Project description:Synthetic selective thyroid hormone (TH) receptor (TR) modulators (STRMs) exhibit beneficial effects on dyslipidemias in animals and humans and reduce obesity, fatty liver and insulin resistance in preclinical animal models. STRMs differ from native THs in preferential binding to the TRβ subtype versus TRα, increased uptake into liver and reduced uptake into other tissues. However, selective modulators of other nuclear receptors (NRs) exhibit important gene-selective actions which have been attributed to differential effects on receptor conformation and dynamics and these effects can have profound influences in animals and humans. While there are suggestions that STRMs could exhibit such gene-specific actions, the extent to which these effects are actually observed in vivo has not been explored. Here, we show that saturating concentrations of the main active form of TH, triiodothyronine (T3), and the prototype STRM GC-1 induce identical gene-sets in livers of euthyroid and hypothyroid mice and a human cultured hepatoma cell line that only expresses TRβ, HepG2. We find one case in which GC-1 exhibits a modest gene-specific reduction in potency versus T3, at angiopoietin-like factor 4 (ANGPTL4) in HepG2. Investigation of the latter effect confirms that GC-1 acts through TRβ to directly induce this gene. However, this gene-selective GC-1 activity is not related to unusual T3 response element (TRE) sequence, unlike previously documented promoter-selective STRM actions. Together, our data suggest that T3 and GC-1 exhibit almost identical gene regulation properties and that gene-selective actions of GC-1 and similar STRMs will be subtle and rare. We treated HepG2 with vehicle or 10nM ligand (T3 or GC1; n=3 / treatment), analyzing mRNA 24h post treatment [Affymetrix]. We also treated 9-week old euthyroid male C57/Bl6 mice with vehicle or ligand (T3 or GC-1) by a single oral gavage (n=5 per treatment) and also performed a similar study in which mice were first made hypothyroid by two week feeding on iodine deficient diet (n=3-4 per treatment), analyzing mRNA 24h post treatment [Illumina].

Project description:Synthetic selective thyroid hormone (TH) receptor (TR) modulators (STRMs) exhibit beneficial effects on dyslipidemias in animals and humans and reduce obesity, fatty liver and insulin resistance in preclinical animal models. STRMs differ from native THs in preferential binding to the TRβ subtype versus TRα, increased uptake into liver and reduced uptake into other tissues. However, selective modulators of other nuclear receptors (NRs) exhibit important gene-selective actions which have been attributed to differential effects on receptor conformation and dynamics and these effects can have profound influences in animals and humans. While there are suggestions that STRMs could exhibit such gene-specific actions, the extent to which these effects are actually observed in vivo has not been explored. Here, we show that saturating concentrations of the main active form of TH, triiodothyronine (T3), and the prototype STRM GC-1 induce identical gene-sets in livers of euthyroid and hypothyroid mice and a human cultured hepatoma cell line that only expresses TRβ, HepG2. We find one case in which GC-1 exhibits a modest gene-specific reduction in potency versus T3, at angiopoietin-like factor 4 (ANGPTL4) in HepG2. Investigation of the latter effect confirms that GC-1 acts through TRβ to directly induce this gene. However, this gene-selective GC-1 activity is not related to unusual T3 response element (TRE) sequence, unlike previously documented promoter-selective STRM actions. Together, our data suggest that T3 and GC-1 exhibit almost identical gene regulation properties and that gene-selective actions of GC-1 and similar STRMs will be subtle and rare.

