Faculty Bibliography

Syndromes of resistance to thyroid hormones are caused by mutations in the T3-binding domain of the c-erbA beta thyroid hormone receptor gene. The S receptor (deletion of THR332) is a potent dominant negative protein cloned from a kindred with generalized resistance to thyroid hormones. The G-H receptor (ARG311HIS) has compromised dominant negative function and was found in both normal individuals and in a patient with severe pituitary resistance to thyroid hormones. We have investigated the mechanism responsible for the difference in receptor phenotypes by analyzing the binding of S and G-H receptors to thyroid hormone response elements with electrophoretic mobility shift analysis. Wild-type human c-erbA beta 1 (WT), S, and G-H receptors were synthesized in reticulocyte lysate, reacted with a thyroid hormone response element consisting of a direct repeat with 4 base pairs (DR+4; AGGTCA CAGG AGGTCA), and the products analyzed by gel shift. G-H receptor homodimerization was greatly impaired; G-H formed predominantly monomeric complex compared with monomeric and homodimeric WT complexes. The G-H receptor was able to form heterodimeric complexes with cellular thyroid hormone receptor auxiliary protein (TRAP) factors including the human retinoid X receptor-alpha. When TRAP was limiting, the levels of G-H heterodimeric complex were 2- to 3-fold reduced compared with WT receptor. In contrast to the WT and G-H receptors, the S receptor formed almost exclusively homodimeric complex with DR+4; the approximate ratio of S:WT:G-H homodimeric complexes at equivalent concentrations of receptors was 60:20:1. A measurable increase (1.2- to 2.6-fold) in heterodimeric complex formation was observed with the S receptor relative to WT when TRAP was at limiting concentration. As reported previously by others, thyroid hormone significantly reduced the WT homodimeric complex with DR+4. There was no effect on the S homodimeric complex. Finally, the WT, S, and G-H receptors formed different complexes with the element consisting of an inverted repeat with 5 base pairs (IR+5; AGGTCA ACAGT TGACCT) and the IR element (AGGTCA TGACCT), which were differently regulated by thyroid hormone. The S receptor bound as a homodimer with IR+5, whereas the WT receptor bound as a homodimer only with thyroid hormone. No homodimeric complex formed with IR+5 and the G-H receptor. Qualitatively similar results were observed with the IR element. We conclude that the ARG311HIS mutation severely perturbs the homodimerization and, to a much less degree, heterodimerization functions of the c-erbA beta 1 receptor. Furthermore, the THR332 deletion mutation augments homodimerization of the c-erbA beta 1 receptor. These results indicate that different mutations in the c-erbA beta 1 thyroid hormone receptor have divergently affected dimerization activities which seem to influence the level of dominant negative activity in man

The receptors for thyroid hormone (T3R), all-trans-retinoic acid (RAR), and 9-cis-retinoic acid (RXR) bind DNA response elements as homo- and heterodimers. The ligand-binding domains of these receptors contain nine conserved heptads proposed to play a role in dimerization. Mutant receptors with changes in the first or last hydrophobic amino acids in the highly conserved ninth heptad of chick T3R alpha [cT3R alpha(L365R) and cT3R(L372R)] and human RAR alpha (hRAR alpha) [hRAR(M377R) and hRAR(L384R)] reveal that this heptad is essential for certain heterodimeric interactions and for diverse functional activities. Without ligands, wild-type receptors form both homodimers and heterodimers, while these mutants form only homodimers. Surprisingly, the cognate ligand for each mutant enables heterodimer formation between cT3R(L365R) and RAR or RXR and between hRAR(M377R) and T3R or RXR. Both cT3R(L365R) and hRAR(M377R) mediate ligand-dependent transcriptional regulation. However, unlike the wild-type receptor, non-ligand-associated cT3R(L365R) does not suppress the basal activity of certain promoters containing thyroid hormone response elements, suggesting that this silencing effect of T3R is mediated by unliganded heterodimers of T3R and endogenous RXR or related factors. Heterodimerization is also necessary for the strong ligand-independent inhibition between T3R and RAR on a common response element, since the ninth-heptad mutants function as poor inhibitors. However, with a T3R-specific response element, hRAR(M377R) acts as a retinoic acid-dependent inhibitor of cT3R, indicating the importance of heterodimerization for this inhibition.(ABSTRACT TRUNCATED AT 250 WORDS)

We report that thyroid hormone (T3) receptor (T3R) can activate the human immunodeficiency virus type 1 (HIV-1) long terminal repeat (LTR). Purified chick T3R-alpha 1 (cT3R-alpha 1) binds as monomers and homodimers to a region in the LTR (nucleotides -104 to -75 [-104/-75]) which contains two tandem NF-kappa B binding sites and to a region (-80/-45) which contains three Sp1 binding sites. In contrast, human retinoic acid receptor alpha (RAR-alpha) and mouse retinoid X receptor beta (RXR-beta) do not bind to these elements. However, RXR-beta binds to these elements as heterodimers with cT3R-alpha 1 and to a lesser extent with RAR-alpha. Gel mobility shift assays also revealed that purified NF-kappa B p50/65 or p50/50 can bind to one but not both NF-kappa B sites simultaneously. Although the binding sites for p50/65, p50/50, and T3R, or Sp1 and T3R, overlap, their binding is mutually exclusive, and with the inclusion of RXR-beta, the major complex is the RXR-beta-cT3R-alpha 1 heterodimer. The NF-kappa B region of the LTR and the NF-kappa B elements from the kappa light chain enhancer both function as T3 response elements (TREs) when linked to a heterologous promoter. The TREs in the HIV-1 NF-kappa B sites appear to be organized as a direct repeat with an 8- or 10-bp gap between the half-sites. Mutations within the NF-kappa B motifs which eliminate binding of cT3R-alpha 1 also abolish stimulation by T3, indicating that cT3R-alpha 1 binding to the Sp1 region does not independently mediate activation by T3. The Sp1 region, however, is converted to a functionally strong TRE by the viral tat factor. These studies indicate that the HIV-1 LTR contains both tat-dependent and tat-independent TREs and reveal the potential for T3R to modulate other genes containing NF-kappa B- and Sp1-like elements. Furthermore, they indicate the importance of other transcription factors in determining whether certain T3R DNA binding sequences can function as an active TRE

