Dialysis-induced transformation of mouse submandibular androgen-receptor

Dialysis induced transformation of cytosol androgen receptor from mouse submandibular gland. On DEAE-Sephacel chromatography, this dialyzed [3H]methyltrienolone receptor complex was eluted at 0.10 M KCl which was lower than 0.25 M KCl required to elute the nontransformed androgen receptor complex, but higher than 0.05 M KCl required to elute the heat transformed receptor. On glycerol density gradient centrifugation, the dialysis transformed receptor complex shifted its sedimentation coefficient to 6 S from 8 S of the nontransformed condition, whereas the heat transformed receptor was sedimented at 4 S. Molybdate inhibited the dialysis-induced transformation on DEAE-Sephacel chromatography. The charge and the molecular size of dialysis-induced transformed receptor complex were different from those of heat-induced transformed receptor complex.     

Conversion of transformed androgen and glucocorticoid receptors to higher molecular forms

The 4 S transformed androgen receptor from rat prostate and thymus converted to a higher molecular form (5-7 S) on low-salt conditions. The converted receptor retained the DNA-binding capacity as well as the 4 S transformed receptor. This conversion was also demonstrated on glucocorticoid receptor from rat liver and thymus. The sedimentation coefficients of both the converted receptors were affected by sodium molybdate, i.e., the receptors converted to a relatively smaller molecule in the presence of molybdate than in the absence of the reagent. These observations suggest that molybdate directly binds to the transformed receptors and prevents the excessive association of a factor(s) to the transformed receptors.     

Characterization of nontransformed and transformed androgen receptor from rat submandibular gland

Rat submandibular gland cytosol contained androgen receptor which had a single class of specific binding and an apparent dissociation constant of (1.1-1.2) X 10(-9) M. The process of transformation was investigated by a slightly modified minicolumn method in which the transformed receptor complexes were separated from the nontransformed receptor and meroreceptor. 10 mM ATP or pyrophosphate at 0 degrees C induced transformation of androgen receptor as did heat or salt treatment. 20 mM of sodium molybdate completely inhibited transformation that resulted from ATP, heat or salt treatment. The nontransformed androgen receptor complexes sedimented at 8 S and eluted at 250-260 mM KCl from DEAE-Sephacel, and its molecular weight was found to be 220 000 on Sephacryl S300 gel chromatography. On the other hand, the transformed androgen receptor complexes sedimented at 4.1-4.3 S (ATP or KCl treatment) or 3.5-3.8 S (heat treatment) and eluted at 60-80 mM KCl from DEAE-Sephacel. The molecular weight of the transformed androgen receptor complexes was 80 000-85 000 (ATP or KCl treatment) or 70 000-80 000 (heat treatment). These results suggest that the transformation of androgen-receptor complexes from rat submandibular gland was induced by the subunit dissociation and that salt bridges may be involved in the subunit interaction.     

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

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

Interaction of vanadyl ribonucleoside complex with the androgen receptor

The addition of vanadyl ribonucleoside complex (VRC), a potent inhibitor of RNase, to the transformed 4.5S androgen receptor from rat submandibular gland caused an increase in the sedimentation coefficient to 7.0S. Moreover, VRC decreased the DNA-cellulose binding of the transformed receptor; 50% inhibition of the DNA-cellulose binding was achieved at 1.8 mM VRC. On the other hand, agents related to VRC and oxoanions of transient metals, such as ribonucleoside, vanadate, molybdate, tungstate and arsenate, exerted no effect on the DNA-cellulose binding ability of the receptor. These findings suggest that VRC binds to the transformed androgen receptor at the DNA-binding site and that both oxovanadium ion and ribonucleoside are indispensable for the binding of VRC to the transformed androgen receptor.     

