Ligand-dependent and -independent transactivation by thyroid hormone receptor beta 2 is determined by the structure of the hormone response element.

Chicken thyroid hormone receptor beta 2 (cTR beta 2) is likely to serve specific functions in gene regulation since it possesses a unique N-terminal domain and is expressed in very few tissues. We demonstrate here that TR beta 2 exhibits distinct transactivation properties which are dependent on the availability of ligand and on the structure of the hormone response element. First, a strong ligand-independent transactivation was observed with hormone response elements composed of direct repeats and everted repeats. Second, TR beta 2 was induced by triiodothyronine to transactivate more efficiently than TR beta 0 on palindromic and everted-repeat types of hormone response elements. However, coexpression of the retinoid X receptor reduced the strong transactivation by TR beta 2 but not by TR beta 0 via palindromic response elements, suggesting that TR beta 2 can transactivate as a homodimer. Finally, the N terminus of TR beta 2 contains two distinct transactivation regions rich in tyrosines, which are essential for transactivation. Our results thus show that the activity of the novel transactivating region of TR beta 2 is dependent on the organization of the half-sites in the response element.     

Ligand-dependent and -independent degradation of the human aryl hydrocarbon receptor (hAHR) in cell culture models

Studies have shown that zebrafish and rodent aryl hydrocarbon receptors (AHRs) are degraded following ligand exposure and that reductions in AHR protein can impact growth and development in vivo. The current study was designed to evaluate the degradation of the AHR in seven human cell lines that were derived from various carcinomas or from normal tissue. Consistent with studies in other species, the results show that the human AHR (hAHR) is degraded in a ligand dependent manner following exposure to 2,3,7,8-tetrachlorodibenzo-p-dioxin for up to 16h. However, the hAHRs expressed in the various cell lines show differences in the time course and magnitude of degradation. The ligand dependent degradation is completely blocked by treatment with the proteasome inhibitor, MG-132. Ligand-independent degradation of the hAHR following exposure to geldanamycin (GA) is also observed in the different cell lines, although the magnitude of hAHR degradation is also is variable. These findings are significant since they indicate that ligand-dependent and independent degradation of the AHR is a conserved aspect of this signal transduction cascade from fish to human. In addition, the study identifies several cell lines that may provide novel models to further assess the regulation of AHR-mediated signaling and degradation of the human AHR.     

Ligand-dependent switching of ubiquitin-proteasome pathways for estrogen receptor

Recent evidence indicates that the transactivation of estrogen receptor alpha (ERalpha) requires estrogen-dependent receptor ubiquitination and degradation. Here we show that estrogen-unbound (unliganded) ERalpha is also ubiquitinated and degraded through a ubiquitin-proteasome pathway. To investigate this ubiquitin-proteasome pathway, we purified the ubiquitin ligase complex for unliganded ERalpha and identified a protein complex containing the carboxyl terminus of Hsc70-interacting protein (CHIP). CHIP preferentially bound to misfolded ERalpha and ubiquitinated it to induce degradation. Ligand binding to the receptor induced the dissociation of CHIP from ERalpha. In CHIP-/- cells, the degradation of unliganded ERalpha was abrogated; however, estrogen-induced degradation was observed to the same extent as in CHIP+/+ cells. Our findings suggest that ERalpha is regulated by two independent ubiquitin-proteasome pathways, which are switched by ligand binding to ERalpha. One pathway is necessary for the transactivation of the receptor and the other is involved in the quality control of the receptor.     

Ligand-dependent inhibition of oligomerization at the human thyrotropin receptor

Recently, several studies have reported oligomerization of G protein-coupled receptors, although the functional implications of this phenomenon are still unclear. Using fluorescence resonance energy transfer (FRET) and coimmunoprecipitation (COIP), we previously reported that the human thyrotropin (TSH) receptor tagged with green fluorescent protein (TSHR(GFP)) and expressed in a heterologous system was present as oligomeric complexes on the cell surface. Here, we have extended this biophysical and biochemical approach to study the regulation of such oligomeric complexes. Co-expression of TSHR(GFP) and TSHR(Myc) constructs in Chinese hamster ovary cells resulted in FRET-positive cells. The specificity of the FRET signal was verified by the absence of energy transfer in individually transfected TSHR(GFP) and TSHR(Myc):Cy3 cells cultured together and also by acceptor photobleaching. Occupation of the receptor molecule by the ligand (TSH) resulted in a dose-dependent decrease in the FRET index from 20% in the absence of TSH to <1% with 10(3) microunits/ml of TSH. Such reduction in oligomeric forms was also confirmed by coimmunoprecipitation. Exposure of TSHR(GFP/Myc) cells to forskolin or cytochalasin D caused no change in the FRET index, confirming that the decrease in the oligomeric complexes was a receptor-dependent phenomenon and free of energy or microtuble requirements. The TSH-induced decrease in TSHR oligomers was found to be secondary to dissociation of the TSHR complexes as evidenced by an increase in fluorescent intensity of photobleached spots of GFP fluorescence with 10(3) microunits/ml of TSH. These data indicated that the less active conformation of the TSHR was comprised of receptor complexes and that such complexes were dissociated on the binding of ligand. Such observations support the concept of a constitutively active TSHR dimer or monomer that is naturally inhibited by the formation of higher order complexes. Inhibition of these oligomeric forms by ligand binding returns the TSHR to an activated state.     

