A novel effect of molybdate on the binding of [3H]aldosterone to gel-filtered type I receptors in brain cytosol

Recently we reported that adding molybdate to crude steroid-free cytosol at 0°C results in a dose-dependent reduction in the binding of [³H]aldosterone ([³H]ALDO), to Type I adrenocorticosteroid receptors. In the experiments outlined here, we found that addition of molybdate to steroid-free brain cytosol produces a 30–50% increase in the subsequently measured maximal specific binding capacity (B _MAX) of [³H]ALDO-Type I receptors if the cytosol is subjected to Sephadex G-25 gel filtration prior to steroid addition. These manipulations were found to have no effect on the equilibrium dissociation constant (K _d) of the receptors. In contrast, when gel filtration of steroid-free cytosol was performed in the absence of molybdate, there was a 2-fold increase in the K_d and over a 50% reduction in the subsequently measuredB _MAX of [³H]ALDO-Type I receptors. When molybdate was added to this steroid-free cytosol immediately following gel filtration, there was no reduction (or increase) in Type I receptor [³H]ALDO binding capacity compared with nongel-filtered controls. The addition of as little as 2 mM molybdate to crude steroid-free cytosol was found to stabilize the binding capacity of Type I receptors during exposure to 22°C incubations; however, when gel-filtered steroid-free cytosol was exposed to these conditions at least 10 mM molybdate was required to stabilize Type I receptor binding capacity. Adding the sulfhydryl reducing reagent, dithiothreitol, to the various steroid-free cytosols had little effect on [³H]ALDO-Type I receptor binding. The effects of molybdate, revealed in this study, on Type I receptors in brain cytosol subjected to gel filtration are clearly different from those seen with receptors in crude cytosol preparations, as well as from those reported in the literature for other steroid receptors. Possible mechanisms of action of molybdate on unoccupied Type I receptors in crude and gel-filtered cytosol are discussed.     

Analysis of renal and hippocampal type I and type II receptors by fast protein liquid chromatography

Type I and Type II adrenal steroid receptors from rat renal and hippocampal cytosols were studied by the technique of Fast Protein Liquid Chromatography. Type I receptors were labelled with [3H]aldosterone plus excess RU26988, and Type II receptors with [3H]dexamethasone. On a Mono Q anion exchange column the molybdate-stabilized renal and hippocampal Type I receptors both eluted as single symmetrical peaks at 0.27 M NaCl, with a recovery of approximately 90% and 60-fold purification (renal) and 10-15-fold (hippocampal). Molybdate-stabilized Type II binding sites from both hippocampal and renal cytosols co-eluted with the Type I sites. On Superose gel filtration renal Type I receptor-steroid complexes consistently eluted two fractions later than hippocampal Type I complexes, suggesting that the renal complexes are smaller; Type II receptor-steroid complexes from both cytosols co-eluted, consistently one fraction behind hippocampal Type I sites. Sequential gel filtration and anion exchange chromatography achieved a 1000-fold purification of renal Type I binding sites, with an overall recovery of 10%.     

Activation of cytosol aldosterone receptors in rat kidney

Cytosolic aldosterone-protein complexes are isolated from rat kidney slices after incubation with [3H]aldosterone and dexamethasone. Activated and unactivated forms of the complex are characterized by gel electrophoresis and hydroxyapatite chromatography after incubation at 4 degrees C and 25 degrees C respectively. It is found that the activated form reaches a maximum after 30 min at 25 degrees C and can be separated as an homogeneous peak by electrophoresis. Intermediate forms can also be identified. In the presence of 10 mM ATP, activation immediately occurs at 4 degrees C and is almost complete. In the presence of 10 mM molybdate, the activation is strongly enhanced and the increase in activated form may be about fifteen-fold whether molybdate is added during kidney homogenization or just before incubation at 25 degrees C. On the other hand molybdate reduces to one third the binding of the aldosterone-receptor complexes to nuclei. In the presence of the steroid RU 26988 which is a pure glucocorticoid, experiments done on aldosterone-receptors complexes and their binding to nuclei are confirmed. This proves that aldosterone is specific for mineralocorticoid sites. The general pattern of the mineralocorticoid receptor activation is discussed and its resemblance to the case of other steroid hormones is emphasized.     

