL2/MCP-1 in adipocytes is not yet known. Our lipidomic analysis showed that PGE2, a pro-inflammatory prostaglandin involved in numerous inflammatory processes (38 -41), is one of the most abundant lipidomic metabolites generated from the COX-2 enzyme during lipolysis. Also, it has been reported that PGE2 treatment up-regulates MCP-1/CCL2 expression in mesangial cells (42). However, we were unable to demonstrate that exposure of 3T3-L1 adipocytes to PGE2 alone (up to 50 M for up to 24 h) could up-regulate CCL2 (not shown). Furthermore, various combinations of other prostaglandins (e.g. PGD2, PGJ2, d12-PGJ2, 0 -25 M) were also ineffective. It is possible that exogenous PGE2 dampens COX-2-dependent pro-inflammatory signaling by activating the EP4 receptor (43)(44)(45)(46). Thus, we speculate that either a combination of prostaglandins and/or other lipid mediator(s) could be responsible for the COX-2-mediated up-regulation of CCL2/MCP-1. Alternatively, it is possible that the up-regulation of CCL2/MCP-1 is mediated by intracellular effects of eicosanoids generated by the COX-2 pathway. Future studies are needed to reveal the molecular link between specific lipolysis-stimulated COX-2 products and CCL2/MCP-1 expression in adipocytes.
We observed that celecoxib treatment alone slightly, but significantly, increased levels of COX-2, CCL2, and IL-6 in animal gonadal WATs (Fig. 5). The mechanism for elevated expression of those adipose inflammatory markers by COX-2 inhibition alone is currently unknown. We found that noticeable quantity of PGE2 is secreted by cultured adipocytes, and these levels of PGE2 was significantly reduced by celecoxib treatment (Fig. 2D and Supplemental Table 2). As discussed earlier, PGE2 was shown to suppress lipolysis (43)(44)(45)(46). Thus, it is possible that the basal level of PGE2 secreted by adipocytes functions to suppress adipose lipolysis and inflammation, and this process would be reversed somewhat by COX-2 inhibition.
In summary, our data reveal that lipolysis induces large changes in the fatty acyl lipidome of adipocytes, including the production of potential pro-inflammatory mediators. Furthermore, our study delineates a pro-inflammatory pathway involv-

COX-2 Activation in Lipolysis-triggered Adipose Inflammation
ing COX-2 activation, induction of CCL2 expression, and infiltration of immune cells into adipose tissue. Our results indicate that lipid mediators derived from lipolysis activate divergent pathways, and that an understanding of these pathways could define new approaches to controlling adipose tissue inflammation and associated metabolic dysfunction.
Cell Culture-3T3-L1 and 3T3-L1-CAR cells were cultured and differentiated as previously described (15,16). Two days post-differentiation, cells were cultured overnight in serumfree DMEM. Subsequently, medium was replaced with phenol red free plain DMEM. Cells were treated with 10 M of ISO or PBS control for 3 h at 37°C. Alternatively, cells were pretreated with a selective HSL inhibitor BAY59-9435 (10 M), JNK inhibitor (SP-600125, 10 M), NFB inhibitor (BAY 11-7082, 10 M), or cyclooxygenase-2 inhibitor (celecoxib, 5 M) for 1 h, followed by stimulating with or without isoproterenol (ISO, 10 M) for an additional 3 h. Cell pellets and culture media were collected and processed for biochemical analysis and lipids quantification by LC-MS/MS methods, respectively, as described below. Transduction of 3T3-L1-CAR cells with adenoviral particles was performed essentially as we previously described (16).
Fatty Acyl Extraction from Cell Culture Medium-Culture medium was added with Internal Standard mixture (5 ng each of 15(S)-HETE-d8, LTB4-d4, and PGE1-d4, delivered in 5 l of methanol) (48), followed by the addition of methanol to a final concentration of 15%. The samples were mixed thoroughly and stood at room temperature for 30 -60 min. The samples were then applied to Strata-X cartridges that were preconditioned injected with celecoxib (100 mg/kg) or control vehicle for 1 h. Subsequently, mice were i.p. injected with or without CL 316 -243 (10 nmol). Three hours later, EWAT were collected, and measured for levels of COX-2 (A), COX-1 (B), CCL2/MCP-1 (D), and IL-6 (E) by qPCR analysis. **, p Ͻ 0.01; NS, not statistically significant (n ϭ 5, Two-way ANOVA). C, protein levels of COX-2 and COX-1 were measured by Western blotting analysis. JULY 29, 2016 • VOLUME 291 • NUMBER 31 with methanol. The sample tube and cartridge were each rinsed twice with 1 ml of 15% methanol and dried briefly. Then, the cartridge was washed with 2 ml of hexane and dried. The cartridge was eluted with 0.5 ml of methanol containing 0.1% formic acid into a 1-ml glass vial. The eluate was evaporated to dryness with nitrogen gas. The lipid extracts were reconstituted with 30 l of methanol and 30 l of 25 mM ammonium acetate in MilliQ water, and used for LC-MS/MS fatty acyl analysis as described below.

