Thyroid hormone receptor beta-deficient mice show complete loss of the normal cholesterol 7alpha-hydroxylase (CYP7A) response to thyroid hormone but display enhanced resistance to dietary cholesterol

Thyroid hormone (T3) influences hepatic cholesterol metabolism, and previous studies have established an important role of this hormone in the regulation of cholesterol 7alpha-hydroxylase (CYP7A), the rate-limiting enzyme in the synthesis of bile acids. To evaluate the respective contribution of thyroid hormone receptors (TR) alpha1 and beta in this regulation, the responses to 2% dietary cholesterol and T3 were studied in TRalpha1 and TRbeta knockout mice under hypo- and hyperthyroid conditions. Our experiments show that the normal stimulation in CYP7A activity and mRNA level by T3 is lost in TRbeta-/- but not in TRalpha1-/-mice, identifying TRbeta as the mediator of T3 action on CYP7A and, consequently, as a major regulator of cholesterol metabolism in vivo. Somewhat unexpectedly, T3-deficient TRbeta-/- mice showed an augmented CYP7A response after challenge with dietary cholesterol, and these animals did not develop hypercholesterolemia to the extent as did wild-type (wt) controls. The latter results lend strong support to the concept that TRs may exert regulatory effects in vivo independent of T3.     

TRs have common and isoform-specific functions in regulation of the cardiac myosin heavy chain genes.

TRalpha1 and TRbeta mediate the regulatory effects of T3 and have profound effects on the cardiovascular system. We have analyzed the expression of the cardiac myosin heavy chain (MyHC) genes alpha and beta in mouse strains deficient for one or several TR genes to identify specific regulatory functions of TRalpha1 and TRbeta. The results show that TRalpha1 deficiency, which slows the heart rate, causes chronic overexpression of MyHCbeta. However, MyHCbeta was still suppressible by T3 in both TRalpha1- and TRbeta-deficient mice, indicating that either receptor can mediate repression of MyHCbeta. T3-dependent induction of the positively regulated MyHCalpha gene was similar in both TRalpha1- and TRbeta-deficient mice. The data identify a specific role for TRalpha1 in the negative regulation of MyHCbeta, whereas TRalpha1 and TRbeta appear interchangeable for hormone-dependent induction of MyHCalpha. This suggests that TR isoforms exhibit distinct specificities in the genes that they regulate within a given tissue type. Thus, dysregulation of MyHCbeta is likely to contribute to the critical role of TRalpha1 in cardiac function.     

Distinct modulatory roles for thyroid hormone receptors TRalpha and TRbeta in SREBP1-activated ABCD2 expression

Adrenoleukodystrophy-related protein, a peroxisomal ABC transporter encoded by ABCD2, displays functional redundancy with the disease-associated X-linked adrenoleukodystrophy protein, making pharmacological induction of ABCD2 a potentially attractive therapeutic approach. Sterol regulatory element (SRE)-binding proteins (SREBPs) induce ABCD2 through an SRE overlapping with a direct repeat (DR-4) element. Here we show that thyroid hormone (T(3)) receptor (TR)alpha and TRbeta bind this motif thereby modulating SREBP1-dependent activation of ABCD2. Unliganded TRbeta, but not TRalpha, represses ABCD2 induction independently of DNA binding. However, activation by TRalpha and derepression of TRbeta are T(3)-dependent and require intact SRE/DR-4 motifs. Electrophoretic mobility shift assays with nuclear extracts support a direct interaction of TR and SREBP1 at the SRE/DR-4. In the liver, Abcd2 expression is high in young mice (with high T(3) and TRalpha levels) but downregulated in adults (with low T(3) and TRalpha but elevated TRbeta levels). This temporal repression of Abcd2 is blunted in TRbeta-deficient mice, and the response to manipulated T(3) states is abrogated in TRalpha-deficient mice. These findings show that TRalpha and TRbeta differentially modulate SREBP1-activated ABCD2 expression at overlapping SRE/DR-4 elements, suggesting a novel mode of cross-talk between TR and SREBP in gene regulation.     

