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.     

Development of a thyroid hormone receptor targeting conjugate

Molecular conjugates of hormone receptor-ligands with molecular probes or functional domains are finding diverse applications in chemical biology. Whereas many examples of hormone conjugates that target steroid hormone receptors have been reported, practical ligand conjugates that target the nuclear thyroid hormone receptor (TRbeta) are lacking. TR-targeting conjugate scaffolds based on the ligands GC-1 and NH-2 and the natural ligand triiodothyronine (T3) were synthesized and evaluated in vitro and in cellular assays. Whereas the T3 or GC-1 based conjugates did not bind TRbeta with high affinity, the NH-2 inspired fluorescein-conjugate JZ01 showed low nanomolar affinity for TRbeta and could be used as a nonradiometric probe for ligand binding. A related analogue JZ07 was a potent TR antagonist that is 13-fold selective for TRbeta over TRalpha. JZ01 localizes in the nuclei of TRbeta expressing cells and may serve as a prototype for other TR-targeting conjugates.     

Acetylation of nuclear hormone receptor superfamily members: thyroid hormone causes acetylation of its own receptor by a mitogen-activated protein kinase-dependent mechanism

Because the androgen and estrogen nuclear hormone receptors are subject to acetylation, we speculated that the nuclear thyroid hormone receptor-beta1 (TRbeta1), another superfamily member, was also subject to this posttranslational modification. Treatment of 293T cells that contain TRbeta1(wt) with l-thyroxine (T4)(10(-7)M, total concentration) resulted in the accumulation of acetylated TR in nuclear fractions at 30-45 min and a decrease in signal by 60 min. A similar time course characterized recruitment by TR of p300, a coactivator protein with intrinsic transacetylase activity. Recruitment by the receptor of SRC-1, a TR coactivator that also acetylates nucleoproteins, was also demonstrated. Inhibition of the MAPK (ERK1/2) signal transduction cascade by PD 98059 blocked the acetylation of TR caused by T4. Tetraiodothyroacetic acid (tetrac) decreased T4-induced acetylation of TR. At 10(-7)M, 3,5,3'-triiodo-l-thyronine (T3) was comparably effective to T4 in causing acetylation of TR. We studied acetylation in TR that contained mutations in the DNA-binding domain (DBD) (residues 128-142) that are known to be relevant to recruitment of coactivators and to include the MAPK docking site. In response to T4 treatment, the K128A TR mutant transfected into CV-1 cells recruited p300, but not SRC-1, and was subject to acetylation. R132A complexed with SRC-1, but not p300; it was acetylated equally well in both the absence and presence of T4. S142E was acetylated in the absence and presence of T4 and bound SRC-1 under both conditions; this mutant was also capable of binding p300 in the presence of T4. There was no serine phosphorylation of TR in any of these mutants. We conclude that (1) TRbeta1, like AR and ER, is subject to acetylation; (2) the process of acetylation of TR requires thyroid hormone-directed MAPK activity, but not serine phosphorylation of TR by MAPK, suggesting that the contribution of MAPK is upstream in the activation of the acetylase; (3) the amino acid residue 128-142 region of the DBD of TR is important to thyroid hormone-associated recruitment of p300 and SRC-1; (4) acetylation of TR DBD mutants that is directed by T4 appears to be associated with recruitment of p300.     

An LXXLL motif in nuclear receptor corepressor mediates ligand-induced repression of the thyroid stimulating hormone-beta gene

Nuclear receptor corepressor (N-CoR) regulates gene expression through interaction with DNA-bound nuclear receptors, recruiting multicomponent repressor complexes to the sites of target genes. We recently reported the presence of an LXXLL motif in N-CoR, and showed that this motif interacts in vitro and in vivo with retinoic acid receptor alpha (RARalpha) and thyroid hormone receptor beta (TRbeta). Transient transfection experiments now suggest that TRbeta and N-CoR act synergistically and may both be required for ligand-induced repression from the negative TR response element in the thyroid stimulating hormone-beta (TSHbeta) gene promoter. Mutation of the LXXLL motif in N-CoR abolished ligand-induced repression at this response element. Furthermore, in vitro binding of N-CoR to a complex between TRbeta and the negative TR response element was strictly ligand-dependent. We conclude that N-CoR and TRbeta cooperate in the regulation of the TSHbeta gene and that the ligand-dependent repression is mediated by the LXXLL motif in N-CoR.     

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.     

Rearrangements in thyroid hormone receptor charge clusters that stabilize bound 3,5',5-triiodo-L-thyronine and inhibit homodimer formation

In this study, we investigated how thyroid hormone (3,5',5-triiodo-l-thyronine, T3) inhibits binding of thyroid hormone receptor (TR) homodimers, but not TR-retinoid X receptor heterodimers, to thyroid hormone response elements. Specifically we asked why a small subset of TRbeta mutations that arise in resistance to thyroid hormone syndrome inhibit both T3 binding and formation of TRbeta homodimers on thyroid hormone response elements. We reasoned that these mutations may affect structural elements involved in the coupling of T3 binding to inhibition of TR DNA binding activity. Analysis of TR x-ray structures revealed that each of these resistance to thyroid hormone syndrome mutations affects a cluster of charged amino acids with potential for ionic bond formation between oppositely charged partners. Two clusters (1 and 2) are adjacent to the dimer surface at the junction of helices 10 and 11. Targeted mutagenesis of residues in Cluster 1 (Arg338, Lys342, Asp351, and Asp355) and Cluster 2 (Arg429, Arg383, and Glu311) confirmed that the clusters are required for stable T3 binding and for optimal TR homodimer formation on DNA but also revealed that different arrangements of charged residues are needed for these effects. We propose that the charge clusters are homodimer-specific extensions of the dimer surface and further that T3 binding promotes specific rearrangements of these surfaces that simultaneously block homodimer formation on DNA and stabilize the bound hormone. Our data yield insight into the way that T3 regulates TR DNA binding activity and also highlight hitherto unsuspected T3-dependent conformational changes in the receptor ligand binding domain.     

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.