A potential mechanism in medroxyprogesterone acetate teratogenesis.

MPA (medroxyprogeste)rone acetate) has been shown to be te)ratogenic in rabbits but not in rats or mice (Andrew and Staples 1977). Since normal steroid action appears to be mediated, in large part, through interaction with specific steroid receptors, it was postulated that the species difference in teratogenicity might be due to a difference in the interaction of MPA with target cells. A primary event in steroid-cell interaction is the binding of a steroid to intracellular receptors. Studies were initiated to measure the specific nature of MPA binding to glucocorticoid and progestin receptors in appropriate rat and rabbit target tissues. The competition of MPA with 3H-dexamethasone binding in liver cytosol (glucocorticoid receptor) and with 3H-progesterone binding in uterine cytosol (progesterone receptor) was determined. In rabbit liver cytosol, MPA was as effective at competing for specific dexamethasone binding as the natural glucocorticoids and considerably more effective than the nonspecific steroids. In rat liver cytosol MPA was only 10% as effective as the natural glucocorticoids and the competition could not be distinguished from that of nonspecific steroids. A similar species difference was not seen in uterine cytosol; MPA competed with progesterone in a similar fashion in both rat and rabbit. These data demonstrate a distinct species difference in the competitive nature of MPA for the glucocorticoid receptor but not for the progestin receptor. The results suggest that MPA, or possibly a metabolite, may be teratogenic in rabbits by binding with specific glucocorticoid receptors to inhibit or alter normal steroidal function in embryo-fetal development.     

New functions for the components of glucocorticoid receptor apparatus?

By ammonium sulphate precipitation, phosphocellulose and DEAE-Sephacel chromatography and Sephadex G-75 gel filtration, a factor was separated from rat liver cytosol which was shown to suppress the inhibitory effect of the steroid deoxycorticosterone (DOC) on the specific [3H]glucocorticoid binding to cytoplasmic receptors. By SDS-polyacrylamide gel electrophoresis (SDS-PAGE) of factor-containing fractions its Mr was suggested to be about 40000. The possible role of this factor in the regulation of glucocorticoid receptor apparatus function is discussed.     

The heat-stable cytosolic factor that promotes glucocorticoid receptor binding to DNA is neither thioredoxin nor ribonuclease

Treatment of rat liver cytosol containing temperature-transformed [3H]dexamethasone-bound receptors at 0 degree C with the sulfhydryl modifying reagent methyl methanethiosulfonate (MMTS) inhibits the DNA-binding activity of the receptor, and DNA-binding activity is restored after addition of dithiothreitol (DTT). However, transformed receptors that are treated with MMTS and then separated from low Mr components of cytosol by passage through a column of Sephadex G-50 have very little DNA-binding activity when DTT is added to regenerate sulfhydryl moities. The receptors will bind to DNA if whole liver cytosol or boiled liver cytosol is added in addition to DTT. The effect of boiled cytosol is mimicked by purified rat thioredoxin or bovine RNase A in a manner that does not reflect the reducing activity of the former or the catalytic activity of the latter. This suggests that the reported ability of each of these heat-stable peptides to stimulate DNA binding by glucocorticoid receptors is not a biologically relevant action. We suggest that stimulation of DNA binding of partially purified receptors by boiled cytosol does not constitute a reconstitution of a complete cytosolic system in which the dissociated receptor must associate with a specific heat-stable accessory protein required for DNA binding, as has been suggested in the "two-step" model of receptor transformation recently proposed by Schmidt et al. (Schmidt T.J., Miller-Diener, A., Webb M.L. and Litwack G. (1985) J. biol. Chem. 260, 16255-16262).     

Modulators of the glucocorticoid receptor also regulate mineralocorticoid receptor function.

