Characterization of glucocorticoid receptor in HeLa-S3 cells

Glucocorticoid receptor of the human cell line HeLa-S3 has been characterized and has been compared to rat and to mouse glucocorticoid receptors. If HeLa cells were lysed in the absence of glucocorticoid, glucocorticoid receptor was isolated in a nonactivated form, which did not bind to DNA-cellulose. If HeLa cells were preincubated with glucocorticoid, glucocorticoid receptor was isolated in an activated, DNA-binding form. HeLa cell glucocorticoid receptor bound [3H]triamcinolone acetonide with a dissociation constant (KD = 1.3 nM at 0 degrees C) that was similar to those of mouse and rat glucocorticoid receptors. Similarly, the relative binding affinities for steroid hormones decreased in the order of triamcinolone acetonide greater than dexamethasone greater than promegestone greater than methyltrienolone greater than aldosterone greater than or equal to moxestrol. Nonactivated and activated receptors were characterized by high-resolution anion-exchange chromatography (FPLC), DNA-cellulose chromatography, and sucrose gradient centrifugation. Human, mouse, and rat nonactivated glucocorticoid receptors had very similar ionic and sedimentation properties. Activated glucocorticoid receptors were eluted at similar salt concentrations from DNA-cellulose columns but at different salt concentrations from the FPLC column. A monoclonal mouse anti-rat liver glucocorticoid receptor antibody [Westphal, H.M., Mugele, K., Beato, M., & Gehring, U. (1984) EMBO J. 3, 1493-1498] did not cross-react with HeLa cell glucocorticoid receptor. Glucocorticoid receptors of HeLa, HTC, and S49.1 cells were affinity labeled with [3H]dexamethasone and with [3H]dexamethasone 21-mesylate. The molecular weights of [3H]dexamethasone 21-mesylate labeled glucocorticoid receptors (MT 96 000 +/- 1000) were undistinguishable by polyacrylamide gel electrophoresis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activation of the human glucocorticoid receptor: evidence for a two-step model

The relationship between glucocorticoid receptor subunit dissociation and activation was investigated by DEAE-cellulose and DNA-cellulose chromatography of monomeric and multimeric [3H]triamcinolone acetonide ([3H]TA)-labeled IM-9 cell glucocorticoid receptors. Multimeric (7-8 nm) and monomeric (5-6 nm) complexes were isolated by Sephacryl S-300 chromatography. Multimeric complexes did not bind to DNA-cellulose and eluted from DEAE-cellulose at a salt concentration (0.2 M KCl) characteristic of unactivated steroid-receptor complexes. Monomeric [3H]TA-receptor complexes eluted from DEAE-cellulose at a salt concentration (20 mM KCl) characteristic of activated steroid-receptor complexes. However, only half of these complexes bound to DNA-cellulose. This proportion could not be increased by heat treatment, addition of bovine serum albumin, or incubation with RNase A. Incubation of monomeric complexes with heat inactivated cytosol resulted in a 2-fold increase in DNA-cellulose binding. Unlike receptor dissociation, this increase was not inhibited by the presence of sodium molybdate. Fractionation of heat inactivated cytosol by Sephadex G-25 chromatography demonstrated that the activity responsible for the increased DNA binding of monomeric [3H]TA-receptor complexes was macromolecular. These results are consistent with a two-step model for glucocorticoid receptor activation, in which subunit dissociation is a necessary but insufficient condition for complete activation. They also indicate that conversion of the steroid-receptor complex to the low-salt eluting form is a reflection of receptor dissociation but not necessarily acquisition of DNA-binding activity.     