Ligand-dependent and -independent transforming growth factor-beta receptor recycling regulated by clathrin-mediated endocytosis and Rab11

Proteins in the transforming growth factor-beta (TGF-beta) family recognize transmembrane serine/threonine kinases known as type I and type II receptors. Binding of TGF-beta to receptors results in receptor down-regulation and signaling. Whereas previous work has focused on activities controlling TGF-beta signaling, more recent studies have begun to address the trafficking properties of TGF-beta receptors. In this report, it is shown that receptors undergo recycling both in the presence and absence of ligand activation, with the rates of internalization and recycling being unaffected by ligand binding. Recycling occurs as receptors are most likely internalized through clathrin-coated pits, and then returned to the plasma membrane via a rab11-dependent, rab4-independent mechanism. Together, the results suggest a mechanism wherein activated TGF-beta receptors are directed to a distinct endocytic pathway for down-regulation and clathrin-dependent degradation after one or more rounds of recycling.     

Probing the structure and function of the estrogen receptor ligand binding domain by analysis of mutants with altered transactivation characteristics.

We have developed a genetic screen for the yeast Saccharomyces cerevisiae to isolate estrogen receptor (ER) mutants with altered transactivation characteristics. Use of a "reverse" ER, in which the mutagenized ligand binding domain was placed at the N terminus of the receptor, eliminated the isolation of truncated constitutively active mutants. A library was screened with a low-affinity estrogen, 2-methoxyestrone (2ME), at concentrations 50-fold lower than those required for activation of the unmutagenized ER. Several mutants displaying enhanced sensitivity to 2ME were isolated. We further characterized a mutant carrying the substitution L536P, which was located immediately N terminal to the AF-2-activating domain of the receptor. Amino acid 536 corresponds to a ligand contact residue in retinoic acid receptor gamma, suggesting that key contact points are conserved among receptors. Introduction of L536P into the original ER cDNA isolate HE0, which contains the substitution G400V, rendered the receptor more sensitive to a variety of agonists. When introduced into the wild-type ER HEG0, L536P also rendered the receptor more sensitive to agonists, and, in addition, induced high levels of constitutive activity that could be inhibited by antiestrogens. Estrogens containing a keto substitution in the steroid D ring, but not those containing a hydroxyl group, were full agonists of L536P-HEG0. Limited proteolytic analysis suggested that the L536P substitution, which is located immediately N terminal to the AF-2 domain, induces a conformational change in the ER that partially mimics binding by hormone. Both HEG0 and L536P-HEG0 formed complexes with hsp90 in vitro, indicating a lack of correlation between interaction with hsp90 in vitro and hormonal regulation of ER transactivation in vivo. This supports the idea that a factor(s) acting downstream of hsp90 is important for controlling activity of the hormone-free receptor.     

Structure/function of the human glucocorticoid receptor: tyrosine 735 is important for transactivation.

Ligand-induced activation of the glucocorticoid receptor (GR) is not well understood. The GR ligand-binding domain was modeled, based on homology with the progesterone receptor. Tyrosine 735 interacts with the D ring of dexamethasone, and substitution of D ring functional groups results in partial agonist steroids with reduced ability to direct transactivation. Loss of the Tyr735 hydroxyl group by substitution to phenylalanine (Tyr735Phe) did not reduce ligand binding affinity [dissociation constant (Kd) 4.3 nM compared with Kd 4.6 nM for wild-type] and did not alter transrepression of an nuclear factor-kappaB (NF-kappaB reporter. But, there was a significant 30% reduction in maximal transactivation of a mouse mammary tumor virus (MMTV) reporter, although with an unchanged EC50 (8.6 nM compared with 6 nM). Substitution to a nonaromatic hydrophobic amino acid, valine (Tyr735Val), retained high-affinity ligand binding for dexamethasone (Kd 6 nM compared with 4.6 nM) and did not alter transrepression of NF-kappaB. However, there was a 36% reduction in MMTV activity with a right shift in EC50 (14.8 nM). The change to serine, a small polar amino acid (Tyr735Ser), caused significantly lower affinity for dexamethasone (10.4 nM). Maximal transrepression of NF-kappaB was unaltered, but the IC50 for this effect was increased. Tyr735Ser had a major shift in EC50 (118 nM) for transactivation of an MMTV reporter. Maximal transactivation of MMTV induced by the natural ligand cortisol was reduced to 60% by Tyr735Phe and Tyr735Val and was completely absent by Tyr735Ser. These data suggest that tyrosine 735 is important for ligand interpretation and transactivation.