1. Volume 23, Issue 3, Pages 479-491 (March 2016)
Ligand Activation of ERRα by Cholesterol Mediates Statin and Bisphosphonate Effects 
Wei Wei, Adam G. Schwaid, Xueqian Wang, Xunde Wang, Shili Chen, Qian Chu, Alan Saghatelian, Yihong Wan 
Cell Metabolism 
Volume 23, Issue 3, Pages (March 2016)
DOI: /j.cmet
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2. Cell Metabolism 2016 23, 479-491DOI: (10.1016/j.cmet.2015.12.010)
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3. Figure 1
The ERRα-LBD Selectively Enriches Cholesterol from the Lipidome
(A) A schematic diagram of the workflow for the identification of HIS-ERRα-LBD binders. HIS-ERRα-LBD is immobilized on a solid support and incubated with lipids from brain or kidney. After washing away unbound lipids, the protein complex is eluted, and eluent is analyzed by LC-MS. Lipids that bind HIS-ERRα-LBD are only present in the ERRα sample, but not in the no-protein (resin only) control.
(B) HIS-ERRα-LBD was incubated with a pool of lipids from brain, and bound lipids were analyzed by untargeted LC-MS. Cholesterol was the only lipid that was strongly and consistently enriched.
(C) Cholesterol binding is also demonstrated by a targeted MS/MS method designed for sensitive and specific identification of sterol HIS-ERRα-LBD binding. A representative LC-MS chromatogram is shown.
(D) Cholesterol binding could be blocked by the ERRα synthetic antagonist diethylstilbestrol (DES). In the absence of DES, HIS-ERRα-LBD strongly enriched cholesterol from a pool of brain sterols relative to a resin only sample. When DES was added to the sterol mixture, HIS-ERRα-LBD could no longer enrich cholesterol. Error bars, SD.
See also Figures S1 and S2 and Table S1.
Cell Metabolism  , DOI: ( /j.cmet )
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4. Figure 2 Characterization of Cholesterol Binding to the ERRα-LBD
(A) Molecular docking simulations suggested that cholesterol bound to ERRα in the ligand binding pocket with the hydroxyl group facing into the ligand binding pocket. In this model, cholesterol makes important interactions with three residues: E235, F232, and L228 (highlighted in blue).
(B) Fluorescent cholesterol derivatives demonstrated that cholesterol bound with its hydroxyl group facing into the ligand binding pocket. Labeling at the alkyl but not hydroxyl group with an NDB fluorophore permitted ERRα-cholesterol binding.
(C) Competition fluorescence polarization assay with increasing amount of cholesterol and estradiol indicates that only cholesterol was able to compete with 25-NBD-cholesterol in binding to ERRα-LBD.
(D) Cholesterol binding quenches the intrinsic tryptophan fluorescence intensity of ERRα-LBD, while estradiol, which is known to not bind ERRα, has no effect on ERRα tryptophan fluorescence.
(E) A E235A, F232A, L228A ERRα triple mutant had impaired cholesterol binding ability relative to wild-type ERRα. Error bars, SD.
See also Figure S3.
Cell Metabolism  , DOI: ( /j.cmet )
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5. Figure 3 Cholesterol Increases ERRα Transcriptional Activity
ERRα transcriptional activity was analyzed using transient transfection and reporter assays.
(A) Cholesterol depletion by lovastatin and/or the cholesterol binder hydroxypropyl-beta-cyclodextrin (HPCD) results in lower ERRα transcriptional activity. Results are shown as fold induction by ERRα + PGC1α transfection compared to vector (vec) transfection control (n = 6). ∗ indicates HPCD effect; + indicates lovastain effect.
(B) The addition of cholesterol (gray bars) back to cholesterol-depleted cells dose-dependently rescues ERRα activity, whereas XCT790 (black bars), a known ERRα antagonist and thus a control for this assay, further suppressed ERRα activity dose dependently (n = 6). CV-1 cells were transfected with expression vectors for ERRα and PGC1α coactivator as well as ERRE-luc and CMV-βgal reporters. For cholesterol depletion, the cells were treated with lovastatin at indicated concentration and HPCD (10 mM) for 4 hr in DMEM containing 10% NCLPPS (newborn calf lipoprotein poor serum), and then with lovastatin in DMEM containing 10% NCLPPS for another 20 hr. For cholesterol additions to cells, cholesterol-depleted cells were treated with cholesterol or vehicle during the 20 hr of lovastatin treatment, or with XCT790 as a control. Error bars, SD.
See also Figure S4.
Cell Metabolism  , DOI: ( /j.cmet )
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6. Figure 4 ERRα Mediates Statin-Induced Muscle Toxicity
(A and B) Effects of statins, cholesterol, and XCT790 on C2C12 myotube differentiation. Lovastatin (Lova), simvastatin (Simva), cholesterol, and XCT790 were added at 10 μM. (A) Representative images of C2C12 differentiation cultures on day 5. Scale bar, 25 μm. (B) mRNA expression of myotube differentiation markers on day 5 (n = 3).
(C) mRNA expression of the muscle atrophy gene atrogin-1 (Fbxo32) on day 5 (n = 3).