An unliganded thyroid hormone beta receptor activates the cyclin D1/cyclin-dependent kinase/retinoblastoma/E2F pathway and induces pituitary tumorigenesis

Thyroid-stimulating hormone (TSH)-secreting tumors (TSH-omas) are pituitary tumors that constitutively secrete TSH. The molecular genetics underlying this abnormality are not known. We discovered that a knock-in mouse harboring a mutated thyroid hormone receptor (TR) beta (PV; TRbeta(PV/PV) mouse) spontaneously developed TSH-omas. TRbeta(PV/PV) mice lost the negative feedback regulation with highly elevated TSH levels associated with increased thyroid hormone levels (3,3',5-triiodo-l-thyronine [T3]). Remarkably, we found that mice deficient in all TRs (TRalpha1(-/-) TRbeta(-/-)) had similarly increased T3 and TSH levels, but no discernible TSH-omas, indicating that the dysregulation of the pituitary-thyroid axis alone is not sufficient to induce TSH-omas. Comparison of gene expression profiles by cDNA microarrays identified overexpression of cyclin D1 mRNA in TRbeta(PV/PV) but not in TRalpha1(-/-) TRbeta(-/-) mice. Overexpression of cyclin D1 protein led to activation of the cyclin D1/cyclin-dependent kinase/retinoblastoma protein/E2F pathway only in TRbeta(PV/PV) mice. The liganded TRbeta repressed cyclin D1 expression via tethering to the cyclin D1 promoter through binding to the cyclic AMP response element-binding protein. That repression effect was lost in mutant PV, thereby resulting in constitutive activation of cyclin D1 in TRbeta(PV/PV) mice. The present study revealed a novel molecular mechanism by which an unliganded TRbeta mutant acts to contribute to pituitary tumorigenesis in vivo and provided mechanistic insights into the understanding of pathogenesis of TSH-omas in patients.     

Contrasting skeletal phenotypes in mice with an identical mutation targeted to thyroid hormone receptor alpha1 or beta

Thyroid hormone (T(3)) regulates bone turnover and mineralization in adults and is essential for skeletal development. Surprisingly, we identified a phenotype of skeletal thyrotoxicosis in T(3) receptor beta(PV) (TRbeta(PV)) mice in which a targeted frameshift mutation in TRbeta results in resistance to thyroid hormone. To characterize mechanisms underlying thyroid hormone action in bone, we analyzed skeletal development in TRalpha1(PV) mice in which the same PV mutation was targeted to TRalpha1. In contrast to TRbeta(PV) mice, TRalpha1(PV) mutants exhibited skeletal hypothyroidism with delayed endochondral and intramembranous ossification, severe postnatal growth retardation, diminished trabecular bone mineralization, reduced cortical bone deposition, and delayed closure of the skull sutures. Skeletal hypothyroidism in TRalpha1(PV) mutants was accompanied by impaired GH receptor and IGF-I receptor expression and signaling in the growth plate, whereas GH receptor and IGF-I receptor expression and signaling were increased in TRbeta(PV) mice. These data indicate that GH receptor and IGF-I receptor are physiological targets for T(3) action in bone in vivo. The divergent phenotypes observed in TRalpha1(PV) and TRbeta(PV) mice arise because the pituitary gland is a TRbeta-responsive tissue, whereas bone is TRalpha responsive. These studies provide a new understanding of the complex relationship between central and peripheral thyroid status.     

Differential expression of thyroid hormone receptor isoforms dictates the dominant negative activity of mutant Beta receptor