COX-2 Activation in Lipolysis-triggered Adipose Inflammation
LC-MS/MS Quantification-LC-MS/MS quantification was performed as described (17,48). For LC-MS/MS analysis, reverse phase HPLC was performed using C18 column (Luna, C18, 3 m, 2 mm ϫ 150 mm, Phenomenex, CA) using a gradient elution on Waters Alliance 2695 system (Waters Corp.). The mobile phase consisted of methanol, water, acetonitrile, and ammonium acetate. Solvent A: methanol:10 mM aqueous ammonium acetate:acetonitrile (85:10:5, v/v); solvent B: methanol:10 mM aqueous ammonium acetate:acetonitrile (10:85:5, v/v). The column was eluted isocratically from 0 to 10 min at 55% A followed by a linear gradient to 100% A from 10 to 20 min. Samples were injected using the autosampler (an integral part of the Waters Alliance 2695 system) maintained at 10 Ϯ 2°C and the injection volumes were 10 l for each sample. Total injection cycle for each sample was 25 min including column equilibration to initial conditions. The flow rate was 0.2 ml/min. The HPLC eluent was directly introduced to Quattro LC mass spectrometer (Micromass-Waters). The mass spectrometric detector settings were as follows: ESI needle voltage, 2.8 kV; source block temperature, 120°C; desolvation temperature, 350°C; desolvation gas flow, 540 liters/h; nebulizer gas flow, 80 liters/h; and the collision gas pressure was 3.2 ϫ 10 Ϫ4 bar. Cone voltage and collision energy for each MRM transition were optimized. Chromatographic data were analyzed by Quanlynx module of the Masslynx software (Waters Corp.) to integrate the chromatograms for each MRM transition.
Animal Studies-All animal procedures were performed according to the NIH and institutional guidelines, and were approved by the Wayne State University Animal Use and Care Committee. C57BL/6 mice (8-week-old male, Jackson Laboratory) were used in this study. To examine the role of ADRB3/ HSL signaling in the regulation of COX-2 expression, mice were intraperitoneally (i.p.) injected with the selective HSL inhibitor, BAY59-9435 (30 mg/kg), celecoxib (100 mg/kg body weight), or vehicle control as previous described (20,21,49). One hour later, mice were i.p. injected with 10 nmol of CL 316-243 or saline for additional 3 h (20,21). Mice were euthanized, and the EWAT pads were collected and processed for biochemical and immunohistochemical analysis as described below.
Real-time PCR-Total RNA was isolated from cultured cells using Trizol and was reversely transcribed with an oligo-dT primer (Promega) by M-MLV Reverse Transcriptase (Pro-FIGURE 6. COX-2 activity is required for the ADRB3-stimulated macrophage/monocyte infiltration in adipose tissues. C57BL/6 mice (male, 8-week-old) were i.p. injected with celecoxib (100 mg/kg) or control vehicle for 1 h. Subsequently, mice were i.p. injected with or without CL 316 -243 (10 nmol). Three hours later, EWAT were collected. A, paraffin sections (5 m) of EWAT were immunohistochemically stained with anti-F4/80. a, vehicle; b, CL 316-243; c, celecoxib alone; d, celecoxib ϩ CL 316 -243; e and f, enlarged image of box area in a and b, respectively. Arrows, infiltrated macrophages/monocytes. B, macrophages/ monocytes present in each treatment (4 -5 microscopic fields) were scored. *, p Ͻ 0.05, t test. C, levels of Mac-2, a macrophage maker, were quantitated by qPCR. *, p Ͻ 0.05, t test. D, model of our findings, revealing a COX-2-mediated mechanism through which the HSL-driven lipolysis stimulates macrophage/ monocyte infiltration into adipose tissue. Various ways to inhibit this signaling pathway may reduce adipose inflammation triggered by acute lipolytic process.

