Preserved glucose tolerance in high-fat-fed C57BL/6 mice transplanted with PPAR{gamma}-/-, PPAR{delta}-/-, PPAR{gamma}{delta}-/-, or LXR{alpha}{beta}-/- bone marrow

doi:10.1194/jlr.M800189-JLR200

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Preserved glucose tolerance in high-fat-fed C57BL/6 mice transplanted with PPAR ${gamma}$ ^–/–, PPAR ${delta}$ ^–/–, PPAR ${gamma}$ ${delta}$ ^–/–, or LXR ${alpha}$ β^–/– bone marrow^*

Chaitra Marathe, Michelle N. Bradley, Cynthia Hong, Lily Chao, Damien Wilpitz, Jon Salazar and Peter Tontonoz¹

Howard Hughes Medical Institute, Molecular Biology Institute and Department of Pathology and Laboratory Medicine, University of California, Los Angeles, CA 90095

^* This work was supported by National Institutes of Health grantHL030568.

Published, JLR Papers in Press, September 4, 2008.

^¹ To whom correspondence should be addressed. e-mail: ptontonoz{at}mednet.ucla.edu

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Macrophage lipid metabolism and inflammatory responses are bothregulated by the nuclear receptors PPAR and LXR. Emerging linksbetween inflammation and metabolic disease progression suggestthat PPAR and LXR signaling may alter macrophage function andthereby impact systemic metabolism. In this study, the functionof macrophage PPAR and LXR in Th1-biased C57BL/6 mice was testedusing a bone marrow transplantation approach with PPAR ${gamma}$ ^–/–,PPAR ${delta}$ ^–/–, PPAR ${gamma}$ ${delta}$ ^–/–, and LXR ${alpha}$ β^–/–cells. Despite their inhibitory effects on inflammatory geneexpression, loss of PPARs or LXRs in macrophages did not exertmajor effects on obesity or glucose tolerance induced by a high-fatdiet. Treatment with rosiglitazone effectively improved glucosetolerance in mice lacking macrophage PPAR ${gamma}$ , suggesting that celltypes other than macrophages are the primary mediators of theanti-diabetic effects of PPAR ${gamma}$ agonists in our model system.C57BL/6 macrophages lacking PPARs or LXRs exhibited normal expressionof most alternative activation gene markers, indicating thatmacrophage alternative activation is not absolutely dependenton these receptors in the C57BL/6 background under the conditionsused here. These studies suggest that genetic background maybe an important modifier of nuclear receptor effects in macrophages.Our results do not exclude a contribution of macrophage PPARand LXR expression to systemic metabolism in certain contexts,but these factors do not appear to be dominant contributorsto glucose tolerance in a high-fat-fed Th1-biased bone marrowtransplant model.

Supplementary key words PPAR • LXR • macrophage • inflammation • insulin resistance • immune phenotype

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Macrophages play an important role in innate and acquired immuneresponses. They can be directed to acquire distinct phenotypesthrough classical (M1) or alternative (M2) pathways of activation(1). Depending on the trigger for macrophage activation, differentoutcomes in the adaptive immune response, inflammation, andgene expression result. For instance, macrophages activatedclassically by lipopolysaccharide (LPS) (M1 phenotype) promotea Th1 T cell response, characterized by the release of inflammatorycytokines and the activation of cytotoxic CD8 T cells (2). TheTh1 response is primarily geared toward the phagocytosis andkilling of pathogens. Macrophages activated by alternative stimulisuch as IL-4 (M2 phenotype) are less inflammatory and fostera Th2 response by directing the proliferation and differentiationof B cells (2). The biological impact of these distinct pathwaysof macrophage activation has been studied in mouse models thatfavor either Th1 or Th2 immune responses. The widely used C57BL/6mouse strain preferentially mounts Th1-biased immune responses,including classical macrophage activation, leading to robustinflammatory responses (1). By contrast, the more Th2-permissiveBALB/C strain is more susceptible to alternative macrophageactivation and does not exhibit such a dominant inflammatoryreaction (1).

Recent work suggests that macrophage-dependent inflammatorypathways are linked to the development and possibly treatmentof insulin resistance. In particular, adipose tissue inflammationhas attracted widespread interest as a potential causal factorin insulin resistance (3). Type 2 diabetes is associated withlow-grade or chronic inflammation (4), and adipose tissue isnow recognized to be a major producer of bioactive signalingmolecules, known as adipokines, some of which may contributeto chronic inflammation (5). In addition, macrophages have beenshown to accumulate in adipose tissue of obese mice and humans,where they are postulated to contribute to inflammatory signaling(6, 7). In fact, studies have consistently revealed elevatedexpression of inflammatory genes such as TNF ${alpha}$ , IL-6, and iNOSin adipose tissue of obese mice, and tissue macrophages appearto be a prime source of these factors (6, 8, 9).

