Cell-free synthesis of rat glucocorticoid receptor in rabbit reticulocyte lysate. In vitro synthesis of receptor in Mr 90,000 heat shock protein-depleted lysate

The glucocorticoid receptor is present in the cytosol of cell extracts as a large nonactivated (i.e. non-DNA-binding) approximately 9 S (Mr 300,000) complex. Experimental evidence indicates that the purified nonactivated glucocorticoid receptor contains a single steroid-binding protein and two approximately 90-kDa nonsteroid-binding subunits identified as heat shock protein (hsp) 90. Translation of the glucocorticoid receptor mRNA in vitro in reticulocyte lysates produces a large nonactivated glucocorticoid receptor complex similar to that found in cytosols. The cell-free synthesized glucocorticoid receptor is able to bind steroid and can be activated further to the DNA-binding form. To test the hypothesis of an active role played by hsp90 in the stabilization of a competent steroid-binding conformation of the glucocorticoid receptor, we have synthesized the receptor in a reticulocyte lysate that has been depleted of hsp90 by immunoadsorption with AC88 anti-hsp90. Although the translation capacity of the reticulocyte system was reduced considerably upon hsp90 removal, the glucocorticoid receptor was synthesized, and a significant number of molecules were found to bind [3H]triamcinolone acetonide. Chromatography on DEAE-cellulose showed that most of the receptor molecules synthesized in hsp90-depleted lysate had lost the capacity to form an oligomeric receptor complex. Addition of purified rat liver hsp90 to the hsp90-depleted lysate before translation did not increase steroid binding nor did it restore formation of the heteromeric receptor complex. Analysis of [35S] methionine-labeled glucocorticoid receptor molecules synthesized in the hsp90-depleted lysate showed the production of polypeptides differing from the expected chromatographic pattern on DEAE-cellulose. Upon addition of purified hsp90 to the hsp90-depleted lysate, before translation, the 35S-labeled synthesized receptor fractionated on DEAE-cellulose as an intermediate peak between activated and nonactivated receptor forms. The data suggest that hsp90 alone may not be sufficient for the formation of the nonactivated steroid receptor complex.     

Translation of glucocorticoid receptor mRNA in vitro yields a nonactivated protein

The glucocorticoid receptor is present in cytosol prepared from cell extracts of nonhormone-treated cells as a large nonactivated (i.e. non-DNA binding) 9 S heteromeric complex which contains the Mr approximately 90,000 heat shock protein, hsp90. hsp90 is expressed under physiological conditions in mammalian cells and is also present in reticulocyte lysate, as assessed by Western immunoblotting using specific anti-hsp90 antibodies. We have translated glucocorticoid receptor mRNA in reticulocyte lysates. The receptor synthesized under cell-free conditions also interacts with hsp90 both in the presence and absence of ligand, as determined by sucrose gradient centrifugation. The in vitro synthesized glucocorticoid receptor does not bind to DNA-cellulose but can be converted to a DNA binding form following labeling with dexamethasone and heat treatment. Thus, the glucocorticoid receptor is synthesized in a nonactivated form under cell-free conditions. These data indicate that the 9 S glucocorticoid receptor complex found in cytosol does not represent an artifact due to cell homogenization and supports the existence in vivo of the glucocorticoid receptor-hsp90 complex.     

Glucocorticoid receptor phosphorylation in mouse L-cells

This paper summarizes our observations on the phosphorylation state of untransformed and transformed glucocorticoid receptors isolated from 32P-labeled L-cells. The 300-350-kDa 9S untransformed murine glucocorticoid receptor complex is composed of a 100-kDa steroid-binding phosphoprotein and one or possibly two units of the 90-kDa heat shock protein (hsp90), which is also a phosphoprotein. Transformation of this complex to the 4S DNA-binding state is accompanied by dissociation of hsp90. When receptors in cytosol are transformed by heating at 25 degrees C, there is no gross change in the degree of phosphorylation of the steroid-binding protein. Both receptors that are bound to DNA after transformation under cell-free conditions and receptors that are located in the nucleus of cells incubated at 37 degrees C in the presence of glucocorticoid are labeled with 32P. The results of experiments in which the 32P-labeled receptor was submitted to limited proteolysis suggest that the 16-kDa DNA-binding domain is phosphorylated and that the 28-kDa steroid-binding domain is not.     

