Subunit composition of the untransformed glucocorticoid receptor in the cytosol and in the cell.

We have used bifunctional reagents to examine the subunit composition of the non-DNA-binding form of the rat and human glucocorticoid receptor. Treatment of intact cells and cell extracts with a reversible cross-linker, followed by electrophoretic analysis of immunoadsorbed receptor revealed that three proteins of apparent approximate molecular masses, 90, 53 and 14 kDa are associated with the receptor. The first of these was identified immunochemically as a 90-kDa heat-shock protein (hsp90). The complex isolated from HeLa cells contained 2.2 mol hsp90/mol steroid-binding subunit. Cross-linking of the receptor complex in the cytosol completely prevented salt-induced dissociation of the subunits. The cross-linked receptor was electrophoretically resolved into two oligomeric complexes of apparent molecular mass 288 kDa and 347 kDa, reflecting the association of the 53-kDa protein with a fraction of the receptor. Since no higher oligomeric complexes could be generated by cross-linking cell extracts under different conditions, we conclude that most of the untransformed cytosolic receptor is devoid of additional components.     

Mechanism of action of a steroidal antiglucocorticoid in lymphoid cells

We compared the biochemical properties of receptors extracted from mouse lymphoma cells and complexed with the glucocorticoid, triamcinolone acetonide, or with the high affinity antiglucocorticoid RU 38486 [17 beta-hydroxy-11 beta-(4-dimethylaminophenyl)-17 alpha-(1-propynyl)-estra- 4,9-diene-3-one]. Upon salt treatment the high molecular weight receptor complexes of both types yielded dissociated forms that had the same affinity for DNA. Increased temperature caused subunit dissociation of the agonist complex but ligand dissociation of the antagonist complex. The latter was prevented if subunit dissociation was blocked by sodium molybdate but not by chemical cross-linking of the heteromeric receptor. Immunochemical studies suggest that the instability of the RU 38486 complex only affects the level of bound ligand but not the integrity of the receptor polypeptide. In intact cells at 37 degrees C the receptor polypeptide associated with nuclei only in the presence of hormone but not in its absence or if the antihormone was present. Cells incubated at 37 degrees C with RU 38486 retained in the cytosol the high molecular weight receptor in its ligand bound form. The data suggest that in intact cells under physiological conditions the antagonist binds to the heteromeric receptor and blocks its dissociation into subunits thus preventing nuclear receptor translocation.     

Nonactivated and activated glucocorticoid receptor complexes from human salivary gland adenocarcinoma cell line

[3H]Triamcinolone acetonide glucocorticoid receptor complexes from human salivary gland adenocarcinoma cells (HSG cells) were shown to be activated with an accompanying decrease in molecular weight in intact cells, as analyzed by gel filtration, DEAE chromatography, the mini-column method and glycerol gradient centrifugation. Glucocorticoid receptor complexes consist of steroid-binding protein (or glucocorticoid receptor) and non-steroid-binding factors such as the heat-shock protein of molecular weight 90,000. To determine whether the steroid-binding protein decreases in molecular weight upon activation, affinity labeling of glucocorticoid receptor in intact cells by incubation with [3H]dexamethasone 21-mesylate, which forms a covalent complex with glucocorticoid receptor, was performed. Analysis by gel filtration and a mini-column method indicated that [3H]dexamethasone 21-mesylate-labeled receptor complexes can be activated under culture conditions at 37 degrees C. SDS-polyacrylamide gel electrophoresis of [3H]dexamethasone 21-mesylate-labeled steroid-binding protein resolved only one specific 92 kDa form. Furthermore, only one specific band at 92 kDa was detected in the nuclear fraction which was extracted from the cells incubated at 37 degrees C. These results suggest that there is no change in the molecular weight of steroid-binding protein of HSG cell glucocorticoid receptor complexes upon activation and that the molecular weight of nuclear-binding receptor does not change, although the molecular weight of activated glucocorticoid receptor complexes does decrease. Triamcinolone acetonide induced an inhibitory effect on DNA synthesis in HSG cells. Dexamethasone 21-mesylate exerted no such effect and blocked the action of triamcinolone acetonide on DNA synthesis. These results suggests that dexamethasone 21-mesylate acts as antagonist of glucocorticoid in HSG cells. The fact that dexamethasone 21-mesylate-labeled receptor complexes could be activated and could bind to DNA or nuclei as well as triamcinolone acetonide-labeled complexes suggests that dexamethasone 21-mesylate-labeled complexes can not induce specific gene expression after their binding to DNA.     

