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.     

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.     

A dynamic model of glucocorticoid receptor phosphorylation and cycling in intact cells

Glucocorticoid receptors have been proposed to undergo an ATP-dependent recycling process in intact cells, and a functional role for receptor phosphorylation has been suggested. To further investigate this possibility we have examined the phosphate content of the steroid-binding protein of all glucocorticoid receptor forms which have been isolated from WEHI-7 mouse thymoma cells. By labeling of intact cells with 32Pi for 18-20 h in the absence of hormone, covalent binding of [3H]dexamethasone 21-mesylate, immunopurification and SDS-PAGE analysis, the steroid binding protein was found to contain, on average, 2-3 phosphates as phosphoserine. One third of the phosphates were associated with proteolytic fragments encompassing the C-terminal steroid-binding domain. The central DNA-binding domain was not phosphorylated, leaving the other two thirds of the phosphates localized in the N-terminal domain. The phosphate content of various receptor forms from cells incubated with 32Pi and [35S]methionine was compared using 35S to normalize for quantity of protein. In ATP-depleted cells a non-steroid-binding form of the receptor (the "null" receptor) is found tightly bound to the nucleus, even without steroid. The phosphate content of null receptors was two thirds that of cytosolic receptors from normal cells, suggesting phosphorylation-dependent cycling in the absence of hormone. Addition of glucocorticoid agonists, but not antagonist, to 32P- and 35S-labeled cells increased the phosphate content of the cytosolic steroid-binding protein up to 170%, indicating an average increase in the phosphates from about 3 to 5. After 30 min of hormone treatment the phosphate content of the steroid-binding protein of cytosolic activated (DNA-binding) and nonactivated receptors, and that of nuclear receptors extractable with high salt concentrations and/or DNase I digestion, was the same. No change in the phosphate content of the 90-kDa heat shock protein associated with unliganded and nonactivated receptors was detected following association of the free protein with the receptor and following hormone binding of the receptor. Analysis of the unextractable nuclear receptors indicated that they contained less phosphate (60% of that of cytosolic receptors), similarly to null receptors, indicating that dephosphorylation is associated with the unextractable nuclear fraction. The rate of hormone-dependent phosphorylation appeared to be much faster than the rate of dephosphorylation in the presence of hormone, the latter determined by a chase of the 32P label with unlabeled phosphate. Our results show that phosphorylation and dephosphorylation are involved in the mechanism of action of glucocorticoid receptors.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structure of the glucocorticoid receptor in intact cells in the absence of hormone.

The nonactivated glucocorticoid receptor (Mr approximately 330,000, Strokes radius = 82 A) contained in cell extracts and complexed with a steroidal ligand was previously investigated by chemical cross-linking. It was identified as a heterotetramer composed of one receptor polypeptide, two molecules of the 90-kDa heat shock protein hsp90, and one 59-kDa protein subunit (Rexin, M., Busch, W., and Gehring, U. (1991) J. Biol. Chem. 266, 24601-24605). We now have used the cross-linking technique to investigate the receptor structure in intact WEHI-7 mouse lymphoma cells at 37 degrees C and under steroid-free conditions. Using immunochemical methods we show that the receptor present in whole cells likewise exists as a high molecular weight structure of Strokes radius 82 A. It has a subunit composition identical to that of the nonactivated receptor-steroid complex in cell extracts. This is the first account of a steroid hormone receptor in its native state as it is contained in target cells under physiological conditions and before a hormonal signal is received.     

Characterization of nonactivated and activated glucocorticoid-receptor complexes from intact rat thymus cells

In cells exposed to glucocorticoids at 37 degrees C activated glucocorticoid-receptor complexes (complexes with affinity for nuclei and DNA) are formed after nonactivated complexes. Activation thus appears to be an obligatory physiological process. To investigate this process we have characterized cytoplasmic complexes formed in rat thymocytes at 0 and 37 degrees C. Complexes in cytosols stabilized with molybdate were analyzed by sucrose gradient centrifugation and by chromatography on DNA-cellulose, DEAE-cellulose, and agarose gels. Two major complexes were observed: the nonactivated complex, eluted from DEAE at approximately 200 mM KCl, was formed at 0 and 37 degrees C, gave S20,w = 9.2 S, Stokes radius = 8.3 nm, and calculated Mr = 330,000; the activated complex, eluted from DEAE at approximately 50 mM KCl, appeared only at 37 degrees C, gave S20,w = 4.8 S, Stokes radius = 5.0 nm, and Mr = 100,000. A third, minor complex, probably mero-receptor, which appeared mainly at 37 degrees C, bound to neither DNA nor DEAE, and gave S20,w = 2.9 S, Stokes radius = 2.3 nm, and Mr = 27,000. With three small columns in series (DNA-cellulose, DEAE-cellulose and hydroxylapatite), the three complexes can be separated in 5-10 min. By this method we have examined the stability of complexes under our conditions. We conclude that in intact thymus cells glucocorticoid-receptor complexes occur principally in two forms, nonactivated and activated, and that activation is accompanied by a large reduction in size. The origin of the mero-receptor complex remains uncertain.     