Monoclonal antibody to the rat glucocorticoid receptor. Relationship between the immunoreactive and DNA-binding domain

The region of the glucocorticoid receptor that reacted with a monoclonal antibody (BUGR-1) was identified. In order to identify the immunoreactive region, the rat liver glucocorticoid receptor was subjected to limited proteolysis; immunoreactive fragments were identified by Western blotting. The monoclonal antibody reacted with both the undigested Mr approximately 97,000 receptor subunit and a Mr approximately 45,000 fragment containing the steroid-binding and DNA-binding domains. Digestion by trypsin also produced two steroid-binding fragments of Mr approximately 27,000 and 31,000 which did not react with the antibody and an immunoreactive Mr approximately 16,000 fragment. This Mr approximately 16,000 fragment was shown to bind to DNA-cellulose, indicating that it contained a DNA-binding domain of the receptor. The undigested receptor must have steroid associated with it to undergo activation to a DNA-binding form. However, the Mr approximately 16,000 immunoreactive fragment binds to DNA-cellulose even if it is obtained by digestion of the steroid-free holoreceptor which does not itself bind to DNA.     

The Mr 90,000 heat shock protein-free androgen receptor has a high affinity for steroid, in contrast to the glucocorticoid receptor

Transformed and bacterially expressed glucocorticoid receptors free from Mr 90,000 heat shock protein (hsp90) have a 100-fold lower steroid-binding affinity than the hsp90-bound nontransformed receptor, suggesting that hsp90 is needed for high-affinity steroid binding [Nemoto, T., Ohara-Nemoto, Y., Denis, M., & Gustafsson, J.-A. (1990) Biochemistry 29, 1880-1886]. To investigate whether or not this phenomenon is common to all steroid receptors, we investigated the steroid-binding affinities of bacterially expressed and transformed androgen receptors. The C-terminal portion of the rat androgen receptor containing the putative steroid-binding domain was expressed as a fusion protein of protein A in Escherichia coli. The recombinant protein bound a synthetic androgen, [3H]R1881, with high affinity (Kd = 0.8 +/- 0.3 nM). Glycerol gradient analysis revealed that the recombinant protein sedimented at around the 3S region irrespective of the presence of molybdate, indicating that the receptor is present in monomeric form. The steroid-free transformed androgen receptor was obtained by exposure of rat submandibular gland cytosol to 0.4 M NaCl in the absence of steroid. High-performance ion-exchange liquid chromatography analysis showed that the transformed androgen receptor bound to [3H]R1881 with high affinity. Thus these observations indicate that, in contrast to the glucocorticoid receptor, hsp90 is not required for the high-affinity steroid binding of the androgen receptor. In addition, the hsp90-free androgen receptor prebound with radioinert R1881 was efficiently relabeled with [3H]R1881, while the triamcinolone acetonide-bound, transformed glucocorticoid receptor failed in ligand exchange. The inability to achieve ligand exchange probably reflects the low steroid-binding affinity of this entity.     

Interaction of the Mr = 90,000 heat shock protein with the steroid-binding domain of the glucocorticoid receptor

We have investigated the physiochemical characteristics of trypsin-treated, molybdate-stabilized glucocorticoid-receptor complexes from rat liver in the presence of 10 mM sodium molybdate by high performance ion-exchange chromatography, high performance size-exclusion chromatography, and sedimentation analysis. Trypsin treatment was performed under conditions previously reported to degrade the monomeric Mr approximately 94,000 steroid-binding protein to an Mr approximately 27,000 ligand-binding entity (Wrange, O., and Gustafsson, J.-A. (1978) J. Biol. Chem. 253, 856-865). Also in the presence of molybdate, an Mr approximately 27,000 steroid-binding fragment was obtained by limited trypsinization. However, no major differences in the tested physicochemical parameters were seen when trypsin-treated glucocorticoid-receptor complexes were compared with crude cytosolic complexes. Furthermore, the Mr approximately 27,000 steroid-binding fragment generated in the presence of molybdate could be immunoprecipitated by antibodies specific for the glucocorticoid receptor-associated Mr approximately 90,000 heat shock protein. These results provide direct evidence for an interaction of the Mr approximately 90,000 heat shock protein with the steroid-binding domain of the glucocorticoid receptor, known to correspond to the C-terminal third of the receptor protein.     