Extraction of DNA-cellulose-bound glucocorticoid-receptor complexes with sodium tungstate

Glucocorticoid-receptor complex from rat liver cytosol, activated by warming at 23°C or fractionation with (NH₄)₂SO₄, was adsorbed over DNA-cellulose. This DNA-cellulose-bound [³H]triamcinolone acetonide-receptor complex was extracted in a dose-dependent manner by incubation with different concentrations of sodium tungstate. A 50% recovery of receptor was achieved with 5 mM sodium tungstate. Almost the entire glucocorticoid-receptor complex bound to DNA-cellulose could be extracted with 20 mM sodium tungstate. The [³H]triamcinolone acetonide released from DNA-cellulose following tungstate and molybdate treatment was found to be associated with a macromolecule, as seen by analysis on a Sephadex G-75 column. The glucocorticoid-receptor complex extracted by both the compounds sedimented as a 4 S entity of 5–20% sucrose gradients under low- and high-salt conditions. Addition of tungstate or molybdate to the preparations containing activated receptor had no effect on the sedimentation rate of receptor. However, addition of tungstate to non-activated receptor preparation caused aggregates of larger size. The tungstate-extracted glucocorticoid-receptor complex failed to rebind to DNA-cellulose even after extensive dialysis, whereas receptor in molybdate-extract retained its DNA-cellulose binding capacity.     

Cytosol glucocorticoid receptor in the neoplastic epithelial duct cell line from human salivary gland (HSG)

Neoplastic epithelial duct cell line from human salivary gland (HSG cell) contained cytosol glucocorticoid receptor. Scatchard analysis of cytosol indicated that the dissociation constant (Kd) was 5.6-6.5 nmol/l and the number of binding sites was 83-92 fmol/mg protein. A competitive assay showed that the binding sites for [3H]triamcinolone acetonide were specific to glucocorticoid. Glycerol density gradient centrifugation displayed that the [3H]triamcinolone acetonide receptor complexes sedimented in the 8.5 S region under low salt conditions and in the 4.2 S region under high salt condition (0.4 M KCl). The same high salt conditions induced an increased binding of [3H]triamcinolone acetonide complexes for DNA-cellulose.     

Activation of [3H]estradiol--and [3H]H1285-receptor complexes: effect of salt versus ATP on molybdate-stabilized estrogen receptors

The activation by salt or ATP of [3H]estradiol- and [3H]H1285-receptor complexes from rabbit uterus and their binding capacity to DNA-cellulose, phosphocellulose and ATP-Sepharose has been studied. The estrogen-receptor was prepared in 1 mM molybdate which stabilized the receptor; but both salt- and ATP-transformation of estrogen receptors occurred. The binding of molybdate-stabilized cytosol [3H]estradiol-receptor complexes to the various resins revealed that salt-activation by 0.3 M KCl caused the greatest binding (5-6-fold) to DNA-cellulose as compared to other resins. However, 5 mM ATP-dependent activation of receptor-complexes resulted in preferential binding to ATP-Sepharose. Activated cytosol [3H]H1285-receptor complexes bound all the resins to a lesser degree when compared to [3H]estradiol-receptor complexes. Partially purified receptor complexes also showed different resin-binding patterns for salt- and ATP-mediated activation. These findings suggest that salt-activation is different than ATP-activation. Further, the differential magnitude of [3H]estradiol- and [3H]H1285-receptor activation suggests that estrogen-receptor complexes are "fully" activated as compared to "partially" activated antiestrogen-receptor complexes.     

Activation of the rat liver cytosol glucocorticoid receptor by sephacryl S-300 filtration in the presence and absence of molybdate. Physical properties of the receptor and evidence for an activation inhibitor

The DNA-binding and physical properties of the rat liver cytosol glucocorticoid receptor were determined before and after Sephacryl S-300 filtration in the presence or absence of molybdate. Cytosol was prepared and labeled with [3H]triamcinolone acetonide in buffer containing molybdate. Prior to gel filtration, only 5 +/- 3% (mean +/- S.E.) of labeled receptors bound to DNA-cellulose. After gel filtration in the presence and absence of molybdate, the per cent of labeled receptors binding to DNA-cellulose was 57 +/- 10% and 83 +/- 1%, respectively. Nonreceptor fractions from the Sephacryl S-300 column contained a heat-stable factor which blocked receptor activation but did not block the binding of activated receptors to DNA-cellulose. The activation inhibitor eluted from the column in the region of the albumin standard, but after heating its size was considerably reduced (Mr less than 3500). Receptors activated by Sephacryl S-300 filtration underwent the same size changes in the presence or absence of molybdate. Prior to gel filtration, the S20,w of labeled receptors in the presence of molybdate was 9.2 +/- 0.2 S. After filtration in the presence and absence of molybdate, the S20,w of labeled receptors was 4.2 +/- 0.2 and 4.4 +/- 0.1 S, respectively. The Stokes radius (Rs) of labeled receptors after gel filtration in either the presence or absence of molybdate was 65 +/- 1 A. From the Rs and S20,w values, the molecular weight (Mr) of activated receptors was calculated to be 115,000 to 121,000, which was in close agreement with the Mr of affinity-labeled receptors determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