Several lines of evidence support a causal role for macrophageinflammatory signaling in insulin resistance. For example, inhibitionof TNF ${alpha}$ signaling in obese mice improves insulin sensitivity,whereas exogenously administering TNF ${alpha}$ worsens insulin resistance(4, 10, 11). Furthermore, blocking macrophage inflammatory geneexpression through genetic deletion of IKKβ, an essentialkinase in the NF- ${kappa}$ B activation pathway, improves insulin sensitivityin obese mice (12, 13). Inhibiting macrophage infiltration intoadipose tissue by deletion of MCP-1 expression in fat also improvesinsulin resistance (14 –16).

The observation that inflammatory gene expression in adiposetissue is suppressed by systemic treatment with PPAR ${gamma}$ agonistssuch as rosiglitazone has led several groups to investigatethe impact of anti-inflammatory nuclear receptor signaling ondiabetes (17, 18). Members of both the peroxisome proliferator-activatedreceptor (PPAR) and liver X receptor (LXR) subfamilies haveemerged as important negative regulators of macrophage-mediatedinflammation. PPAR ${gamma}$ , PPAR ${delta}$ , LXR ${alpha}$ , and LXRβ are each expressedat high levels in murine macrophages, and numerous studies haveaddressed the potential for these receptors to alter macrophageinflammatory gene expression (19 –21). Recent studies inTh2-biased BALB/C mice have suggested that PPAR ${gamma}$ is importantfor M2 macrophage activation and that genetic deletion of PPAR ${gamma}$ in myeloid cells alters the balance between M1 and M2 macrophages(22). Moreover, BALB/C mice lacking PPAR ${gamma}$ expression in macrophagesare more susceptible to the development of diet-induced insulinresistance (22). Hevener et al. (18) have also examined theconsequence of loss of bone marrow (BM) PPAR ${gamma}$ expression on amixed genetic background. Similar to the previous study, lossof PPAR ${gamma}$ was associated with increased expression of inflammatorygenes as well as defective insulin signaling in target tissuessuch as adipose tissue, liver, and muscle. The contributionof macrophage PPAR ${delta}$ or LXR expression to systemic glucose metabolismhas not been addressed previously.

C57BL/6 is the genetic background most widely studied in thecontext of metabolism; however, the importance of anti-inflammatorynuclear receptor function for obesity-linked insulin resistancein this strain remains unclear. Here we assess the impact ofloss of BM expression of four different nuclear receptors onsystemic glucose metabolism in C57BL/6 mice. BM geneticallydeleted for PPAR ${gamma}$ , PPAR ${delta}$ , both PPAR ${gamma}$ and PPAR ${delta}$ , or both LXR ${alpha}$ andLXRβ was isolated from C57BL/6 donors and transplantedinto wild-type C57BL/6 recipients. Mice were fed a high-fatdiet to induce obesity and insulin resistance. None of thesenuclear receptors significantly altered obesity or glucose toleranceof transplanted mice in our study. In addition, treatment withrosiglitazone improved glucose tolerance in mice receiving PPAR ${gamma}$ -nullBM. Although our results do not exclude a contribution of macrophagePPAR and LXR expression to systemic metabolism in certain contexts,these factors do not appear to be dominant contributors to glucosetolerance in a high-fat-fed Th1-biased bone marrow transplant(BMT) model. Our data suggest that genetic background and dietmay influence the metabolic consequences of nuclear receptorsignaling in macrophages.

METHODS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Reagents and cell culture
The synthetic ligands for LXR (GW3965 and T1317), PPAR ${alpha}$ (GW9544),PPAR ${delta}$ (GW742), and PPAR ${gamma}$ (GW7845) were provided by GlaxoSmithKline.All ligands were dissolved in DMSO before use in cell culture.The LXR ligand was used at a concentration of 1 µM, whereasthe PPAR ligands were all used at 100 nM. LPS from Salmonellatyphimurium and poly(I:C) were purchased from Sigma and usedat 100 ng/ml and 2.5 mg/ml, respectively. IL-13 was purchasedfrom Peprotech and used at 10 ng/ml. Thioglycollate-elictedprimary murine macrophages were maintained in DMEM containing10% FBS. BM-derived macrophages were differentiated in DMEMcontaining 20% FBS and 30% L929-conditioned media for 7 days.After differentiation, macrophages were cultured in DMEM containing10% FBS. Cells were harvested from wild-type, PPAR ${gamma}$ ^–/–,PPAR ${delta}$ ^–/–, or PPAR ${gamma}$ ${delta}$ ^–/– mice. The Mx Cremice were purchased from Jackson Laboratories. The Mx Cre, PPAR ${gamma}$ fl/fl,and PPAR ${delta}$ ^–/– mice are all on the C57BL/6 background(more than nine generations backcrossed).