Modulators are proposed to be novel ether aminophosphoglycerides that stabilize unoccupied and occupied glucocorticoid receptor steroid binding and inhibit glucocorticoid receptor complex activation. Two isoforms, modulator 1 and modulator 2, have been purified from rat liver cytosol [Bodine, P.V., & Litwack, G. (1990) J. Biol. Chem. 265, 9544-9554]. Since the mineralocorticoid receptor is relatively resistant to activation, modulator's effect on rat distal colon mineralocorticoid receptor function was examined. Warming of unoccupied receptor decreased residual specific [3H]aldosterone binding by 86 +/- 2%. Both modulator isoforms completely prevented this destabilization with Km's of 2 +/- 1 microM modulator 1 and 24 +/- 5 microM modulator 2. Warming of occupied mineralocorticoid receptors decreased [3H]aldosterone binding by 56 +/- 3%. Modulator only partially stabilized occupied receptor binding with Km's of 10 +/- 2 microM modulator 1 and 68 +/- 8 microM modulator 2. Modulator inhibited receptor activation with Km's of 3 +/- 1 microM modulator 1 and 33 +/- 10 microM modulator 2. Double-reciprocal analysis showed linear kinetics, and mixing modulator isoforms together had additive effects on unoccupied and occupied receptor steroid binding stabilization and activation inhibition. Colon cytosol contained a low molecular weight, heat-stable factor(s) which inhibited receptor activation and stabilized occupied receptor steroid binding. Molybdate completely stabilized unoccupied mineralocorticoid receptor steroid binding and inhibited activation with half-maximal effects at 3-4 mM but only stabilized occupied receptor binding by approximately 40%. These data indicate that (i) apparent physiologic concentrations of modulator stabilize mineralocorticoid receptor steroid binding and inhibit receptor activation, (ii) an aldosterone-responsive tissue contains a modulator-like activity, and (iii) molybdate mimics the effects of modulator.(ABSTRACT TRUNCATED AT 250 WORDS)     

Factor-assisted DNA binding as a possible general mechanism for steroid receptors. Functional heterogeneity among activated receptor-steroid complexes

We previously reported that activated glucocorticoid receptor-steroid complexes from rat HTC cell cytosol exist as at least two sub-populations, one of which requires a low molecular weight (700–3000 Da) factor(s) for binding to DNA. This factor is removed by Sephadex G-50 chromatography and is found predominantly in extracts of crude HTC cell nuclei. We have now determined that factor is not limited to HTC cells since an apparently identical factor(s) was found in nuclear extracts of rat kidney and liver as well as human HeLa and MCF-7 cells. Furthermore, the DNA binding of a sub-population of human glucocorticoid receptors depends on factor. While these results were obtained with agonist (dexamethasone) bound receptors, a sub-population of HTC cell receptors covalently labeled by the antiglucocorticoid dexamethasone 21-mesylate also displayed factor-dependent DNA binding. This receptor heterogeneity was not an artifact of cell-free activation since the cell-free nuclear binding of dexamethasone mesylate labeled complexes was, as in intact cells, less than that for dexamethasone bound complexes. Earlier results suggested that the increased DNA binding with factor involved a direct interaction of receptor with factor(s). We now find that the factor-induced DNA binding is retained by amino terminal truncated (42 kDa) glucocorticoid receptors from HTC cells. Thus the ability of receptor to interact with factor(s) is encoded by the DNA and/or steroid binding domains. Two dimensional gel electrophoresis analysis of dexamethasone-mesylate labeled 98 kDa receptors revealed multiple charged isoforms for both sub-populations but no differences in the amount of the various isoforms in each sub-population. Finally, activated progesterone and estrogen receptor complexes were also found to be heterogeneous, with a similar, if not identical, small molecular weight factor(s) being required for the DNA binding of one sub-population. The observations that functional heterogeneity of receptors is not unique to glucocorticoid receptors, whether bound by an agonist or antagonist, and that the factor(s) is neither species nor tissue specific suggests that factor-assisted DNA binding may be a general mechanism for all steroid receptors.     

Molecules acting on receptor level at weaning, durably influence liver glucocorticoid receptors

In the experiments the effect of late hormonal imprinting to the liver glucocorticoid receptors were studied. Three-week-old (weanling) female rats were treated with five molecules acting at receptor level and four weeks later receptor kinetic analysis was done on liver glucocorticoid receptors. The tricyclic antidepressant, histamine and serotonin receptor blocker mianserin positively influenced receptor density and negatively receptor affinity. Vitamin D3 and the environmental pollutant benzpyrene elevated receptor density. Mifepristone (RU 486) which is bound by progesterone- and glucorticoid-receptor without postreceptorial effects was ineffective as well, as the H1 receptor blocker chlorpheniramine. The results demonstrate that receptor-level-acting foreign molecules can durably influence the binding capacity of glucocorticoid receptors, however, this is not a general phenomenon and it is not dependent on the type of receptors (membrane or cytosol). Those molecules were effective which 1. have receptor in the same receptor family (vitamin D3) and have postreceptorial effect, or 2. have a structure similar to steroids (benzpyrene) or 3. deeply influenced steroid receptors in earlier experiments (mianserin). This effect should be considered before administering such type of medicaments.     