Mutations in the thyroid hormone receptor beta gene (TRbeta) cause resistance to thyroid hormone (RTH). Genetic analyses indicate that phenotypic manifestation of RTH is due to the dominant negative action of mutant TRbeta. However, the molecular mechanisms underlying the dominant negative action of mutants and how the same mutation results in marked variability of resistance in different tissues in vivo are not clear. Here we used a knock-in mouse (TRbetaPV mouse) that faithfully reproduces human RTH to address these questions. We demonstrated directly that TRbeta1 protein was approximately 3-fold higher than TRalpha1 in the liver of TRbeta(+/+) mice but was not detectable in the heart of wild-type and TRbetaPV mice. The abundance of PV in the liver of TRbeta(PV/PV) was more than TRbeta(PV/+) mice but not detectable in the heart. TRalpha1 in the liver was approximately 6-fold higher than that in the heart of wild-type and TRbetaPV mice. Using TR isoforms and PV-specific antibodies in gel shift assays, we found that in vivo, PV competed not only with TR isoforms for binding to thyroid hormone response elements (TRE) but also competed with TR for the retinoid X receptors in binding to TRE. These competitions led to the inhibition of the thyroid hormone (T(3))-positive regulated genes in the liver. In the heart, however, PV was significantly lower and thus could not effectively compete with TRalpha1 for binding to TRE, resulting in activation of the T(3)-target genes by higher levels of circulating thyroid hormones. These results indicate that in vivo, differential expression of TR isoforms in tissues dictates the dominant negative activity of mutant beta receptor, thereby resulting in variable phenotypic expression in RTH.     

Cardiac glucose utilization in mice with mutated alpha- and beta-thyroid hormone receptors

Abnormal thyroid function is usually associated with altered cardiac function. Mutations in the thyroid hormone (TH)-binding region of the TH beta-receptor (TRbeta) that eliminate its TH-binding ability lead to the thyroid hormone resistance syndrome (RTH) in humans, which is characterized by high blood TH levels, goiter, hyperactivity, and tachycardia. Mice with "knock-in" mutations in the TH alpha-receptor (TRalpha) or TRbeta that remove their TH-binding ability have been developed, and those with the mutated TRbeta (TRbeta(PV/PV)) appear to provide a model for RTH. These two types of mutants show different effects on cerebral energy metabolism, e.g., negligible change in glucose utilization (CMR(Glc)) in TRbeta(PV/PV) mice and markedly reduced CMR(Glc), like that found in cretinous rats, in the mice (TRalpha(PV/+)) with the knock-in mutation of the TRalpha gene. Studies in knockout mice have indicated that the TRalpha may also influence heart rate. Because mutations in both receptor genes appear to affect some parameters of cardiac function and because cardiac functional activity and energy metabolism are linked, we measured heart glucose utilization (HMR(Glc)) in both the TRbeta(PV/PV) and TRalpha(PV/+) mutants. Compared with values in normal wild-type mice, HMR(Glc) was reduced (-77 to -95%) in TRalpha(PV/+) mutants and increased (87 to 340%) in TRbeta(PV/PV) mutants, the degree depending on the region of the heart. Thus the TRalpha(PV/+) and TRbeta(PV/PV) mutations lead, respectively, to opposite effects on energy metabolism in the heart that are consistent with the bradycardia seen in hypothyroidism and the tachycardia associated with hyperthyroidism and RTH.     

Age-related changes in renal and hepatic cellular mechanisms associated with variations in rat serum thyroid hormone levels

Aging is associated with changes in thyroid gland physiology. Age-related changes in the contribution of peripheral tissues to thyroid hormone serum levels have yet to be systematically assessed. Here, we investigated age-related alterations in the contributions of the liver and kidney to thyroid hormone homeostasis using 6-, 12-, and 24-mo-old male Wistar rats. A significant and progressive decline in plasma thyroxine occurred with age, but triiodothyronine (T(3)) was decreased only at 24 mo. This was associated with an unchanged protein level of the thyroid hormone transporter monocarboxylate transporter 8 (MCT8) in the kidney and with a decreased MCT8 level in the liver at 24 mo. Hepatic type I deiodinase (D1) protein level and activity declined progressively with age. Renal D1 levels were decreased at both 12 and 24 mo but D1 activity was decreased only at 24 mo. In the liver, no changes occurred in thyroid hormone receptor (TR) TRalpha(1), whereas a progressive increase in TRbeta(1) occurred at both mRNA and total protein levels. In the kidney, both TRalpha(1) and TRbeta(1) mRNA and total protein levels were unchanged between 6 and 12 mo but increased at 24 mo. Interestingly, nuclear TRbeta1 levels were decreased in both liver and kidney at 12 and 24 mo, whereas nuclear TRalpha(1) levels were unchanged. Collectively, our data show differential age-related changes among hepatic and renal MCT8 and D1 and TR expressions, and they suggest that renal D1 activity is maintained with age to compensate for the decrease in hepatic T(3) production.     