Animal studies
The recipient wild-type mice used for the BMT studies were irradiatedwith 900 rads the night prior to reconstitution. Each of thefour groups of recipient mice contained 12 mice. BM cells fromrecipient mice were harvested and injected into tail veins ofthe recipient mice. The irradiated mice were kept in sterilecages with autoclaved food and trimethoprim-sulfamethoxazole-treatedwater for 2 weeks. Mice were challenged with a 60% caloric fatdiet (Research Diets) for 16 weeks. Mice were fasted the nightprior to glucose tolerance tests, and glucose levels were monitoredafter intraperitoneal injections of glucose (2 g/kg; Sigma).For gavage experiments, mice were gavaged with either vehicleor rosiglitazone (30 mg/kg; Cayman Chemicals) for 8 days.

Insulin ELISA
Wild-type, PPAR ${gamma}$ ^–/–, and PPAR ${gamma}$ ${delta}$ ^–/– BMTmice were fasted overnight, and blood was collected in heparintubes. Samples were then spun at 8,000 rpm for 5 min to isolateserum. An ultrasensitive mouse insulin ELISA kit (Crystal Chem,Inc.) was used to perform an insulin ELISA on the serum to determineinsulin levels.

RNA and quantitative PCR
Total RNA was extracted from cells using TRIzol reagent (Invitrogen)and was reverse transcribed to obtain cDNA (Applied Biosystems).Real-time quantitative PCR assays were performed using an AppliedBiosystems 7900 sequence detector as previously described (23).Data were normalized to housekeeping gene 36B4.

Statistical analysis
Statistical significance was determined using Student's t-testfor in vitro assays. A one-way or two-way ANOVA test was usedto determine statistical significance for all glucose tolerancetests.

RESULTS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

To investigate the function of macrophage PPAR ${gamma}$ , we used a Crerecombinase system to disrupt the PPAR ${gamma}$ gene. Specifically, wecrossed C57BL/6 mice with loxP sites flanking the second exonof PPAR ${gamma}$ (PPAR ${gamma}$ fl/fl) with C57BL/6 mice expressing Cre recombinasedownstream of the ${alpha}$ /β interferon-inducible (Mx) promoter.Cre recombinase activity was initiated by intraperitoneal injectionof the Mx activator poly IC 3 to 4 weeks after birth. Interestingly,injection of poly IC at weaning age caused a permanent disruptionof PPAR ${gamma}$ in myeloid precursor cells; new myeloid cells generatedpostinjection remain PPAR ${gamma}$ -null for the life of the mouse. Typically,we analyzed macrophages from these mice at least 4 weeks afterinducing recombination to reduce any potential effects of thepoly IC. Quantitative real-time PCR confirmed that the Mx Cresystem was extremely efficient, yielding nearly complete (>95%)deletion of PPAR ${gamma}$ exon 2 in vivo (Fig. 1A ). As expected, inductionof PPAR target genes (aP2, ADRP, PGAR) by PPAR ${gamma}$ but not PPAR ${delta}$ agonists was lost in Mx Cre PPAR ${gamma}$ ^–/– macrophages(Fig. 1A).

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Fig. 1. Induction of the Mx promoter effectively disrupts PPAR ${gamma}$ , whereas LysM Cre cannot efficiently delete PPAR ${gamma}$ exon 2. Cells were harvested and pooled from three to five mice per group. The presented data are representative of at least three independent experiments. A: Thioglycollate-elicited wild-type and Mx Cre PPAR ${gamma}$ ^–/– peritoneal macrophages were treated with PPAR ${gamma}$ or PPAR ${delta}$ ligands (GW7845 or GD742, respectively; 100 nM each) overnight. PPAR ${gamma}$ exon 2 could not be detected in PPAR ${gamma}$ ^–/– cells (P < 0.005), whereas PPAR ${gamma}$ exon 6 expression was unaffected. Known PPAR ${gamma}$ target genes (aP2, ADRP, and PGAR) were tested to confirm loss of ligand response in PPAR ${gamma}$ ^–/– macrophages. B: Thioglycollate-elicited wild-type and LysM Cre PPAR ${gamma}$ ^–/– peritoneal macrophages were treated with PPAR ${gamma}$ ligand (GW7845; 100 nM) overnight. PPAR ${gamma}$ exon 2 could still be detected in PPAR ${gamma}$ ^–/– macrophages, and PGAR, a known PPAR ${gamma}$ target gene, could still be induced by PPAR ${gamma}$ ligand in these cells (P < 0.02). Error bars represent SEM.

