Regulation of Cholesterol Homeostasis and Lipid Metabolism in Skeletal Muscle by Liver X Receptors

doi:10.1074/jbc.M206681200

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Regulation of Cholesterol Homeostasis and Lipid Metabolism in Skeletal Muscle by Liver X Receptors^*

George E. O. Muscat^§^¶, Brandee L. Wagner, Jinzhao Hou, Rajendra K. Tangirala, Eric D. Bischoff, Paul Rohde^§, Mary Petrowski, Jiali Li, Gang Shao, Griffin Macondray, and Ira G. Schulman^¶

From the X-Ceptor Therapeutics, Inc., San Diego, California 92121 and ^§ Institute for Molecular Bioscience, Centre for Molecular and Cellular Biology, Ritchie Research Laboratories, University of Queensland, St. Lucia, 4072 Queensland, Australia

Received for publication, July 5, 2002, and in revised form, August 20, 2002

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Recent studies have identified the liver X receptors (LXR $alpha$ and LXR $beta$ ) as important regulators of cholesterol and lipid metabolism.Although originally identified as liver-enriched transcriptionfactors, LXRs are also expressed in skeletal muscle, a tissuethat accounts for ~40% of human total body weight and is the majorsite of glucose utilization and fatty acid oxidation. Nevertheless,no studies have yet addressed the functional role of LXRs in muscle.In this work we utilize a combination of in vivo and in vitroanalysis to demonstrate that LXRs can functionally regulate genesinvolved in cholesterol metabolism in skeletal muscle. Furthermorewe show that treatment of muscle cells in vitro with syntheticagonists of LXR increases the efflux of intracellular cholesterolto extracellular acceptors such as high density lipoprotein, thusidentifying this tissue as a potential important regulator ofreverse cholesterol transport and high density lipoprotein levels.Additionally we demonstrate that LXR $alpha$ and a subset of LXR targetgenes are induced during myogenesis, suggesting a role for LXR-dependentsignaling in the differentiationprocess.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Disorders of cholesterol and lipid metabolism are associated with cardiovascular disease, obesity, diabetes, and hypertension.Not surprisingly organisms have developed exquisite regulatorynetworks that ensure lipid homeostasis is maintained by controllingdietary intake, de novo synthesis, transport, and catabolism.For instance, numerous studies over the past five years have identifiedmembers of the nuclear hormone receptor superfamily of ligand-dependenttranscription factors as important regulators of the genes involvedcholesterol and lipid metabolism (3). In particular, the peroxisomeproliferator-activated receptors (PPAR $alpha$ ,¹ $beta$ / $delta$ , and $gamma$ ), the farnesoid X receptor, and the liver X receptors(LXR $alpha$ , and LXR $beta$ ) are transcription factors whose activity canbe controlled by the direct binding of fatty acids (PPARs andLXRs) and cholesterol derivatives (LXRs and farnesoid X receptor).Thus, these transcription factors are poised to sense changesin the intracellular concentrations of lipids and cholesteroland to regulate cellular metabolism accordingly (3, 4).

Recently several studies have demonstrated that the LXRs play a dynamic role in the regulation of genes involved in cholesteroland fatty acid metabolism. LXRs bind to DNA as obligate heterodimerswith retinoid X receptors and directly bind cholesterol metabolitesand fatty acids (5, 6). Interestingly cholesterol derivativesand fatty acids have opposing effects on LXR transcriptional activity.Oxysterols including 24(S), 25-epoxycholesterol, 22(R)-hydroxycholesterol,and 24(S)-hydroxycholesterol are activators of LXR and increasetranscription of genes involved in sterol transport includingthe ATP binding cassette transporters ABCA1, ABCG1, ABCG5, andABCG8 and the apolipoprotein apoE (7-11). The importance of theseLXR target genes to sterol metabolism has recently been highlightedby linkage of ABCA1 to Tangier disease and ABCG5 together withABCG8 to sitosterolemia, both human genetic syndromes characterizedby perturbed cholesterol transport (12-16). Strikingly, mutationsin ABCA1 that give rise to Tangier disease result in an almostcomplete absence of HDL cholesterol and promote accumulation ofcholesterol within peripheral tissues. Biochemical analysis ofABCA1 indicates that it mediates the transport of intracellularcholesterol and phospholipids to extracellular acceptors suchas HDL, a process termed reverse cholesterol transport (17-19).LXR agonists also increase expression of CYP7a, the gene encodingcholesterol 7 $alpha$ hydroxylase, which is the rate-limiting enzymein the metabolic conversion of cholesterol to bile acids (20).Thus, under conditions of elevated cholesterol, LXRs promote thetransfer of cholesterol from the periphery to the liver for catabolismand excretion. Furthermore, up-regulation of ABCA1, ABCG5, andABCG8 in the intestine by LXRs limits the absorption of sterolsby promoting efflux from enterocytes to the lumen, resulting inan overall decrease in cholesterol loads (8).

