DNA binding and dimerization determinants for thyroid hormone receptor alpha and its interaction with a nuclear protein.

The gel retardation assay was used to analyze the role of the thyroid hormone receptor alpha (TR alpha) ligand-binding domain (LBD) in controlling receptor interaction with a thyroid hormone responsive element (TRE). While wild type receptor TR alpha binds to the TRE mainly as monomer, deletion of 85 amino acids from its C-terminus results in a mutant receptor with enhanced DNA binding that forms several slow mobility complexes as revealed by gel retardation assay. Receptor deletion mutants that lack most of the LBD show significantly elevated DNA binding and are still able to bind to DNA as two complexes. Thus, the C-terminal end of TR alpha appears to interfere with the dimerization/oligomerization function and DNA binding of TR alpha. All C-terminal deletion mutants have lost their T3-responsive activator function, but some show constitutive activity. Nuclear factor from several cell lines, including CV-1, F9, and GC cells, interacts with TR alpha receptor to form a larger molecular weight complex as determined by gel retardation assay. This factor could not be detected in HeLatk- cells, where TR alpha does not activate a TRE-containing reporter gene. The nuclear factor is heat sensitive and does not bind to TRE itself but can interact with TR alpha in the absence of DNA. Deletion analysis demonstrates that the leucine zipper-like sequence located in the LBD of TR alpha is involved in this interaction. Together, our data suggest that TR alpha contains a dimerization function outside the LBD which is inhibited by the carboxy-terminal region, while the leucine zipper-like sequence in the LBD is required for interaction with a nuclear factor.     

3,5,3'-triiodothyronine receptor auxiliary protein (TRAP) enhances receptor binding by interactions within the thyroid hormone response element.

We have previously demonstrated that binding of in vitro synthesized thyroid hormone receptor (TR) to thyroid hormone response elements (TREs) is enhanced by the addition of nuclear extracts from several different cell types, suggesting that binding of TR is partially dependent on a T3 receptor auxiliary protein (TRAP). We have used the avidin-biotin complex DNA-binding assay to discriminate between regions of TREs that bind TR alone and sites that are influenced by interactions with TRAP. Mutations in the TREs from rat GH and glycoprotein hormone alpha-subunit genes show that a specific DNA sequence is required for TRAP-mediated enhancement of TR binding. Mutations in the B half-site of the rat GH TRE or in similar sequences [(T/A)GGGA] in the alpha-subunit TRE ablate the enhancement of TR binding by TRAP. Furthermore, binding of TR to a natural half-site in the TSH beta-subunit gene (bases -16 to 6), which lacks an additional AGGGA-like sequence, is not enhanced by the addition of TRAP. Binding of TR to TREs was also tested at physiological salt concentrations in the avidin-biotin complex DNA-binding assay. Binding of human TR beta to TREs decreases dramatically at 140 mM KCl compared to binding at 50 mM KCl; however, the addition of TRAP enhances the binding to almost 4-fold of basal binding, suggesting that TRAP may be important for stabilization of TR binding to TREs in the cell.     

牙鲆甲状腺激素受体TRαA介导甲状腺激素调控的靶基因鉴定

为了鉴定牙鲆甲状腺激素受体TRs介导甲状腺激素调控的靶基因,研究采用RT-PCR克隆了TRαA基因的CDS区,并构建了p3×Flag-TRαA重组真核表达载体;该重组质粒转染HEK293T细胞后, RT-PCR、实时定量PCR与Western blot检测均表明牙鲆TRαA在哺乳动物蛋白表达系统中成功转录并翻译;且重组质粒转染的细胞裂解液通过G1亲和层析柱纯化、过滤除菌可得到纯的融合蛋白3×Flag-TRαA,然后双荧光素酶报告实验通过在HEK293T细胞中共转染p3×Flag-TRαA和含候选靶启动子的报告基因表达载体pGL3-Pro-atoh8-1517/1333/708,表明TRαA受体结合在atoh8基因启动子区–1497—–688特异的2个TRE识别序列来调控该基因的转录,即atoh8是TRαA介导甲状腺激素直接调控的靶基因。研究为深入探究甲状腺激素受体TRαA介导甲状腺激素调控的信号通路提供了基础依据。     

Isolation and characterization of a cDNA encoding a chicken beta thyroid hormone receptor.