In addition to using the Mx Cre system, we also generated micewith macrophage-specific PPAR ${gamma}$ deletion using the LysM Cre system.Unlike Mx Cre, LysM Cre is constitutively active. However, comparedwith the Mx Cre system, the LysM Cre system was not as efficientin recombining PPAR ${gamma}$ to create a disrupted gene in our hands.After harvesting peritoneal macrophages from wild-type and LysMCre PPAR ${gamma}$ ^–/– mice, we treated the cells with PPAR ${gamma}$ ligand to test whether disruption of PPAR ${gamma}$ was able to preventPPAR ${gamma}$ target gene regulation. We found that PPAR ${gamma}$ exon 2 couldstill be detected by quantitative real-time PCR and that PGAR,a PPAR ${gamma}$ target gene, could be regulated by ligand even in PPAR ${gamma}$ ^–/–macrophages (Fig. 1B). In contrast, the Mx Cre system yieldscell populations with complete deletion of PPAR ${gamma}$ exon 2 expression,and more importantly, these cells are unable to respond to PPAR ${gamma}$ ligand and do not regulate target genes. Consequently, we optedto use the Mx Cre system for our studies.

Recent work suggests that PPARs mediate inflammatory signalingpathways in macrophages and may affect inflammation associatedwith insulin resistance (18, 22). To address this issue in ourgenetic loss-of-function system, thioglycollate-elicited PPAR ${gamma}$ ^–/–,PPAR ${delta}$ ^–/–, or PPAR ${gamma}$ ${delta}$ ^–/– peritoneal macrophageswere isolated and pretreated with either PPAR ligand or LXRligand overnight. Cells were then stimulated with LPS (10 ng/ml)for 6 h, and inflammatory and receptor target gene was measuredby real-time PCR. As shown in Fig. 2A , the PPAR target geneaP2, and the LXR target gene ABCA1, were upregulated in wild-typecells by ligand, confirming proper ligand response. As expected,LXR agonist (GW3965) efficiently suppressed inflammatory geneexpression (iNOS). Furthermore, PPAR ${gamma}$ ligand (GW7845) repressedIL-6, MCP-1, and iNOS expression in wild-type cells but notin PPAR ${gamma}$ -null cells (Fig. 2B, C). PPAR ${delta}$ agonist (GW742) had nosignificant effect on expression of these genes in any genotype.

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Fig. 2. PPAR ${gamma}$ ^–/–, PPAR ${delta}$ ^–/–, and PPAR ${gamma}$ ${delta}$ ^–/– macrophages exhibited heightened inflammatory gene expression compared with wild-type cells in vitro. Cells were harvested and pooled from three to five mice per group. The presented data are representative of at least three independent experiments. A: Thioglycollate-elicited wild-type, PPAR ${gamma}$ ^–/–, PPAR ${delta}$ ^–/–, and PPAR ${gamma}$ ${delta}$ ^–/– peritoneal macrophages were harvested and pretreated with GW7845 (100 nM), GW742 (100 nM), or GW3965 (1 µM) overnight. The cells were then stimulated with LPS (10 ng/ml) for 6 h. PPAR and LXR target genes (aP2 and ABCA1, respectively) were tested to confirm ligand response. B: Macrophages were analyzed for inflammatory gene expression. iNOS was markedly upregulated in macrophages with deleted PPARs; in wild-type cells, treatment with LXR ligands consistently suppressed inflammatory genes, whereas treatment only with PPAR ${gamma}$ and not PPAR ${delta}$ ligand resulted in repression. C: Additional inflammatory genes were tested in response to LPS and PPAR ligand treatments. Similar to iNOS, both IL-6 and MCP-1 expression was repressed by PPAR ${gamma}$ ligand. However, IL-1β has a different expression profile compared with the other genes and highlights inconsistencies in PPAR signaling in inflammation. Error bars represent SEM.