Along with the effects on cholesterol metabolism, LXR agonists also increase expression of genes involved in fatty acid metabolism,including the master transcriptional regulator of fatty acid synthesis,the sterol response element-binding protein 1c (SREBP1c) (1,21, 22). Additionally, several of the genes encoding the enzymesinvolved in fatty acid metabolism, including fatty acid synthase(FAS) and stearoyl-CoA desaturase 1 (SCD-1), are regulated directlyor indirectly by LXR (1, 20, 21, 23). The coordinateup-regulation of fatty acid synthesis with reverse cholesteroltransport is most likely to provide lipids for the transport andstorage of cholesterol. In contrast, however, to the agonist activityof cholesterol metabolites, fatty acids act as antagonists ofLXR transcriptional activity, suggesting the possibility of anegative feedback loop whereby the metabolic end product inhibitsthe inducer (5).

Skeletal muscle accounts for ~40% of adult total body weight and is a major site of glucose and fatty acid oxidation. Importantly,insulin regulates the balance between glucose and fatty acid utilizationin this tissue, and increased fatty acid oxidation in skeletalmuscle is a hallmark of type II diabetes. Although LXRs have beenshown to be important regulators of hepatic fatty acid metabolism,the function of these transcription factors in muscle has notbeen well addressed. Nevertheless, given the recent interest inLXR ligands as potential therapeutic agents for the treatmentof disorders of cholesterol and lipid metabolism, the contributionof this major mass tissue to LXR action must be defined. In thisstudy we used in vivo analysis in wild type and LXR knockout micealong with the well defined C2C12 skeletal muscle cell culturemodel to characterize LXR activity in muscle. The results of thiswork identify skeletal muscle as an important site of LXRactivity.

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In Vivo Analysis-- Homozygous LXR $alpha$ $beta$ -double knockout mice (LXR $alpha$ $beta$ ^/) were from a breeding colony established and maintained at X-Ceptor TherapeuticsInc. Mice were fed ad libitum. The LXR agonist T0901317 (1)was administered by daily oral gavage in a sesame oil/ethanolvehicle via a 1-cc syringe fitted with a 20-gauge disposable feedingneedle for 7 days. Compound was solvated in ethanol (5% finalvolume) and brought up to final volume with sesame oil (Sigma).Plasma triglyceride levels were measured using an enzymatic assayand the supplier's protocols(Sigma).

Reporter Plasmids-- Luciferase reporter plasmids were constructed by PCR amplification of the human ABCA1 promoter ( $-$ 621-+45) and the mouse SREBP1cpromoter ( $-$ 543-+39) and cloning into pGL3-basic (Promega, Madison,WI).