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.     

Tetrameric structure of centromeric nucleosomes in interphase Drosophila cells

Centromeres, the specialized chromatin structures that are responsible for equal segregation of chromosomes at mitosis, are epigenetically maintained by a centromere-specific histone H3 variant (CenH3). However, the mechanistic basis for centromere maintenance is unknown. We investigated biochemical properties of CenH3 nucleosomes from Drosophila melanogaster cells. Cross-linking of CenH3 nucleosomes identifies heterotypic tetramers containing one copy of CenH3, H2A, H2B, and H4 each. Interphase CenH3 particles display a stable association of approximately 120 DNA base pairs. Purified centromeric nucleosomal arrays have typical “beads-on-a-string” appearance by electron microscopy but appear to resist condensation under physiological conditions. Atomic force microscopy reveals that native CenH3-containing nucleosomes are only half as high as canonical octameric nucleosomes are, confirming that the tetrameric structure detected by cross-linking comprises the entire interphase nucleosome particle. This demonstration of stable half-nucleosomes in vivo provides a possible basis for the instability of centromeric nucleosomes that are deposited in euchromatic regions, which might help maintain centromere identity.     

Evidence from pulse-chase labeling studies that the antiglucocorticoid hormone RU486 stabilizes the nonactivated form of the glucocorticoid receptor in mouse lymphoma cells

A pulse-chase labeling technique was used to determine the properties of glucocorticoid receptors occupied by the antiglucocorticoid hormone RU486 in S49.1 mouse lymphoma cells. Cells were pulse-labeled with [35S]methionine and then at the beginning of the chase, either no hormone (control), dexamethasone, or RU486 was added to cells. At 4 h into the chase, cytosol was prepared and receptors were immunoadsorbed to protein A-Sepharose using the BuGR2 antireceptor antibody. Immunoadsorbed proteins were resolved by gel electrophoresis and analyzed by autoradiography. The 90 kDa heat shock protein (hsp90) coimmunoadsorbed with receptors from control cells when protein A-Sepharose pellets were washed with 250 mM NaCl but not when protein A-Sepharose pellets were washed with 500 mM NaCl, indicating that hsp90-receptor complexes are disrupted by a high concentration of salt in the absence of molybdate. hsp90 coimmunoadsorbed with receptors from RU486-treated cells even when protein A-Sepharose pellets were washed with 500 mM NaCl, indicating that RU486 stabilizes the association of hsp90 with the glucocorticoid receptor. In contrast, hsp90 did not coimmunoadsorb with receptors from dexamethasone-treated cells, consistent with earlier evidence that hsp90 dissociates from the receptor when the receptor binds glucocorticoid hormone. Dexamethasone induced a rapid quantum decrease in the amount of normal receptor recovered from cytosol but did not induce a decrease in the amount of nuclear transfer deficient receptor recovered from cytosol, consistent with tight nuclear binding of normal receptors occupied by dexamethasone. In contrast, RU486 did not induce a quantum decrease in the recovery of normal receptors from cytosol, indicating that receptors occupied by RU486 are not tightly bound in the nuclear fraction. We conclude that the antiglucocorticoid hormone RU486, in contrast to the glucocorticoid hormone dexamethasone, stabilizes the association between the glucocorticoid receptor and hsp90. The decreased affinity of receptors occupied by RU486 for the nuclear fraction may be due to their association with hsp90 and may account for the failure of RU486 to exert agonist activity.     