Retinoic acid transcriptionally regulate growth hormone (GH) gene expression through sequences located in the 5'-flanking region of the gene. A partial induction by retinoic acid was obtained with the -181 bp of the rat GH promoter, and sequences up to -209 were required for a full response. These sequences contain the previously identified thyroid hormone responsive element. The retinoid X receptor RXR increased transactivation by T3 and RA. The retinoid was relatively more effective in stimulating the native GH promoter than an heterologous promoter which contains the response element, thus showing the importance of the promoter context on transactivation by the nuclear receptors

Thyroid hormone (T3) receptors (T3Rs) regulate transcription by binding to T3 response elements (TREs) located within promoter regions of T3-regulated genes. In rat pituitary GH4C1 cells, expression of a reporter containing herpes simplex virus thymidine kinase (TK) gene sequences (-105/+51) linked to the chloramphenicol acetyltransferase gene was stimulated 4- to 5-fold by T3. Linker scanning mutants of the TK promoter revealed that regions around -80 containing a CTF/NF-1 recognition sequence and around -10 are both required for regulation by T3. Endogenous T3Rs from GH4C1 cells labeled with [125I]T3 bound only to TK promoter DNA fragments containing the -10 region. The -22/-2 sequence (TK-TRE) contains half-sites oriented as an inverted repeat separated by 6 basepairs that are identical to and similar to an optimized TRE half-site. Purified chicken T3R alpha 1 forms apparent monomeric and dimeric complexes on the 32P-labeled TK-TRE, as found previously with an inverted repeat of the optimized TRE (TREp) with no basepair gap. T3 enhances the formation and alters the mobility of these complexes on both elements. When positioned up-stream of a heterologous promoter-chloramphenicol acetyltransferase reporter, the TK-TRE conferred T3 regulation by endogenous T3R in GH4C1 cells and by cotransfected chicken T3R alpha 1 in HeLa cells. The TK-TRE does not bind and is not activated by retinoic acid receptor. T3Rs and nuclear proteins from GH4C1, HeLa, and COS1 cells form heterodimers on the TK-TRE which differ in abundance and mobility from heterodimers formed on the TREp. The identification of a TRE in the TK promoter raises the possibility that T3R or related proteins may play important roles in regulating the life cycle of herpes simplex virus

We have examined the c-erbA beta thyroid hormone receptor gene in a kindred, G.H., with a member, patient G.H., who had a severe form of selective pituitary resistance to thyroid hormones (PRTH). This patient manifested inappropriately normal thyrotropin-stimulating hormone, markedly elevated serum free thyroxine (T4) and total triiodothyronine (T3), and clinical hyperthyroidism. The complete c-erbA beta 1 coding sequence was examined by a combination of genomic and cDNA cloning for patient G.H. and her unaffected father. A single mutation, a guanine to adenine transition at nucleotide 1,232, was found in one allele of both these members, altering codon 311 from arginine to histidine. In addition, a half-sister of patient G.H. also harbored this mutant allele and, like the father, was clinically normal. The G.H. receptor, synthesized with reticulocyte lysate, had significantly defective T3-binding activity with a Ka of approximately 5 x 10(8) M-1. RNA phenotyping using leukocytes and fibroblasts demonstrated an equal level of expression of wild-type and mutant alleles in patient G.H. and her unaffected father. Finally, the G.H. receptor had no detectable dominant negative activity in a transfection assay. Thus, in contrast to the many other beta-receptor mutants responsible for the generalized form of thyroid hormone resistance, the G.H. receptor appeared unable to antagonize normal receptor function. These results suggest that the arginine at codon 311 in c-erbA beta is crucial for the structural integrity required for dominant negative function. The ARG-311-HIS mutation may contribute to PRTH in patient G.H. by inactivating a beta-receptor allele, but it cannot be the sole cause of the disease

A classic model of steroid/thyroid hormone receptor activation postulates that a conformational change or 'transformation' occurs upon ligand binding as a first step toward regulation of gene transcription. In order to test this model, physical studies have been carried out using purified full-length chicken thyroid hormone receptor alpha 1 (cT3R-alpha 1) expressed in Escherichia coli. Circular dichroism spectroscopic studies reveal that cT3R-alpha 1 adopts a different conformation upon specific binding to a cognate ligand triiodothyroacetic acid as well as to a thyroid hormone response element, an idealized inverted repeat AGGTCA TGACCT. These results suggest that cT3R-alpha 1 may adopt distinct conformations whether free or bound to ligand or to DNA. These states may reflect the changes in the conformation of steroid/thyroid hormone receptors in the signal transduction pathway