Project description:Synthetic selective thyroid hormone (TH) receptor (TR) modulators (STRMs) exhibit beneficial effects on dyslipidemias in animals and humans and reduce obesity, fatty liver and insulin resistance in preclinical animal models. STRMs differ from native THs in preferential binding to the TR? subtype versus TR?, increased uptake into liver and reduced uptake into other tissues. However, selective modulators of other nuclear receptors (NRs) exhibit important gene-selective actions which have been attributed to differential effects on receptor conformation and dynamics and these effects can have profound influences in animals and humans. While there are suggestions that STRMs could exhibit such gene-specific actions, the extent to which these effects are actually observed in vivo has not been explored. Here, we show that saturating concentrations of the main active form of TH, triiodothyronine (T3), and the prototype STRM GC-1 induce identical gene-sets in livers of euthyroid and hypothyroid mice and a human cultured hepatoma cell line that only expresses TR?, HepG2. We find one case in which GC-1 exhibits a modest gene-specific reduction in potency versus T3, at angiopoietin-like factor 4 (ANGPTL4) in HepG2. Investigation of the latter effect confirms that GC-1 acts through TR? to directly induce this gene. However, this gene-selective GC-1 activity is not related to unusual T3 response element (TRE) sequence, unlike previously documented promoter-selective STRM actions. Together, our data suggest that T3 and GC-1 exhibit almost identical gene regulation properties and that gene-selective actions of GC-1 and similar STRMs will be subtle and rare. We treated 9-week old euthyroid male C57/Bl6 mice with vehicle or ligand (T3 or GC-1) by a single oral gavage (n=5 per treatment) and also performed a similar study in which mice were first made hypothyroid by two week feeding on iodine deficient diet (n=3-4 per treatment), analyzing mRNA 24h post treatment [Illumina]. We also treated HepG2 with vehicle or 10nM ligand (T3 or GC1; n=3 / treatment), analyzing mRNA 24h post treatment [Affymetrix].

Project description:Thyroid hormone (TH) influences metabolic pathways by binding to specific receptors (TRs), which are conditional transcription factors. T3 works through TRs to induce fibroblast growth factor (FGF) 21, a peptide hormone that is usually induced in fasting and influences lipid and carbohydrate metabolism via local hepatic and systemic endocrine effects. While administered TH and FGF21 display overlapping actions, including reductions in serum lipids, current models suggest that these hormones act independently in vivo. Here, we examined mechanisms of TH regulation of FGF21 expression and tested the possibility that FGF21 is required for induction of hepatic TH-responsive genes. We confirm that active TH (T3) and the TRβ selective thyromimetic GC-1 increase FGF21 transcript and peptide levels in mouse liver and that this effect requires TRβ. T3 also induces FGF21 in cultured hepatocytes and this effect involves direct actions of TRβ1, which binds a TRE within intron 2 of FGF21. Gene expression profiles in wild type and FGF21 knockout mice are highly similar indicating that FGF21 is dispensable for the majority of hepatic T3 gene responses. A small subset of genes displays diminished T3 response in the absence of FGF21. However, most of these are not obviously involved in T3-dependent hepatic lipid and carbohydrate metabolic processes. Accordingly, T3-dependent effects upon serum lipids are maintained in the FGF21-/- background. Our findings suggest that T3 regulates genes involved in classical hepatic metabolic responses independently of FGF21.

Project description:A greater understanding of the glucose homeostasis mediated by glucagon-like peptide-1 (GLP-1) will facilitate the development of novel glucose-lowering treatments. Here we show that improved glucose metabolism in hypothyroid mice after treatment of T3, the active form of thyroid hormone (TH), is accompanied with increased GLP-1 production and insulin secretion. Treatment of a GLP-1 receptor antagonist is able to attenuate the observed T3 effect on insulin and glucose levels, suggesting that GLP-1 is critically involved in the regulation of glucose homeostasis by T3. By using a mouse model lacking hepatic TH receptor β (TRβ) and a liver-specific TRβ-selective agonist, we demonstrate that TRβ-mediated hepatic TH signalling is not only required for the regulation of GLP-1 production by T3 but also the insulinotropic and glucose-lowering effects of T3. Accordingly, administration of the liver-targeted TRβ-selective agonist is capable of increasing GLP-1 and insulin levels and alleviating hyperglycemia in diet-induced obesity. Mechanistically, through suppressing CYP8B1 expression, T3 shapes the bile acid (BA) composition and increases the levels of Farnesoid X receptor (FXR)-antagonistic BAs, thereby potentiating the GLP-1 production and insulin secretion by repressing intestinal FXR signalling. Consistently, correlations between the T3 levels and either GLP-1 or FXR-antagonistic BA levels can be observed in euthyroid human subjects. Thus, our study reveals a previously undescribed role of hepatic TH signalling in glucose homeostasis through the regulation of GLP-1 production via BA-mediated FXR antagonism, which will underpin the development of novel therapeutics.