(D–F) Statin-induced muscle toxicity is abolished in ERRαKO mice. ERRαKO mice or WT controls (6 month old, females, n = 6) were treated with simvastatin (Simva) for 2 weeks at 20 mg/kg/day. (D) mRNA expression of myotube differentiation markers in quadriceps muscle (n = 6). (E) mRNA expression of the muscle atrophy gene atrogin-1 (Fbxo32) in quadriceps muscle (n = 6). (F) Serum muscle damage marker creatine kinase (CK, n = 6). Black ∗ and n.s. compare statin with vehicle (Veh) control; blue + and n.s. compare ERRαKO with WT control.
(G) Coimmunoprecipitation analysis of the effects of statin and cholesterol on ERRα and PGC1α interaction. C2C12 myotube differentiation cultures were treated with vehicle, simvastatin, or simvastatin + cholesterol at 10 μM for 24 hr. Average results for the IP/Input ratio from three independent experiments are shown. Error bars, SD.
See also Figures S5 and S7.
Cell Metabolism  , DOI: ( /j.cmet )
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7. Figure 5
ERRα Mediates Cholesterol Stimulation of Osteoclastogenesis Ex Vivo
(A and B) Cholesterol promotes whereas statin and bisphosphonate inhibit osteoclastogenesis in WT but not ERRαKO bone marrow osteoclast differentiation cultures. (A) Representative images of TRAP-stained differentiation cultures showing the number and size of mature osteoclasts. Mature osteoclasts were identified as multinucleated (>3 nuclei) TRAP+ (purple) cells. Scale bar, 25 μm. Number of osteoclast/well is shown as insets; black ∗ or n.s. compare cholesterol versus veh, red ∗ or n.s. compare lovastatin versus control, green ∗ or n.s. compare zoledronate versus control. (B) Quantification of the mRNA expression of ERRα target genes and osteoclast differentiation markers. p values compare each treatment condition with vehicle control in the same genotype.
(C) Cholesterol induction of ERRα target genes and osteoclast differentiation markers in WT bone marrow osteoclast differentiation cultures was abolished by the treatment of an ERRα antagonist XCT790. Chol, cholesterol (10 μM); lova, lovastatin (10 μM); zole, zoledronate (20 μM); ctrl, control; XCT, XCT790 (10 μM).
(D) Coimmunoprecipitation analysis of the effects of statin and cholesterol on ERRα and PGC1β interaction. Bone marrow osteoclast differentiation cultures were treated with RANKL for 6 days in the presence of lovastatin (10 nM), cholesterol (2 μM), or vehicle control. Representative results from three independent experiments are shown.
(E) Cholesterol inhibits whereas statin and bisphosphonate enhance cxcl9 and cxcl10 expression in WT but not ERRαKO macrophages. Macrophages were differentiated from bone marrow cells of WT or ERRαKO mice with 20ng/ml MCSF for 8 days, in the presence of compound or vehicle, and then treated with 200 μg/ml LPS for 6 hr at the end. p values compare each treatment condition with vehicle control in the same genotype.
(F) Cholesterol suppression of cxcl9 and cxcl10 in WT macrophages was abolished by XCT790. Chol, cholesterol (10 μM); lova, lovastatin (10 μM); zole, zoledronate (20 μM); ctrl, control; XCT, XCT790 (10 μM). Error bars, SD.
See also Figures S5 and S6.
Cell Metabolism  , DOI: ( /j.cmet )
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8. Figure 6
ERRα Mediates Cholesterol Stimulation of Bone Resorption In Vivo
(A–D) Osteoprotective effects of zoledronate were abolished in ERRαKO mice. WT or ERRαKO mice (6-week-old male, n = 4) were treated with a single i.v. injection of zoledronate at 0.54 mg/kg or PBS vehicle control and analyzed 4 weeks later. (A) Serum levels of the bone resorption marker CTX-1. (B and C) MicroCT analysis of tibiae. (B) Trabecular bone volume/tissue volume ratio (BV/TV). (C) Representative CT images of the entire proximal tibia (scale bar, 1 mm). (D) Bone histomorphometry analysis of osteoclast surface/bone surface (Oc.S/BS) (top) and osteoclast number/bone area (Oc.N/B.Ar) (bottom).
(E–H) Bone loss induced by high-cholesterol diet (HCD) feeding was abolished in ERRαKO mice. WT or ERRαKO mice (7 week old female, n = 4) were fed with a HCD or chow control diet for 4 weeks. (E) Serum levels of the bone resorption marker CTX-1. (F and G) MicroCT analysis of tibiae. (F) Trabecular BV/TV. (G) Representative CT images of the entire proximal tibia (scale bar, 1 mm). (H) Bone histomorphometry analysis of Oc.S/BS (top) and Oc.N/B.Ar (bottom). Error bars, SD.
See also Figure S7.
Cell Metabolism  , DOI: ( /j.cmet )
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9. Figure 7
A Schematic Diagram of How ERRα Mediates the Effects of Cholesterol, Statins, and Bisphosphonates
Cholesterol serves as a natural ERRα agonist to recruit coactivators PGC1α/β and increase ERRα transcriptional activity, thereby promoting osteoclastogenesis and myogenesis but inhibiting macrophage cytokine production. A reduction in cholesterol synthesis by statins or bisphosphonates decreases ERRα transcriptional activity, thereby mediating the statin-induced muscle toxicity and bisphosphonate suppression of bone resorption.
Cell Metabolism  , DOI: ( /j.cmet )
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