Characterization of the nontransformed and transformed androgen receptor and heat shock protein 90 with high-performance hydrophobic-interaction chromatography

The hydrophobicity of the nontransformed and transformed androgen receptor from rat submandibular gland and heat shock protein 90 (hsp90) from rat submandibular gland and liver was characterized by using high-performance hydrophobic-interaction chromatography on TSK gel Ether-5PW. In the absence of molybdate, cytosol [3H]R1881-androgen receptor complexes were mainly eluted in the 1.3 M region (Peak 1) with a small peak in the 0.8 M region (Peak 2) of a descending salt gradient (2 to 0 M) of ammonium sulfate. In the presence of molybdate, Peak 2 was predominant. When labeled-cytosol was applied after being heated at 25 degrees C for 30 min, a third peak (Peak 3) at around 0.64 M ammonium sulfate was newly observed. Peaks 2 and 3 were observed, while Peak 1 completely disappeared with the labeled-cytosol precipitated at 40% saturated ammonium sulfate. The Stokes radius of Peak 1 was 7 nm, and of Peak 2 was 8 nm. Both peaks were retained poorly by DNA-cellulose but bound rather well to DEAE-cellulose. These results suggest that these two peaks represent the nontransformed receptor, indicating that there are isoforms of the nontransformed androgen receptor which are distinguished by their hydrophobic properties and Stokes radii. Peak 3 had a Stokes radius of 5 nm and preferentially bound to DNA-cellulose, suggesting that this peak corresponds to the transformed receptor. These results indicated that the transformation of the androgen receptor accompanies the enrichment of the hydrophobicity of the receptor molecule. Hsp90 purified from rat livers and hsp90 in the cytosol both from livers and submandibular glands were eluted from Ether-5PW at 0.8 M ammonium sulfate, at almost the same position as Peak 2. This finding suggests that the enrichment of hydrophobicity on transformation is due to dissociation of hsp90 from the nontransformed androgen receptor.     

Binding of the rat liver 7-8 S dexamethasone receptor to deoxyribonucleic acid

The 7-8 S form of the [3H]dexamethasone (9 alpha-fluoro-11 beta,17,21-trihydroxy-16 alpha-methylpregna-1,4-diene-3, 20-dione) receptor from rat liver cytosol can be converted to the 3-4 S form by RNase treatment or high salt, suggesting a salt-sensitive association between the receptor protein and RNA. In DNA-cellulose column assays, the gradient-purified 3-4 S form bound DNA more efficiently than the 7-8 S form, though the 7-8 S form was also capable of binding to DNA-cellulose to a significant extent. Activated 7-8 S dexamethasone receptor could be released from its association with soluble DNA by treatment with DNase I. Sucrose gradient analysis showed that the released receptor sedimented as the 7-8 S form and was sensitive to RNase treatment, which induced a conversion to the 3-4 S form. Activated RNase-generated 3-4 S receptor again displayed a higher degree of binding to soluble DNA and was recovered in the 3-4 S form following DNase extraction. The fact that the 3-4 S form bound immobilized or soluble DNA more efficiently suggests that the associated RNA of the 7-8 S form interferes directly or indirectly with the receptor association with DNA. The observation that the receptor binds to DNA in its 7-8 S form suggests that the receptor complex is capable of binding RNA and DNA concurrently.     

Effects of proteases and protease inhibitors on the 4.5 S and 8 S androgen receptor.

The size of androgen receptors from rat ventral and dorsal prostate, dorsal prostate (Dunning) tumor, testis, epididymis, and seminal vesicle was determined using Sephadex G-200 chromatogrpahy and sucrose gradient centrifugation. The protease inhibitor diisopropyl fluorophosphate (DFP) was used to minimize receptor breakdown. An 8-9 S, 85 to 106 A receptor (Mr = 280,000 to 365,000; f/fo = 1.9 to 2.4) observed in unfractionated cytosol prepared in low ionic strength buffer with or without DFP is in equilibrium with a 4.5-5 S, 58 A form (Mr = 117,000; f/fo = 1.8) observed at salt concentrations greater than 0.1 M KCl. Receptor partially purified using (NH4)2SO4 or phosphocellulose chromatography in the absence of DFP was present as smaller fragments of 3.6 S, 37 A and 3.0 S, 23 A. Similar fragments could be generated from the 4.5 S or 8 S receptor by mild trypsin treatment. In addition, ventral prostate contains a DFP-insensitive enzyme which specifically converts the 4.5 S, 58 A receptor to the 3.6 S 37 A fragment. The DFP-insensitive enzyme is partially inhibited by rabbit bile and appears similar to the enzyme seminin, a secretory protein of human prostate. Androgen receptor isolated in the presence of DFP from nuclei labeled in vivo is predominantly 4.5 S, 58 A, with smaller forms (37 and 23 A) appearing in the absence of DFP. The 4.5 S, 58 A nuclear receptors were also in equilibrium with a large 8 S form. Receptor breakdown by DFP-insensitive and sensitive proteases appears to be an in vitro phenomenon. Furthermore, the size of the androgen receptor is not significantly changed during receptor migration from cytoplasm to nucleus.     