Inactivation of hepatic glucocorticoid receptors by heparin

Heparin dramatically enhanced the rate of unbound glucocorticoid receptor inactivation in vitro in a concentration, time and temperature-dependent manner. Control specific binding decreased only about 25% after incubation for 6 h at 4°C. However in the presence of heparin (40 μg per ml cytosol) receptor binding decreased about 75%. At 25°C liver receptor specific binding was found to have a half0life of about 60 min in control cytosol. However, in the presence of heparin (40 μg per ml cytosol) the glucocorticoid receptor had a half-life of only 15 min at 25°C. Interestingly, 10 mM molybdate (with or without 5 mM dithiothreitol) greatly inhibited heparin-dependent receptor inactivation at 4°C. Dithiothreitol (alone) significantly stabilized receptor binding in control samples at 4°C, but provided no protection from heparin-dependent receptor inactivation. Heparin had no apparent inactivating effect on prebound glucocorticoid receptor complexes at 4°C. Interestingly however, heparin altered the sedimentation coefficient of prebound hepatic glucococorticoid-receptor complexes in low salt gradients from 7–8 S to about 3–4 S. When molybdate plus dithiothreitol were added with heparin, the sedimentation coefficient was found to be approx. 6—7 S. These results demonstrate that heparin, which is often used pharmacologically and which occurs naturally in animal tissues, has significant effects on liver glucocorticoid receptors in vitro.     

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.     

A study of the cytoplasmic receptors for glucocorticoids in intestine of pre- and postweanling rats.

Glucocorticoids cause both enzymic and morphologic changes in the rat intestine during the time of weaning. To obtain information regarding the mechanism of these actions, we examined the cytoplasmic fraction of intestines from 18-day-old rats for the presence of specific glucocorticoid-binding proteins which are characteristics of target tissues. Incubation of slices of intestine with [3H]dexamethasone in a physiological medium at 2 degrees showed the presence of a cytoplasmic binding macromolecule with high specificity for steroids having glucocorticoid activity. The binding reaction was saturable (concentration of binding sites equals 0.24 pmol per mg of protein) and of high affinity (dissociation constant equals 9.3 nM). Binding was reversible on addition of nonlabeled dexamethasone (t 1/2 equals 5.2 hours), indicating that the usual assay procedure measured both corticosterone-filled and unoccupied binding sites. Sucrose density gradient centrifugation showed that the receptor-dexamethasone complex from intestinal cytosol sedimented at the same rate as that from liver (8.2 S). The receptor-dexamethasone complex was stable at 2 degrees for at least 24 hours in intestinal slices, but in isolated cytosol fractions there was considerable loss of binding even in the presence of high concentrations of [3H]dexamethasone. Furthermore, mixing experiments showed that the presence of cytosol from intestinal mucosa (but not from the muscle layers) caused a dissociation of dexamethasone from receptors of liver cytosol. This suggested the presence of some interfering factor in isolated mucosal cytosol and meant that quantitative studies had to be confined to intact slices. Although the reasons for the instability of steroid-receptor complexes in the presence of isolated intestinal cytosol are not understood, the instability is believed to be associated with homogenization and, therefore, is believed to have no physiological significance. Finally, the ontogenesis of cytoplasmic glucocorticoid receptors in intestinal slices was examined and the pattern compared with that in liver and lung. Receptor activity was present in intestine from late fetal life through adulthood, but concentrations were significantly higher during the first two postnatal weeks than at all other times. By contrast, receptor activity detected in cytosol prepared from rat lung was high around the time of birth, while that in liver rose steadily during the first postnatal week and remained at high levels. Thus specific receptors for glucocorticoids are present in the rat intestine during periods of both responsiveness and unresponsiveness. This suggests that although corticosteroids exert their effects through the cytoplasmic receptors, this early event in glucocorticoid action may not be a controlling step for changes in responsiveness during development.     

Inactivation by Na+,K+-ATPase of cytosol glucocorticoid receptors from rat brain and liver

Summary We have examined the effect of Na⁺,K⁺-ATPase on ³H-triamcinolone acetonide binding capacity of cytosol glucocorticoid receptors from rat brain and liver. Preincubation of the brain or liver cytosol with Na⁺,K⁺-ATPase (10 units/ml) at 30 °C resulted in a rapid loss of specific ³H-triamcinolone acetonide binding, with a half-life of approximately 7 min. The ATPase effect could be prevented by the addition of 10^–5 M ouabain, or substantially reduced by the omission of Na⁺,K⁺ or Mg⁺². The cytosol receptor bound with ³H-triamcinolone acetonide was totally resistant to the inactivation by the ATPase. Since there is some evidence that ATP may bind to glucocorticoid receptor, our findings indicate that an ATP-receptor complex may be essential for steroid binding. The effects of the ATPase in the inactivation of the receptor are very similar to those of alkaline phosphatase reported by others. This raises doubts about the proposal based on the phosphatase inactivation that the cytosol glucocorticoid receptor may be phosphorylated.     