We also noted a significant effect of loss of PPAR expressionon LPS-inducible inflammatory gene expression in the absenceof receptor ligands. Loss of either PPAR ${gamma}$ or PPAR ${delta}$ alone led toenhanced induction of iNOS and IL-6 by LPS (Fig. 2B, C). Moreover,the combined deletion of both receptors had an additive effect,i.e., inflammatory gene expression was most responsive in thedouble knockouts. Interestingly, the combined loss of PPAR ${gamma}$ andPPAR ${delta}$ affected the expression of some inflammatory markers morethan others. For example, in contrast to IL-6, MCP-1, and iNOS,expression of IL-1β was not altered in the wild-type cells(Fig. 2C).

To investigate the impact of BM PPAR expression on systemicglucose metabolism in C57BL/6 mice, we used wild-type, PPAR ${gamma}$ ^–/–,PPAR ${delta}$ ^–/–, or PPAR ${gamma}$ ${delta}$ ^–/– BM (from mice morethan 10 generations backcrossed to C57/BL6) to reconstituteirradiated wild-type mice. After recovery for 4 weeks, the micewere challenged with a 60% fat diet for an additional 14 weeksto cause obesity. All four groups of mice gained weight at asimilar rate and had equivalent food intake during the courseof the feeding (Fig. 3A ; data not shown). To confirm the degreeof BM reconstitution after 14 weeks of high-fat diet, we harvestedthioglycollate-elicted peritoneal macrophages from PPAR ${gamma}$ ^–/–and wild-type BMT-recipient mice. Real-time PCR verified thatvirtually all of the macrophages from PPAR ${gamma}$ ^–/– BMTmice were derived from the donor cells, because PPAR ${gamma}$ exon 2was not expressed (Fig. 3B). We also tested whether the macrophageswere responsive to ligand by examining PPAR target gene expression.As shown in Fig. 3C, expression of ADRP was induced by PPAR ${gamma}$ ligand (GW7845) in cells from wild-type but not PPAR ${gamma}$ ^–/–BMT mice. Basal expression of ADRP was also reduced in PPAR ${gamma}$ -nullcells.

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Fig. 3. All PPAR mice had equivalent weight gain and exhibited reconstitution with myeloid cells derived from donor mice. A: Irradiated mice transplanted with wild-type, PPAR ${gamma}$ ^–/–, PPAR ${delta}$ ^–/–, or PPAR ${gamma}$ ${delta}$ ^–/– myeloid cells were challenged with a 60% fat diet. All groups of mice gained weight at similar rates. B: Thioglycollate-elicted wild-type and PPAR ${gamma}$ ^–/– peritoneal macrophages were harvested from recipient mice to determine degree of reconstitution. PPAR ${gamma}$ exon 2 could not be detected in PPAR ${gamma}$ ^–/– macrophages (P < 0.05), whereas PPAR ${gamma}$ exon 6 could be detected. Cells were harvested and pooled from four wild-type and three PPAR ${gamma}$ ^–/– bone marrow transplant (BMT) mice. C: Wild-type and PPAR ${gamma}$ ^–/– macrophages were treated with GW7845 overnight. PPAR ${gamma}$ target genes (aP2 and ADRP) did not increase in expression as a result of ligand treatment in PPAR ${gamma}$ ^–/– cells. Cells were harvested and pooled from four wild-type and three PPAR ${gamma}$ ^–/– BMT mice. Error bars represent SEM.

After mice were on the diet for 14 weeks, we performed glucosetolerance tests to determine whether reconstitution with differingPPAR knockout macrophages would alter systemic metabolism. Miceclearly became glucose intolerant as a result of high-fat feeding;however, high-fat-fed mice lacking BM expression of PPAR ${gamma}$ , PPAR ${delta}$ ,or both on the C57BL/6 background showed no significant differencefrom controls (Fig. 4A ). A second set of glucose tolerancetests performed 4 weeks later yielded similar results (Fig. 4B).Fasting serum insulin levels were also not significantly differentbetween groups, as determined by ELISA (P > 0.05; data notshown).

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Fig. 4. Glucose tolerance tests and insulin levels exhibited no significant differences in insulin sensitivity. A two-way ANOVA test was used to determine significance. A: After 14 weeks on the diet, the four groups of PPAR mice were equally diabetic and similarly insulin resistant (P > 0.05). After the mice were fasted overnight, basal blood glucose levels were measured (0 min) before intraperitoneal administration of 2 g/kg glucose. Blood glucose was assessed every 30 min after the glucose bolus. B: A second glucose tolerance test performed after an additional 4 weeks yielded similar results (P > 0.05). C: Wild-type and PPAR ${gamma}$ ^–/– mice were treated with rosiglitazone (30 mg/kg) for 8 days. A glucose tolerance test was performed as previously described. Rosiglitazone improved insulin sensitivity in both wild-type and PPAR ${gamma}$ ^–/– mice, whereas vehicle treatment did not demonstrate a decrease in blood glucose levels in either group (P < 0.02). Error bars represent SEM.