Relationship between glucocorticoid receptor steroid-binding capacity and association of the Mr 90,000 heat shock protein with the unliganded receptor

Treatment of rat liver cytosol with hydrogen peroxide (H2O2) or sodium molybdate (MoO4(2-)) inhibits thermal inactivation of glucocorticoid receptor steroid-binding capacity at 25 degrees C. Dithiothreitol (DTT) prevents the stabilization of receptors by H2O2. Heating (25 degrees C) of immune pellets formed by immunoadsorption of L-cell murine glucocorticoid receptor complexes to protein-A-Sepharose with an anti-receptor monoclonal antibody (BuGR2) results in dissociation of the M 90,000 heat shock protein (hsp90) from the steroid binding protein. Such thermal-induced dissociation of hsp90 is inhibited by H2O2. Pretreatment of immunoadsorbed receptor complexes with the thiol derivatizing agent, methyl methanethiosulfonate (MMTS) prevents the ability of H2O2 to stabilize the hsp90-receptor interaction. These data suggest a role for hsp90 in maintaining an active steroid-binding conformation of the glucocorticoid receptor.     

Evidence that the 90-kDa heat shock protein is necessary for the steroid binding conformation of the L cell glucocorticoid receptor

Using L cell glucocorticoid receptors that have been immunopurified by adsorption to protein A Sepharose with a monoclonal antireceptor antibody, we have developed an assay to study the requirements for maintenance of steroid-binding capacity. After rapid purification by immunoadsorption, heteromeric receptor complexes retain the ability to bind glucocorticoid hormone. When the receptor complexes are warmed at 20 degrees C, steroid-binding capacity is lost, and the 90-kDa heat shock protein (hsp90) dissociates from the receptor. The rates of both temperature- and salt-dependent dissociation of hsp90 parallel the rates of loss of hormone-binding activity. Molybdate and hydrogen peroxide stabilize the hsp90-receptor complex against temperature-dependent dissociation. Molybdate, however, is much more effective in stabilizing steroid-binding capacity than peroxide. Receptors that have been inactivated in the absence of molybdate or peroxide cannot be reactivated. Inactivation of steroid-binding capacity occurs in the presence or absence of reducing agent, and inactivation is not accompanied by receptor cleavage or dephosphorylation. Under no conditions does an hsp90-free receptor bind steroid. Receptor bound to hsp90 can be cleaved to the 27-kDa meroreceptor in the presence of molybdate with retention of both hsp90 and steroid-binding activity. These observations lead us to propose that hsp90 is necessary but not sufficient for maintaining a competent high affinity glucocorticoid-binding site. Although the 27-kDa meroreceptor fragment is not itself sufficient for a competent binding site, it is sufficient when it is associated with hsp90.     

The steroid-binding properties of recombinant glucocorticoid receptor: a putative role for heat shock protein hsp90

The steroid-binding domain of the human glucocorticoid receptor was expressed in Escherichia coli either as a fusion protein with protein A or under control of the T7 RNA polymerase promoter. The recombinant proteins were found to bind steroids with the normal specificity for a glucocorticoid receptor but with reduced affinity (Kd for triamcinolone acetonide approximately 70 nM). Glycerol gradient analysis of the E. coli lystate containing the recombinant protein indicated no interaction between the glucocorticoid receptor fragment and heat shock proteins. However, synthesis of the corresponding fragments of glucocorticoid receptor in vitro using rabbit reticulocyte lystate resulted in the formation of proteins that bound triamcinolone acetonide with high affinity (Kd 2nM). Glycerol gradient analysis of these proteins, with and without molybdate, indicated that the in vitro synthesised receptor fragments formed complexes with hsp90 as previously shown for the full-length rat glucocorticoid receptor. Radiosequence analysis of the recombinant steroid-binding domain expressed in E. coli and affinity labelled with dexamethasone mesylate identified binding of the steroid to Cys-638 predominantly. However, all cysteine residues within the steroid-binding domain were affinity labelled to a certain degree indicating that the recombinant protein has a structure similar to the native receptor but more open and accessible.     