C2C12 Cell Culture and Transient Transfection Assays-- Mouse myogenic C2 cells were grown in Dulbecco's modified Eagle's medium supplemented with 20% fetal bovine serum in 5% CO₂.Cells were induced to biochemically and morphologically differentiateinto multinucleated myotubes by mitogen withdrawal (Dulbecco'smodified Eagle's medium supplemented with 2% horse serum) as previouslydescribed (2). Differentiation was essentially complete within96 h with respect to the cytoskeletal and contractile isoformtransition. For transient transfections, cells were grown in 24-welldishes to 60-70% confluence and transfected with 0.5-0.8 µg/wellof the pGL3b-LUC, SREBP1c-LUC, or ABC1c-LUC reporter constructsusing a DOTAP/DOSPER (Roche Molecular Biochemicals) liposome mixturein 1× HEBS (42 mM HEPES, 275 mM NaCl, 10 mM KCl, 0.4 mM Na₂HPO₄,11 mM dextrose, pH 7.1). A $beta$ -galactosidase expression plasmidwas included as an internal control. The DNA/DOTAP/DOSPER mixtureof 16-20 µg of DNA supplemented with 60 µl of DOTAP and 40 µlof DOSPER in 200 µl of 1× HEBS buffer was incubated for 10 minat room temperature and mixed with 14.4 ml of fresh Dulbecco'smodified Eagle's medium supplemented with 10% fetal bovine serumor 2% horse serum. Subsequently, 0.6 ml/well of the DNA/DOTAP/DOSPERmixture was added to the cells and incubated for 16-24 h. Post-transfection,the medium was replaced, and the cells were grown a further 48h. Cells were harvested and assayed for luciferase activity. Theluciferase activity in sample was normalized by determining $beta$ -galactosidaseactivity. Each experiment represented at least two sets of independenttriplicates to overcome the variability inherent in transfectionexperiments.

RNA Isolation and Analysis of Gene Expression by Quantitative Reverse Transcription-PCR-- Total RNA from mouse tissues and C2C12 cells was isolated using RNeasy kits (Qiagen Inc.) according to the supplier's totalRNA isolation procedure. Real time PCR was performed using a PerkinElmer/ABI7700 prism. RNA samples were incubated with 1 unit RNase-freeDNase (Roche Molecular Biochemicals) per 1.6 µg of total RNA for40 min at 37 °C followed by a 10-min incubation at 75 °C. Foreach target quadruplicate reactions, each containing 100 ng oftotal RNA (including one minus reverse transcriptase control),were utilized. RNA was reverse-transcribed using 10 units of SuperscriptII reverse transcriptase (Invitrogen), 400 nM target-specificreverse primer, 500 µM dNTPs, 10 mM dithiothreitol, and 1× SuperscriptII buffer. Quantitative PCR of reverse transcriptase reactionswas carried out with 1.25 units of Taq polymerase (Invitrogen),1× Taq buffer, 3 mM MgCl₂, 200 µM dNTPs, 400 nM target-specificforward and reverse primers, and 100 nM target-specific fluorogenicprobe. All assays were run for 40 cycles (95 °C for 12 s followedby 60 °C for 60 s). Probes and primers were designed using PrimerExpress (Applied Biosystems, Inc.). Levels of cyclophilin weremeasured in all in vivo samples, and the results are presentedas the number of target transcripts per cyclophilin transcript.GAPDH was used to normalize transcript levels in the experimentsusing C2C12cells.

Cholesterol Efflux-- C2C12 cells were differentiated as described above for 48 h and then labeled with [¹⁴C]cholesterol for an additional 48 h. Labeled cells were washed,and efflux was initiated in medium with or without 10 µg/ml apoAIin the absence or presence of receptor-specific ligands. After24 h, media were removed, cell debris was pelleted, and radioactivityin the media was determined by scintillation counting. To determinethe cell-associated radioactivity, cells were lysed in 0.2 M sodiumhydroxide, and radioactivity was determine by scintillation counting.Percent efflux was calculated by dividing the radioactivity inthe media by the sum of the radioactivity in the media and celllysate. ApoAI-dependent efflux was determined by subtracting theefflux observed in the absence of addedapoAI.

Statistical Analysis-- Statistical analysis was carried out using a two-tailed unpaired ttest.