We also assessed the influence of BM PPAR ${gamma}$ expression for theanti-diabetic effects of PPAR ${gamma}$ agonists on a C57BL/6 background.We treated wild-type and PPAR ${gamma}$ ^–/– BMT-recipient micewith rosiglitazone for 8 days. As shown in Fig. 4C, both groupstreated with rosiglitazone showed markedly and equivalentlyimproved glucose tolerance, compared with vehicle controls.This observation suggests that tissues other than BM are theprimary mediators of the anti-diabetic effects of PPAR ${gamma}$ ligandin mice on a C57BL/6 background under the experimental conditionsemployed here.

Macrophage infiltration into adipose tissue is a well-characterizedfeature in obese mouse models (6). Furthermore, administrationof thiazoladinediones reverses macrophage infiltration, presumablyby activating PPAR ${gamma}$ . We therefore investigated whether the lackof macrophage PPAR ${gamma}$ would affect macrophage infiltration intoadipose tissue. To our surprise, we found that there was nochange in the numbers of macrophages present in adipose tissuewhen we compared wild-type and PPAR ${gamma}$ BMT mice (data not shown).Additionally, the size of adipocytes was similar in wild-typeand PPAR ${gamma}$ BMT mice and we did not observe any obvious differencesin body composition (data not shown).

Previous work has established that both LXR ${alpha}$ and LXRβ areexpressed at high levels in macrophages, and both isotypes havestrong anti-inflammatory effects (19). As shown in Fig. 2B,the anti-inflammatory effects of LXRs are especially prominentin vitro. We hypothesized that loss of LXR receptor expressionin BM cells might exacerbate inflammatory signaling in vivoand impact glucose metabolism. We therefore transplanted BMcells from wild-type and LXR ${alpha}$ β^–/– mice intoirradiated wild-type recipients. As with the mice used for PPARstudies, the animals used for these experiments were also morethan 10 generations backcrossed to C57BL/6 mice. After 4 weeksof recovery, the BMT mice were challenged with a 60% fat dietto induce obesity and insulin resistance. All groups consumedsimilar amounts of food and gained weight at similar rates (Fig. 5A ).We confirmed that the reconstituted animals had been repopulatedwith LXR ${alpha}$ β^–/– BM by harvesting thioglycollate-elictedperitoneal macrophages and performing real-time PCR to examinethe expression of LXRs and their downstream target genes. Asexpected, LXR ligands (GW3965 and T1317) induced expressionof ABCA1 in wild-type but not in LXR ${alpha}$ β^–/– BMTcells (Fig. 5B). We also verified that LXRs had maintained theiranti-inflammatory abilities after reconstitution by stimulatingmacrophages with LPS in the presence or absence of LXR ligand.Indeed, LXR ligand repressed expression of TNF ${alpha}$ in wild-typebut not LXR-null BM recipients (Fig. 5B).

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Fig. 5. Recipient mice showed equivalent weight gain and exhibited efficient reconstitution with wild-type or LXR-null donor bone marrow (BM). A: Wild-type and LXR ${alpha}$ β^–/– mice gained weight at similar rates on a 60% fat diet. B: Thioglycollate-elicted wild-type and LXR ${alpha}$ β^–/– peritoneal macrophages were harvested from recipient mice to determine degree of reconstitution. Wild-type and LXR ${alpha}$ β^–/– macrophages were pretreated with GW3965 or T1317 (1 µM) and then stimulated with LPS (10 ng/ml) for 6 h. The LXR ${alpha}$ β target gene, ABCA1, did not increase in expression as a result of ligand treatment in LXR ${alpha}$ β^–/– cells. Furthermore, LXR ${alpha}$ β^–/– cells failed to repress TNF ${alpha}$ gene expression. Wild-type cells treated with LXR ligand were able to exert anti-inflammatory control. Error bars represent SEM.

After mice were on on a high-fat diet for 14 weeks, a glucosetolerance test was performed. Similar to the results obtainedwith the PPAR BM transplants, we observed no difference in glucosetolerance or insulin levels between mice transplanted with wild-typeor LXR ${alpha}$ β^–/– BM (Fig. 6A ; data not shown).A second independent test performed 4 weeks later showed similarresults (Fig. 6B). These observations indicate that despitetheir anti-inflammatory effects, loss of LXR expression in theBM does not exert a major influence on glucose tolerance inhigh-fat-fed mice.