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.     

The glucocorticoid antagonist 17 alpha-methyltestosterone binds to the 10 S glucocorticoid receptor and blocks agonist-mediated dissociation of the 10 S oligomer to the 4 S deoxyribonucleic acid-binding subunit

The glucocorticoid antagonist 17 alpha-methyltestosterone inhibits binding of the agonist [3H]triamcinolone acetonide ot the glocucorticoid receptor in cytosol prepared from rat pituitary tumor GH1 cells. Competitive binding studies indicate that the dissociation constant for 17 alpha-methyltestosterone is about 1 microM. After incubation of intact GH1 cells with 10 nM [3H]triamcinolone acetonide at 37 C and subsequent cell fractionation at 4 C, three glucocorticoid receptor forms are observed: cytosolic 10 S receptor, cytosolic 4 S receptor, and nuclear receptor. Concurrent incubation with 17 alpha-methyltestosterone reduces the amount of [3H]triamcinolone acetonide bound to each of these receptor forms. Ligand-exchange assays performed at 0 C in intact cells using [3H]triamcinolone acetonide show that the exchangeable antagonist is associated predominantly with cytosolic 10 S receptor. Immunochemical analysis using monoclonal antibody BuGR2 indicates that 17 alpha-methyltestosterone does not cause substantial accumulation of glucocorticoid receptors in GH1 cell nuclei and, when present together with agonist, reduces nuclear accumulation of receptor seen with agonist alone. Results from dense amino acid labeling studies show that unlike [3H]triamcinolone acetonide, 17 alpha-methyltestosterone does not reduce the total amount of cellular glucocorticoid receptor and does not reduce receptor half-life. These results are consistent with a model for glucocorticoid receptor transformation in which binding of agonist promotes the dissociation of an oligomeric 10 S cytosolic receptor protein to its DNA-binding 4 S subunit. The antagonist 17 alpha-methyltestosterone competes with agonist for binding to the 10 S cytosolic receptor but does not appear to promote dissociation of the oligomer, thus inhibiting agonist-mediated nuclear actions of the glucocorticoid receptor.     

Nonactivated and activated glucocorticoid receptor complexes from human salivary gland adenocarcinoma cell line

[³H]Triamcinolone acetonide glucocorticoid receptor complexes from human salivary gland adenocarcinoma cells (HSG cells) were shown to be activated with an accompanying decrease in molecular weight in intact cells, as analyzed by gel filtration, DEAE chromatography, the mini-column method and glycerol gradient centrifugation. Glucocorticoid receptor complexes consist of steroid-binding protein (or glucocorticoid receptor) and non-steroid-binding factors such as the heat-shock protein of molecular weight 90 000. To determine whether the steroid-binding protein decreases in molecular weight upon activation, affinity labeling of glucocorticoid receptor in intact cells by incubation with [³H]dexamethasone 21-mesylate, which forms a covalent complex with glucocorticoid receptor, was performed. Analysis by gel filtration and a mini-column method indicated that [³H]dexamethasone 21-mesylate-labeled receptor complexes can be activated under culture conditions at 37°C. SDS-polyacrylamide gel electrophoresis of [³H]dexamethasone 21-mesylate-labeled steroid-binding protein resolved only one specific 92 kDa form. Furthermore, only one specific band at 92 kDa was detected in the nuclear fraction which was extracted from the cells incubated at 37°C. These results suggest that there is no change in the molecular weight of steroid-binding protein of HSG cell glucocorticoid receptor complexes upon activation and that the molecular weight of nuclear-binding receptor does not change, although the molecular weight of activated glucocorticoid receptor complexes does decrease. Triamcinolone acetonide induced an inhibitory effect on DNA synthesis in HSG cells. Dexamethasone 21-mesylate exerted no such effect and blocked the action of triamcinolone acetonide on DNA synthesis. These results suggests that dexamethasone 21-mesylate acts as antagonist of glucocorticoid in HSG cells. The fact that dexamethasone 21-mesylate-labeled receptor complexes could be activated and could bind to DNA or nuclei aas well as triamcinolone acetonide-labeled complexes suggests that dexamethasone 21-mesylate-labeled complexes can not induce specific gene expression after their binding to DNA.     

