The use of selective agonists of the thyroid hormone receptor isoform β (TRβ) has been linked to metabolic improvement in animal models of diet-induced obesity, nonalcoholic liver disease, and genetic hypercholesterolemia.
Methods:
To identify potential target tissues of such compounds, we exposed primary murine brown adipocytes and skeletal myocytes for 24 hours to 50 nM GC-24, a highly selective TRβ agonist. GC-24 (17 ng/[g BW·day] for 36 days) was also tested in a mouse model of diet-induced obesity.
Results:
While the brown adipocytes responded to GC-24, with 17%–400% increases in the expression of 12 metabolically relevant genes, the myocytes remained largely unresponsive to GC-24 treatment. In control mice kept on chow diet, GC-24 treatment accelerated energy expenditure by about 15% and limited body weight gain by about 50%. However, in the obese animals the GC-24-mediated reduction in body weight gain dropped to only 20%, while energy expenditure remained unaffected. In addition, an analysis of gene expression in the skeletal muscle, brown adipose tissue, and liver of these obese animals failed to identify a conclusive GC-24 transcriptome footprint.
Conclusion:
Feeding a high-fat diet impairs most of the beneficial metabolic effects associated with treatment with TRβ-selective agonists.
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References
1.
BiancoAC, MaiaAL, da SilvaWS, ChristoffoleteMA. 2005. Adaptive activation of thyroid hormone and energy expenditure. Biosci Rep, 25:191–208.
2.
YenPM. 2001. Physiological and molecular basis of thyroid hormone action. Physiol Rev, 81:1097–1142.
3.
BrentGA. 2000. Tissue-specific actions of thyroid hormone: insights from animal models. Rev Endocr Metab Disord, 1:27–33.
4.
ChielliniG, AprilettiJW, YoshiharaHA, BaxterJD, RibeiroRC, ScanlanTS. 1998. A high-affinity subtype-selective agonist ligand for the thyroid hormone receptor. Chem Biol, 5:299–306.
ErionMD, CableEE, ItoBR, JiangH, FujitakiJM, FinnPD, ZhangBH, HouJ, BoyerSH, van PoeljePD, LinemeyerDL. 2007. Targeting thyroid hormone receptor-beta agonists to the liver reduces cholesterol and triglycerides and improves the therapeutic index. Proc Natl Acad Sci U S A, 104:15490–15495.
8.
MiyabaraEH, AokiMS, SoaresAG, SaltaoRM, VilicevCM, PassarelliM, ScanlanTS, GouveiaCH, MoriscotAS. 2005. Thyroid hormone receptor-beta-selective agonist GC-24 spares skeletal muscle type I to II fiber shift. Cell Tissue Res, 321:233–241.
GroverGJ, MellstromK, MalmJ. 2007. Therapeutic potential for thyroid hormone receptor-beta selective agonists for treating obesity, hyperlipidemia and diabetes. Curr Vasc Pharmacol, 5:141–154.
11.
VillicevCM, FreitasFR, AokiMS, TaffarelC, ScanlanTS, MoriscotAS, RibeiroMO, BiancoAC, GouveiaCH. 2007. Thyroid hormone receptor beta-specific agonist GC-1 increases energy expenditure and prevents fat-mass accumulation in rats. J Endocrinol, 193:21–29.
12.
BrancoM, RibeiroM, NegraoN, BiancoAC. 1999. 3,5,3'-Triiodothyronine actively stimulates UCP in brown fat under minimal sympathetic activity. Am J Physiol, 276:E179–E187.
de JesusLA, CarvalhoSD, RibeiroMO, SchneiderM, KimSW, HarneyJW, LarsenPR, BiancoAC. 2001. The type 2 iodothyronine deiodinase is essential for adaptive thermogenesis in brown adipose tissue. J Clin Invest, 108:1379–1385.
17.