In vitro activation of rat cardiac glucocorticoid antagonist- versus agonist-receptor complexes

The synthetic antiglucocorticoid RU 38486 interacts with cardiac cytoplasmic glucocorticoid receptors and competes for in vitro binding with the potent agonist triamcinolone acetonide. In addition to binding to receptors with high affinity, RU 38486 also facilitates the in vitro conformational change in the receptor which is a consequence of the physiologically relevant activation step during which the receptor is converted from a non DNA- to a DNA-binding form. This ability of RU 38486 to promote receptor activation is reflected by both the appropriate shift in the elution profile of [3H]RU 38486-receptor complexes from DEAE-cellulose as well as by an increased binding of these complexes to DNA-cellulose. Although less effective than triamcinolone acetonide, RU 38486 promotes in vitro receptor activation under a variety of experimental conditions, including incubation of labeled cardiac cytosols at 25 degrees C for 30 min or at 15 degrees C for 30 min in the presence of 5 mM pyridoxal 5'-phosphate. Once thermally activated, the cardiac [3H]triamcinolone acetonide and [3H]RU 38486-receptor complexes bind to nonspecific DNA-cellulose with the same relative affinities, as evidenced by the fact that 50% of both activated complexes are eluted at approx. 215-250 mM NaCl. Thus, this pure antiglucocorticoid does promote, at least to some extent, many of the crucial in vitro events including high-affinity binding, activation, and DNA binding which have been shown to be required to elicit a physiological response in vivo.     

Activation of Glucocorticoid-Type II Receptor Complexes in Brain Cytosol Leads to an Increase in Surface Hydrophobicity as Determined by Hydrophobic Interaction Chromatography

Hydrophobic interaction chromatography has been used to demonstrate an increase in the surface hydrophobicity of [3H]triamcinolone acetonide ([3H]TA)-labeled type II receptors in mouse brain cytosol following transformation of these receptor complexes to the activated DNA-binding form. After removing unbound [3H]TA and molybdate (which prevents activation) by gel filtration, [3H]TA-type II receptors were activated by incubation at 22 degrees C for 20 min. Gel filtration was then used to remove newly dissociated steroid and to readjust the molybdate and/or KCl concentration. Unactivated and activated receptors were then added to propyl, butyl, pentyl, hexyl, octyl, decyl, and dodecyl alkyl agarose, phenyl agarose, or unmodified agarose columns equilibrated and eluted with buffers of various molybdate and KCl concentrations and/or other additions, including glycerol, ethylene glycol, and urea. Under high-salt conditions, activated receptors were retained longer than unactivated receptors run on butyl, pentyl, hexyl, and phenyl agaroses. With the longer alkyl chain columns, essentially none of the [3H]TA was eluted in association with receptor macromolecules. Removal of the remaining steroid required receptor denaturation with urea. Under low-salt conditions, both receptor forms were retained more avidly on all alkyl agarose columns; however, on phenyl agarose only activated receptors displayed this increased retention. Further studies revealed that optimal separation and subsequent recovery of unactivated and activated [3H]TA-type II receptor complexes were achieved on pentyl agarose columns equilibrated and eluted with buffers containing 50 mM molybdate and 600-1,200 mM KCl.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro activation of rat cardiac glucocorticoid antagonist-versus agonist-receptor complexes