We have isolated and characterized a cDNA encoding a chicken beta homolog of c-erbA, or thyroid hormone receptor (TR). Chicken liver cDNA libraries were screened with a rat TR beta-1 cDNA probe, and several cDNA inserts were isolated and characterized. The sequence of one cDNA predicts a 369-amino-acid open reading frame (ORF), with a protein sequence that possesses 96% identity with that of rat TR beta-1, but only 88% identity with chicken TR alpha. These data indicate that the cDNA likely encodes a beta form of TR that has the expected putative DNA and T3 binding domains. The chicken TR beta (chTR beta) in vitro translated protein binds T3 with high affinity, and binds both the thyroid hormone response element (TRE) from the rat growth hormone gene and the Xenopus vitellogenin A2 gene estrogen response element (ERE), similarly to that of the rat TR beta-1. Northern blot analysis revealed the expression of a 7.0-kb RNA in several tissues including cerebellum, pituitary, kidney, and liver. This chicken liver TR beta cDNA sequence varies in both the 5' and 3' untranslated regions from the chicken kidney TR beta cDNA sequence recently reported (Forrest et al., 1990). The 5' untranslated cDNA sequence divergence occurs near a potential splice site junction of the human TR beta gene, suggesting that this chicken liver cDNA may represent an alternatively spliced RNA product of the chicken TR beta gene.     

Transcriptional regulation of the Xenopus laevis Stromelysin-3 gene by thyroid hormone is mediated by a DNA element in the first intron

The matrix metalloproteinase (MMP) stromelysin-3 (ST3) (MMP11) was first isolated as a breast cancer-associated gene and is expressed in diverse human carcinomas and various developmental processes involving apoptosis. The Xenopus laevis ST3 is highly up-regulated by thyroid hormone (T3) during amphibian metamorphosis, and its expression is spatially and temporally correlated with apoptosis in different tissues. Furthermore, it has been shown in vivo and in organ cultures to play a critical role in regulating T3-induced epithelial cell death during intestinal metamorphosis. Earlier studies suggest that ST3 is a direct T3 response gene, although a thyroid hormone response element (TRE) was not found in the initial analysis of the ST3 promoter. Here, we have identified a strong TRE consisting of two nearly perfect direct repeats of the consensus nuclear hormone receptor binding element AGGTCA separated by 4 bp in the first intron of the Xenopus ST3 gene. We show that the heterodimers of T3 receptor (TR) and 9-cis-retinoic acid receptor bind to the TRE both in vitro and in vivo in the context of chromatin. Furthermore, T3 induces strong activation of the promoter through the intronic TRE. Interestingly, although the unliganded TR/9-cis-retinoic acid receptor was able to recruit corepressors to the promoter, it had little repressive effect on the promoter in vivo. These results suggest that the intronic TRE mediates the inductive effect of T3 and that promoter context plays an important role in gene repression by unliganded TR.     

Myocyte-specific enhancer factor 2 and thyroid hormone receptor associate and synergistically activate the alpha-cardiac myosin heavy-chain gene.