Characterization of steroid hormone receptors with ion-exchange fast protein liquid chromatography

Androgen, estrogen and progesterone receptors have been characterized with anion exchange Fast Protein Liquid Chromatography (FPLC) on a Mono Q column (Pharmacia). In the presence of sodium molybdate androgen receptors in cytosols from rat prostate, rat epididymis and calf uterus eluted as a single sharp peak at 0.32 M NaCl with recoveries of approx 90%. The molybdate-stabilized form of the androgen receptor from rat prostate was purified about 75-fold. The receptor containing FPLC-peak fractions sedimented in high salt (0.4 M KCl) linear sucrose gradients at 3.6 S (prostate) and at 4.6 S (epididymis and calf uterus) respectively. Multiple forms of the androgen receptor were present in cytosols from rat prostate prepared in the absence of sodium molybdate, probably due to proteolytic breakdown of the native form. Calf uterine estradiol and progesterone receptors prepared in the presence of sodium molybdate (20 mM) eluted from the Mono Q column at 0.32 M NaCl. The molybdate-stabilized forms of the oestradiol and progesterone receptors were purified approx 70-fold and 30-fold respectively. In the absence of molybdate the estradiol receptor dissociated into two major forms eluting at 0.23 M NaCl and 0.37 M NaCl. After heat induced transformation (30 min at 25 degrees C) of the estradiol receptor one major peak was eluted at 0.42 M NaCl, indicating a change in the surface charge of the estradiol receptor as a result of the 4 S to 5 S transformation. It is concluded that the FPLC anion exchange system is a powerful, fast tool for characterization and partial purification of steroid receptors. In addition this technique could be applied as a rapid procedure for the quantitative estimation of steroid receptors in small biological samples.     

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.     

Chemical differentiation of type I and type II receptors for adrenal steroids in brain cytosol

Studies outlined here compare the properties of mineralocorticoid (Type I) and glucocorticoid (Type II) receptors in cytosol from adrenalectomized mouse brain. Pretreating cytosol with dextran-coated charcoal (DCC) produced a 4.7-fold increase in the subsequent macromolecular binding of the mineralocorticoid, [3H]aldosterone (20 nM ALDO, in the presence of a 50-fold molar excess of the highly specific synthetic glucocorticoid, RU 26988), whereas it produced a 55% decrease in the binding of the glucocorticoid, [3H]triamcinolone acetonide (20 nM TA). Scatchard analyses revealed that DCC pretreatment had no effect on the affinity or maximal binding of Type I receptors for [3H]ALDO (in the presence of a 0-, 50- or 500-fold excess of RU 26988), whereas it produced a 3- to 6-fold increase in the Kd, and an 8-43% decrease in the maximal binding, of Type II receptors for [3H]TA and [3H]dexamethasone. Optimal stability of unoccupied Type I receptors at 0 degree C was found to be achieved in buffers containing glycerol, but lacking molybdate. Although the addition of molybdate was found to reduce the loss in Type I receptor binding observed after incubating unlabelled cytosol at 12 or 22 degrees C, this stabilization was accompanied by a concentration-dependent reduction in the binding of [3H]ALDO at 0 degree C. Scatchard analyses showed that this reduction was due to a shift in the maximal binding, and not the affinity, of the Type I receptors for [3H]ALDO. The presence or absence of dithiothreitol in cytosol appeared to have little effect on the stability of Type I receptors. In contrast to our finding for Type I receptors, it was possible to stabilize the binding capacity of unoccupied Type II receptors, even after 2-4 h at 12 or 22 degrees C, if the glycerol containing buffers were supplemented with both molybdate and dithiothreitol. In summary, these results indicate distinct chemical differences between Type I and Type II receptors for adrenal steroids.     