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Regulation of LXR Target Genes in Muscle-- Treatment of rodents with synthetic LXR agonists has been shown to increase expression of genes involved in cholesterol andlipid metabolism in liver, intestine, and adipose tissue (1,7-11, 21, 23). To examine the activity of LXR in skeletalmuscle, we first quantitated the mRNA levels of LXR $alpha$ and LXR $beta$ in the quadriceps of mice and determined that LXR $alpha$ and LXR $beta$ areexpressed in skeletal muscle at similar levels (Fig. 1A). To furtherdefine the functional activity of skeletal muscle LXR, wild typeand LXR $alpha$ $beta$ ^/ mice were treated with the synthetic LXR agonist T0901317 (1)for 7 days. After treatment, total RNA was isolated from quadriceps,and LXR-dependent gene expression was measured by quantitativereal-time PCR. As shown in Fig. 1, B-F, treatment with LXR agonistincreases the mRNAs encoding known LXR target genes includingABCA1 (4.5-fold), SREBP1c (8.3-fold), and apoE (2.3-fold). Incontrast to what has been observed in livers of treated mice (1,8, 21), the mRNAs encoding SCD-1 and FAS are not inducedby LXR agonist treatment in muscle. Nevertheless, SCD-1 and FASare significantly induced by LXR agonist treatment in the liversof these same animals (Fig. 2). LXR agonist-dependent inductionof genes involved in fatty acid synthesis in the liver most likelyaccount for the increase plasma triglyceride levels observed inagonist-treated mice (Fig. 2D). As expected, all agonist-dependenteffects on gene expression are completely eliminated in LXR $alpha$ $beta$ ^/ mice.

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Fig. 1. Expression of LXRs and LXR target genes in skeletal muscle. LXR $alpha$ $beta$ ^+/+ and LXR $alpha$ $beta$ ^/ mice (n = 4) were treated for 7 days in the absence (white bars) or presence (black bars) of the LXR agonist T0901317 (10 mg/kg), and total RNA was isolated from the quadriceps. Expression of the mRNAs encoding LXR $alpha$ and LXR $beta$ (A), ABCA1 (B), apoE (C), SREBP1c (D), SCD-1 (E), and FAS (F) was determined by real-time quantitative PCR. Levels of cyclophilin were measured in all samples, and the results are presented as the number of target transcripts per cyclophilin transcript. RNA from each individual animal was assayed in quadruplicate. p values indicate statistically significant differences between vehicle and T0901317-treated animals.

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Fig. 2. LXR agonist-dependent induction of SCD-1 and FAS in the liver. LXR $alpha$ $beta$ ^+/+ and LXR $alpha$ $beta$ ^/ mice (n = 4, the same mice used in Fig. 1) were treated for 7 days in the absence (white bars) or presence (black bars) of the LXR agonist T0901317 (10 mg/kg), and total RNA was isolated from the liver. Expression of the mRNAs encoding SREBP1c (A), SCD-1 (B), and FAS (C) was determined by real-time quantitative PCR. Levels of cyclophilin were measured in all samples, and the results are presented as the number of target transcripts per cyclophilin transcript. RNA from each individual animal was assayed in quadruplicate. Plasma triglyceride levels (D) were determined as described under "Experimental Procedures." p values indicate statistically significant differences between vehicle- and T0901317-treated animals.