The muscle-specific regulatory region of the alpha-cardiac myosin heavy-chain (MHC) gene contains the thyroid hormone response element (TRE) and two A/T-rich DNA sequences, designated A/T1 and A/T2, the putative myocyte-specific enhancer factor 2 (MEF2) binding sites. We investigated the roles of the TRE and MEF2 binding sites and the potential interaction between thyroid hormone receptor (TR) and MEF2 proteins regulating the alpha-MHC promoter. Deletion mutation analysis indicated that both the A/T2 motif and TRE were required for muscle-specific expression of the alpha-MHC gene. The alpha-MHC enhancer containing both the A/T2 motif and TRE was synergistically activated by coexpression of MEF2 and TR in nonmuscle cells, whereas neither factor by itself activated the alpha-MHC reporters. The reporter construct containing the A/T2 sequence and the TRE linked to a heterologous promoter also showed synergistic activation by coexpression of MEF2 and TR in nonmuscle cells. Moreover, protein binding assays demonstrated that MEF2 and TR specifically bound to one another in vitro and in vivo. The MADS domain of MEF2 and the DNA-binding domain of TR were necessary and sufficient to mediate their physical interaction. Our results suggest that the members of the MADS family (MEF2) and steroid receptor superfamily (TR) interact with one another to synergistically activate the alpha-cardiac MHC gene expression.     

The nuclear corepressors recognize distinct nuclear receptor complexes

The thyroid hormone receptor (TR) and retinoic acid receptor (RAR) isoforms have the capacity to silence gene expression in the absence of their ligands on target response elements. This active repression is mediated by the ability of the corepressors, nuclear receptor corepressor (NCoR) and silencing mediator of retinoid and thyroid hormone receptors (SMRT), to recruit a complex containing histone deacetylase activity. Interestingly, NCoR and SMRT share significant differences in the their two nuclear receptor-interacting domains (IDs), suggesting that they may recruit receptors with different affinities. In addition, the role of the receptor complex bound to a response element has not been fully evaluated in its ability to recruit separate corepressors. We demonstrate in this report that the proximal ID in NCoR and SMRT, which share only 23% homology, allows preferential recognition of nuclear receptors, such that TR prefers to recruit NCoR, and RAR prefers to recruit SMRT, to DNA response elements. However, mutations in the TR found in the syndromes of resistance to thyroid hormone can change the corepressor recruited by changing the complex (homodimer or heterodimer) formed on the TRE. These results demonstrate that the corepressor complex recruited can be both nuclear receptor- and receptor complex-specific.     

Thyroid Hormone Receptor Isoform-specific Modification by Small Ubiquitin-like Modifier (SUMO) Modulates Thyroid Hormone-dependent Gene Regulation

Thyroid hormone receptor (TR) α and β mediate thyroid hormone action at target tissues. TR isoforms have specific roles in development and in adult tissues. The mechanisms underlying TR isoform-specific action, however, are not well understood. We demonstrate that posttranslational modification of TR by conjugation of small SUMO to TRα and TRβ plays an important role in triiodothyronine (T3) action and TR isoform specificity. TRα was sumoylated at lysines 283 and 389, and TRβ at lysines 50, 146, and 443. Sumoylation of TRβ was ligand-dependent, and sumoylation of TRα was ligand-independent. TRα-SUMO conjugation utilized the E3 ligase PIASxβ and TRβ-SUMO conjugation utilized predominantly PIAS1. SUMO1 and SUMO3 conjugation to TR was important for T3-dependent gene regulation, as demonstrated in transient transfection assay and studies of endogenous gene regulation. The functional role of SUMO1 and SUMO3 in T3 induction in transient expression assays was closely matched to the pattern of TR and cofactor recruitment to thyroid hormone response elements (TREs) as determined by ChIP assays. SUMO1 was required for the T3-induced recruitment of the co-activator CREB-binding protein (CBP) and release of nuclear receptor co-repressor (NCoR) on a TRE but had no significant effect on TR DNA binding. SUMO1 was required for T3-mediated recruitment of NCoR and release of CBP from the TSHβ-negative TRE. SUMO3 was required for T3-stimulated TR binding to the TSHβ-negative TRE and recruitment of NCoR. These findings demonstrate that conjugation of SUMO to TR has a TR-isoform preference and is important for T3-dependent gene induction and repression.