Relationship of the 90-kDa murine heat shock protein to the untransformed and transformed states of the L cell glucocorticoid receptor

Incubation of molybdate-stabilized L cell cytosol with a monoclonal antibody directed against the 100-kDa glucocorticoid-binding protein causes the immune-specific adsorption to protein A-Sepharose of both the 100-kDa glucocorticoid receptor and the 90-kDa murine heat shock protein (hsp90) (Sanchez, E. R., Toft, D. O., Schlesinger, M. J., and Pratt, W. B. (1985) J. Biol. Chem. 260, 12398-12401). When the glucocorticoid receptor in cytosol is transformed to the DNA-binding state, hsp90 dissociates. In this paper, we show that temperature-mediated dissociation of hsp90 from the receptor is a hormone-dependent event in the same manner as temperature-mediated transformation to the DNA-binding state. In contrast to temperature-mediated transformation, ammonium sulfate causes both dissociation of hsp90 from the receptor and conversion of the receptor to the DNA-binding form in a manner that does not require the presence of steroid. The untransformed form of the glucocorticoid receptor and the strongly negatively charged hsp90 protein behave similarly on DEAE-cellulose chromatography, suggesting that the hsp90 component may contribute significantly to the net negative charge behavior of the non-DNA-binding form of the receptor complex.     

Elimination and reconstitution of the requirement for hormone in promoting temperature-dependent transformation of cytosolic glucocorticoid receptors to the DNA-binding state

Cytosols contain a heat-stable, chelatable, anionic, molybdate-like factor that stabilizes glucocorticoid receptors in a heteromeric complex with hsp90 (refers to the 90-kDa heat shock protein) and inhibits their transformation to the DNA-binding state (Meshinchi, S., Grippo, J.F., Sanchez, E.R., Bresnick, E.H., and Pratt, W.B. (1988) J. Biol. Chem. 263, 16809-16817). In this work, we demonstrate that removal of this factor by passage of L cell cytosol through the metal-chelating resin Chelex-100 makes the glucocorticoid receptor unstable, thus markedly facilitating both its dissociation from hsp90 and its transformation to the DNA-binding state. In normal cytosol, both temperature-mediated dissociation of hsp90 and temperature-mediated receptor transformation are hormone-dependent events. In the Chelex-treated, metal-depleted cytosol, however, temperature-mediated dissociation of hsp90 and receptor transformation occur very rapidly in a manner that is no longer hormone-dependent. When boiled L cell cytosol is added to the metal-depleted receptor system, the hormone dependence of both temperature-mediated dissociation of receptor from hsp90 and receptor transformation to the DNA-binding state is reconstituted. Like boiled cytosol, molybdate stabilizes the receptor complex and inhibits its transformation in metal-depleted cytosol, but it does not reconstitute the hormone dependence of the system. These results support the proposal that an endogenous metal anion interacts with the glucocorticoid receptor to stabilize it in the heteromeric, inactive, non-DNA-binding state in cytosol and that binding of the hormone promotes conversion of the receptor to the DNA-binding state through an effect on this metal anion center.     