The results of Fig. 1 indicate that skeletal muscle is responsive to LXR ligands. Studies in vivo, however, do not rule outthe possibility that effects on skeletal muscle gene expressionare indirect, arising from the ability of LXR agonists to influencecholesterol and lipid metabolism in other tissues. To confirmthat LXR is active in skeletal muscle we turned to the well establishedmouse C2C12 myoblast cell line as a model. Proliferating C2C12myoblasts can be induced to biochemically and morphologicallydifferentiate into post-mitotic multinucleated myotubes by serumwithdrawal in culture over a 96-h period. This transition froma non-muscle phenotype to contractile phenotype is associatedwith the repression of non-muscle proteins and the activationof the contractile apparatus and metabolic enzymes. Treatmentof differentiated myotubes (72 h after serum withdrawal) withT0901317-induced expression of LXR target genes involved in reversecholesterol transport including ABCA1, ABCG1, a second ABC transporterimplicated in cholesterol transport, and apoE (Fig. 3, A-C). Inmacrophages several studies have shown that ligands for PPAR $gamma$ can also induce expression of ABCA1 indirectly via up-regulationof the gene encoding LXR $alpha$ . Thus, at least in macrophages, LXRsare thought to act downstream of PPAR $gamma$ in a signaling cascadethat leads to induction of ABCA1 and increases in reverse cholesteroltransport. In C2C12 cells, however, the PPAR $gamma$ ligand BRL49653has little or no effect on the expression of ABCA1 (Fig. 3A) orany other LXR target gene examined (data not shown). Thus PPAR $gamma$ ligands do not act directly on skeletal muscle to influence expressionof genes that regulate reverse cholesterol transport. Similarly,activators of PPAR $delta$ do not induce ABCA1 in C2C12 cells (data notshown). LXR target genes that contribute to lipogenesis such asSREBP1c, FAS, and SCD-1 were also induced by LXR agonist in C2C12cells (Fig. 2, D-F). As observed in vivo, however, the inductionof SREBP1c (8-fold) was much greater than the induction observedfor SCD-1 (1.5-fold) and FAS (3-fold).

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Fig. 3. Regulation of LXR target genes in C2C12 cells. Confluent C2C12 cells were allowed to differentiate into myotubes in the absence of serum for 72 h. After differentiation cells were cultured for an additional 24 h in the absence (white bars) or presence of 1.0 µM LXR agonist T0901317 (black bars) or 5.0 µM of the PPAR $gamma$ agonist BRL49653 (striped bar, A only), and total RNA was isolated. Expression of the mRNAs encoding ABCA1 (A), ABCG1 (B), apoE (C), SREBP1c (D), SCD-1 (E), and FAS (F) was determined by real-time quantitative PCR. Levels of GAPDH were measured in all samples, and the results are presented as the number of target transcripts per GAPDH transcript. Fold inductions by T0901317 relative to vehicle-treated controls are noted above the appropriate bars (p < .02). Each sample was assayed in quadruplicate.

Binding sites for LXR-retinoid X receptor heterodimers have been identified in the promoters of the ABCA1 and SREBP1c, andthese genes have been shown to be direct targets of LXR in theliver, intestine, and macrophages (1, 8, 21, 22). Toevaluate the ability of endogenous LXRs to directly activate SREBP1cand ABCA1 in muscle, promoter-reporter constructs were transfectedinto proliferating C2C12 myoblasts, and the cells were allowedto differentiate in the absence or presence of LXR agonist. Asshown in Fig. 4, there is a dramatic ligand-dependent inductionof both promoters, indicating a direct action of endogenous LXRson SREBP1c and ABCA1 in muscle cells.

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Fig. 4. Induction of the ABCA1 and SREBP1c promoters by endogenous LXRs in C2C12 cells. Reporter constructs with the human (h) ABCA1 (A) and mouse (m) SREBP1c (B) promoters linked to luciferase were transfected into proliferating C2C12 myoblasts along with $beta$ -galactosidase expression plasmid. Transfected cells were then allowed to differentiate for 48 h in the absence (white bars) or presence (black bars) of 1.0 µM T0901317. After ligand treatment, luciferase activity was measured and normalized by $beta$ -galactosidase activity. Each sample was assayed in triplicate.