The synthetic antiglucocorticoid RU 38486 interacts with cardiac cytoplasmic glucocorticoid receptors and competes for in vitro binding with the potent agonist triamcinolone acetonide. In addition to binding to receptors with high affinity, RU 38486 also facilitates the in vitro conformational change in the receptor which is a consequence of the physiologically relevant activation step during which the receptor is converted from a non DNA- to a DNA-binding form. This ability of RU 38486 to promote receptor activation is reflected by both the appropriate shift in the elution profile of [³H]RU 38486-receptor complexes from DEAE-cellulose as well as by an increased binding of these complexes to DNA-cellulose. Although less effective than triamcinolone acetonide, RU 38486 promotes in vitro receptor activation under a variety of experimental conditions, including incubation of labeled cardiac cytosols at 25°C for 30 min or at 15°C for 30 min in the presence of 5 mM pyridoxal 5′-phosphate. Once thermally activated, the cardiac [³H]triamcinolone acetonide and [³H]RU 38486-receptor complexes bind to nonspecific DNA-cellulose with the same relative affinities, as evidenced by the fact that 50% of both activated complexes are eluted at approx. 215–250 mM NaCl. Thus, this pure antiglucocorticoid does promote, at least to some extent, many of the crucial in vitro events including high-affinity binding, activation, and DNA binding which have been shown to be required to elicit a physiological response in vivo.     

Characterization of human glucocorticoid receptor complexes formed with DNA fragments containing or lacking glucocorticoid response elements

Sucrose density gradient shift assays were used to study the interactions of human glucocorticoid receptors (GR) with small DNA fragments either containing or lacking glucocorticoid response element (GRE) DNA consensus sequences. When crude cytoplasmic extracts containing [3H]triamcinolone acetonide [( 3H]TA) labeled GR were incubated with unlabeled DNA under conditions of DNA excess, a GRE-containing DNA fragment obtained from the 5' long terminal repeat of mouse mammary tumor virus (MMTV LTR) formed a stable 12-16S complex with activated, but not nonactivated, [3H]TA receptor. By contrast, if the cytosols were treated with calf thymus DNA-cellulose to deplete non-GR-DNA-binding proteins prior to heat activation, a smaller 7-10S complex was formed with the MMTV LTR DNA fragment. When similar experiments were conducted under conditions of large receptor excess, using 3' [32P]-MMTV LTR DNA, the trace quantity of DNA formed a stable 10-14S complex with DNA-cellulose pretreated cytosols or with untreated cytosols in the presence of excess Escherichia coli competitor DNA. If trace quantities of the 3' [32P]-MMTV LTR DNA were incubated with untreated crude cytosols, much larger complexes were formed, indicating the association of other cytosolic proteins with the MMTV LTR DNA fragment. Activated [3H]TA receptor from DNA-cellulose pretreated cytosols also interacted with two similarly sized fragments from pBR322 DNA, but with lower apparent affinities in the order MMTV LTR DNA fragment much greater than pBR322 fragment containing a single GRE DNA consensus sequence greater than non-GRE-containing pBR322 fragment.(ABSTRACT TRUNCATED AT 250 WORDS)     

Resolution of non-activated and activated androgen receptors based on differences in their hydrodynamic properties

This study shows that cytosolic androgen receptor of rat ventral prostate sediments at 10-11 S on conventional low salt sucrose density gradients (SDG), and at 4.6 S on high salt SDG, whether it is activated or not; inclusion of 10 mM Na2MoO4 in all buffers does not alter these sedimentation coefficients. In the presence of 50 mM Na2MoO4 non-activated and activated androgen receptors sediment in high salt SDG at 7-8 S and 4.6 S, respectively. Thus the presence of high concentrations of molybdate during centrifugation inhibits the KCl induced disaggregation of receptor into subunits. Similar effects are observed on Sephacryl-S200 gel filtration; in 50 mM MoO2-4 and 0.4 M KCl non-activated receptor has an estimated Stokes radius of 67 A; this value decreases to 52 A upon activation in the presence of proteolysis inhibitors; omission of molybdate during chromatography yielded 52 A and 27 A entities. Estimated mol. wts are 198,000 Daltons for the non-activated 67 A form and 98,000 Daltons for the activated 52 A receptor. Sodium molybdate (50 mM) prevents temperature (18 degrees C) and high ionic strength (0.4 M KCl) induced receptor activation. This inhibition was overcome by removing molybdate by centrifugal gel filtration, or by increasing the KCl concentration to 0.8 M. The inhibitory effects of molybdate on salt induced receptor disaggregation into activated subunits are no longer observed at pH greater than 7.4 or after chemical modification of sulfhydryl groups. Once androgen receptor has been disaggregated into its activated subunits the activated state is maintained even upon reassociation to 10-11 S aggregates in low salt. The relative concentrations of KCl and molybdate are critical; thus, 10 mM Na2MoO4/0.4 M KCl and 50 mM Na2MoO4/0.8-1.2 M KCl did not differentiate activated from non-activated androgen receptor based on their hydrodynamic properties. In the presence of 0.4 M KCl and 50 mM molybdate, however, the hydrodynamic properties of androgen receptor can be correlated with receptor activation.     