The molybdate-stabilized nonactivated glucocorticoid receptor contains a dimer of Mr 90,000 non-hormone-binding protein

A glucocorticoid receptor-associated Mr approximately 90,000 non-hormone-binding protein was purified and characterized. The molybdate-stabilized nonactivated rat liver glucocorticoid-receptor complex (Mr approximately 300,000) was immunoadsorbed on cyanogen bromide-activated Sepharose 4B to which a monoclonal IgG 2a antibody directed against the activated rat glucocorticoid receptor (Mr approximately 94,000) had been coupled. Following removal of molybdate and thermal activation of the receptor immobilized on the immunoaffinity matrix, an Mr approximately 90,000 non-hormone-binding protein was specifically eluted. This protein was further purified to homogeneity using high performance ion exchange chromatography and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, sucrose gradient ultra-centrifugation, and high performance size-exclusion chromatography. Hydrodynamic characterization under nondenaturing conditions revealed that the purified glucocorticoid receptor-associated protein represents a molecular species with a sedimentation coefficient of 6.1 S, a Stokes radius of 6.9 nm, and a calculated Mr approximately 184,000. These results, combined with analysis on denaturing electrophoresis indicate that, under certain conditions, the Mr approximately 94,000 steroid-binding protein is associated with a dimer of Mr approximately 90,000 non-hormone-binding protein.     

Reconstitution of progesterone receptor with heat shock proteins

Nonactivated chick progesterone receptor from hypotonic tissue extracts exists in a large complex containing the heat shock proteins hsp90 and hsp70 plus additional smaller proteins; activation of receptor to a DNA-binding form involves the dissociation of proteins from the complex. Whereas numerous attempts to reversibly bind components to the activated receptor have been unsuccessful, we now report conditions that promote the reassociation of hsp90 and hsp70 to progesterone receptor. Cytosolic receptor was dissociated from hsp90 and hsp70 by treatment with 0.5 M KCl and 10 mM ATP in the absence of progesterone. It was then purified by binding to immunoaffinity resins. After wash steps, the receptor-resin complex was incubated in rabbit reticulocyte lysate at 30 C, rewashed, and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Saturable binding of rabbit hsp90 and hsp70 to chick receptor was found after incubation with reticulocyte lysate; hsp binding was temperature dependent, but not dependent on exogenous ATP. Incubation of dissolved receptor with oviduct cytosol, from which receptor was obtained, or with purified hsp did not result in hsp binding. Furthermore, mixing oviduct cytosol with lysate inhibited hsp reconstitution, suggesting negative factors for hsp binding in oviduct cytosol. The steroid-binding domain of the receptor was required, since no hsp binding was observed in the reconstitution system using a receptor mutant lacking this domain. When the receptor was isolated in the presence of progesterone, reconstitution with hsp90 and hsp70 did not occur. This is consistent with the in vivo effects of progesterone in promoting hsp dissociation.     

Subunit composition of the molybdate-stabilized non-activated glucocorticoid receptor from rat liver

A monoclonal IgG 2a antibody directed against the activated rat liver glucocorticoid receptor (GR) was used to prepare an immunoaffinity matrix of high capacity. The molybdate-stabilized GR from rat liver cytosol was immunoadsorbed on this gel. A non-hormone-binding protein of Mr approximately 90,000, as determined after denaturing gel electrophoresis, was eluted from this matrix following removal of molybdate and exposure to heat (25 degrees C) and salt (0.15 M NaCl). Subsequently, the Mr approximately 90,000 protein was purified to homogeneity using high-performance ion-exchange chromatography, covalently radiolabelled, and analyzed by high-performance size-exclusion chromatography and sucrose gradient ultracentrifugation. Hydrodynamic characterization indicates that, under our experimental conditions, the molybdate-stabilized rat liver GR (Rs approximately 7.4 nm, s20,w approximately 9.1 S, calculated mol. wt Mr approximately 285,000) includes one steroid-binding unit (Rs approximately 5.5 nm, S20,w approximately 4.3 S, calculated Mr approximately 100,000) and a dimer of Mr approximately 90,000 non-hormone-binding protein (Rs approximately 6.9 nm, S20,w approximately 6.1 S, calculated native Mr approximately 180,000).     