Regulation of Cholesterol Efflux in C2C12 Cells-- ABCA1 has been shown to be essential for the transfer of intracellular cholesterol to extracellular acceptors such as HDL,a process termed reverse cholesterol transport (17, 24, 25).The importance of ABCA1 to reverse cholesterol transport is illustratedby the finding that inactivation of ABCA1 in humans results inHDL deficiencies (17-19,25). Similarly, overexpression of ABCA1has been shown to elevate HDL by increasing reverse cholesteroltransport (26-28). To date, most studies of reverse cholesteroltransport have been carried out in fibroblasts and macrophages.Nevertheless, given the ability of LXRs to regulate ABCA1 expressionin muscle in vitro and in vivo, we decided to measure reversecholesterol transport in C2C12 cells. Treatment of [³H]cholesterol-labeled differentiated myotubes with T0901317 resultedin a 2.9-fold increase in the ability of these cells to effluxcholesterol to apoA1, and this effect was further enhanced byan agonist for LXR's heterodimeric partner retinoid X receptor(Fig. 5). Thus, skeletal muscle is a potential site for reversecholesterol transport and may contribute to the control of HDLcholesterol levels. Once again, the PPAR $gamma$ agonist BRL49653 hadno effect.

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Fig. 5. Induction of reverse cholesterol transport in differentiated myotubes by LXR. Confluent C2C12 cells were allowed to differentiate into myotubes in the absence of serum for 72 h. After differentiation, cells were cultured for an additional 24 h in the absence (white bar) or presence of 1.0 µM LXR agonist T0901317 (black bar), 1.0 µM of the retinoid X receptor (RXR) agonist LG101305 (spotted bar), 1.0 µM T0901317 + 1.0 µM LG101305 (gray bar), or 5.0 µM of BRL49653 (striped bar). After ligand treatment, ApoA1-dependent cholesterol efflux was measured as described under "Experimental Procedures."

Expression of LXRs during Myogenesis-- Several studies have shown that the gene encoding LXR $alpha$ is induced during the differentiation of monocytes to macrophages,indicating an important role for this receptor in macrophage biology(29-31). To examine LXR activity during skeletal myogenesis, expressionlevels of LXR $alpha$ and LXR $beta$ were measured in differentiating C2C12cells (Fig. 6). LXR $alpha$ is induced beginning when cells reach confluence(Fig. 6A, CMB) and peaking as myoblasts exit the cell cycle andform differentiated multinucleated cells (Fig. 6A, MT1), suggestinga role for this isotype in the myogenic process. In contrast,LXR $beta$ mRNA is constitutively expressed during myogenic differentiationin culture and is 200-fold more abundant than LXR $alpha$ in proliferatingmyoblasts (Fig. 6B). Northern analysis demonstrates the inductionof myogenin mRNA (encoding the basic HLH protein), repressionof the cytoskeletal non-muscle $beta$ / $gamma$ -actin mRNAs, and the activationof the sarcomeric $alpha$ -actins relative to equivalent levels of GAPDHmRNA, confirming that these cells had terminally differentiated(Fig. 6C).

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Fig. 6. LXR $alpha$ is induced during myogenesis. Total RNA was isolated from proliferating C2C12 myoblasts (PMB), confluent myoblasts (CMB), or cells that had been differentiated to myotubes in the absence of serum for 24 (MT1) and 96 (MT4) h. The expression levels of LXR $alpha$ (A) and LXR $beta$ (B) were determined by real-time quantitative PCR. Levels of GAPDH were measured in all samples, and the results are presented as the number of target transcripts per GAPDH transcript. Each sample was assayed in quadruplicate. The fold induction of LXR $alpha$ mRNA when MT1 is compared with PMB is noted over the appropriate bar (p = .01). C, Northern analysis was used to measure the levels of the mRNAs encoding myogenin, sarcomeric, and cytoskeletal actins and GAPDH. All samples were run on the same blot. An irrelevant lane (between lanes 3 and 4) was removed for preparation of the figure.