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Fig. 6. Glucose tolerance tests in wild-type and LXR ${alpha}$ β^–/– mice revealed no difference in blood glucose levels. A two-way ANOVA test was used to determine significance. A: Wild-type and LXR ${alpha}$ β^–/– mice were challenged with a 60% fat diet for 14 weeks. After mice were fasted overnight, basal blood glucose levels were measured. Glucose (2 g/kg) was administered, then blood glucose was assessed every 30 min for 2 h. Both groups of mice were equally insulin resistant (P > 0.05). B: A second glucose tolerance test was performed after an additional 4 weeks as previously described. Similar results were obtained (P > 0.05). Error bars represent SEM.

It has been previously reported that alternative activationof BALB/C macrophages relies significantly on appropriate PPARsignaling (22, 24). Studies have demonstrated that PPAR ${gamma}$ -deficientmacrophages express low levels of M2 marker genes and are noteffectively alternatively activated (22). As a result, thesecells may be more inflammatory and may act as contributors toworsened insulin sensitivity. To test whether PPAR ${gamma}$ ^–/–or PPAR ${delta}$ ^–/– macrophages from C57BL/6 mice also expressedreduced levels of alternative activation marker genes, we stimulatedBM-derived macrophages with cytokines that upregulate Th-2 response,such as IL-4 or IL-13 (25). We found that the absence of PPARsdid not compromise M2 inflammatory responses under our experimentalconditions. Expression of classical M2 marker genes such asChi3l3, Pdcd1lg2, and Clec7a (26, 27) in response to IL-4 orIL-13 in PPAR ${gamma}$ ^–/–, PPAR ${delta}$ ^–/–, or PPAR ${gamma}$ ${delta}$ ^–/–macrophages was not significantly different from wild-type macrophages(Fig. 7 ). However, the loss of PPAR ${gamma}$ in macrophages resultedin lower expression of arginase I (ArgI), a primary M2 markergene (28), in response to IL-4 or IL-13 stimulation. ArgI hasbeen previously described as a direct PPAR ${gamma}$ and PPAR ${delta}$ target gene,and this may explain the reduced ArgI expression in PPAR ${gamma}$ -deficientmacrophages (22, 29). Interestingly, ArgI expression was uniquein its dependence on PPAR ${gamma}$ for induction; the expression of theremaining M2 marker genes we tested was not altered by the lossof PPARs.

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Fig. 7. Classical M2 gene expression is not absolutely dependent on PPAR expression in BM-derived macrophages. Wild-type, PPAR ${gamma}$ ^–/–, PPAR ${delta}$ ^–/–, and PPAR ${gamma}$ ${delta}$ ^–/– BM cells were harvested, differentiated into macrophages, and treated with IL-4 or IL-13 (10 ng/ml each) overnight. Expression of M2 genes was analyzed to determine impact of PPAR ${gamma}$ , PPAR ${delta}$ , or both PPAR ${gamma}$ and PPAR ${delta}$ deficiencies. The presented data are representative of two independent experiments. Error bars represent SEM.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

In the present study, we report that loss of BM expression ofanti-inflammatory nuclear receptors is not a dominant contributorto the development of diet-induced obesity or glucose intolerancein high-fat-fed C57BL/6 mice. This was true not only for PPAR ${gamma}$ ,which has been reported to play a role in insulin resistancein BALB/C mice, but also for PPAR ${delta}$ , LXR ${alpha}$ , and LXRβ, whichhave not been previously studied in this context. Using a BMTapproach, we found that loss of PPAR ${gamma}$ , PPAR ${delta}$ , both PPAR ${gamma}$ and PPAR ${delta}$ ,or both LXR ${alpha}$ and LXRβ did not alter weight gain in micechallenged with a 60% fat diet or have a significant effecton glucose tolerance. We also found that administration of rosiglitazoneto PPAR ${gamma}$ ^–/– BMT mice improved glucose tolerance,suggesting that BM expression of this receptor is not absolutelyrequired for the therapeutic effects of thiazolidinediones inC57BL/6 mice.

Previous work has reported that macrophage PPAR ${gamma}$ expression affectsthe development of obesity and insulin resistance (18, 22).It is important to point out that our studies were conductedin parallel to those of Glass and Chawla (18, 22) and were notdesigned to replicate the experimental conditions used in eitherof these reports. Therefore, our results are not necessarilyin conflict with those of prior work, and there are a numberof factors that may have contributed to the differences in experimentaloutcomes.

