Active, interactive, and inactive steroid receptor mutants

Helix 8 of the ligand binding domain of the glucocorticoid receptor (GR) is essential for ligand binding

Membrane association of estrogen receptors (ER) depends on cysteine palmitoylation and two leucines in the ligand binding domain (LBD), conserved in most steroid receptors. The role of this region, corresponding to helix 8 of the glucocorticoid receptor (GR) LBD, on membrane association of GR was studied in 4B cells, expressing endogenous GR, and Cos-7 cells transfected EGFP-GR constructs. 4B cells preloaded with radiolabeled palmitic acid showed no radioactivity incorporation into immunoprecipitated GR. Moreover, mutation C683A (corresponding to ER palmitoylation site) did not affect corticosterone-induced membrane association of GR. Mutations L687-690A, L682A, E680G and K685G prevented membrane and also nuclear localization through reduced ligand binding. L687-690A mutation decreased association of GR with heat shock protein 90 and transcriptional activity, without overt effects on receptor protein stability. The data demonstrate that palmitoylation does not mediate membrane association of GR, but that the region 680-690 (helix 8) is critical for ligand binding and receptor function.

Definition of a negative modulation domain in the human progesterone receptor

The progesterone receptor (PR) occurs in two major forms, the full-length PRB and the amino-truncated PRA, which lacks 164 amino-terminal residues. PRB functions as a strong transcriptional activator of progesterone-responsive genes, whereas PRA is inactive in several cell types where it may even act as a trans-dominant repressor of PRB and other steroid receptors, like the glucocorticoid receptor or, reportedly, the estrogen receptor. We initially observed that a PR deleted of its entire amino domain (PR538-C) is incapable of trans-repressing PRB or glucocorticoid receptor, suggesting that a negative modulation domain must be contained in the region between position 165 and 538. After testing progressive deletion mutants and chimeras, we demonstrate that this negative modulating domain is confined within 120 residues in the amino-terminal region and that it contains a subdomain of 40 residues that is crucial for intermolecular transrepression. Duplication, deletion, and transplantation of the negative modulation domain show that the negative modulation domain has only a limited functional autonomy. In our hands, transrepression of estrogen receptor could not be substantiated, and, under our conditions, at least an equimolar concentration of PRA expression plasmid is required for transrepression. Our deletion studies reveal domains that correlate with strong homology patches between the amino-terminal domains of mammalian and avian PR.

Generation of estrogen receptor mutants with altered ligand specificity for use in establishing a regulatable gene expression system

Considerable interest exists in developing an artificial system for the control of gene expression, based on the hormone binding domain (HBD) of steroid receptors. In this study we describe a yeast based approach which allows the identification of mutations within the HBD of steroid receptors, in this case the estrogen receptor, which result in altered specificity of the HBD with respect to its activation by ligands. Using this approach in yeast, we identified an estrogen receptor (HBD) mutant (His524 to Gln) whose activation by 17 beta-estradiol (E2) is significantly reduced while activation by a diphenol indene-ol compound (GR132706X) is increased, compared to the wild type estrogen receptor. When the activity of the mutant receptor was tested in mammalian cells the altered specificity was maintained. A chimeric transcription factor was constructed, in which the mutated estrogen receptor HBD was linked to the DNA binding domain of GAL4 and an 11 amino acid transcriptional activation domain of RelA. Reporter gene activation by this chimera was decreased in response to E2 and increased in response to GR132706X, as compared to the corresponding chimeric transcription factor containing the wild type estrogen receptor HBD. This approach should allow the development of a steroid receptor HBD based regulator of gene expression, whose activity is controlled specifically by a synthetic ligand, that would not affect the activity of endogenous steroid receptors.

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.

A transcriptional repressor obtained by alternative translation of a trinucleotide repeat

Triplet nucleotide repeats are ubiquitous and rapidly evolving sequences in eucaryotic genomes. They are sporadically found in coding regions of transcription regulators where they become translated in different homopolymeric aminoacid (HPAA) stretches, depending on the local frame. Poly(CAG) yields three different HPAAs (poly Gln, Ser or Ala). Current sequence databases indicate a clear bias in the size and frequency of these HPAAs according to the rule: (Gln)n > (Ser)n >> (Ala)n. Aiming to understand the reasons of this bias, we changed the translational reading frame of the highly polymorphic CAG-repeat that normally encodes poly-Gln in the N-terminal portion of the rat glucocorticoid receptor (GR). The GR mutant in which the CAG repeat is translated to poly-Ala (called GR[Ala]) is incapable of transactivation, but maintains competence for hormone binding, nuclear translocation and specific DNA binding. We show that GR desactivation is obtained only when a very precise threshold length of the repeat is reached. GR[Ala] displays a strong negative dominance when tested for transcriptional activation in vivo and may become useful for selective competition of receptor dependent activities in tissue culture cells and transgenic animals. We discuss the implications of our findings for the understanding of the evolutionary behaviour of trinucleotide repeats in coding sequences.