Transformation of glucocorticoid and progesterone receptors to the DNA-binding state

This brief review explores some recent observations relating to the structure of untransformed glucocorticoid and progesterone receptors and the mechanism by which the receptors are transformed to the DNA-binding state. In their molybdatestabilized, untransformed state, progesterone and glucocorticoid receptors exist as a heteromeric 8-9S complex containing one unit of steroid binding phosphoprotein and one or two units of the 90 kD heat shock protein hsp90. When the receptors are transformed, the steroid-binding protein dissociates from hsp90. In cytosol preparations, temperature-mediated dissociation proceeds much more rapidly in the presence of hormone. The dissociated receptor binds to DNA with high affinity, regardless of whether it is in the hormone-bound or the hormone-free state. These observations raise the possibility that the primary, and perhaps the only, role for the hormone is to promote dissociation of the receptor-hsp90 complex. Molybdate, vanadate, and tungstate inhibit receptor transformation to the DNA-binding form, an effect that appears to reflect the ability of these transition metal oxyanions to stabilize the complex between the steroid receptor and hsp90. By promoting the formation of disulfide bonds, hydrogen peroxide also stabilizes the glucocorticoid receptor-hsp90 complex and prevents receptor transformation. A small, heat-stable factor present in all cytosol preparations inhibits receptor transformation, and, when the factor is removed, glucocorticoid receptors are rapidly transformed. This ubiquitous factor has the physical properties of a metal anion, and it is proposed that molybdate and vanadate affect steroid receptor complexes by interacting with a metal anion-binding site that is normally occupied by this endogenous receptor-stabilizing factor.     

Interaction of rat liver glucocorticoid receptor with sodium tungstate.

Effects of sodium tungstate on various properties of rat liver glucocorticoid receptor were examined at pH7 and pH 8. At pH 7, [3H]triamcinolone acetonide binding in rat liver cytosol preparations was completely blocked in the presence of 10--20 mM-sodium tungstate at 4 degrees C, whereas at 37 degrees C a 30 min incubation of cytosol receptor preparation with 1 mM-sodium tungstate reduced the loss of unoccupied receptor by 50%. At pH 8.0, tungstate presence during the 37 degrees C incubation maintained the steroid-binding capacity of unoccupied glucocorticoid receptor at control (4 degrees C) levels. In addition, heat-activation of cytosolic glucocorticoid-receptor complex was blocked by 1 mM- and 10 mM-sodium tungstate at pH 7 and pH 8 respectively. The DNA-cellulose binding by activated receptor was also inhibited completely and irreversibly by 5 mM-tungstate at pH 7, whereas at pH 8 no significant effect was observed with up to 20 mM-tungstate. The entire DNA-cellulose-bound glucocorticoid-receptor complex from control samples could be extracted by incubation with 1 mM- and 20 mM-tungstate at pH 7 and pH 8 respectively, and appeared to sediment as a 4.3--4.6 S molecule, both in 0.01 M- and 0.3 M-KCl-containing sucrose gradients. Tungstate effects are, therefore, pH-dependent and appear to involve an interaction with both the non-activated and the activated forms of the glucocorticoid receptor.     

Stabilization of glucocorticoid receptors in vitro using divalent cations plus cation chelators

The specific glucocorticoid receptor binding of rat liver cytosol was very unstable in vitro at 25 and 4 degrees C. However, 5 mM CaCl2 added with 5 mM EDTA to cytosol prior to incubation markedly stabilized unbound glucocorticoid receptors at both temperatures. Optimal effectiveness was achieved using equimolar (5 mM) amounts of CaCl2 and EDTA. On the other hand, 5 mM CaCl2 (added alone) further destabilized the unbound glucocorticoid receptor, while 5 mM EDTA (added alone) had no effect at 25 degrees C. EGTA (in lieu of EDTA) added with CaCl2 stabilized hepatic receptor binding at 25 degrees C. On the other hand, citrate added with calcium was ineffective in stabilizing the hepatic glucocorticoid receptor. MgCl2 effectively replaced CaCl2 as a stabilizing agent at 25 degrees C if added with 5 mM EDTA. When added alone, MgCl2 slightly destabilized the unbound receptor. Sucrose density gradient analysis (in low salt) revealed that CaCl2 plus EDTA enhanced the steroid-receptor complex sedimentation coefficient from 7 S to about 10 S. Unlike molybdate, CaCl2 plus EDTA had no apparent effect on steroid-receptor complex thermal transformation into a nuclear binding form, while MgCl2 plus EDTA partially reduced transformation. These results suggest a novel means to chemically stabilize unbound hepatic glucocorticoid receptors in vitro which may be of particular importance for receptor purification studies.     