Different functions for the thyroid hormone receptors TRalpha and TRbeta in the control of thyroid hormone production and post-natal development.

The biological activities of thyroid hormones are thought to be mediated by receptors generated by the TRalpha and TRbeta loci. The existence of several receptor isoforms suggests that different functions are mediated by specific isoforms and raises the possibility of functional redundancies. We have inactivated both TRalpha and TRbeta genes by homologous recombination in the mouse and compared the phenotypes of wild-type, and single and double mutant mice. We show by this method that the TRbeta receptors are the most potent regulators of the production of thyroid stimulating hormone (TSH). However, in the absence of TRbeta, the products of the TRalpha gene can fulfill this function as, in the absence of any receptors, TSH and thyroid hormone concentrations reach very high levels. We also show that TRbeta, in contrast to TRalpha, is dispensable for the normal development of bone and intestine. In bone, the disruption of both TRalpha and TRbeta genes does not modify the maturation delay observed in TRalpha -/- mice. In the ileum, the absence of any receptor results in a much more severe impairment than that observed in TRalpha -/- animals. We conclude that each of the two families of proteins mediate specific functions of triiodothyronin (T3), and that redundancy is only partial and concerns a limited number of functions.     

Hypermetabolism in mice caused by the central action of an unliganded thyroid hormone receptor alpha1

Thyroid hormone, via its nuclear receptors TRalpha and TRbeta, controls metabolism by acting locally in peripheral tissues and centrally by regulating sympathetic signaling. We have defined aporeceptor regulation of metabolism by using mice heterozygous for a mutant TRalpha1 with low affinity to T3. The animals were hypermetabolic, showing strongly reduced fat depots, hyperphagia and resistance to diet-induced obesity accompanied by induction of genes involved in glucose handling and fatty acid metabolism in liver and adipose tissues. Increased lipid mobilization and beta-oxidation occurred in adipose tissues, whereas blockade of sympathetic signaling to brown adipose tissue normalized the metabolic phenotype despite a continued perturbed hormone signaling in this cell type. The results define a novel and important role for the TRalpha1 aporeceptor in governing metabolic homeostasis. Furthermore, the data demonstrate that a nuclear hormone receptor affecting sympathetic signaling can override its autonomous effects in peripheral tissues.     

Marked potentiation of the dominant negative action of a mutant thyroid hormone receptor beta in mice by the ablation of one wild-type beta allele

Mutations in the thyroid hormone receptor (TR) beta gene result in resistance to thyroid hormone (RTH), characterized by reduced sensitivity of tissues to thyroid hormone. To understand which physiological TR pathways are affected by mutant receptors, we crossed mice with a dominantly negative TRbeta mutation (TRbetaPV) with mice carrying a TRbeta null mutation (TRbeta(-/-)) to determine the consequences of the TRbetaPV mutation in the absence of wild-type TRbeta. TRbeta(PV/-) mice are distinct from TRbeta(+/-) mice that did not show abnormalities in thyroid function tests. TRbeta(PV/-) mice are also distinct from TRbeta(PV/+) and TRbeta(-/-) mice in that the latter shows mild dysfunction in the pituitary-thyroid axis, whereas the former exhibit very severe abnormalities, including extensive papillary hyperplasia of the thyroid epithelium, indistinguishable from that observed in TRbeta(PV/PV) mice. Similar to TRbeta(PV/PV) mice, TRbeta(PV/-) mice exhibited impairment in weight gain. Moreover, the abnormal regulation patterns of T3-target genes in the tissues of TRbeta(PV/-) and TRbeta(PV/PV) mice were strikingly similar. Using TR isoforms and PV-specific antibodies in gel shift assays, we found that in vivo, PV competed with TRalpha1 for binding to thyroid hormone response elements in TRbeta(PV/-) mice as effectively as in TRbeta(PV/PV) mice. Thus, the actions of mutant TRbeta are markedly potentiated by the ablation of the second TRbeta allele, suggesting that interference with wild-type TRalpha1-mediated gene regulation by mutant TRbeta leads to severe RTH.     