Activation of cytosolic glucocorticoid-receptor complexes in intact WEHI-7 cells does not dephosphorylate the steroid-binding protein

In order to determine the ratio of phosphates to hormone-binding sites on nonactivated (non-DNA-binding) glucocorticoid receptors in WEHI-7 mouse thymoma cells, we have extracted these receptors from cells grown to a steady state with 32P, labeled them with a saturating concentration of [3H]dexamethasone 21-mesylate, purified them using a monoclonal antibody, and analyzed them by polyacrylamide gel electrophoresis under denaturing and reducing conditions. The complexes contained approximately 5 mol of phosphate/mol of bound steroid. Only half of the phosphates were associated with the approximately 100-kDa protein which is labeled with [3H]dexamethasone 21-mesylate. The remaining phosphates were associated with the approximately 90-kDa non-steroid-binding component of the nonactivated complex. Dual label studies, using [35S]methionine to measure receptor protein and 32P to measure receptor phosphates, have enabled us to determine the phosphate content, relative to receptor protein, of both nonactivated and activated cytosolic complexes generated in intact WEHI-7 cells exposed to triamcinolone acetonide at 37 degrees C. The total amount of phosphate associated with the activated complex is roughly half of that associated with the nonactivated complex, the decrease being accounted for by dissociation of the approximately 90-kDa phosphoprotein which accompanies activation. However, the ratio of 32P to 35S counts associated with the approximately 100-kDa steroid-binding protein is the same for the activated and nonactivated complexes. These results indicate that there is no net change in the phosphorylation of the approximately 100-kDa steroid-binding component of the cytosolic glucocorticoid-receptor complex upon activation in the intact cell.     

The non-activated glucocorticoid receptor: structure and activation

Glucocorticoid hormone receptors are present in the soluble fraction of target cell homogenates as large entities (Mr approximately 300,000) that are unable to interact with DNA. These large complexes contain an Mr approximately 94,000 steroid- and DNA-binding polypeptide, in association with an Mr approximately 90,000 non-ligand-binding entity, which has been identified as a heat shock protein, hsp90. This protein has been purified to near homogeneity as a component of the non-activated receptor complex. Characterization of the purified protein revealed its presence as a dimer in the large receptor form. Dissociation of the receptor-hsp90 complex can be induced by heat treatment only when ligand is bound to the receptor, as demonstrated by specific DNA-binding assay and sucrose gradient ultracentrifugation, hsp90 represents ca 1% of total proteins in rat liver cytosol, and milligram amounts were purified using a combination of high performance ion exchange and gel permeation chromatography. Monospecific antibodies were raised in rabbits. They were found to precipitate the intact non-activated glucocorticoid receptor, as well as the Mr approximately 27,000 steroid-binding fragment of the receptor generated by trypsin treatment, indicating that hsp90 interacts with the steroid-binding domain of the glucocorticoid receptor. Finally, translation of glucocorticoid receptor mRNA in reticulocyte lysate yields a protein which also interacts with hsp90 and binds to DNA only after ligand-binding and heat treatment. Thus, the glucocorticoid receptor is synthesized in a non-activated form also in vitro.     

Molybdate-stabilized nonactivated glucocorticoid-receptor complexes contain a 90-kDa non-steroid-binding phosphoprotein that is lost on activation

We have used a monoclonal antibody to purify glucocorticoid-receptor complexes from WEHI-7 mouse thymoma cells. Molybdate-stabilized, nonactivated complexes were found to contain two distinct proteins which could be separated by polyacrylamide gel electrophoresis under denaturing and reducing conditions. One of the proteins, 100 kDa, was labeled when cytosol was incubated with the affinity ligand [3H]dexamethasone 21-mesylate. The second protein, 90 kDa, was not labeled. Several lines of evidence, including Western blot analysis of purified nonactivated complexes, indicate that only the 100-kDa protein is directly recognized by the antibody. The 90-kDa protein appears to be purified as a component of the nonactivated complex due to noncovalent association with the 100-kDa protein. Both the 100-kDa and 90-kDa components of the nonactivated complex become labeled with 35S when cells are grown in medium containing [35S]methionine. Using cells labeled in this manner, we have shown that activated (i.e. DNA-binding) cytosolic complexes, formed by warming either in intact cells or under cell-free conditions, contain only the 100-kDa protein. Complexes extracted from nuclei of warmed cells similarly contain only the 100-kDa protein. These results indicate that the 100-kDa and 90-kDa components of nonactivated complexes separate upon activation. Purification of nonactivated complexes from cells grown in medium containing [32P]orthophosphoric acid indicates that both the 100-kDa and 90-kDa components are phosphoproteins which can be labeled with 32P. Therefore, resolution of the two proteins will be essential in order to determine whether the receptor is dephosphorylated on activation.     