COX-2 Activation in Lipolysis-triggered Adipose Inflammation
mega) for first strand cDNA synthesis. Total RNA was isolated from the EWAT using liquid nitrogen and a mortar and pestle to grind the tissue in to a powder and then Trizol was added. Then, the RNA was reversely transcribed with an oligo-dT primer (Promega) by M-MLV Reverse Transcriptase (Promega) for first strand cDNA synthesis. For real-time PCR quantitation, 50 ng of reversely transcribed cDNAs were amplified with the ABI 7500 system (Applied Biosystems) in the presence of SYBR Green master mix. PCR primer pairs used were: mouse PTGS1 (COX-1): sense, 5Ј-ACA AAA GAA CCC AGT GTC CA-3Ј, antisense, 5Ј-AGA ACT GTG GTG GTT TCC AA-3Ј; mouse PTGS2 (COX-2): sense, 5Ј-TGA TCG AAG ACT ACG TGC AA-3Ј, antisense, 5Ј-GTG AGT CCA TGT TCC AGG AG-3Ј; mouse GAPDH: sense, 5Ј-CAC CTT CGA TGC CGG GGC TG-3Ј, antisense, 5Ј-GGC CAT GAG GTC CAC CAC CC-3Ј; mouse CCL2: sense, 5Ј-CAC AGT TGC CGG CTG GAG CAT-3Ј; antisense, 5Ј-GCT TCT TTG GGA CAC CTG CTG C-3Ј; and mouse Mac-2: sense, 5Ј-AGG AGA GGG AAT GAT GTT GCC-3Ј, antisense, 5Ј-GGT TTG CCA CTC TCA AAG GG-3Ј. The qPCR reaction was performed by using a universal PCR Master Mix (Applied Biosystems) according to manufacturer's instructions. Relative quantification (RQ) was calculated using the SDS software (Applied Biosystems) based on the equation RQ ϭ 2 Ϫ⌬⌬Ct where Ct is the threshold cycle to detect fluorescence. Ct values were normalized to the internal GAPDH standard.
Western Blotting Analysis-Protein extraction procedure and Western blotting analysis were performed as described (50). Cells were collected in ice-cold PBS using cell scrapers followed by centrifugation (250 ϫ g, 5 min). Cell extracts were prepared in RIPA buffer (10 mM Tris-HCl, pH 7.4, 150 mM NaCl, 5 mM EDTA, 1% Triton X-100, 1% sodium deoxycholate, 0.1% SDS) containing protease inhibitors (Calbiochem) with constant agitation at 4°C for 30 min. After centrifugation at 15,000 ϫ g for 20 min, supernatant was collected and protein concentration was measured using a bicinchoninic acid protein assay kit with BSA as standard. 50 g of protein extracts were dissolved in 2ϫ Laemmli sample buffer, heated at 95°C for 5 min, and resolved on a 10% SDS-PAGE gel. After electrophoresis, gels were transferred to nitrocellulose membranes. Subsequently, membranes were blocked in 5% nonfat dry milk (Lab Scientific) in TBST buffer (20 mM Tris-HCl, pH 7.4, 500 mM NaCl and 0.05% Tween-20). Membranes were washed and incubated with the indicated primary antibodies (1:1000 dilution) on a rotary shaker at 4°C overnight. The blots were then incubated with peroxidase-conjugated goat anti-rabbit secondary antibody for 1 h at room temperature, and developed with enhanced chemiluminescent reagent (Thermo Scientific).
Immunohistochemical Staining-The immunohistochemical staining procedure followed the protocol from the Vector Laboratories Vectastain Universal Elite ABC Kit (Anti-mouse IgG/ Rabbit IgG, Cat. No. PK-6200). Briefly, mouse EWAT tissues were fixed in 10% formalin followed by paraffin embedding. Paraffin sections (5 m) were performed antigen retrieval in citrate buffer (10 mM citric acid, 0.05% Tween 20, pH 6.0) at 90°C for 10 min, and then deparaffinized by incubating the slides in xylene followed by a graded series of ethanol and then water. Endogenous peroxidase activity was quenched with 0.3% H 2 O 2 for 5 min. After washes, sections were incubated with blocking serum (normal horse serum) for 20 min. Subsequently, samples were incubated with anti-F4/80 (1:200 dilution in PBS) at 4°C for overnight. The slides were then washed with PBS and incubated with the diluted biotinylated secondary antibody for 30 min. After washing with PBS, Vectastain ABC Reagent was applied to the slides for 30 min. After washing with PBS, DAB substrate reagent was added to the slides for 10 min and then washed several times with water. Slides were examined and analyzed using the Leica inverted microscope and the image acquisition was from the SPOT Pursuit monochrome digital camera.
Statistical Analysis-Results are shown as mean Ϯ S.D. Differences between various treatments were analyzed by ANOVA. Statistical significance was measured by student's t test. p value Ͻ 0.01 is considered highly significant and p Ͻ 0.05 is considered statistically significant.