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)     

Physicochemical characteristics of the interaction of the glucocorticoid antagonist RU38486 with glucocorticoid receptors in vitro, and the role of molybdate

The physicochemical properties of complexes formed between the glucocorticoid antagonist, RU38486, and the glucocorticoid receptor in rat thymus cytosol were investigated and compared with those of complexes formed with the potent agonist, triamcinolone acetonide. The equilibrium dissociation constant for the interaction of [3H]RU38486 with the molybdate-stabilized glucocorticoid receptor was lower than that for [1,2,4-3H]triamcinolone acetonide at 0 degree C but higher at 25 degrees C, suggesting that hydrophobic interactions play a major role in the binding of RU38486. Differences in equilibrium constants were reflected in corresponding differences in dissociation rate constants; association rate constants for the two steroids were similar. The rate of dissociation of [3H]RU38486 from the glucocorticoid receptor was higher in the absence of molybdate than in its presence both at 0 degree C and at 25 degrees C, suggesting that molybdate modifies the physical state of the antagonist-receptor complex, but other physical properties were similar both in the presence and in the absence of molybdate. The rate of inactivation of the unoccupied glucocorticoid receptor at 25 degrees C in the absence of molybdate was lower in phosphate buffer than in Tris-HCl buffer but the rate of dissociation of [3H]RU38486 was the same in both buffers. The binding of RU38486 afforded little, if any, protection against inactivation in either buffer; [3H]RU38486 dissociated irreversibly from the inactivated receptor at the same rate as from the non-inactivated complex but molybdate had no effect on the dissociation kinetics of the inactivated complex. It is concluded that RU38486 interacts with the ground state of the glucocorticoid receptor in a manner which neither promotes receptor transformation nor prevents receptor inactivation.     

The receptor for 2,3,7,8-tetrachlorodibenzo-p-dioxin in the mouse hepatoma cell line Hepa 1c1c7. A comparison with the glucocorticoid receptor and the mouse and rat hepatic dioxin receptors

The molecular properties of the receptor for 2,3,7,8-tetrachlorodibenzo-p-dioxin in the mouse hepatoma cell line Hepa 1c1c7 were investigated. The receptor was found to represent a highly asymmetrical molecule with a sedimentation coefficient, s20,w, of approximately 8 S, a Stokes radius of 7-8 nm, and a calculated Mr approximately equal to 260,000-300,000. In comparison, the Hepa 1c1c7 glucocorticoid receptor in analogy to the glucocorticoid receptor in general as well as the C57BL/6 mouse and rat hepatic dioxin receptors are molecules with an s20,w value of 4-5 S, a Stokes radius of approximately 6 nm, and a calculated Mr approximately equal to 100,000. In the presence of 20 mM sodium molybdate, a large Mr approximately equal to 270,000-310,000 form of the Hepa 1c1c7 glucocorticoid receptor is stabilized which is hydrodynamically indistinguishable from the Mr approximately equal to 260,000-300,000 Hepa 1c1c7 dioxin receptor. Sodium molybdate does not have any effect on the molecular properties of the Hepa 1c1c7 dioxin receptor. In conclusion, the large form of dioxin receptor present in Hepa 1c1c7 mouse hepatoma cells in the absence of sodium molybdate is strikingly similar to molybdate-stabilized steroid hormone receptors as well as the molybdate-stabilized form of the dioxin receptor previously demonstrated in rat hepatic cytosol. Therefore, the Hepa 1c1c7 dioxin receptor might offer an interesting model for studies on the structure and function of Mr approximately equal to 300,000 forms of soluble receptors.     

Transformation and nuclear translocation of brain type L corticosteroid receptors complexed with the mineralocorticoid antagonist ZK 91587, aldosterone or dexamethasone.