The antiprogesterone RU486 stabilizes the heterooligomeric, non-DNA-binding, 8S-form of the rabbit uterus cytosol progesterone receptor

The salt-induced (0.3 M KCl) transformation of the non-transformed, heterooligomeric 8S-form of the rabbit uterus cytosol progesterone receptor (PR) was analyzed by density gradient ultracentrifugation (8S----4S conversion) and DNA-cellulose chromatography (non-binding----binding forms). After 1 h treatment at 2 C, greater than 90% of agonist (R5020 or Org2058)-PR complexes were transformed, contrary to antagonist (RU486)-PR complexes, which did not undergo any transformation. Thus, there is stabilization of the non-transformed receptor form by RU486 as compared to the effect of agonist binding. The hydrodynamic parameters of both agonist- and antagonist-bound non-transformed receptors were similar and the calculated Mr were approximately 283,000 and approximately 293,000, respectively. In both cases, purification indicated the presence of a 90-kD non-hormone-binding protein associated with the hormone binding unit(s). Transformation of RU486-PR complexes occurred after exposure to high salt at increased temperature and was correlated to the dissociation of the 90-kD protein from the receptor. Both agonist- and antagonist-bound transformed forms of PR had apparent similar affinities for DNA-cellulose. Molybdate-stabilized and KCl-treated RU486-PR complexes were more stable, as assessed by steroid binding, than the corresponding R5020-PR complexes, arguing in favor of a stabilizing effect of both the 90-kD protein and RU486 against inactivation. These cell-free experiments support the concept that RU486 in the rabbit uterus system stabilizes the 8S non-DNA binding, non-transformed form of the receptor at low temperature. The possibility that impaired dissociation of the heterooligomeric receptor form is involved in the antiprogesterone activity of RU486 is discussed.     

Degradation without apparent change in size of molybdate-stabilized nonactivated glucocorticoid-receptor complexes in rat thymus cytosol

We have investigated the stability of the [3H]dexamethasone 21-mesylate-labeled nonactivated glucocorticoid-receptor complex in rat thymus cytosol containing 20 mM sodium molybdate. Cytosol complexes were analyzed under nondenaturing conditions by gel filtration chromatography in the presence of molybdate and under denaturing conditions by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. When analyzed under nondenaturing conditions, complexes from fresh cytosol and from cytosol left for 2 h at 3 degrees C eluted from gel filtration as a single peak of radioactivity with a Stokes radius of approximately 7.7 nm, suggesting that no proteolysis of the complexes had occurred in either cytosol. When analyzed under denaturing conditions, however, whereas the fresh cytosol gave a receptor band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis at Mr approximately 90,000 (corresponding to the intact complex), the cytosol that had been left for 2 h at 3 degrees C gave only a fragment (Mr approximately 50,000). This fragment, just as the intact complex, could be thermally activated to a DNA-binding form. Proteolysis of the receptor could be blocked by preparing the cytosol in the presence of EGTA, leupeptin, or a heat-stable factor present in the cytosol of rat liver and WEHI-7 mouse thymoma cells. From these results we conclude: (i) 20 mM molybdate does not protect the nonactivated glucocorticoid-receptor complex present in rat thymus cytosol against proteolysis under conditions which are commonly used for cell-free labeling of the receptor, and (ii) the demonstration of a Stokes radius of approximately 8 nm for the nonactivated glucocorticoid-receptor complex is not sufficient to indicate that the receptor complex is present in its intact form.     