Androgen receptor binding to nuclear matrix in vitro and its inhibition by 8S androgen receptor promoting factor

The partially purified 4.5S [3H]dihydrotestosterone receptor binds to nuclear matrix isolated from rat Dunning prostate tumor with properties similar to those reported for androgen receptor binding in intact nuclei [Colvard, D.S., & Wilson, E.M. (1984) Biochemistry (preceding paper in this issue)] in that it requires Zn2+ and mercaptoethanol, is saturable, and is temperature dependent and of high affinity (Ka approximately 10(13) M-1). On a milligrams of DNA equivalent basis, the extent of matrix binding of androgen receptor (700 fmol of receptor bound/mg of matrix protein) is similar to that of intact nuclei, corresponding to approximately 1400 sites/nucleus. Association rate constants (ka) for 4.5S androgen receptor binding to matrix at 0, 15, and 25 degrees C are 2.7 X 10(5), 1.2 X 10(6), and 2.4 X 10(6) M-1 min-1, respectively, indicating an energy of activation of 15 kcal/mol. Up to 50% of matrix-bound receptor is extractable in buffer containing 3 mM ethylenediaminetetraacetic acid plus either 0.4 M KCl or 5 mM pyridoxal 5'-phosphate. A protein fraction designated 8S androgen receptor promoting factor that promotes conversion of the 4.5S androgen receptor to 8 S [Colvard, D. S., & Wilson, E. M. (1981) Endocrinology (Baltimore) 109, 496-504] has been further purified and found to inhibit the binding of the 4.5S androgen receptor to isolated nuclei and nuclear matrix in a concentration-dependent manner. The results support the hypothesis that the 8S steroid receptor is a complex of the activated 4.5S androgen receptor with a non-steroid binding protein that renders the receptor incapable of binding in nuclei.     

Characteristics of the calf uterine androgen receptor

The highest molecular weight form of the calf uterine androgen receptor separates as an 11S form in glycerol gradients. This "cytosolic" receptor, prepared in the presence of molybdate, polyethyleneimide and low ionic strength, dissociates into 9S and 7.2S forms with increasing KCl concentration. A 4.5S androgen binding component appears as the predominant form of the receptor in the absence of polyethyleneimide and this unit quantitatively converts to a stable 3.5S form in the absence of molybdate. Renaturation of partially purified protein, separated by SDS-PAGE electrophoresis, demonstrates the presence of an androgen binding component in the 110 kDa region of the gel. This renatured protein separates as a 4.5S component in glycerol gradients and has a Stokes radius of 6 nm. Photoaffinity labelling of partially purified receptor preparations, followed by SDS-PAGE electrophoresis, reveals the presence of an androgen binding component having a molecular weight of 115 kDa. The binding characteristics and specificity of the receptor binding to R1881 have been studied and a DHT-affinity chromatography resin used to purify the receptor.     

Binding of methyltrienolone to various androgen-dependent and androgen-responsive tissues in four animal species.

Comparative sucrose gradient studies of the in vitro binding of dihydrotestosterone (DHT) and of a synthetic androgen, methyltrienolone (R 1881), have been done with the cytosols of various tissues of the rat, mouse, cock and man. With rat prostate cytosol, the amount of R 1881 and DHT binding in the 8-9S region of the gradient was found to be comparable. Specific 8-9S peaks of R 1881 were also found in rat levator ani/bulbocavernosus and skeletal muscles and in the mouse kidney. Only 4-5S peaks could be demonstrated in the cock's comb while DHT under the same conditions showed both 8-9S and 4-5S binding. Binding of R 1881 to the cytosol of the hyperplastic prostate was polydispersed, and showed evidence of the presence of aggregates. Evidence was also found that R 1881 could bind to the progesterone receptor in rat uterus. Our study supports the theory that in a given species the androgen receptors are similar if not identical in all the tissues. The synthetic androgen R 1881 appears to be a useful tool for androgen receptor studies in various animal species provided that the tissue under study contains no progesterone receptor.     

