Molecular interactions of steroid hormone receptor with its enhancer element: evidence for receptor dimer formation

A steroid hormone responsive element (GRE/PRE), sufficient to confer glucocorticoid and progesterone inducibility when linked to a reporter gene, was used in band-shift assays to examine its molecular interactions with steroid hormone receptors. Both progesterone and glucocorticoid receptors bound directly and specifically to the GRE/PRE. The purine contact sites for both form A and form B chicken progesterone receptor, as well as those for rat glucocorticoid receptor, are identical. A peptide fragment produced in bacteria that primarily contain the DNA binding domain of the glucocorticoid receptor binds first to the TGTTCT half-site of the GRE/PRE, and a second molecule binds subsequently to the TGTACA (half-site) of the GRE/PRE in a cooperative manner. Utilizing the peptide fragment and the protein A-linked fragment, we demonstrated that the receptor interacts with its cognate enhancer as a dimer.     

Functional interaction of hybrid response elements with wild-type and mutant steroid hormone receptors.

Steroid hormone receptors can be divided into two subfamilies according to the structure of their DNA binding domains and the nucleotide sequences which they recognize. The glucocorticoid receptor and the progesterone receptor (PR) recognize an imperfect palindrome (glucocorticoid responsive element/progesterone responsive element [GRE/PRE]) with the conserved half-sequence TGTYCY, whereas the estrogen receptor (ER) recognizes a palindrome (estrogen responsive element) with the half-sequence TGACC. A series of symmetric and asymmetric variants of these hormone responsive elements (HREs) have been tested for receptor binding and for the ability to mediate induction in vivo. High-resolution analysis demonstrates that the overall number and distribution of contacts with the N-7 position of guanines and with the phosphate backbone of various HREs are quite similar for PR and ER. However, PR and glucocorticoid receptor, but not ER, are able to contact the 5'-methyl group of thymines found in position 3 of HREs, as shown by potassium permanganate interference. The ER mutant HE84, which contains a single amino acid exchange, Glu-203 to Gly, in the knuckle of ER, creates a promiscuous ER that is able to bind to GRE/PREs by contacting this thymine. Elements with the sequence GGTCAcagTGTYCT that represent hybrids between an estrogen response element and a GRE/PRE respond to estrogens, glucocorticoids, and progestins in vivo and bind all three wild-type receptors in vitro. These hybrid HREs could serve to confer promiscuous gene regulation.     

Functional characterization of an androgen response element in the first intron of the C3(1) gene of prostatic binding protein

We demonstrate that the 204 bp intronic gene fragment of C3(1), which has a specific in vitro affinity for the androgen receptor, is able to confer androgen responsiveness to a heterologous promoter. This characteristic is completely destroyed by a single G----T substitution, affecting a 5'-TGTTCT-3' element that closely resembles the consensus sequence of the glucocorticoid and progesterone response elements (GRE/PRE). In fact we could show that this androgen response element (ARE) also acts as a similarly weak GRE or PRE in T-47D cells.     

Expression of active hormone and DNA-binding domains of the chicken progesterone receptor in E. coli.

Bacterially-expressed fusion proteins containing the DNA-(region C) or hormone-binding (region E) domains of the chicken progesterone receptor (cPR) fused to the C terminus of Escherichia coli beta-galactosidase were analysed for the specificity of interaction with natural and synthetic hormone-responsive elements (HREs) and progestins, respectively. The purified fusion protein containing the progestin-binding domain bound progesterone with an apparent Kd of 1.0-1.5 nM and was specifically photocross-linked with the synthetic progestin R5020 in crude bacterial lysates. Labelling of intact bacterial cells with [3H]R5020 revealed that the majority, if not all, of the bacterially produced hormone-binding domain was active. No differences in the binding to a synthetic palindromic glucocorticoid/progestin-responsive element (GRE/PRE) were found when the bacterially produced cPR DNA-binding domain was compared in methylation interference assays with the full-length chicken progesterone receptor form A expressed in eukaryotic cells. The study of dissociation kinetics, however, revealed differences in the half-life of the complexes formed between the palindromic GRE/PRE and either the receptor form A or the fusion protein containing the cPR DNA-binding domain. DNase I protection experiments demonstrated that the bacterially produced region C of the cPR generated specific 'footprints' on the mouse mammary tumour virus long terminal repeat (MMTV-LTR) which were nearly identical to those previously reported for the rat glucocorticoid receptor.     

Identification of protein contact sites within the glucocorticoid/progestin response element

The glucocorticoid receptor (GR) and the progestin receptor (PR) bind specifically to a variety of DNA sequences, glucocorticoid/progestin response elements (GRE/PRE), located in the proximity of responsive gene promoters. Using the isolated recombinant GR DNA-binding domain (DBD), it has recently been shown that GR interacts with the GRE/PRE, a 15-basepair partially palindromic consensus sequence, as a dimer. In this study an investigation into the GR-GRE/PRE and PR-GRE/PRE interaction has been performed using missing base contact analysis with the tyrosine aminotransferase GREII (TATII) and recombinant GR DBD as well as a fusion protein consisting of the PR DBD fused to Staph. aureus protein-A. GR and PR had identical base contact points, localized within two consecutive major grooves, binding to the same face of the DNA. Ethylation interference was also performed on the GR DBD-TATII interaction. The contact points with the backbone phosphate groups flank the contacts within the major groove for each of the two half-sites. Knowledge of the contact points within the DNA sequence together with the three-dimensional structure of the protein enables modelling of the protein-DNA interaction.     