Relationship between glucocorticoid receptor steroid-binding capacity and association of the Mr 90,000 heat shock protein with the unliganded receptor

Treatment of rat liver cytosol with hydrogen peroxide (H2O2) or sodium molybdate (MoO4(2-)) inhibits thermal inactivation of glucocorticoid receptor steroid-binding capacity at 25 degrees C. Dithiothreitol (DTT) prevents the stabilization of receptors by H2O2. Heating (25 degrees C) of immune pellets formed by immunoadsorption of L-cell murine glucocorticoid receptor complexes to protein-A-Sepharose with an anti-receptor monoclonal antibody (BuGR2) results in dissociation of the M 90,000 heat shock protein (hsp90) from the steroid binding protein. Such thermal-induced dissociation of hsp90 is inhibited by H2O2. Pretreatment of immunoadsorbed receptor complexes with the thiol derivatizing agent, methyl methanethiosulfonate (MMTS) prevents the ability of H2O2 to stabilize the hsp90-receptor interaction. These data suggest a role for hsp90 in maintaining an active steroid-binding conformation of the glucocorticoid receptor.     

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.     

Influence of molybdate, ionic strength and pH on ligand binding to the glucocorticoid receptor

The addition of molybdate to rabbit liver cytosol increased significantly the affinity of the glucocorticoid receptor for [3H] dexamethasone without influencing the concentration of binding sites. This effect was concentration dependent. Analysis of the binding data by curve-fitting and Scatchard plot revealed the occurrence of a complex binding process in the presence of molybdate. The pH-dependence curve of the binding was shifted towards alkaline values by the oxyanion. Taken together, these data suggest that molybdate exerts its effects via an interaction with the receptor molecule.     

Duration of antagonizing effect of RU486 on the agonist induction of tyrosine aminotransferase via glucocorticoid receptor

The duration of the antagonizing activity of RU486 on tyrosine aminotransferase (TAT) induction and the glucocorticoid receptor in rat liver was studied. A single dose of RU486 (10 mg/kg) caused occupation of the cytosol glucocorticoid receptor in rat liver at 1h. During this time no nuclear binding of [³H]dexamethasone ([³H]Dex) receptor complex was recorded, and TAT induction was completely blocked. TAT inducibility recovery parallelled receptor binding in both the cytosol and the nuclei, reaching maximum at 12 h. In contrast, nuclear binding recovered in 24 h, and [³H]Dex receptor binding in cytosol 48 h after RU486 application. It is concluded that the inhibitory effect of a single dose of RU486 on TAT induction is of rather short duration. At concomitant presence of agonist and antagonist in vivo, no direct correlation between agonist receptor occupancy and TAT induction could be observed.     

Monoclonal antibodies to the rat liver glucocorticoid receptor.

Monoclonal antibodies against the 90 000 mol. wt. form of the activated rat liver glucocorticoid receptor were generated from mice immunized with a partially purified receptor preparation. The screening assay was based on the precipitation of liver cytosol, labelled with [3H]triamcinolone acetonide, with monoclonal antibodies bound to immobilized rabbit anti-mouse IgG. Out of 102 hybridomas obtained, 76 produced immunoglobulin and eight of them were found to react with the receptor molecule. Only one of the positive clones secreted IgG whereas the other seven produced IgM. The complexes of receptor and antibodies were identified by sucrose density gradient centrifugation. All seven monoclonal antibodies tested reacted with the 90 000 mol. wt. form of the receptor but not with the 40 000 mol. wt. form that contains the steroid and DNA binding domains. None of the monoclonal antibodies interfered with the binding of the receptor to DNA cellulose, thus suggesting that the antigenic determinants are located in a region of the receptor that is not directly implicated in either steroid binding or DNA binding. These antigenic determinants were common to glucocorticoid receptors from several tissues of the rat, whereas glucocorticoid receptors from other species react only with some of the antibodies.     

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.     

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.