Binding of [3H]methyltrienolone to androgen receptor in rat liver

The synthetic androgen methyltrienolone is superior to testosterone and androstenedione for the measurement of androgen receptor in tissues where the native ligands are metabolized into inactive derivatives. [3H]Methyltrienolone binds with a high affinity to androgen receptor in cytosol prepared from male rat livers, as the Scatchard analysis revealed that the Kd value was 3.3 X 10(-8) M and the number of binding sites was 35.5 fmol/mg protein. Since methyltrienolone also binds glucocorticoid receptor which exists in rat liver, the apparent binding of androgen receptor is faulty when measured in the presence of glucocorticoid receptor. The binding of methyltrienolone to glucocorticoid receptor can be blocked by the presence of a 100-fold molar excess of unlabeled synthetic glucocorticoid, triamcinolone acetonide, without interfering in its binding to androgen receptor, because triamcinolone does not bind to androgen receptor. Triamcinolone-blocked cytosol exhibited that the Kd value was 2.5 X 10(-8) M and the number of binding sites was 26.3 fmol/mg protein, indicating a reduction to 3/4 of that in the untreated cytosol. The profile of glycerol gradient centrifugation indicated that [3H]methyltrienolone-bound receptor migrated in the 8-9 S region in both untreated and triamcinolone-blocked cytosols, but the 8-9 S peak in triamcinolone-blocked cytosol was reduced to about 3/4 of that of untreated cytosol.     

Differential effects of molybdate on the hydrodynamic and DNA-binding properties of the non-activated and activated forms of the androgen receptor in calf uterus

Calf uterine cytosol contains an androgen receptor with a relative molecular mass of approx. 90,000. In this study we have analysed the structure and aggregation properties of the androgen receptor, using sucrose density gradient centrifugation on a vertical rotor (VTi65). In the presence of 10 mM NaCl the androgen receptor in whole cytosol sedimented at 8 S irrespective of the presence of molybdate. In 400 mM NaCl the receptor dissociated to a 4.3 S entity. In whole cytosol molybdate promoted a partial shift of the 4.3 S receptor into the aggregated 8 S state. The time of exposure of the receptor to molybdate and NaCl determined the proportion of receptor sedimentating at 8 S and 4.3 S. The DNA-binding form of the uterine androgen receptor when analysed under the conditions of the DNA-cellulose binding assay, sedimented at 6.5 S. Increasing concentrations of molybdate shifted its sedimentation coefficient gradually from 6.5 S to 4.5 S and in parallel reduced the DNA-binding capacity. Molybdate added to a partially purified, DNA-binding form of the androgen receptor did not promote receptor aggregation to faster sedimentating forms. This suggests that such preparations are devoid of an androgen receptor-aggregation factor. Indirect evidence for such a factor was obtained from reconstitution experiments with whole cytosol. Our results indicate that the DNA-binding form of the androgen receptor interacts with a cytosol factor to form the 8 S receptor complex. Molybdate has diverse effects: in the presence of the cytosol factor it stabilizes the 8S complex; in its absence molybdate prevents in a concentration-dependent way DNA-binding as well as reaggregation of the monomeric 4.3 S form.     

Purification and characterization of the untransformed androgen receptor in rat prostate

The isolation and characterization of the untransformed form of androgen receptors has not yet been successful, owing to their inherent lability as well as to their ready proteolysis. In this study, we have stabilized rat prostate androgen receptors by sodium molybdate and by rapid filtration on phosphocellulose. Proteases were inhibited by bacitracin, aprotinin, leupeptin and PMSF. Under these conditions the untransformed complex was purified approx 3000-fold, corresponding to 18% yield, by differential chromatography on DEAE cellulose and phosphocellulose gels. The partially purified receptor has the same ionic characteristics as the original untransformed receptor of crude cytosol; in addition, it possesses a Stokes' radius of 75 A, as determined by Sephacryl S-300 gel filtration, a sedimentation coefficient of 8.8S, a calculated molecular weight of 275 kDa and a friction coefficient of 1.6. The [3H]R1881 receptor complex was specific to androgens since unlabelled R1881 and dihydrotestosterone were able to completely displace bound [3H]R1881, whereas estradiol, cortisol, and triamcinolone acetonide did not compete. The purified complex was a multimer dissociable by 0.6 M KCl, resulting in a form migrating in the 4S area on sucrose density gradient. After treatment with 0.5% formaldehyde, three forms were obtained, migrating in the areas of 8-9, 5-6 and 3-4S respectively, of a sucrose density gradient containing 0.6 M KCl. This is the first step towards the purification to homogeneity of the untransformed androgen receptor.     