Type I corticosteroid receptors were determined in cytosol from hippocampus (HIPPO) and amygdala (AMYG), using [3H]aldosterone (ALDO), [3H]dexamethasone (DEX) or the mineralocorticoid antagonist [3H]ZK 91587 as ligands. Incubations with the first two compounds also contained the pure glucocorticoid RU 28362 to block type II receptors. Binding of the three ligands was comparable in cytosol from HIPPO and it was slightly higher for [3H]DEX in AMYG. However, after heat-induced receptor transformation, binding to DNA-cellulose was observed for [3H]ALDO-receptor complex obtained from HIPPO or AMYG, whereas it was negligible for [3H]ZK 91587. Receptors charged with [3H]DEX or [3H]ALDO showed similar retention on DNA-cellulose columns in the case of the AMYG, while binding to the polynucleotide was higher for [3H]ALDO in the HIPPO. Finally, only [3H]ALDO was taken up to a significant extent in purified cell nuclei prepared from slices of HIPPO and AMYG previously incubated with the three ligands. It is concluded that binding of a natural agonist steroid may be a prerequisite for type I receptor transformation and translocation from the cytoplasm into the nuclear fraction. DEX binding to type I receptors resembles a partial agonist with antagonist properties, whereas antagonists such as ZK 91587 are bound and retained in cytoplasm, without further translocation.     

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.     

Immunochemical characterization of the rat kidney glucocorticoid receptor. The role of proteolysis in the formation of corticosteroid binder IB

Glucocorticoid receptors of rat kidney and liver were compared by physicochemical and immunochemical methods to investigate the role of proteolysis in the formation of corticosteroid binder IB. Kidney cytosol prepared in the presence of sodium molybdate contained receptor forms comparable to rat liver glucocorticoid receptor; [3H]triamcinolone acetonide-labeled receptors eluted from Sephacryl S-300 as a multimeric 6.1 nm component in the presence of molybdate and as a monomeric 5.7 nm component in the absence of molybdate. Both forms were recognized by the monoclonal antibody BUGR-1 which was raised against rat liver glucocorticoid receptor. When kidney cytosol was prepared in the absence of molybdate, labeled receptor complexes eluted from Sephacryl S-300 as a 5.8 nm component in the presence of molybdate. However, in the absence of molybdate, the receptor eluted as a smaller 3.4 nm component which was identical with the size of activated kidney glucocorticoid receptor chromatographed in either the presence or absence of molybdate. The 3.4 nm activated kidney glucocorticoid receptor did not bind to DEAE-cellulose under conditions where activated liver receptor was retained. These properties of the activated kidney receptor are characteristic of corticosteroid binder IB. Incubation of the activated kidney receptor complex with BUGR-1 resulted in a shift in apparent Stokes radius from 3.4 nm to 5.4 nm, indicating immunochemical similarity with rat liver receptor. Identification of the immunoreactive receptor subunit by Western blotting demonstrated that kidney cytosol prepared in the presence of molybdate contained a major 94-kDa immunoreactive component which co-migrated with rat liver glucocorticoid receptor, while cytosol prepared in the absence of molybdate contained principally a 44-kDa immunoreactive species. These results suggest that corticosteroid binder IB can be generated by in vitro proteolysis and does not represent a polymorphic form of the glucocorticoid receptor.     

Efficacy of five methods for the bound-free separation of gluco- and mineralocorticoids from type I,II and III receptors found in HEPES- and TRIS-buffered mouse brain cytosol.

We compared the efficacy of G-25 and LH-20 column chromatography, dextran-coated charcoal adsorption, and DEAE-cellulose and glass fiber filter disc assays to separate unbound steroids from three classes of brain cytosolic receptors prepared in HEPES and TRIS buffers and labeled selectively as follows: Type I = [³H]aldosterone + unlabeled RU26988, Type II = [³H]triamcinolone acetomide and Type III = [³H]corticosterone + unlabeled Prorenone and RU26988. Prorenone and RU26988 were added to reduce unwanted [³H]steroid binding to Type I and Type II receptors, respectively. In each case total, non-specific and specific binding and free steroid were compared individually. No single assay was found to be best for all three receptor classes, but both buffers and most assays could be used with appropriate correction factors. Variations between the results with different assays suggest fundamental differences between the three classes of adrenosteroid receptors and their ligands.     