Analysis of LXR targets during myogenesis indicates that genes involved in reverse cholesterol transport (ABCA1, ABCG1, andapoE) are also induced from 4.7- to 29-fold (Fig. 7, A-C) duringthe differentiation process in the absence of added exogenousLXR ligands. The kinetics of the ABCA1, ABCG1, and apoE lag slightlybehind the induction of LXR $alpha$ and, thus, are consistent with thehypothesis that LXR $alpha$ plays a role in inducing these genes. TheLXR targets involved in lipogenesis (SREBP1c, SCD-1, and FAS),however, are poorly, if at all, induced during differentiation(Fig. 7, D-F). This observation is particularly interesting forSREBP1c and FAS, which have recently been shown to be directlyregulated by LXR $alpha$ (1, 21, 23). Nevertheless, treatmentof differentiating C2C12 cells with LXR ligands increases themRNAs for all LXR target genes examined including SREBP1c, SCD-1,and FAS (Fig. 2 and data not shown), indicating that endogenousLXRs are competent to activate these targets during myogenesisif a potent agonist is available. These observations suggest,at least during myogenesis, that the regulation of these two functionalclasses of LXR targets (cholesterol transport and fatty acid synthesis)can be temporally and mechanistically separated.

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Fig. 7. Expression of LXR target genes during myogenesis. Total RNA was isolated from proliferating C2C12 myoblasts (PMB), confluent myoblasts (CMB), or cells that had been differentiated to myotubes in the absence of serum for 24 (MT1) and 96 (MT4) h. The expression levels of ABCA1 (A), ABCG1 (B), apoE (C), SREBP1c (D), SCD-1 (E), and FAS (F) were determined by real-time quantitative PCR. Levels of GAPDH were measured in all samples, and the results are presented as number of target transcripts per GAPDH transcript. Significant fold inductions (p < .02) when compared with PMB levels are noted over the relevant bars. Each sample was assayed in quadruplicate.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

In this study we demonstrate that both LXR $alpha$ and LXR $beta$ are expressed in skeletal muscle and can be functionally regulated byLXR agonists. The ability of LXRs to induce reverse cholesteroltransport in skeletal muscle, most likely via the up-regulationof ABCA1, ABCG1, and apoE expression, suggests that this majormass tissue can make significant contributions to whole body cholesterolhomeostasis. We have not detected LXR agonist-dependent effectson the expression of 3-hydroxy-3-methylglutaryl-CoA reductasein muscle, indicating that increased reverse cholesterol transportis not stimulating de novo cholesterol synthesis (data not shown).Not surprisingly, the ability of LXR agonists to promote reversecholesterol transport has stimulated great interest in the potentialof small molecule activators of LXRs as therapeutic agents forthe treatment of cardiovascular disease (3, 4). Previousstudies, however, focus on the therapeutic benefit of regulatingreverse cholesterol transport in macrophage foam cells, a cell-typethat directly contributes to atherosclerotic lesion development(32). Based on the overall mass of skeletal muscle, our workalso identifies this tissue as an important site of action forLXR-baseddrugs.

LXRs also regulate fatty acid metabolism by controlling expression of SREBP1c, the master transcriptional regulator of fattyacid synthesis, and the enzymes that participate in this metabolicpathway (1, 21, 22). Not surprisingly, treatment of experimentalanimals with LXR agonists results in significant increases inhepatic and serum triglycerides (1). The ability of LXRs toregulate fatty acid metabolism in skeletal muscle has importantconsequences for carbohydrate and lipid homeostasis. In responseto insulin, skeletal muscle accounts for the majority of glucoseuptake in the body. Insulin also induces SREBP1c expression inskeletal muscle, and this regulation is defective in patientswith type II diabetes (33). Thus LXR ligands should partiallymimic insulin by inducing SREBP1c in muscle and may function asinsulin sensitizers. However, significant correlations also existbetween high levels of intra-muscular lipid content and insulinresistance (34, 35), suggesting that increased fatty acidsynthesis by muscle may also have adverse effects. Interestingly,although SREBP1c is induced in skeletal muscle by LXR ligands,two down-stream targets involved in fatty acid synthesis, SCD-1and FAS, are not. Thus, in muscle LXR activity may be uncoupledfrom fatty acid metabolism. Clearly additional studies will beneeded to fully understand the cross-talk between insulin signalingand LXR transcriptionalactivity.