Effect of glucocorticoid on epidermal growth factor receptor in human salivary gland adenocarcinoma cell line HSG

Human salivary gland adenocarcinoma (HSG) cells treated with 10(-6) M triamcinolone acetonide for 48 h exhibited a 1.7- to 2.0-fold increase in [125I]human epidermal growth factor (hEGF) binding capacity as compared with untreated HSG cells. Scatchard analysis of [125I]EGF binding data revealed that the number of binding sites was 83,700 (+/- 29,200) receptors/cell in untreated cells and 160,500 (+/- 35,500) receptors/cell in treated cells. No substantial change in receptor affinity was detected. The dissociation constant of the EGF receptor was 0.78 (+/- 0.26).10(-9) M for untreated cells, whereas it was 0.93 (+/- 0.31).10(-9)M for treated cells. The triamcinolone acetonide-induced increase in [125I]EGF binding capacity was dose-dependent between 10(-9) and 10(-6)M, and maximal binding was observed at 10(-6)M. EGF receptors on HSG cells were affinity-labeled with [125I]EGF by use of the cross-linking reagent disuccinimidyl suberate (DSS). The cross-linked [125I]EGF was 3-4% of the total [125I]EGF bound to HSG cells. The affinity-labeled EGF receptor was detected as a specific 170 kDa band in the autoradiograph after SDS-polyacrylamide gel electrophoresis (SDS-PAGE). Densitometric analysis revealed that triamcinolone acetonide amplified the intensity of this band 2.0-fold over that of the band of untreated cells. EGF receptor synthesis was also measured by immunoprecipitation of [3H]leucine-labeled EGF receptor protein with anti-hEGF receptor monoclonal antibody. Receptor synthesis was increased 1.7- to 1.8-fold when HSG cells were treated with 10(-8)-10(-6)M triamcinolone acetonide for 48 h. When the immunoprecipitated, [35S]methionine-pulse-labeled EGF receptor was analyzed by SDS-PAGE and fluorography, the newly synthesized EGF receptor was detected at the position of 170 kDa; and treatment of HSG cells with triamcinolone acetonide resulted in a 2.0-fold amplification of this 170 kDa band. There was no significant difference in turnover rate of EGF receptor between treated and untreated HSG cells. These results demonstrate that the triamcinolone acetonide-induced increase in [125I]EGF binding capacity is due to the increased synthesis of EGF receptor protein in HSG cells.     

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.     

Transformation of calf uterine progesterone receptor: analysis of the process when receptor is bound to progesterone and RU38486

Effects of different transforming agents were examined on the sedimentation characteristics of calf uterine progesterone receptor (PR) bound to the synthetic progestin [3H]R5020 or the known progesterone antagonist [3H]RU38486 (RU486). [3H]R5020-receptor complexes [progesterone-receptor complexes (PRc)] sedimented as fast migrating 8S moieties in 8-30% linear glycerol gradients containing 0.15 M KCl and 20 mM Na2MoO4. Incubation of cytosol containing [3H]PRc at 23 degrees C for 10-60 min, or at 0 degrees C with 0.15-0.3 M KCl or 1-10 mM ATP, caused a gradual transformation of PRc to a slow sedimenting 4S form. This 8S to 4S transformation was molybdate sensitive. In contrast, the [3H]RU486-receptor complex exhibited only the 8S form. Treatment with all three activation agents caused a decrease in the 8S form but no concomitant transformation of the [3H]RU486-receptor complex into the 4S form. PR in the calf uterine cytosol incubated at 23 or at 0 degrees C with 0.3 M KCl or 10 mM ATP could be subsequently complexed with [3H]R5020 to yield the 4S form of PR. However, the cytosol PR transformed in the absence of any added ligand failed to bind [3H]RU486. Heat treatment of both [3H]R5020- and [3H]RU486-receptor complexes caused an increase in DNA-cellulose binding, although the extent of this binding was lower when RU486 was bound to receptors. An aqueous two-phase partitioning analysis revealed a significant change in the surface properties of PR following both binding to ligand and subsequent transformation. The partition coefficient (Kobsd) of the heat-transformed [3H]R5020-receptor complex increased about 5-fold over that observed with PR at 0 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nonactivated and activated glucocorticoid-receptor complexes in WEHI-7 and rat thymus cells