The use of the biotinyl estradiol-avidin system for the purification of "nontransformed" estrogen receptor by biohormonal affinity chromatography

Several biotinyl estradiol derivatives have been prepared by coupling estradiol 7 alpha-carboxylic acid to biotin via different linear linkers. All these compounds exhibit a high affinity for the estrogen receptor as determined by competitive binding assays against [3H]estradiol. These compounds also displaced the dye 4-hydroxyazobenzene-2'-carboxylic acid from the biotin-binding sites of avidin free or immobilized on agarose. It was demonstrated that only the derivatives bearing a long spacer chain (greater than 42 A greater than) between estradiol and biotin were able to bind receptor and avidin simultaneously, suggesting some steric hindrance. The biotin-avidin system has been investigated for the purification of the cytosoluble "nontransformed" estrogen receptor stabilized by sodium molybdate. The method relies on: 1) high biohormonal affinity of receptor for biotinyl estradiol derivative; 2) the specific selection by avidin-agarose column of biotinyl estradiol-receptor complexes; and 3) the biohormonal elution step by an excess of radioactive estradiol. Starting from unfractionated cytosol containing molybdate-stabilized nontransformed 8S estrogen receptor with estradiol 7 alpha-(CH2)10-CO-NH-(CH2)2-O-(CH2)2-O-(CH2)2-NH-CO-(CH2)3-NH-biotin, preliminary experiments using avidin-agarose chromatography and then a specific elution step by exchange with free [3H]estradiol, allowed a 500-1,500-fold purification. Further purification of estrogen receptor was obtained by ion exchange chromatography through a DEAE-Sephacel column and led to a congruent to 20% pure protein, assuming one binding site/65,000-Da unit. The hydrodynamic parameters of the purified receptor were essentially identical to those of molybdate-stabilized nontransformed receptor present in crude cytosol. The advantages of this double biotinyl steroid derivative-avidin chromatographic technique over more conventional affinity procedures are discussed and make it applicable to the purification of minute amounts of steroid receptors in a wide variety of tissues.     

Chick oviduct glucocorticosteroid receptor. Specific binding of the synthetic steroid RU 486 and immunological studies with antibodies to chick oviduct progesterone receptor

The glucocorticosteroid receptor (GR) has been studied in oviduct cytosol prepared from estrogen-primed, 4-week-withdrawn chicken. The equilibrium dissociation constant was 6 nM for dexamethasone, and 18 300 receptor sites/cell were measured assuming that all cells contain identical concentrations of GR. Dexamethasone, used in most studies investigating glucocorticosteroid action, was found not to be the best GR ligand. The affinities of several natural and synthetic glucocorticosteroids for GR increased in the following order: cortisol less than deoxycorticosterone less than dexamethasone less than corticosterone less than triamcinolone acetonide. The synthetic steroid RU 486 was the most specific ligand of GR (its affinity was approximately equal to 10-fold higher than that of triamcinolone acetonide), while it did not bind either to plasma transcortin (which binds dexamethasone nor, surprisingly, to progesterone receptor (PR), contrary to what occurs in mammalian species. The molybdate-stabilized, 8-S form of GR was prepared from withdrawn chick oviduct, whole chick embryo or cultured chick embryo fibroblasts (which do not contain PR), and was labeled with either [3H]dexamethasone or [3H]RU 486. The sedimentation coefficient of radioactive ligand--8-S GR complexes was shifted towards heavier forms after incubation with polyclonal (IgG-G3) or monoclonal (BF4) antibodies generated against the molybdate-stabilized, 8-S form of the chick oviduct PR. Since neither IgG-G3 nor BF4 interacted with the steroid binding 4-S form of GR, it is suggested that these antibodies recognized a non-steroid binding protein common to molybdate-stabilized, 8-S forms of GR and PR.     