Selective molybdate-directed covalent modification of sulfhydryl groups in the steroid-binding versus the DNA-binding domain of the glucocorticoid receptor

Hydrogen peroxide produces all of the effects on glucocorticoid receptors that are produced by molybdate, including stabilization of the receptor 90-kDa heat shock protein (hsp90) complex (Tienrungroj, W., Meshinchi, S., Sanchez, E. R., Pratt, S. E., Grippo, J. F., Holmgren, A., and Pratt, W. B. (1987) J. Biol. Chem. 262, 6992-7000). When the glucocorticoid receptor is exposed simultaneously to molybdate and peroxide at concentrations that are optimal for receptor stabilization if each agent is present alone, there is an irreversible loss of steroid binding activity. The effect is accompanied by a covalent modification of the receptor, which is demonstrated by an increase in its apparent Mr on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Preincubation of the receptor with the sulfhydryl-modifying reagents methyl methanethiosulfonate or N-ethylmaleimide prevents covalent modification, suggesting that cysteine moieties are the site of attack. The covalently modified receptor can still bind to DNA. Molybdate-peroxide treatment does not covalently modify the 15-kDa tryptic fragment containing the DNA-binding domain and 11 of the 20 cysteine moieties in the receptor. However, the 27-kDa tryptic fragment, which contains the steroid-binding domain and 5 cysteines, is covalently modified. The 27-kDa tryptic fragment is covalently modified by the molybdate-peroxide combination when [3H]dexamethasone 21-mesylate is covalently bound to Cys-644. This leaves some combination of 4 cysteines in the steroid-binding domain (628, 649, 671, and 742) as the modified groups. These modifications occur in a region of the receptor that is known to contain its sites of interaction with both hsp90 and molybdate, with the latter having a well-established avidity for sulfur. These observations raise the possibility that the covalent modification caused by the molybdate-peroxide combination represents a modification of sulfur ligands involved in molybdate stabilization of the receptor.     

Tetrameric structure of the nonactivated glucocorticoid receptor in cell extracts and intact cells

Mouse lymphoma cells contain a nonactivated glucocorticoid receptor of Mr approximately 330,000 which is heteromeric in nature and is unable to bind to DNA. Following affinity labeling of the steroid-binding subunit and subsequent cross-linking with dimethyl suberimidate at various times either in cell extracts or in intact cells, a series of labeled bands was detected in SDS gels. From the molecular masses of completely and partially cross-linked complexes we conclude that the large nonactivated receptor is a tetramer composed of two 90 kDa subunits, one 50 kDa polypeptide and one steroid-binding subunit.     

Subunit structure of the glucocorticoid receptor and activation to the DNA-binding state

Glucocorticoid receptors of S49.1 mouse lymphoma cells were analyzed under a variety of conditions. The complexes with an agonist or a steroidal antagonist can be formed in cytosolic extracts, they are of high molecular weight, Mr approximately 330,000 and have a Stokes radius of 82 A. Cross-linking by several agents stabilized this structure against subunit dissociation which produces the activated receptor form of 60 A and DNA-binding ability. Careful analysis of intermediate cross-linked forms lead to the conclusion that the large receptor structure is a hetero-tetramer consisting of one hormone-bearing polypeptide of Mr approximately 94,000, two 90 kDa subunits and a protein component of Mr approximately 50,000. The 90 kDa subunits are the heat shock protein hsp90. The high molecular weight receptor form also exists in intact cells as revealed again by cross-linking. The cytosolic complex with the antagonist can become activated to the DNA-binding form upon warming but simultaneously looses the ligand. Ligand rebinding does not occur subsequent to receptor dissociation. Upon incubation of intact cells at 37 degrees C with agonist or antagonist the respective receptor-ligand complexes are formed. The agonist complex is immediately activated, however, the antagonist complex remains stable in the undissociated state. This explains the biological effect of the antagonist.     

