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.     

Capacity for cooperative binding of thyroid hormone (T3) receptor dimers defines wild type T3 response elements.

Thyroid hormone response elements (T3REs) have been identified in a variety of promoters including those directing expression of rat GH (rGH), alpha-myosin heavy chain (rMHC), and malic enzyme (rME). A detailed biochemical and genetic analysis of the rGH element has shown that it consists of three hexamers related to the consensus [(A/G)GGT(C/A)A]. We have extended this analysis to the rMHC and rME elements. Binding of highly purified thyroid hormone receptor (T3R) to T3REs was determined using the gel shift assay, and thyroid hormone (T3) induction was measured in transient tranfections. We show that the wild type version of each of the three elements binds T3R dimers cooperatively. Mutational analysis of the rMHC and rME elements identified domains important for binding T3R dimers and allowed a direct determination of the relationship between T3R binding and function. In each element two hexamers are required for dimer binding, and mutations that interfere with dimer formation significantly reduce T3 induction. Similar to the rGH element, the rMHC T3RE contains three hexameric domains arranged as a direct repeat followed by an inverted copy, although the third domain is weaker than in rGH. All three are required for full function and T3R binding. The rME T3RE is a two-hexamer direct repeat T3RE, which also binds T3R monomer and dimer. Across a series of mutant elements, there was a strong correlation between dimer binding in vitro and function in vivo for rMHC (r = 0.99, P less than 0.01) and rME (r = 0.67, P less than 0.05) T3REs. Our results demonstrate a similar pattern of T3R dimer binding to a diverse array of hexameric sequences and arrangements in three wild type T3REs. Addition of nuclear protein enhanced T3R binding but did not alter the specificity of binding to wild type or mutant elements. Binding of purified T3R to T3REs was highly correlated with function, both with and without the addition of nuclear protein. T3R dimer formation is the common feature which defines the capacity of these elements to confer T3 induction.     

Thyroid hormone aporeceptor represses T3-inducible promoters and blocks activity of the retinoic acid receptor

In the presence of its ligand, thyroid hormone receptor (T3R) binds specifically to DNA sequences near a number of genes and induces their expression. We show that in the absence of the hormone, a T3R binding site acts in cis to decrease expression from such genes. The endogenous T3 receptors in rat pituitary cell lines are sufficient to mediate this effect, as shown by comparisons of basal levels of expression directed by transiently transfected plasmids containing the rat growth hormone promoter with wild-type or point-mutated T3 response elements (T3RE). The magnitude of the negative effect is increased by increasing the strength of the T3RE or by raising intracellular levels of T3R by appropriate transfections. T3REs exert a similar negative effect on the herpes virus thymidine kinase (TK) promoter; this effect is dependent on expression of functional T3 aporeceptor (apoT3R). Analysis of a set of T3REs of increasing strength inserted upstream of the TK promoter showed a strong correlation between the level of induced expression in the presence of hormone and the level of repressed expression in the absence of hormone. These results show that, unlike other members of the nuclear hormone receptor family, T3R binds to specific DNA sequences in the absence of hormone and exerts a negative effect on expression of linked genes. The apparent affinity of apoT3R and hormone-bound T3R for a T3RE was assessed by using varying amounts of T3R expression vector in a transfection dose response assay.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hormone-induced changes in the in vitro DNA-binding activity of the chicken progesterone receptor

Previous analyses have indicated that steroid hormone receptors undergo an allosteric change in structure upon binding by the steroid ligand. This structural change was envisioned as an intramolecular unmasking of the protein's DNA-binding domain, thus allowing the receptor to function in gene regulation. We report an analysis of the effect of hormone on the DNA-binding activity of the chicken progesterone receptor. Using an isocratic elution of DNA affinity columns we show that unliganded receptor (aporeceptor) can bind a 23-basepair progesterone response element with high affinity and a high degree of sequence preference. Hormone causes a 1.5-fold increase in affinity for the PRE sequence and a 2-fold decrease in affinity for non-specific DNA. Kinetic analysis of the off-rate of receptor-DNA complexes is consistent with this minor effect of hormone. In addition, gel retardation analysis of receptor-progesterone response element complexes further substantiates that hormone is not required for sequence-specific DNA binding. These results indicate that hormone is not necessary for the progesterone receptor to fold into a conformation that recognizes specific gene regulatory sequences.     

Differential capacity of wild type promoter elements for binding and trans-activation by retinoic acid and thyroid hormone receptors.

Retinoic acid receptor (RAR) and thyroid hormone receptor (T3R) are structurally similar and can bind as homodimers or T3R-RAR heterodimers to a single synthetic DNA response element. The interaction of these two types of receptors with wild type elements, however, has not been systematically investigated. Promoter elements from genes regulated by retinoic acid (RA) or thyroid hormone (T3) were tested for response to T3 and RA in transient transfections in both JEG and COS cells. The elements were classified as primarily responsive to RA or to T3 or responsive to both ligands. Binding of highly purified RAR alpha and T3R alpha to the various elements was assessed using the gel shift assay. Those elements predominantly responsive to one ligand showed preferential binding to the appropriate receptor. A series of point mutations were introduced into the rat GH T3 response element to further define sequence requirements for response to both RA and T3. Down-mutations in any of the three hexamers (previously demonstrated to be required for full response to T3 and full binding of T3R) also decreased RA induction and RAR binding. However, only one of two sets of up-mutations for T3 response also increased RA induction, demonstrating differences in hexamer preference between RAR and T3R. Variation in spacing of the three hexamers did not influence RA vs. T3 induction or RAR vs. T3R binding according to the predictions of a simple hexamer spacing model. There was a strong correlation between the extent of T3R dimer binding and strength of T3 induction for a subset of elements studied in JEG cells (r = 0.97, P < 0.01) and a weaker but significant correlation in COS cells (r = 0.65, P < 0.05)). In contrast, RAR dimer binding by the wild type elements did not quantitatively correlate with RA induction in either JEG (r = 0.13, P > 0.05) or COS cells (r = 0.21, P > 0.05). These results suggests that RAR interacts with a heterodimer partner(s) which influences binding site specificity, whereas T3R heterodimer partner(s) is less likely to alter binding site recognition. The observed difference in COS and JEG cells as well as the weak T3R binding-function relationship of the malic enzyme element, however, suggest that the influence of T3R heterodimer partner(s) on binding site specificity is likely to vary with cell type and the specific element tested.