Temperature dependence of the dissociation rate constants for 8 S, 4 S, and meroreceptor forms of the estrogen receptor from rat uterus

Conversion of a steroid receptor complex from the 8 S to the 4S form results in new interactions between the steroid and the receptor and/or formation of new intra-protein bonds within the receptor molecule itself. These bonds must be broken before the steroid is released. In order to localize these newly formed interactions, the dissociation kinetics of meroreceptors derived from 4 S and 8 S (molybdate-stabilized) receptor complexes were examined. At temperatures between 6 and 30 degrees C, no differences in the rates of dissociation were observed for the meroreceptors derived from the two forms of estrogen receptor, whereas approximately a twofold difference in dissociation rates for 4 S intact receptor versus 8 S intact receptor was detected. These findings indicate that the new interactions accompanying this conversion are likely to occur in regions of the receptor molecule other than the C-terminal portion of the steroid-binding site. The thermodynamic parameters of the dissociation reaction for the intact 4 S, and 8 S, and meroreceptor forms, respectively were: delta H [symbol; see text] = 26.2 +/- 1.3, 19.7 +/- 1.7, and 23.2 +/- 1.0 kcal/mol; +T delta S [symbol; see text] = 9.4 +/- 1.2, 3.2 +/- 1.7 and 6.6 +/- 0.9 kcal/mol (at 25 degrees C); and delta G [symbol; see text] = 16.8 +/- 2.5, 16.5 +/- 3.4, and 16.7 +/- 1.9 kcal/mol. As is the case for other steroid receptors, an increase in the enthalpy of steroid-receptor interaction after this conversion reflects the stability of the 4 S estrogen receptor complex.     

Kinetic analyses of activation-induced changes in the hydrodynamic and surface properties of the glucocorticoid-receptor complex in mouse brain

Unactivated, molybdate-stabilized, [³H]triamcinolone acetonide-labeled, glucocorticoid receptors from mouse whole brain were activated by removal of the molybdate and incubation at 22°C for 1.5 to 24 min and then rapidly quenched at 0°C with molybdate. The loss of the 9.2 S (unactivated) form of the [³H]TA-receptor complex and the concomitant formation of the 3.8 S (activated) form displayed first-order kinetics with a half-time of less than two min. The increase in the 3.8 S form correlated nearly perfectly with an increased binding to DNA-cellulose, and with a decreased and increased adsorption to DEAE-cellulose and glass fiber filters, respectively. The changes in adsorption to these filters, which occurred at a faster rate than did the changes in binding to DNA-C, are thought to reflect an increase in the relative number of positive charges and hydrophobic groups on the surface of the activated complex.     

Hepatic Ah receptor for 2,3,7,8-tetrachlorodibenzo-p-dioxin. Partial stabilization by molybdate

In structure and general mode of action, the Ah receptor is very similar to the receptors for steroid hormones. Molybdate previously has been shown to be highly effective at preserving ligand-binding function in steroid receptors during their exposure to elevated temperature or high ionic strength and at stabilizing steroid receptors as high molecular weight oligomeric complexes. Since such stabilization by molybdate can be very useful during characterization and purification of receptors, we tested the effects of molybdate on the Ah receptor to determine if the Ah receptor, like the receptors for steroid hormones, might be stabilized. In hepatic cytosols from C57BL/6N mice and Sprague-Dawley rats, molybdate concentrations up to 30 mM in homogenizing and analysis buffers did not alter the concentration of specific Ah receptor sites detected by binding of [3H]2,3,7,8-tetrachlorodibenzo-p-dioxin. However, inclusion of 20 mM molybdate in the homogenizing buffer did significantly protect unliganded Ah receptor from thermal inactivation at 20 degrees C and from KCl-induced loss of ligand-binding ability. In accord with previous reports, 20 mM molybdate in homogenizing and analysis buffers greatly increased the concentration of detectable glucocorticoid receptor in rat hepatic cytosol and estrogen receptor in rat uterine cytosol. Exposure to 0.4 M KC1 caused the glucocorticoid receptor from rat liver to shift sedimentation from approximately equal to 8 S to approximately equal to 4 S and caused a severe loss of specific glucocorticoid binding. Presence of 20 mM molybdate stabilized the glucocorticoid receptor as a single discrete peak sedimenting at approximately equal to 8 S. In contrast, the Ah receptor from rat liver exposed to 0.4 M KC1 in the presence of molybdate sedimented as biphasic peaks; one peak (approximately equal to 9.5 S) corresponded to the form of Ah receptor observed at low ionic strength, while the other peak (approximately equal to 5.5 S) corresponded to the form of Ah receptor seen in cytosol treated with 0.4 M KC1 in the absence of molybdate. Addition of heparin to hepatic cytosols from mice or rats shifted sedimentation of Ah receptor from approximately equal to 9.5 S to approximately equal to 5.5 S. Molybdate, again, provided stabilization in the approximately equal to 9.5 S form, but only for about one-half the total Ah receptor content in both rat and mouse hepatic cytosols. In sum, molybdate is far less effective at stabilizing rodent Ah receptors than it is at stabilizing steroid receptors in the same species.     