Molybdate effect on the glucocorticoid receptor in cell-free systems and intact lymphocytes

The effect of sodium molybdate on the stability and activation of the glucocorticoid receptor from chick and rat thymus were investigated. Molybdate, at a concentration range of 1–10 mM, blocked denaturation of the cytosol receptor by elevated (25 and 37°C) temperatures. This effect could be observed only with the aggregated (low-salt) form of the receptor. Molybdate also inhibited transformation of the receptor-hormone complex to the DNA-binding state which occurs either with incubation at 25°C or with salt treatment. The inhibitory effect of molybdate could be observed only on the non-activated receptor; nuclear- and DNA-binding of the activated receptor was not significantly changed by molybdate. Both effects were concentration-dependent. Molybdate had no effect on the activation of the partially purified glucocorticoid receptor. Molybdate effect was also examined using intact lymphocytes. Sodium molybdate had no effect either on the steroid binding of whole cells or on the nuclear transfer of the hormone-receptor complex. While the mechanism of molybdate action remains unknown the results of experiments on purified receptor suggest that molybdate does not act directly on the receptor molecule; rather through some cytosol factor(s). However, these effects could only be seen in cell-free experiments, and not during the conditions of the living cell.     

糖皮质激素受体的结构和功能

近年来已克隆出人、大鼠和小鼠糖皮质激素受体的cDNA,并利用定点突变等技术分析了受体结构和功能的关系。还利用小鼠乳腺瘤病毒、人金属硫蛋白II_A基因等详细研究了受体和DNA的相互作用,对糖皮质激素的诱导蛋白也进行了深入研究。     

Direct demonstration of glucocorticoid receptor phosphorylation by intact L-cells

Glucocorticoid-sensitive L-cells were cultured for 18 h in the presence of [32P]orthophosphate and steroid-binding proteins of cytosol were separated by affinity chromatography and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and isoelectric focusing. Cytosol contains a major phosphoprotein of Mr = 92,000 and a minor phosphoprotein of Mr = 100,000, both of which bind glucocorticoids in a stereospecific, high affinity manner and have the same Mr as glucocorticoid receptor species that have been covalently labeled with the site-specific affinity ligand [3H] 9 alpha-fluoro-16-methyl-11 beta,17 alpha,21-trihydroxypregna-1, 4-diene-3,20-dione 21-mesylate. Cytosol from 32P-labeled, glucocorticoid-resistant L-cells possessing 5% of the steroid-binding capacity of sensitive cells contains very little of the Mr = 92,000 phosphoprotein and none of the Mr = 100,000 phosphoprotein. These observations provide strong evidence that the glucocorticoid receptor is phosphorylated by intact L-cells. The Mr = 92,000 protein is phosphorylated on serine and it can be resolved into two species using isoelectric focusing, consistent with the proposal that there is more than 1 phosphorylated serine/steroid-binding unit. The glucocorticoid-resistant L-cell line produces a unique phosphoprotein of Mr = 104,000 that is recovered in variable amounts after affinity chromatography. It is not known whether this phosphoprotein is a separate gene product or whether it represents a precursor with weak steroid-binding activity that is not cleaved in the resistant cell to the high affinity, Mr = 92,000 mature receptor form.     

Kinetics of dexamethasone binding to the glucocorticoid receptor of intact erythroid cells from rat fetal liver

The erythroid cells from the rat fetal liver have been shown to possess a receptor for glucocorticoids. In the present work, the characteristics of [3H]dexamethasone binding have been studied on intact cells, in order to minimize receptor degradation, and at 4 degrees C, in order to prevent the activation of the hormone-receptor complex. Dissociation kinetics were those of a first-order reaction and the value of the rate constant of dissociation was similar to the values available in the literature. When studied at low concentrations of the ligand and using short-term incubations, association kinetics were apparently those of a simple bimolecular reaction. But at high ligand concentrations and/or using long-term incubations, association kinetics indicated a more complex reaction. Our results were compatible with the model proposed by Pratt W.B., Kaine J.L. and Pratt V.D. (J. Biol. Chem. 250 (1975) 4584-4591) for cytosolic preparations. This model implies the rapid formation of a transient unstable form of the complex, further converted into a stable form with slower kinetics. Equilibrium dissociation constant of the first (rapid) reaction was 80 microM and the rate constant of 'stabilization' was of the order of 70 X 10(-3) min-1. These values agree with the results of Pratt et al. relative to a cytosolic preparation from rat thymocytes.     

Different states of glucocorticoid receptors in intact cells and cytosol preparations

Binding of the glucocorticoid dexamethasone was studied in intact cells of the mouse lymphoma lines S49. 1, WEHI-7, WEHI-22, and WEHI-112. The number of binding sites per cell varied from 13 000 to 130 000 depending on the cell line. The equilibrium dissociation constant at 37° was in the range of 10 nM. When dexamethasone binding was investigated at 0° in cytosol preparations of the same cell lines significantly lower receptor levels were found and the dissociation constants were about one order of magnitude lower than those determined in whole cells. The data suggest that glucocorticoid receptors exist in different states in intact cells and cell extracts.     