Steroid hormone-dependent interaction of human progesterone receptor with its target enhancer element

We investigated the requirement of steroid hormone for the specific binding of progesterone receptor to its cognate progesterone responsive element (PRE) in cell-free experiments. We prepared unfractionated nuclear extracts from human breast cancer (T47D) cells which are rich in progesterone receptors and used a gel retardation assay to monitor receptor-DNA complex formation. Exposure of receptor to either progesterone, R5020, or the antiprogestin RU38 486 in vivo or in vitro led to the formation of two protein-DNA complexes (1 and 2) which were not detected in nuclear extracts unexposed to hormone. Similar treatment with cortisol or estradiol failed to induce the formation of these complexes. The complexes were specific for PRE, since they could be competed efficiently in binding competition experiments by oligonucleotides containing PRE. A monoclonal antibody which recognizes both A and B forms of human progesterone receptor, interacted with both complexes 1 and 2 and shifted them to slower migrating forms. Another antibody which only recognizes the B form interacted with only complex 1 but not with complex 2, establishing that the complexes 1 and 2 were indeed formed by progesterone receptor forms B and A, respectively. We conclude from the above studies that in vivo or in vitro treatment of nuclear progesterone receptor with either progesterone or R5020 or RU38 486 alone can lead to detection of high affinity complexes formed between the PRE and the receptor present in unpurified nuclear extracts.     

Sp1 binding sites and an estrogen response element half-site are involved in regulation of the human progesterone receptor A promoter

Progesterone receptor gene expression is induced by estrogen in MCF-7 human breast cancer cells. Although it is generally thought that estrogen responsiveness is mediated through estrogen response elements (EREs), the progesterone receptor gene lacks an identifiable ERE. The progesterone receptor A promoter does, however, contain a half-ERE/Sp1 binding site comprised of an ERE half-site upstream of two Sp1 binding sites. We have used in vivo deoxyribonuclease I (DNase I) footprinting to demonstrate that the half-ERE/Sp1 binding site is more protected when MCF-7 cells are treated with estrogen than when cells are not exposed to hormone, suggesting that this region is involved in estrogen-regulated gene expression. The ability of the half-ERE/Sp1 binding site to confer estrogen responsiveness to a simple heterologous promoter was confirmed in transient cotransfection assays. In vitro DNase I footprinting and gel mobility shift assays demonstrated that Sp1 present in MCF-7 nuclear extracts and purified Sp1 protein bound to the two Sp1 sites and that the estrogen receptor enhanced Sp1 binding. In addition to its effects on Sp1 binding, the estrogen receptor also bound directly to the ERE half-site. Taken together, these findings suggest that the estrogen receptor and Sp1 play a role in activation of the human progesterone receptor A promoter.     

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.     

Transcriptional regulation of the mouse calbindin-D9k gene by the ovarian sex hormone

Calbindin-D9k levels in the rat uterus are under the control of estrogen. We found that the putative estrogen response element (ERE) failed to bind to the estrogen receptor from the mouse uterus. We therefore isolated mouse genomic clones of the calbindin-D9K gene and analyzed their expression in the mouse uterus. The promoter region of the gene contained several putative steroid hormone receptor binding sites. To characterize these elements, we constructed several promoter-reporter plasmids, and transiently transfected them into T47D breast cancer cells that express both estrogen and progesterone receptors. Luciferase activity was expressed from a promoter region containing the putative progesterone response element (PRE) and expression was stimulated by progesterone. In the uterus of oophorectomized mice, the calbindin-D9k gene was up-regulated by progesterone, but not by estrogen. These results suggest that the mouse uterine calbindin-D9k gene is expressed under the control of a PRE.     

Glucocorticoid receptor binding and activation of a heterologous promoter by dexamethasone by the first intron of the human growth hormone gene.

In this study DNA-binding and gene transfer experiments were performed to examine a potential glucocorticoid regulatory element (GRE) in the human growth hormone gene. As assayed by nitrocellulose filter binding, only two regions of the human growth hormone gene, the 5'-flanking sequences and a fragment containing part of the first intron, were retained preferentially by purified glucocorticoid-receptor complexes. The relative binding by the transcribed sequences was three times greater than the relative binding by the 5'-flanking sequences, but less than the relative binding by a fragment containing the human metallothionein-IIA gene GRE. The intron, but not the 5'-flanking sequences, generated a "footprint" when the receptor complex was used to protect the segments against exonuclease III digestion; the protected sequence spanned nucleotides +86 to +115 in the first intron and contained a structure homologous in 14 of 16 nucleotides to a 16-nucleotide consensus GRE. The hexanucleotide 5'-TGTCCT-3', thought to be important for GRE activity, not only was found in this sequence and in the 5'-flanking region, but also was present twice in the 3' end of the gene that did not show specific receptor binding. The latter results suggest that the hexanucleotide alone is not sufficient to generate specific receptor binding tight enough to be assayed in this way. To test the biological activity of the intron binding site, a fragment containing these sequences was fused 5' to the human metallothionein-IIA gene promoter depleted of its GRE and linked to the structural sequences of the herpes simplex virus thymidine kinase (TK) gene. When this hybrid gene was transfected into Rat 2 TK- cells, its expression was induced threefold by the glucocorticoid dexamethasone, as assessed by transfection efficiency and RNA blotting analyses. Expression of the same gene without the human growth hormone gene segment was not affected by the steroid, whereas the wild-type human metallothionein-IIA gene promoter containing its GRE responded to the hormone by a sixfold increase in thymidine kinase mRNA. These results indicate that the human growth hormone gene contains a structure within its first intron that can function as a GRE.