Functional and structural characterization of the insertion region in the ligand binding domain of the vitamin D nuclear receptor.

Vitamin D nuclear receptor mediates the genomic actions of the active form of vitamin D, 1,25(OH)2D3. This hormone is involved in calcium and phosphate metabolism and cell differentiation. Compared to other nuclear receptors, VDR presents a large insertion region at the N-terminal part of the ligand binding domain between helices H1 and H3, encoded by an additional exon. This region is poorly conserved in VDR in different species and is not well ordered as observed by secondary structure prediction. We engineered a VDR ligand binding domain mutant by removing this insertion region. Here we report its biochemical and biophysical characterization. The mutant protein exhibits the same ligand binding, dimerization with retinoid X receptor and transactivation properties as the wild-type VDR, suggesting that the insertion region does not affect these main functions. Solution studies by small angle X-ray scattering shows that the conformation in solution of the VDR mutant is similar to that observed in the crystal and that the insertion region in the VDR wild-type is not well ordered.     

In vitro phosphorylation and hormone binding activation of the synthetic wild type human estradiol receptor.

A tyrosine kinase purified from calf uterus activates the hormone binding of endogenous estradiol receptor (ER) predephosphorylated and preinactivated by a nuclear phosphotyrosine phosphatase. The kinase also activates and phosphorylates the human estradiol receptor HEO synthesized in vitro, which differs from the wild type receptor HEGO because a glycine is replaced by a valine at position 400. Moreover, the kinase activates and phosphorylates a deletion mutant of HEO which consists almost exclusively of the hormone binding domain. Using HEGO and HEO in parallel and measuring both binding activation and phosphorylation of ER we now observe that the wild type receptor is a good kinase substrate, slightly better than HEO. Furthermore, HEGO like the calf uterus receptor in the presence of estradiol, stimulates the kinase. From present findings it appears that ER and uterus tyrosine kinase are functionally associated and that this association is abolished by glycine to valine substitution at position 400 of ER.     

Cysteine 530 of the human estrogen receptor alpha is the main covalent attachment site of 11beta-(aziridinylalkoxyphenyl)estradiols.

The efficiency of 11beta-[p(aziridinylethoxy)phenyl]estradiol 1 and 11beta-[p(aziridinylpentoxy)phenyl]estradiol 2 affinity labeling of the estrogen receptor alpha (ERalpha) was evaluated on the basis of their capacity to inhibit [(3)H]estradiol binding to lamb and human ERalphas. Relative to RU 39 411 (11beta-[p(dimethylaminoethoxy)phenyl]estradiol), the most closely related and chemically inert analogue of 1, the two electrophiles irreversibly inhibited [(3)H]estradiol binding to the lamb ERalpha. The fact that the compound effects were prevented (i) when the ERalpha hormone-binding site was occupied by estradiol and (ii) when the ERalpha-containing extracts were pretreated with methyl methanethiosulfonate (an SH-specific reagent) suggested that the compounds specifically alkylated ERalpha at cysteine residues. Wild-type human ERalpha was alkylated as efficiently as lamb ER, whereas the quadruple cysteine --> alanine mutant, in which all cysteines of the hormone-binding domain (residues 381, 417, 447, and 530) were changed to alanines, showed no significant electrophile labeling. The single C530A mutant was much less sensitive to the action of the electrophiles than the three other single mutants (C381A, C417A, and C447A). Moreover, analysis of the three double mutants (C381A/C530A, C417A/C530A, and C447A/C530A) showed that only the C381A/C530A mutant was less susceptible to electrophile labeling than the single C530A mutant. We concluded that in the hormone-binding pocket C530 was the main covalent attachment site of aziridines 1 and 2, whereas C381 could be a secondary site. These results agreed with the crystal structure of the hormone-binding domain of the human ERalpha bound to estrogen or antiestrogen, since C381 and C530 appeared to be (i) located in structural elements involved in delineating the hormone-binding pocket and (ii) in spatial proximity to each other, which was closer in the crystal structure of the ER:antiestrogen complex than in that of the ER:estrogen complex. Since C530 and C381 were also the main and secondary covalent attachment sites of tamoxifen aziridine (a nonsteroidal affinity-labeling agent), we propose a selective mode of superimposition of tamoxifen-class antiestrogens with RU 39 411-class antiestrogens, which could account for the relative positioning of the two types of ligands in the ERalpha hormone-binding pocket.     