Melatonin prevents glucocorticoid inhibition of cell proliferation and toxicity in hippocampal cells by reducing glucocorticoid receptor nuclear translocation

Glucocorticoids are the main product of the adrenal cortex and participate in multiple cell functions as immunosupressors and modulators of neural function. Within the brain, glucocorticoid activity is mediated by high-affinity mineralocorticoid and low-affinity glucocorticoid receptors. Among brain cells, hippocampal cells are rich in glucocorticoid receptors where they regulate excitability and morphology. Also, elevated glucocorticoid levels suppress hippocampal neurogenesis in adults. The pineal neuroindole, melatonin, reduces the affinity of glucocorticoid receptors in rat brain and prevents glucocorticoid-induced apoptosis. Here, the ability of melatonin to prevent glucocorticoid-induced cell death in hippocampal HT22 cells was investigated in the presence of neurotoxins. Results showed that glucocorticoids reduce cellular growth and also enhance sensitivity to neurotoxins. We found a G(1) cell cycle arrest mediated by an increase of cyclin/cyclin-dependent kinase inhibitor p21(WAF1/CIP1) protein after dexamethasone treatment and incremental change in amyloid beta protein and glutamate toxicity. Melatonin prevents glucocorticoids inhibition of cell proliferation and reduces the toxicity caused by glucocorticoids when cells were treated with dexamethasone in combination with neurotoxins. Although, melatonin does not reduce glucocorticoid receptor mRNA or protein levels, it decreases receptor translocation to nuclei in these cells.     

Steroid-induced nuclear binding of glucocorticoid receptors in intact hepatoma cells

Some of the early steps of steroid hormone action have been studied in cultured hepatoma cells, in which glucocorticoids induce tyrosine aminotransferase. The hypothesis that inducer steroids promote the binding of specific cytoplasmic receptors to the cell nucleus has been examined in intact cells.Binding of steroids such as dexamethasone and cortisol results in a loss of most of the receptor sites from the cytoplasm. This coincides with the binding of an equivalent number of steroid molecules in the nucleus. Both processes occur concomitantly, even when their kinetics are altered by reducing the temperature. When the inducer is removed from the culture, steroid dissociates from the nucleus while the level of cytoplasmic receptor returns to normal, even if protein or RNA synthesis is inhibited. These results suggest that nuclear binding of glucocorticoids is due to the association with the nucleus of the cytoplasmic receptor-steroid complex itself and make it unlikely that the receptor acts as a mere carrier for the intracellular transfer of the steroid.Steroids that differ in their effects on tyrosine aminotransferase induction were also studied. In contrast to those bound with inducer steroids, receptors complexed with the anti-inducer progesterone did not leave the cytosol. Further, a suboptimal inducer (deoxycorticosterone) produced an intermediate level of depletion. Thus, the biological effect of different classes of steroids can be related to their capacity to promote nuclear binding of the receptor. These data support a model proposed earlier, according to which the receptor is an allosteric regulatory protein directly involved in the hormone action, under the control of specific steroid ligands. They further suggest that the conformational state influenced by the inducer is such that a nuclear binding site on the receptor is exposed.Evidence is also presented that a distinct reaction takes place between the binding of the steroid to the receptor and the association of the complex with the nucleus. At 0 °C, this change is rate-limiting. It could correspond to the “activation” of receptor-steroid complexes known to be required for binding of the complexes by isolated nuclei, and thus represent an additional step in hormone action.     

The biopotency of dexamethasone at causing hepatic glucocorticoid receptor down-regulation in the intact mouse

The effect of dexamethasone administered intraperitoneally on hepatic glucocorticoid receptor binding capacity was measured in adrenalectomized male Swiss Webster mice. The liver content of dexamethasone was also measured. Within 30 min of a 5 micrograms injection, the hepatic content of dexamethasone reached a maximum and fell quickly thereafter. By 6 h the hepatic content of dexamethasone had decreased to 25% of maximum and by 24 h the liver did not contain detectable dexamethasone. At this 24 h point, the glucocorticoid binding capacity was reduced to 50% of control. This decrease reflected down-regulation. Other studies revealed that only glucocorticoids caused this effect and doses of dexamethasone as low as 0.5-5 ng caused a clear down-regulation in binding capacity. Doses that cause receptor down-regulation are also effective at inducing tyrosine aminotransferase, suggesting that dexamethasone down-regulates its own receptors over a physiologically meaningful dosage range. It is concluded that dexamethasone causes a dose-dependent down-regulation of the glucocorticoid receptor in mouse liver.     

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.