Chemical cross-linking of heteromeric glucocorticoid receptors

Glucocorticoid receptors of wild-type and nti ("increased nuclear transfer") mutant S49.1 mouse lymphoma cells exist in extracts under low-salt conditions predominantly as high molecular weight species (Mr greater than or equal to 300,000). These receptor-hormone complexes are unable to bind to DNA. High salt (300 mM KCl) produces dissociated receptors of Mr 116,000 and 60-A Stokes radius (wild type) and Mr 60,000 and 38-A Stokes radius (nti mutant), both of which bind to DNA. We used reaction with bifunctional N-hydroxysuccinimide esters as well as oxidation with Cu2+/o-phenanthroline to stabilize the high molecular weight structures. These cross-linked complexes do not interact with DNA, but reductive cleavage again produces the dissociable receptor forms and restores their ability to bind to DNA. The protein modifying reagents iodoacetamide and diethyl pyrocarbonate also produce stabilized high molecular weight receptor complexes. Cross-linking of the high molecular weight receptor forms can also be achieved in intact cells. Immunochemical techniques were used to prove that the complexes cross-linked either in vivo or in cell extracts do contain the heat shock protein of Mr 90,000 as a common constituent. The data show that the high molecular weight receptor complexes are preexisting in intact cells and that dissociation generates DNA binding ability.     

Glucocorticoid receptor structure as probed by endogenous proteases

Transformation of the glucocorticoid-receptor complex by heating the cytosol in the presence of calcium is accompanied by formation of a series of truncated complexes, of which DI and DIIc are the major members. Formation of DIIc (but not of DI) is inhibited by leupeptin, and the intact transformed complex DIIa appears instead. Estimation of the molecular weights and Stokes' radii of all major complexes revealed that forms DI and DIIc have the same Mr, 48 kDa, but differ in shape, and appear to be digestion products generated by cleavage at the same site. Proteolysis of glucocorticoid receptor, covalently labelled with [3H]dexamethasone mesylate in rat thymus and brain cytosol, corroborated these findings and further implied that DI is the product of digestion of the non-transformed form of the receptor. Covalently labelled receptor fragments, related to the products formed when cytosol is heated, are detected in the nuclei of thymocytes, implying that the same proteolytic cleavages sites are involved in receptor turnover. Cleavage sites in the non-transformed covalently labelled receptor were identified in the "stepladder" of fragments of Mr, 85, 65, 49, 35, 27-30 kDa, generated in the absence of calcium, with an additional 78 kDa fragment in its presence. In the transformed conformation, two of the cleavage sites giving rise to the 65 and 35 kDa fragments, appear to be protected. It is speculated that the change in the proteolytic susceptibility of the cleavage site for the 35 kDa fragment relates to the "unmasking" of enhancer-activating and/or DNA-binding receptor functions previously postulated.     

Effects of molybdate on steroid receptors in intact GH1 cells. Evidence for dissociation of an intracellular 10 S receptor oligomer prior to nuclear accumulation

Treatment of intact GH1 cells with sodium molybdate inhibits the subsequent rate of nuclear accumulation of hormone-occupied glucocorticoid and estrogen receptors. Cells were incubated at 23 degrees C for 1 h with 30 mM molybdate and then for up to 30 min with [3H]triamcinolone acetonide or [3H]estradiol in the continued presence of molybdate. Although molybdate did not affect the rate of receptor occupancy with either steroid, cells treated with molybdate had more occupied cytosolic and fewer occupied nuclear receptors than control cells. For the glucocorticoid receptor, cells treated with molybdate had more 10 S and fewer 4 S cytosolic receptors than control cells. In low salt cytosol molybdate inhibits the temperature-mediated subunit dissociation of occupied 10 S glucocorticoid receptor. These results suggest that a hormone-mediated dissociation of an intracellular 10 S oligomeric glucocorticoid receptor form to its 4 S subunits is required prior to accumulation of occupied receptors in the nuclear fraction. In cells incubated at 37 degrees C for 1 h or longer with [3H]triamcinolone acetonide, molybdate shifts the steady state intracellular distribution of receptor toward the 10 S cytosolic receptor form, consistent with the interpretation that molybdate affects the rapidly exchanging subunit equilibrium between the 10 S and 4 S cytosolic forms by slowing the rate of 10 S receptor dissociation. Molybdate prevents loss of glucocorticoid-occupied 10 S but not 4 S receptors in heated cytosol by stabilizing the relatively protease-resistant 10 S receptor. Since molybdate stabilizes 10 S oligomeric steroid receptors in vitro, the effects of molybdate on nuclear accumulation of occupied receptors in intact cells support the intracellular existence and physiological relevance of 10 S glucocorticoid and estrogen receptors. These results support a general model for steroid receptor activation in which binding of hormone promotes dissociation of intracellular 8-10 S oligomeric receptors to their DNA-binding subunits.     