Thyroid status during skeletal development determines adult bone structure and mineralization

Childhood hypothyroidism delays ossification and bone mineralization, whereas adult thyrotoxicosis causes osteoporosis. To determine how effects of thyroid hormone (T3) during development manifest in adult bone, we characterized TRalpha1(+/m)beta(+/-) mice, which express a mutant T3 receptor (TR) alpha1 with dominant-negative properties due to reduced ligand-binding affinity. Remarkably, adult TRalpha1(+/m)beta(+/-) mice had osteosclerosis with increased bone mineralization even though juveniles had delayed ossification. This phenotype was partially normalized by transient T3 treatment of juveniles and fully reversed in compound TRalpha1(+/m)beta(-/-) mutant mice due to 10-fold elevated hormone levels that allow the mutant TRalpha1 to bind T3. By contrast, deletion of TRbeta in TRalpha1(+/+)beta(-/ -) mice, which causes a 3-fold increase of hormone levels, led to osteoporosis in adults but advanced ossification in juveniles. T3-target gene analysis revealed skeletal hypothyroidism in TRalpha1(m/+)beta(+/-) mice, thyrotoxicosis in TRalpha1(+/+)beta(-/-) mice, and euthyroidism in TRalpha1(+/)beta(-/-) double mutants. Thus, TRalpha1 regulates both skeletal development and adult bone maintenance, with euthyroid status during development being essential to establish normal adult bone structure and mineralization.     

Normal timing of oligodendrocyte development depends on thyroid hormone receptor alpha 1 (TRalpha1)

The timing of oligodendrocyte development is regulated by thyroid hormone (TH) in vitro and in vivo, but it is still uncertain which TH receptors mediate this regulation. TH acts through nuclear receptors that are encoded by two genes, TRalpha and TRbeta. Here, we provide direct evidence for the involvement of the TRalpha1 receptor isoform in vivo, by showing that the number of oligodendrocytes in the postnatal day 7 (P7) and P14 optic nerve of TRalpha1-/- mice is decreased compared with normal. We demonstrate that TRalpha1 mediates the normal differentiation-promoting effect of TH on oligodendrocyte precursor cells (OPCs): unlike wild-type OPCs, postnatal TRalpha1-/- OPCs fail to stop dividing and differentiate in response to TH in culture. We also show that overexpression of TRalpha1 accelerates oligodendrocyte differentiation in culture, suggesting that the level of TRalpha1 expression is normally limiting for TH-dependent OPC differentiation. Finally, we provide evidence that the inhibitory isoforms of TRalpha are unlikely to play a part in the timing of OPC differentiation.     

Genetic Analysis Reveals Different Functions for the Products of the Thyroid Hormone Receptor α Locus

Thyroid hormone receptors are encoded by the TRalpha (NR1A1) and TRbeta (NR1A2) loci. These genes are transcribed into multiple variants whose functions are unclear. Analysis by gene inactivation in mice has provided new insights into the functional complexity of these products. Different strategies designed to modify the TRalpha locus have led to strikingly different phenotypes. In order to analyze the molecular basis for these alterations, we generated mice devoid of all known isoforms produced from the TRalpha locus (TRalpha(0/0)). These mice are viable and exhibit reduced linear growth, bone maturation delay, moderate hypothermia, and reduced thickness of the intestinal mucosa. Compounding TRalpha(0) and TRbeta(-) mutations produces viable TRalpha(0/0)beta(-/-) mice, which display a more severe linear growth reduction and a more profound hypothermia as well as impaired hearing. A striking phenotypic difference is observed between TRalpha(0/0) and the previously described TRalpha(-/-) mice, which retain truncated TRDeltaalpha isoforms arising from a newly described promoter in intron 7. The lethality and severe impairment of the intestinal maturation in TRalpha(-/-) mice are rescued in TRalpha(0/0) animals. We demonstrate that the TRDeltaalpha protein isoforms, which are natural products of the TRalpha locus, are the key determinants of these phenotypical differences. These data reveal the functional importance of the non-T3-binding variants encoded by the TRalpha locus in vertebrate postnatal development and homeostasis.