Our own results and those of others have indicated that nonactivated glucocorticoid-receptor complexes are oligomeric proteins with Stokes radius R_s = 8–9 nm, and that activation is accompanied by a reduction in size to R_s = 5–6 nm. The most convincing evidence for the large size of the nonactivated compared to the activated complex has been obtained with cytosols stabilized with molybdate. It has been suggested, however, that molybdate causes aggregation of complexes. Here we show that nonactivated rat thymus complexes in cytosols with molybdate and 400 M KCl have R_s = 8 nm. Furthermore, cytosols from WEHI-cells, which are exceptionally stable, show clear indications of 8 nM nonactivated complexes even without molybdate.The principal complexes in thymus cells under physiological conditions are the nonactivated, activated and nuclear-bound forms. We have studied the rapid kinetics of formation and interconversion of these complexes in intact cells at 37°C, using our newly-developed mini-column procedure to assay nonactivated and activated complexes. These kinetic results, along with many earlier results, can be accounted for quantitatively with a simple cyclic (irreversible) model in which the dissociation rate constant of the steroid plays a key role. The model predicts correctly the different degrees of activation in the cell with glucocorticoids such as triamcinolone acetonide and dexamethasone on the one hand, and cortisol and corticosterone on the other, without assuming steroid-specific allosteric influences of each of these steroids on the receptor.     

Aldosterone nuclear receptors in kidneys of chick embryo

We have studied the properties of the nuclear receptors for aldosterone in kidneys of chick embryo. Aliquots of 0.4 M KCl nuclear extracts were incubated with [3H]aldosterone with or without 1 microM RU28362, a potent glucocorticoid analog. Scatchard analyses of binding data revealed two classes of binding sites with Ka of 0.26 and 0.03 X 10(9) M-1 and Nmax of 330 fmol and 620 fmol/mg DNA respectively. In presence of RU28362, however, we observed only a single class of binding sites with a Ka of 1.02 X 10(8) M-1 and a Nmax of 90 fmol/mg DNA. Competition studies performed in presence of RU28362 showed that aldosterone was the more effective competitor followed by corticosterone, progesterone, deoxycorticosterone, dexamethasone, cortisol, triamcinolone acetonide and cortisone. The nuclear complexes had a sedimentation coefficient in the area of 8 S which changed to 4-5 S in the presence of 0.4 M KCl. This effect of KCl was prevented by the addition of 10 mM sodium molybdate. Always in the presence of the glucocorticoid analog, by DEAE-c chromatography we observed a major specific aldosterone-binding fraction which was eluted with 0.2 M KCl. This fraction sedimented at 8.4 S in the absence of sodium molybdate and KCl. In the absence of RU28362, DNA-c columns retained only a small portion of the nuclear complexes which were eluted with KCl. These complexes sedimented, on sucrose gradient, at 4.6 and 3.1 S, whereas those which did not bind to DNA-c had a sedimentation coefficient of 8 S. In the presence of RU28362, the majority of bound [3H]aldosterone remained in the column flow-through fraction; when this fraction was further analyzed on DEAE-c, complexes were eluted with 0.2 and 0.3 M KCl. These data indicate that nuclear receptors for aldosterone are present in small number in kidneys of chick embryo and that they are mostly in the 8 S form.     