Characteristics of cytosol androgen receptor in rat thymus

Male and female rat thymic cytosol contained specific androgen receptor. The apparent dissociation constants (Kd) were 2.4 nM in males and 2.5 nM in females, and the number of binding sites (NBS) were 23.7 fmol/mg protein in males and 34.2 fmol/mg protein in females. Transformation of receptor to the DNA binding state was achieved by heat or KCl treatment of [3H]R1881-receptor complex, and the characteristics of transformed and nontransformed receptors were investigated. The nontransformed androgen-receptor complex eluted at 0.20-0.25 M KCl from DEAE-Sephacel and sedimented at 9.1 S and its molecular weight was 255,000 on agarose gel chromatography, while the transformed receptor complex eluted at 0.03-0.15 M KCl with a broad peak and sedimented at 4.5 S and its molecular weight was 80,000-85,000. The minicolumn binding assay revealed that approximately 57% of the total receptor complexes bound to DNA-cellulose following heat treatment (20 degrees C, 1 h). Castration exerted no effect on the physicochemical properties of cytosol androgen receptor, but it increased the number of binding site to the female level.     

Androgen receptor in rat Harderian and submandibular glands

Summary Androgens regulate the development and sexual dimorphism of rodent Harderian and submandibular glands. This effect is believed to be mediated by the androgen receptor. Immunohistochemistry and immunoblotting were carried out to study the receptor in normal, castrated and dihydrotestosterone-supplemented rat Harderian and submandibular glands. Immunohistochemically, the most intense nuclear staining was observed in the acinar cells of the submandibular glands, followed by intercalated duct cells. The granular convoluted tubules showed weak immunostaining and the striated ducts were negative. In the Harderian gland, nuclear staining was seen in both type I and II secretory cells. Castration and treatment had no effect on the expression of the androgen receptor protein in either gland. A 110 K androgen receptor signal was detected by immunoblotting in the Harderian gland but not in the submandibular gland. An experiment was designed to explore the possible effect of proteinases on the receptor protein in the homogenate of submandibular gland. Our results demonstrate the cell-specific location of the receptor in Harderian and submandibular glands, and show that the expression of the receptor protein is androgen-independent.     

Correlation of the 4-5 S form and the 8 S form of the cytosolic androgen receptor in murine skeletal muscle

Binding experiments with the cytosolic androgen receptor from murine skeletal muscle yield with testosterone a biphasic saturation curve and a biphasic Scatchard plot. These binding characteristics result from the conversion of 8 S receptor (KD = 1,4 X 10(-10) M) into 4-5 S receptor (KD = 1,2 X 10(-9) M). This conversion is androgen dependent and is facilitated in vitro by either UV-irradiation or by methods known to activate steroid hormone receptor complexes to a nuclear binding form (e.g. high ionic strength or elevated temperature). The measured data show that both receptor forms are in a complex dissociation equilibrium. The reassociation of the 4-5 S receptor to form the 8 S complex is inhibited by RNase.     

Binding properties of androgen receptors. Evidence for identical receptors in rat testis, epididymis, and prostate.