ChristoffoleteMA, LinardiCC, de JesusL, EbinaKN, CarvalhoSD, RibeiroMO, RabeloR, CurcioC, MartinsL, KimuraET, BiancoAC. 2004. Mice with targeted disruption of the Dio2 gene have cold-induced overexpression of the uncoupling protein 1 gene but fail to increase brown adipose tissue lipogenesis and adaptive thermogenesis. Diabetes, 53:577–584.
18.
AmorimBS, UetaCB, FreitasBC, NassifRJ, GouveiaCH, ChristoffoleteMA, MoriscotAS, LancellotiCL, LlimonaF, BarbeiroHV, de SouzaHP, CatanoziS, PassarelliM, AokiMS, BiancoAC, RibeiroMO. 2009. A TRbeta-selective agonist confers resistance to diet-induced obesity. J Endocrinol, 203:291–299.
19.
FasshauerM, KleinJ, KriauciunasKM, UekiK, BenitoM, KahnCR. 2001. Essential role of insulin receptor substrate 1 in differentiation of brown adipocytes. Mol Cell Biol, 21:319–329.
20.
RandoTA, BlauHM. 1994. Primary mouse myoblast purification, characterization, and transplantation for cell-mediated gene therapy. J Cell Biol, 125:1275–1287.
21.
ChristoffoleteMA, RibeiroR, SingruP, FeketeC, da SilvaWS, GordonDF, HuangSA, CrescenziA, HarneyJW, RidgwayEC, LarsenPR, LechanRM, BiancoAC. 2006. Atypical expression of type 2 iodothyronine deiodinase in thyrotrophs explains the thyroxine-mediated pituitary thyrotropin feedback mechanism. Endocrinology, 147:1735–1743.
22.
FreitasFR, MoriscotAS, JorgettiV, SoaresAG, PassarelliM, ScanlanTS, BrentGA, BiancoAC, GouveiaCH. 2003. Spared bone mass in rats treated with thyroid hormone receptor TR beta-selective compound GC-1. Am J Physiol Endocrinol Metab, 285:E1135–E1141.
23.
GroverGJ, EganDM, SlephPG, BeehlerBC, ChielliniG, NguyenNH, BaxterJD, ScanlanTS. 2004. Effects of the thyroid hormone receptor agonist GC-1 on metabolic rate and cholesterol in rats and primates: selective actions relative to 3,5,3'-triiodo-L-thyronine. Endocrinology, 145:1656–1661.
24.
ManzanoJ, MorteB, ScanlanTS, BernalJ. 2003. Differential effects of triiodothyronine and the thyroid hormone receptor beta-specific agonist GC-1 on thyroid hormone target genes in the brain. Endocrinology, 144:5480–5487.
25.
AmmaLL, Campos-BarrosA, WangZ, VennstromB, ForrestD. 2001. Distinct tissue-specific roles for thyroid hormone receptors beta and alpha1 in regulation of type 1 deiodinase expression. Molecular Endocrinology, 15:467–475.
26.
RibeiroMO. 2008. Effects of thyroid hormone analogs on lipid metabolism and thermogenesis. Thyroid, 18:197–203.
27.
PihlajamäkiJ, BoesT, KimEY, DearieF, KimBW, SchroederJ, MunE, NasserI, ParkPJ, BiancoAC, GoldfineAB, PattiME. 2009. Thyroid hormone-related regulation of gene expression in human fatty liver. J Clin Endocrinol Metab, 94:3521–3529.
28.
KongWM, MartinNM, SmithKL, GardinerJV, ConnoleyIP, StephensDA, DhilloWS, GhateiMA, SmallCJ, BloomSR. 2004. Triiodothyronine stimulates food intake via the hypothalamic ventromedial nucleus independent of changes in energy expenditure. Endocrinology, 145:5252–5258.
29.
DhilloWS. 2007. Appetite regulation: an overview. Thyroid, 17:433–445.
30.
BrentGA. 1994. The molecular basis of thyroid hormone action. N Engl J Med, 331:847–853.