Temperature-Dependent Kinetic Correlates of the Activation of the Glucocorticoid-Receptor Complex

The effects of temperature on the kinetics of activation were studied in [3H]triamcinolone acetonide[( 3H]TA)-labeled cytosol preparations from mouse whole brain. After removal of unbound [3H]TA and molybdate (which prevents activation) from the unactivated steroid-receptor complex by gel exclusion chromatography, activation was initiated by incubation at 6-30 degrees C for 0.75-24 min and then rapidly quenched at -5 degrees C with Na2MoO4 (20 mM final concentration). The loss of the 9.2S (unactivated) form of the [3H]TA-receptor complex and the concomitant formation of the 3.8S (activated) form increased dramatically with increases in the activation temperature. These hydrodynamic changes were correlated directly with rapid time- and temperature-dependent increases in the binding of [3H]TA-labeled cytosol to DNA-cellulose (DNA-C). Further analyses of these data revealed a greater than 50-fold increase in the apparent first-order rate constant for the increased binding to DNA-C as the activation temperature was increased from 6 degrees C to 30 degrees C. An Arrhenius plot of these temperature-dependent kinetic constants revealed an energy of activation of 116 kJ. These data support a proposed model for activation of the glucocorticoid-receptor complex that includes the splitting of a 297 kDa, unactivated species into a 92 kDa, activated species.     

Leupeptin inhibits the transformation of glucocorticoid receptor

The effect of leupeptin upon the transformation of the glucocorticoid receptor was tested. When the labeled receptor was treated with heat or high salt in the presence of leupeptin, the binding to DNA-cellulose decreased in a dose-dependent manner. We observed 50% inhibition with about 40 mM leupeptin. The addition of leupeptin after the transformation procedures did not inhibit the binding to DNA-cellulose. In gradient centrifugation, 40 mM leupeptin retained approximately 10S, untransformed form. Elution profiles from DEAE-cellulose showed the preservation of the peak eluted with 0.2 M KCl, corresponding to the untransformed form. These results indicate that leupeptin might have the similar effects to molybdate in regard to blocking the transformation of rat liver glucocorticoid receptor, though the effects with leupeptin were not as great as those seen with molybdate.     

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.     

Interaction of the antiestrogen [3H]H1285 with the two forms of the molybdate-stabilized calf uterine estrogen receptor

The high affinity antiestrogen [3H]H1285 bound to the cytosol calf uterine estrogen receptor dissociated very slowly (t 1/2 approx 30 h at 20 degrees C) and did not demonstrate a change in dissociation rate in the presence of molybdate, which is characteristic of [3H]estradiol-receptor complexes. [3H]H1285-Receptor complexes sediment at approx 6S on 5-20% sucrose density gradients containing 0.3M KCl with or without 10 mM molybdate. This is in contrast to [3H]estradiol-receptor complexes which sedimented at approx 4.5S without molybdate and at approx 6S with molybdate. These results suggest a physicochemical difference in the estrogen receptor when occupied by antiestrogens versus estrogens. We recently reported that the cytoplasmic uterine estrogen receptor, when bound by estradiol and prepared in 10 mM molybdate, eluted from DEAE-Sephadex columns as Peak I (0.21 M KCl) & Peak II (0.25 M KCl). However, [3H]H1285 bound to the estrogen receptor eluted only as one peak at 0.21 M KCl, also suggesting that the initial interaction of antiestrogens with the estrogen receptor is different. We have extended these studies and report that H1285 can compete with [3H]estradiol for binding to both forms of the estrogen receptor and [3H]H1285 can bind to both forms if the unoccupied receptor is first separated by DEAE-Sephadex chromatography. However, if the receptor is first bound by unlabeled H1285, eluted from the column and post-labeled by exchange with [3H]estradiol, only one peak is measured. Thus, it appears that H1285 binding alters the properties of the receptor such that all receptor components seem to elute as one form. These partially purified [3H]H1285-receptor complexes obtained from DEAE-Sephadex columns sedimented as 5.5S in sucrose density gradients in contrast to the sedimentation values for the [3H]estradiol-receptor components eluting as Peak I (4.5S) and Peak II (6.3S). These differences in the physicochemical characteristics of the estrogen receptor when bound by estrogen versus antiestrogens may be related to some of the biological response differences induced by these ligands.