The accumulation of cholesterol by macrophages in the arterial wall via the uptake of oxidized LDL particles is one the firststeps in the development of atherosclerosis (32). Not surprisingly,the ability of LXR to regulate reverse cholesterol transport inmacrophages, i.e. the efflux of intracellular cholesterol to extracellularHDL particles, has stimulated great interest in understandinghow LXR activity is regulated. In macrophages a second memberof the nuclear receptor superfamily, PPAR $gamma$ , directly regulatesthe gene encoding LXR $alpha$ (36, 37). Interestingly, agonists ofPPAR $gamma$ increase reverse cholesterol transport in isolated macrophages(10, 37) and decrease atherosclerosis in rodent models (38).Based upon these observations and the ability of LXR to directlyregulate ABCA1, it has been suggested that induction of LXR $alpha$ accountsat least in part for the ability of PPAR $gamma$ agonists to stimulatereverse cholesterol transport (3, 4). In muscle, however,PPAR $gamma$ is expressed at relatively low levels, and in differentiatedC2C12 myotubes a potent synthetic PPAR $gamma$ agonist does not induceexpression of ABCA1 or increase reverse cholesterol transport.Thus when compared with PPAR $gamma$ ligands, activators of LXR may havethe added benefit of stimulating reverse cholesterol transportin a cell type that accounts for ~40% of human total bodyweight.

Taking advantage of the C2C12 cell culture system we demonstrate that the mRNA encoding LXR $alpha$ is induced during skeletal myogenesisjust before the induction of LXR target genes involved in reversecholesterol transport (ABCA1, ABCG1, and apoE). Strikingly, however,LXR targets involved in fatty acid synthesis (SREBP1c, FAS, andSCD-1) are not coordinately regulated with LXR $alpha$ . These observationssupport the hypothesis that there are inherent differences inthe regulation of these two classes of LXR targets. This apparentdichotomy in the LXR-dependent regulation of genes involved inreverse cholesterol transport and fatty acid metabolism has importantimplications for the development of LXR agonists as therapeuticagents. Increasing expression of ABC transporters and apoE withLXR agonists has several beneficial effects including increasingreverse cholesterol transport, elevating HDL cholesterol levels,and limiting the absorption of dietary cholesterol (7-10). Incontrast, the LXR-dependent hypertriglyceridemia induced at leastin part by up-regulation of fatty acid synthesis is an undesirableside effect (1). The differential induction of these two classesof LXR target genes observed in skeletal muscle and during myogenesis,however, suggests that there are mechanistic differences in theregulation of each target class that can be exploited for drugdevelopment. Future studies that define the mechanistic basisfor this differential regulation will contribute to an understandingof biological function of LXR and assist in the development ofeffective LXR-based therapeuticagents.

ACKNOWLEDGEMENTS

We thank the chemistry department at X-Ceptor Therapeutics for providing synthetic ligands and Dr. M. Manchester for commentson themanuscript.

	FOOTNOTES

^* The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

^¶ To whom correspondence should be addressed: X-Ceptor Therapeutics, 4757 Nexus Centre Dr., San Diego, CA 92121. Tel.: 858-458-4542;Fax: 858-458-4501; E-mail: ischulman@x-ceptor.com (to I. G. S.)or University of Queensland, Institute for Molecular Bioscience,Centre for Molecular and Cellular Biology, Ritchie Research Laboratories,B402A, St. Lucia, 4072, Queensland, Australia. Tel.: 61733654492;Fax: 61733654388; E-mail: g.muscat@imb.uq.edu.au (to G. E. O.M.).

Published, JBC Papers in Press, August 21, 2002, DOI 10.1074/jbc.M206681200

ABBREVIATIONS

The abbreviations used are: PPAR, peroxisome proliferator-activated receptor; LXR, liver X receptor; HDL, high density lipoprotein; SREBP1c, sterol response element-binding protein 1c; FAS, fatty acid synthase; SCD-1, stearoyl-CoA desaturase 1; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; DOTAP, N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium salts; DOSPER, 1-3-di-oleoyloxy- 2-(6-carboxy-spermyl)-propylamid.

	REFERENCES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

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