Androgen receptors in crude and partially purified 105,000 X g supernatant fractions from rat testis, epididymis, and prostate were studied in vitro using a charcoal adsorption assay and sucrose gradient centrifugation. Androgen metabolism was eliminated during receptor purification allowing determination of the kinetics of [3H]-androgen-receptor complex formation. In all three tissues, receptors were found to have essentially identical capabilities to bind androgen, with the affinity for [3H] dihydrotestosterone being somewhat higher than for [3H] testosterone. Equilibrium dissociation constants for [3H] dihydrotestosterone and [3H] testosterone (KD = 2 to 5 X 10(-10) M) were estimated from independently determined rates of association (ka congruent to 6 X 10(7) M-1 h-1 for [3H] dihydrotestosterone and 2 X 10(8) M-1 h-1 for [3H] testosterone) and dissociation (t 1/2 congruent to 40 hr for [3H] dihydrotestosterone and 15 h [3H] testosterone). Evaluation of the effect of temperature on androgen receptor binding of [3H]testosterone allowed estimation of several thermodynamic parameters, including activation energies of association and dissociation (delta H congruent to 14 kcal/mol), the apparent free energy (delta G congruent to -12 kcal/mol), enthalpy (delta H congruent to -2.5 kcal/mol), and entropy (delta S congruent to 35 cal col-1 K-1). Optimum receptor binding occurred at a pH of 8. Receptor stability was greatly enhanced when bound with androgen. Receptor specificity for testosterone and dihydrotestosterone was demonstrated by competitive binding assays. The potent synthetic androgen, 7 alpha, 17 alpha-dimethyl-19-nortestosterone, inhibited binding of [3H] testosterone or [3H] dihydrotesterone nearly as well as testosterone and dihydrotestosterone while larger amounts of 5 alpha-androstane-3alpha, 17 beta-diol and nonandrogenic steroids were required. Sedimentation coefficients of androgen receptors in all unfractionated supernatants were 4 and 5 to 8 S. Differences in sedimentation coefficients were observed following (NH4)2SO4 precipitation which did not influence the binding properties of the receptors. These results, together with measurements of3alpha/beta-hydroxysteroid oxidoreductase activity in vitro, suggest that organ differences in receptor binding of [3H] dihydrotestosterone and [3H] testosterone in vivo result from relative differences in intracellular concentrations of these androgens rather than from differences in receptor affinities.     

Studies on sex-organ development. Isolation and characterization of an oestrogen receptor from chick Müllerian duct.

An oestradiol-binding macromolecule was observed in the left Müllerian duct of the 15-day female chick embryo. The embryonic receptor binds oestradiol with a high affinity and low capacity, having a Kd of 3.2 X 10(-9)M and a maximal number of sites of 5.45 fmol/10(6) cells in the left Müllerian duct. The receptor is protein in nature, as suggested by its susceptibility to proteolysis; in addition, it is organ- and steroid-specific. Judging by glycerol-gradient analysis, the hormone receptors in the cytosol are present in 8S and 4.5S forms, and the 8S form could be dissociated into a 4.5S form in the presence of 0.5M-KCl. A 4.5-6S receptor could be extracted from the nuclei. Under physiological salt conditions, the embryonic receptors bind to DNA-cellulose and can be eluted when the salt concentration is increased to 0.5M-KCl. Determination by isoelectric focusing indicates that the isoelectric point is 5.8 for the 8S and 6.9 for the 4.5S receptor.     

The ability to convert the 4 S glucocorticoid receptor to the 7-8 S form is dependent on both RNA and protein factors

The DEAE-cellulose-purified 4 S form of the rat liver glucocorticoid receptor can associate with cytosolic factors, as evidenced by an alteration of the sedimentation value of the 7-8 S form. On the basis of sedimentation profile, this form is indistinguishable from the activated, low-salt 7-8 S form isolated from rat liver cytosol. In addition, both the endogenous and reconstituted 7-8 S receptor can bind DNA as the 7-8 S form. In keeping with our reports that the endogenous form of the 7-8 S receptor is sensitive to RNAase digestion, treatment of the cytosol with RNAase prior to mixing with the 4 S receptor prevents the formation of the 7-8 S material. Moreover, warming the cytosol to 50 degrees C prior to mixing with the 4 S receptor also eliminates the ability to form the heavier material. Since RNA is heat-stable, this suggests that other factors may be involved. Treatment of the cytosol with N-ethylmaleimide, a reagent reported to be specific for sulfhydryl groups, also eliminates 7-8 S generating ability. These observations suggest that a protein may be a component of the 7-8 S generating material. This is substantiated by the observation that trypsin or chymotrypsin treatment of the cytosol mitigates the ability of the cytosol to form the 7-8 S material and results in the appearance of a form of the receptor that sediments at approximately 6 S. Protease treatment of partially purified material eliminates the 7-8 S generating activity entirely. We conclude that the 7-8 S form of the receptor can be reconstituted from the 4 S receptor via association with at least two other cytosolic factors, a protein and an RNA.