Agonist-dependent repression mediated by mutant estrogen receptor alpha that lacks the activation function 2 core domain

Nuclear receptor corepressor (N-CoR) and silencing mediator of retinoid and thyroid hormone receptors (SMRT) form heterogeneous complexes with various histone deacetylases (HDACs). In this report, we found that ER alpha-Delta AF2, a mutant estrogen receptor alpha (ER alpha) deleted for the C-terminal activation function 2 (AF2) core domain, directs estradiol (E(2))-dependent repression and impairs E(2)-induced transactivation by wild type ER alpha. This repression required coexpressed BRG1 in SW-13 cells that lack BRG1, the ATPase constituent of the chromatin-remodeling SWI.SNF complex, and was abolished by HDAC inhibitor trichostatin A. We further demonstrated that ER alpha-Delta AF2 constitutively associates with SMRT but binds DNA in an E(2)-dependent manner in vivo. These results suggest that ER alpha-Delta AF2 and similar mutant receptors recently found associated with certain tumors may actively perturb the normal E(2) signaling via SWI/SNF, N-CoR/SMRT, and HDAC.     

Differential DNA-binding abilities of estrogen receptor occupied with two classes of antiestrogens: studies using human estrogen receptor overexpressed in mammalian cells.

We have developed a transient transfection system using the Cytomegalovirus (CMV) promoter to express the human estrogen receptor (ER) at very high levels in COS-1 cells and have used it to study the interaction of agonist and antagonist receptor complexes with estrogen response element (ERE) DNA. ER can be expressed to levels of 20-40 pmol/mg or 0.2-0.3% of total soluble protein and all of the soluble receptor is capable of binding hormone. The ER binds estradiol with high affinity (Kd 0.2 nM), and is indistinguishable from native ER in that the receptor is capable of recognizing its cognate DNA response element with high affinity, and of transactivating a transgene in an estradiol-dependent manner. Gel mobility shift assays reveal interesting ligand-dependent differences in the binding of receptor complexes to ERE DNA. Receptors occupied by estradiol or the type I antiestrogen transhydroxytamoxifen bind to DNA response elements when exposed to the ligand in vitro or in vivo. Likewise, receptors exposed to the type II antiestrogen ICI 164,384 in vitro bind to ERE DNA. However, when receptor exposure to ICI 164,384 is carried out in vivo, the ER-ICI 164,384 complexes do not bind to ERE DNA, or do so only weakly. This effect is not reversed by subsequent incubation with estradiol in vitro, but is rapidly reversible by in vivo estradiol exposure of intact COS-1 cells. This suggests there may be some cellular process involved in the mechanism of antagonism by the pure antiestrogen ICI 164,384, which is not observed in cell-free extracts.     

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.     

Hormone-independent repression of AP-1-inducible collagenase promoter activity by glucocorticoid receptors.

The role of the ligand in glucocorticoid receptor-mediated transactivation and transrepression of gene expression was investigated. Half-maximal transactivation of a mouse mammary tumor virus-chloramphenicol acetyltransferase reporter gene in transfected cells expressing the human glucocorticoid receptor mutant GRL753F, from which the rate of ligand dissociation is four to five times higher than the rate of dissociation from normal receptors, required a 200- to 300-fold-higher concentration of dexamethasone than was required in cells expressing the normal receptor. Immunocytochemical analysis demonstrated that this difference was not the result of a failure of the mutant receptor to accumulate in the nucleus after steroid treatment. In contrast, in cells cotransfected with a reporter gene containing the AP-1-inducible collagenase gene promoter, the concentration of dexamethasone required for 50% transrepression was the same for mutant and normal receptors. Efficient receptor-mediated transrepression was also observed with the double mutant GRL753F/C421Y, in which the first cysteine residue of the proximal zinc finger has been replaced by tyrosine, indicating that neither retention of the ligand nor direct binding of the receptor to DNA is required. RU38486 behaved as a full agonist with respect to transrepression. In addition, receptor-dependent transrepression, but not transactivation, was observed in transfected cells after heat shock in the absence of the ligand. Taken together, these results suggest that unlike transactivation, transrepression of AP-1 activity by the nuclear glucocorticoid receptor is ligand independent.