Structure and properties of the cellular receptor for transforming growth factor type beta

Swiss 3T3 cells respond to picomolar concentrations of type beta transforming growth factor (TGF-beta) with a dose-dependent increase in the formation of colonies in soft agar, a decrease in the growth of cells in monolayer culture, and changes in morphology. This indicates that these cells have functional TGF-beta receptors able to mediate a biological response. Binding analysis revealed a single class of TGF-beta binding sites (80 000 per cell) with a Kd approximately 50 pM. Receptors were affinity-labeled by covalent attachment to 125I-TGF-beta with bis(sulfosuccinimidyl) suberate (BS3). The complexes formed were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of 100 mM dithiothreitol and migrated as Mr approximately 180 000 complexes in 3-10% linear gradient gels. The apparent size of these complexes was larger in gels with a higher percentage of acrylamide. The labeling of the 125I-TGF-beta-receptor complexes was inhibited by the presence of excess unlabeled TGF-beta but was unaffected by other growth factors. These complexes could be formed by cross-linking whole cells, intact membranes, or solubilized membranes, demonstrating that the TGF-beta receptor is located on the plasma membrane and can be solubilized without destruction of its ability to bind TGF-beta. A larger Mr approximately 360 000 complex was present in 3-10% linear gradient gels without reduction or after extensive cross-linking, suggesting that the receptor consists of two subunits of similar size attached by disulfide bonds. Since BS3 is membrane-impermeable, at least a portion of both subunits is located on the outer surface of the plasma membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

Multimeric structure of the tumor necrosis factor receptor of HeLa cells

The tumor necrosis factor (TNF) receptor of HeLa cells was solubilized in Triton X-100 and characterized by gel filtration, affinity labeling, and ligand blotting studies. Receptors solubilized with Triton X-100 eluted in gel filtration as a major peak of Mr = 330,000 and retained high affinity binding (KD = 0.25 nM). Affinity labeling of soluble receptor/125I-TNF complexes using the reversible, bifunctional bis[2-(succinimidooxycarbonyl-oxy)ethyl] sulfone resulted in the formation of cross-linked species of Mr = 310,000, 150,000-175,000, 95,000, and 75,000. The formation of these complexes was competitively inhibited by unlabeled TNF. Partial reversal of cross-linking in these complexes and their analysis by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) resolved 125I-TNF dimers cleaved from the 95,000 band and 125I-TNF monomer cleaved from the 75,000 band, providing evidence for a Mr approximately 60,000 subunit. In addition, the 95,000 and 75,000 bands were resolved as components of larger complexes (Mr = 150,000-175,000), which presumably contain two receptor subunits. The Mr 95,000 and 75,000 bands were also released from the Mr 310,000 complex by reduction with dithiothreitol, suggesting a role for disulfide bond stabilization. To investigate the association of the putative receptor subunits, Triton X-100 extracts from HeLa membranes were fractionated by SDS-PAGE without reduction and transferred electrophoretically to nylon membranes for TNF binding assays. Only two bands of Mr = 60,000 and 70,000 specifically bound TNF, and higher Mr binding activity was not observed. These results indicate that TNF receptors in HeLa cells are high molecular weight complexes containing Mr = 60,000 and 70,000 subunits each capable of binding TNF and that the complexes are primarily stabilized by non-covalent, hydrophobic interactions.     

Reconstitution of the voltage-sensitive calcium channel purified from skeletal muscle transverse tubules