One possible contributor is the influence of genetic background.The macrophages in prior work were derived from either BALB/Cor mixed-background mice. Genetic background in mice contributesto the dominance of M1 or M2 activation of macrophages and canbias how mouse models respond to specific stimuli. For example,the BALB/C mouse strain is Th2-permissive and is more susceptibleto diseases that require an aggressive immune response (1).Conversely, C57BL/6 mice are dominant for Th1 signaling anddisplay more-robust inflammatory signaling and the upregulationof pro-inflammatory genes. The C57BL/6 strain is most widelyused for the study of metabolic disorders because of its susceptibilityto diet-induced insulin resistance and atherosclerosis.

Another plausible explanation for the difference between ourresults and those of the Chawla and Glass groups (18, 22) isenvironment and the immune status of the mice. All animal facilitiesare different, and mice at different sites may therefore beexposed to a range of different pathogens and commensal bacteria.It is conceivable that such differences alter the immune systemsof experimental mice in ways that may affect macrophage responses.

Another notable difference between our study and prior workis the diet employed. Hevener et al. (18) reported more-significantdifferences in blood glucose levels between wild-type and PPAR ${gamma}$ ^–/–BMT mice fed a chow diet rather than a high-fat diet. Odegaardet al. (22) employed a 36% fat diet. We chose to use a 60% fatdiet because our aim was to study PPAR/LXR function in obesemodels. However, it is possible that our high-fat diet may havebeen too robust a diabetic stimulus and therefore masked differencesotherwise seen on a chow diet.

Finally, the BMT approach employed in our study may have contributedto differences in results. Prior studies employed a LysM Creapproach to delete PPAR ${gamma}$ expression from macrophages. We choseto use Mx Cre-mediated deletion coupled with BMT because ofincomplete deletion by LysM Cre in our hands (Fig. 1). However,it is possible that the BMT procedure itself has a confoundingeffect on systemic metabolism. Furthermore, although we confirmedreconstitution of recipient mice with the appropriate donorBM cells, there is a possibility that the tissue macrophagereconstitution was not complete at the time we performed ourstudies. Prior work has shown that adipose tissue macrophagesand hepatic Kupffer cells are effectively replaced by BM cellsin the time frame employed in our study (more than 4 months).However, the possibility that some wild-type macrophages mayhave remained and affected our results cannot be excluded.

While this paper was under review, two additional studies reportedan impact of loss of PPAR ${delta}$ expression on glucose tolerance andalternative macrophage activation (30, 31). Some of the findingsreported in these studies also differ from the results we reporthere. As outlined above for PPAR ${gamma}$ , it is likely that a numberof factors may contribute to the prominence of PPAR ${delta}$ signalingin different experimental contexts. Additional studies willbe required to more precisely define the role of both PPAR ${gamma}$ andPPAR ${delta}$ in macrophage inflammatory signaling in the context ofmetabolic disease.

In conclusion, our studies suggest that the in vitro anti-inflammatoryactivities of nuclear receptors alone are not predictive ofin vivo metabolic effects. Macrophage LXRs show profound anti-inflammatoryeffects in vitro but do not dramatically influence systemicglucose metabolism under the conditions used here. Furthermore,our results suggest that careful consideration of the immunologicaldifferences between mouse strains is warranted in the contextof metabolic disease studies. Inherent biases in mouse strainscan steer immune responses and affect the outcomes of variousdisease models in different ways. Finally, our data indicatethat the influence of BM nuclear expression on systemic metabolismmay differ between experimental context and genetic backgroundand that these factors may not be obligatory components of diseasepathogenesis or thiazolidinedione therapeutic action in allcontexts.

ACKNOWLEDGMENTS

The authors thank Jon Collins and Tim Willson of GlaxoSmithKlinefor the synthetic ligands for LXR (GW3965 and T1317), PPAR ${alpha}$ (GW9544),PPAR ${delta}$ (GW742), and PPAR ${gamma}$ (GW7845). The PPAR ${gamma}$ fl/fl and PPAR ${delta}$ ^–/–mice were provided by Ronald Evans of the Salk Institute andFrank Gonzalez of NCI, respectively.

Submitted on April 17, 2008
Revised on July 7, 2008 and in re-revised form September 3, 2008.

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Preserved glucose tolerance in high-fat-fed C57BL/6 mice transplanted with PPAR–/–, PPAR–/–, PPAR–/–, or LXRβ–/– bone marrow*

Preserved glucose tolerance in high-fat-fed C57BL/6 mice transplanted with PPAR ${gamma}$ ^–/–, PPAR ${delta}$ ^–/–, PPAR ${gamma}$ ${delta}$ ^–/–, or LXR ${alpha}$ β^–/– bone marrow^*