Characterization of an antiserum against the glucocorticoid receptor

An immunoglobulin (IgG) fraction from serum of a rabbit immunized with a highly purified preparation of glucocorticoid receptor from rat liver cytosol contained specific antibodies to glucocorticoid receptor. This was shown following incubation of the [³H]triamcinolone acetonide-glucocorticoid receptor (TA-GR) complex with the IgG fraction by (I) adsorption of the [³H]TA-GR-antibody complex to protein A linked to Sepharose, (II) an increased sedimentation rate of the [³H]TA-GR-antibody complex compared to that of the [³H]TA-GR complex, and (III) an increased molecular size of the [³H]TA-GR-antibody complex when compared to that of the [³H]TA-GR complex as judged from gel filtration. The antibody fraction was characterized with regard to titer, cross-reactivity and specificity. The antibodies cross-reacted with the glucocorticoid receptor from various rat tissues (liver, thymus and hippocampus), as well as with the glucocorticoid receptor from human normal lymphocytes, chronic lymphatic leukemia cells and human hippocampus. In the rat liver, the antibody bound to both the nuclear and the cytosolic glucocorticoid receptor (Stokes radius 6.1 nm). It did not cross-react with the proteolytic fragments of the glucocorticoid receptor, the 3.6 nm complex or the 1.9 nm complex. Binding of the antibodies was not seen to the androgen, estrogen or progestin receptors in rat to rat serum transcortin. With an indirect competitive ELISA (enzyme-linked immunosorbent assay) combined with various separation techniques, based on different physiocochemical principles, it was shown that the glucocorticoid receptor was the only detectable antibody binding protein from rat liver cytosol using this assay system. These findings also indicate an immunochemical similarity between glucocorticoid receptors in different tissues as well as in different species, but not between glucocorticoid receptors and other steroid hormone receptor proteins. The cytosolic and nuclear glucocorticoid receptors in rat liver were shown to be immunochemically similar.     

Investigation of the corticosteroid receptor system in rat hippocampus by ion exchange fast protein liquid chromatography

In order to study the receptor system for adrenocortical steroids, hippocampal cytosolic preparations--containing both type I and type II receptors--were subjected to anion exchange fast protein liquid chromatography (FPLC). With running buffer containing Tris, EDTA, and glycerol three peaks (1-3) were eluted from the column at 220, 400 and 560 mM NaCl respectively regardless of whether [3H]corticosterone or [3H]RU 28362 had been used as radiotracer. None of the peaks was caused by serum transcortin as revealed by control studies. However, the sequestering influence of transcortin on receptor binding of corticosterone could be demonstrated by the FPLC technique with mixtures containing serum and hippocampus cytosol. Competition experiments with cytosolic samples revealed that type I receptor was present only in peaks 2 and 3 while type II was found in all three peaks in variable amounts, depending on the presence of molybdate. When molybdate was added to the running buffer only two peaks (2 and 3) were eluted, both containing type I and type II receptors. Peak 1 was attributed to the activated type II receptor while peak 2 represented nonactivated receptors. The origin of peak 3 remains uncertain. The data indicate that molybdate must be present in the cytosolic preparation and in the running buffer to keep type II receptor in its nonactivated form. Type I receptor was probably not transformed into the activated form in the absence of molybdate but lost binding capacity and/or affinity for corticosterone.