The purified calcium antagonist receptor of the voltage-sensitive calcium channel from skeletal muscle transverse tubule membrane consists of three subunits: alpha with Mr 135 000, beta with Mr 50 000, and gamma with Mr 33 000. Purified receptor preparations were incorporated into phosphatidylcholine (PC) vesicles by addition of PC in 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate and removal of detergent by molecular sieve chromatography. Forty-five percent of the alpha, beta, and gamma polypeptides and the [3H]dihydropyridine/receptor complex were recovered in association with PC vesicles. The rate of dissociation of the purified and reconstituted dihydropyridine/receptor complex was identical with that in T-tubule membranes, and allosteric modulation by verapamil and diltiazem was retained. The reconstituted calcium antagonist receptor, when occupied by the calcium channel activator BAY K 8644, mediated specific 45Ca2+ and 133Ba2+ transport into the reconstituted vesicles. 45Ca2+ influx was blocked by the organic calcium antagonists PN200-110 (K0.5 = 0.2 microM), D600 (K0.5 = 1.0 microM), and verapamil (K0.5 = 1.5 microM) and by inorganic calcium channel antagonists (La3+ greater than Cd2+ greater than Ni2+ greater than Mg2+) as in intact T-tubules. A close quantitative correlation was observed between the presence of the alpha, beta, and gamma subunits of the calcium antagonist receptor and the ability to mediate 45Ca2+ or 133Ba2+ flux into reconstituted vesicles. Comparison of the number of reconstituted calcium antagonist receptors and functional channels supports the conclusion that only a few percent of the purified calcium antagonist receptor polypeptides are capable of mediating calcium transport as previously demonstrated for calcium antagonist receptors in intact T-tubules.     

Analysis of the glucocorticoid antagonist action of dexamethasone 21-mesylate in HeLa S3 cells

Several properties of human glucocorticoid receptors complexed to the synthetic glucocorticoid agonists dexamethasone (DEX) and triamcinolone acetonide (TA) and the antagonist dexamethasone 21-mesylate (DM) are compared in an attempt to define the mode of action of DM. Both DEX and TA induce an increase in alkaline phosphatase activity in HeLa S3 cells. Not only is DM without effect on alkaline phosphatase activity at concentrations as great as 10(-7) M, it blocks the action of DEX and TA on enzyme induction, thus acting as a pure antagonist in this system. DM-receptor complexes, like agonist-receptor complexes, are recovered in the cytosol when cells are incubated with ligand at 0 degrees C but are recovered from the nucleus when incubation is shifted to 37 degrees C, suggesting that activation of the antagonist-receptor complex occurs in vivo. The molecular species that undergoes this temperature-dependent shift from the cytosolic compartment to the nuclear compartment exhibits saturable binding to the antagonist. Both the cytosolic and nuclear species exhibit a relative molecular mass of approximately equal to 94,000 Daltons when analysed by SDS-polyacrylamide gel electrophoresis. Receptors labeled in intact cells with [3H]DM at 0 degrees C sediment at approximately 8S in sucrose gradients, shifting to 4S when the gradients contain 0.4 M KCl. DEX- and TA-labeled receptors show the same sedimentation behavior, which has been accepted as one criterion of receptor subunit dissociation, or activation.     

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.     

Association of the glucocorticoid receptor binding subunit with the 90K nonsteroid-binding component is stabilized by both steroidal and nonsteroidal antiglucocorticoids in intact cells

The interaction of various antiglucocorticoids with the glucocorticoid receptor from intact rat thymocytes was investigated. Reversible antiglucocorticoids (RU 486, cortexolone, progesterone) underwent more limited nuclear transfer than potent glucocorticoids (dexamethasone, triamcinolone acetonide, progesterone). This behavior was correlated with an impeded dissociation of cytosolic antiglucocorticoid receptor complexes preformed in intact cells, as assayed by high-performance size exclusion chromatography in physiological conditions (i.e., isotonic molybdate-free buffer). Antagonist-receptor complexes remained in a 7-8-nm form whatever the antiglucocorticoid tested (including dexamethasone mesylate and trifluoroperazine, a nonsteroidal antiglucocorticoid) and the incubation time at 37 degrees C, whereas agonist-receptor complexes were rapidly converted into 5-nm species. This stabilization was not detectable by conventional sucrose gradient centrifugation because of artifactual dissociation of untransformed complexes, a pitfall overcome by resorting to vertical tube centrifugation. Moreover, the low amount of nuclear antiglucocorticoid receptor complexes was also in the undissociated form, in contrast with nuclear agonist-receptor complexes. Immunological probes demonstrated that the 90-kDa non-steroid-binding component was associated with the antiglucocorticoid-stabilized receptor. Thus, whatever their chemical structure and their affinity for the receptor, antiglucocorticoids stabilize the oligomeric form of the glucocorticoid receptor in intact cells. Our data, demonstrating for the first time that all antiglucocorticoids probably act via a common mechanism, suggest a key role for subunit dissociation during in vivo receptor activation.