Differential effects of the hsp70-binding protein BAG-1 on glucocorticoid receptor folding by the hsp90-based chaperone machinery

The heat shock protein hsp70/hsc70 is a required component of a five-protein (hsp90, hsp70, Hop, hsp40, and p23) minimal chaperone system reconstituted from reticulocyte lysate that forms glucocorticoid receptor (GR).hsp90 heterocomplexes. BAG-1 is a cofactor that binds to the ATPase domain of hsp70/hsc70 and that modulates its chaperone activity. Inasmuch as BAG-1 has been found in association with several members of the steroid receptor family, we have examined the effect of BAG-1 on GR folding and GR.hsp90 heterocomplex assembly. BAG-1 was present in reticulocyte lysate at a BAG-1:hsp70/hsc70 molar ratio of approximately 0.03, and its elimination by immunoadsorption did not affect GR folding and GR. hsp90 heterocomplex assembly. At low BAG-1:hsp70/hsc70 ratios, BAG-1 promoted the release of Hop from the hsp90-based chaperone system without inhibiting GR.hsp90 heterocomplex assembly. However, at molar ratios approaching stoichiometry with hsp70, BAG-1 produced a concentration-dependent inhibition of GR folding to the steroid-binding form with corresponding inhibition of GR.hsp90 heterocomplex assembly by the minimal five-protein chaperone system. Also, there was decreased steroid-binding activity in cells that were transiently or stably transfected with BAG-1. These observations suggest that, at physiological concentrations, BAG-1 modulates assembly by promoting Hop release from the assembly complex; but, at concentrations closer to those in transfected cells and some transformed cell lines, hsp70 is continuously bound by BAG-1, and heterocomplex assembly is blocked.     

Protein components of the nonactivated glucocorticoid receptor.

The nonactivated glucocorticoid receptor (Mr approximately 350,000) of WEHI-7 mouse lymphoma cells was investigated with respect to the stoichiometry of protein subunits. Cross-linking patterns obtained by affinity labeling and denaturing gel electrophoresis revealed a heterotetramer consisting of one receptor polypeptide in association with two 90- and one approximately 50-kDa subunits. The receptor stabilized by molybdate, disulfide bond formation, or chemical cross-linking was purified roughly 6000-fold by immunoaffinity chromatography and analyzed by gel electrophoresis and immunoblotting. The 90-kDa component was consistently detected in a 2:1 ratio with respect to the receptor polypeptide and was identified as the 90-kDa heat shock protein, hsp90. A 70-kDa heat shock protein was found in both stabilized and nonstabilized receptors and bound to the immunomatrix independent of receptor. The additional receptor subunit was unequivocally identified as the 59-kDa protein previously described (Tai, P.-K. K., Maeda, Y., Nakao, K., Wakim, N. G., Duhring, J. L., and Faber, L. E. (1986) Biochemistry 25, 5269-5275). This component was found only in complexes cross-linked via amino groups. It was removed from the molybdate-stabilized receptor under our purification conditions, thus leaving behind a trimer composed of the receptor polypeptide and two molecules of hsp90. In the absence of hormone, the receptor had the same subunit composition as in its presence.     

Determinants of high-affinity DNA binding by the glucocorticoid receptor: evaluation of receptor domains outside the DNA-binding domain.

In this study, we have investigated the influence of regions outside the DNA-binding domain of the human glucocorticoid receptor on high-affinity DNA binding. We find that the DNA-binding domain shows a 10-fold lower affinity for a palindromic DNA-binding site than the intact receptor. The N-terminal part of the receptor protein does not influence its DNA-binding affinity, while the C-terminal steroid-binding domain increases the DNA-binding affinity of the receptor molecule. It has previously been shown that both the intact glucocorticoid receptor and the glucocorticoid receptor DNA-binding domain bind to a palindromic glucocorticoid response element on DNA as dimers. It is likely that differences in DNA-binding affinity observed result from protein-protein interactions outside the DNA-binding domain between receptor monomers, as has been shown for the estrogen receptor. We have previously identified a segment involved in protein-protein interactions between DNA-binding domains of glucocorticoid receptors. This, in combination with results presented in this study, suggests that there are at least two sites of contact between receptor monomers bound to DNA. We suggest that the interaction between the DNA-binding domains may act primarily to restrict DNA binding to binding sites with appropriate half-site spacing and that additional stability of the receptor dimer is provided by the interactions between the steroid-binding domains.