Project description:A greater understanding of the glucose homeostasis mediated by glucagon-like peptide-1 (GLP-1) will facilitate the development of novel glucose-lowering treatments. Here we show that improved glucose metabolism in hypothyroid mice after treatment of T3, the active form of thyroid hormone (TH), is accompanied with increased GLP-1 production and insulin secretion. Treatment of a GLP-1 receptor antagonist is able to attenuate the observed T3 effect on insulin and glucose levels, suggesting that GLP-1 is critically involved in the regulation of glucose homeostasis by T3. By using a mouse model lacking hepatic TH receptor β (TRβ) and a liver-specific TRβ-selective agonist, we demonstrate that TRβ-mediated hepatic TH signalling is not only required for the regulation of GLP-1 production by T3 but also the insulinotropic and glucose-lowering effects of T3. Accordingly, administration of the liver-targeted TRβ-selective agonist is capable of increasing GLP-1 and insulin levels and alleviating hyperglycemia in diet-induced obesity. Mechanistically, through suppressing CYP8B1 expression, T3 shapes the bile acid (BA) composition and increases the levels of Farnesoid X receptor (FXR)-antagonistic BAs, thereby potentiating the GLP-1 production and insulin secretion by repressing intestinal FXR signalling. Consistently, correlations between the T3 levels and either GLP-1 or FXR-antagonistic BA levels can be observed in euthyroid human subjects. Thus, our study reveals a previously undescribed role of hepatic TH signalling in glucose homeostasis through the regulation of GLP-1 production via BA-mediated FXR antagonism, which will underpin the development of novel therapeutics.

Project description:This SuperSeries is composed of the following subset Series: GSE32443: Identical gene regulation patterns of triiodothyronine (T3) and selective thyroid hormone receptor modulator GC-1 [Affymetrix] GSE32444: Identical gene regulation patterns of triiodothyronine (T3) and selective thyroid hormone receptor modulator GC-1 [Illumina] Refer to individual Series

Project description:Since the thyroid hormone receptor β (TRβ) appears to suppress breast tumor growth and metastasis, we have analyzed the possibility that this receptor could affect cancer stem cell biology using TRβ-expressing MCF-7 cells (MCF7-TRβ cells) treated with the thyroid hormone T3.

Project description:Since the thyroid hormone receptor β (TRβ) appears to suppress breast tumor growth and metastasis, we have analyzed the possibility that this receptor could affect cancer stem cell biology using mammospheres from TRβ-expressing MCF-7 cells (MCF7-TRβ cells) treated with the thyroid hormone T3.

Project description:Thyroid hormone (TH) and TH receptors (TRs) α and β act by binding to TH response elements (TREs) in regulatory regions of target genes. This nuclear signaling is established as the canonical pathway for TH action. In addition, however, TRs can activate intra-cellular second messenger signaling pathways. Whether such non-canonical TR signaling is physiologically relevant in vivo is unknown. Here we generated knock-in mice with a mutation in the TR DNA-binding domain that abrogates binding to DNA and TREs and leads to a complete loss of canonical TH action. We show that several important physiological TH effects are preserved despite disrupted DNA-binding, most notably heart rate, body temperature, blood glucose and triglyceride concentration, all of which were regulated by non-canonical TR signaling. Additionally, we confirm that TRE-binding defective TRβ leads to disruption of the hypothalamic-pituitary-thyroid axis with resistance to TH, while mutation of TRα causes a severe delay in skeletal development, showing TRE-mediated and tissue-specific canonical signaling. Our findings provide first in vivo evidence that non-canonical TR signaling exerts important cardiometabolic effects, which are clearly separated from canonical actions. Consequently, these data challenge the current paradigm that TH action is exclusively mediated through regulation of gene transcription at the nuclear level.