A specific glucocorticoid binding macromolecule of rabbit uterine cytosol

A high affinity (K_d=2.7 × 10^?10M at 0°) dexamethasone binding macro-molecule has been identified in the cytosol fraction of rabbit uteri. Competition studies show high specificity for glucocorticoids since binding of labeled dexamethasone is inhibited by cortisol and corticosterone but not by progesterone, testosterone, or estradiol 17β. The binding component has a sedimentation coefficient of 8S and its concentration in uterine cytosol is about 0.2 pmoles per mg protein. Uptake of labeled dexamethasone by isolated uterine nuclei requires the presence of cytosol and is temperature dependent. The KCl-extractable nuclear complex sediments at 4S. Thus the dexamethasone binding components of the rabbit uterus have properties similar to those described for steroid hormone receptors present in target tissues. Specific dexamethasone binding could not be demonstrated in rat uterine cytosol.     

Androgen receptors from the epididymis of the rhesus monkey

The demonstration and partial characterization of androgen "receptors" in the epididymis of the rhesus monkey are reported. The affinity of specific binding sites for dihydrotestosterone was higher than that for testosterone while cortisol and corticosterone did not compete. Density gradient analysis of the cytosol revealed that macromolecules responsible for specific binding have a sedimentation coefficient of 8 S. The isoelectric point of the complex was 5.5 and thermoability was evidenced by the release of hormone during incubation at 27 degrees C (20% and 44% after 30 and 60 minutes, respectively.) A concomitant decrease in radioactivity bound to 8 S cytoplasmic components suggests the translocation into the nuclei of a modified 8 S-receptor complex. These data indicate the presence of similar cytoplasmic and nuclear androgen receptors in the monkey seminal vesicles and prostate gland.     

Activation of glucocorticoid cytoreceptors in rat heart]

Accumulation of 3H-dexamethasone by the nuclei in a cell-free system was studied. The increase in temperature from 0 degrees to 20 degrees C and treatment of cytosol by KCl (0.4 M) or theophylline (10mM) significantly increased the absorption the bound hormone by the nuclear fraction. Activation of the steroid-protein complex induced by temperature and addition of theophylline did not change its size. The increase in the ionic strength decreased the Stokes radius from 53 A down to 39.5 A and the sedimentation coefficient value from 7S down to 4S. It is concluded that the heart tissue cytoplasm contains a glucocorticoid receptor.     

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

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

Progesterone-binding components of chick oviduct. VIII. Receptor activation and hormone-dependent binding to purified nuclei.

A cell-free system prepared from the estrogen-primed chick oviduct was developed and used to study the uptake of cytoplasmic progesterone-receptor complex by isolated nuclei. The receptor and purified nuclei were shown to be stable at 25 degrees, but not at 37 degrees. Thus, nuclear incubations were routinely performed at 25 degrees. Such incubations revealed greater nuclear uptake of the cytoplasmic hormone-receptor complex as compared to control incubations performed at 0 degrees. The uptake process showed a quantitative preference for oviduct nuclei. No net uptake occurred during 0 degrees incubations when the nuclei were preincubated in the absence of cytoplasmic components at 25 degrees. In contrast, the temperature requirement was partially removed by preincubation of the hormone-receptor complex at 25 degrees prior to incubation with nuclei at 0 degrees. Nuclear uptake was not accompanied by measurable alterations in the sedimentation properties of the progesterone receptor. The activation and nuclear uptake of receptor was clearly dependent upon prior binding of steroid hormone to the receptor indicating that the active nuclear form of the receptor could not be generated in the absence of the hormone. Receptor precipitation with ammonium sulfate also partially removed the temperature requirement for nuclear binding. In contrast to temperature activation, ammonium sulfate precipitation activated the receptor in the absence of hormone. It thus seemed likely that temperature and salt activation of receptor occurred via different mechanisms. Although we were able to destroy up to 60% of the nuclear DNA content by treatment with DNase prior to nuclear incubation, some 80 to 85% of the receptor-binding capacity was still present in the treated nuclei. Thus, chick progesterone receptors apparently bind to a relatively DNase-resistant portion of the oviduct genome. The properties of this system indicate its value for further investigation into the initial events of progesterone action in the chick oviduct.     

Comparison of formation, activation, and nuclear translocation of receptor . estradiol (R . E2) complex at 0 degrees C and 37 degrees C in intact uterine cells.

The present study was undertaken to establish whether molecular events leading to binding, transformation-activation, and nuclear translocation of cytoplasmic uterine estrogen receptor described for cell-free systems also occur in intact uterine cells. Cell suspensions were incubated at 0 degrees C or 37 degrees C with estradiol (E2) and specific binding to intracellular receptors was measured. The data demonstrate that saturation of specific estrogen binding sites occurs within 60 min at 37 degrees C and within 22 h at 0 degrees C, with a total of approximately 24,000 to 30,000 receptor sites per cell. At equilibrium, the total number and subcellular distribution of receptor . estradiol (R . E2) complexes formed in cells incubated at 0 degrees C or 37 degrees C were identical. Scatchard analysis of the equilibrium binding data yielded the same association constants for cytoplasmic and nuclear R . E2 formed in intact cells incubated at either temperature. Sucrose density gradient analysis of nuclear and cytoplasmic R . E2 formed in intact cells at 0 degrees C or 37 degrees C showed that at both temperatures, the nuclear R . E2 had a 5 S sedimentation coefficient; at both temperatures, a 5 S cytosol R . E2 was detected; only in the 0 degrees C incubation, an additional 4 S cytosol R . E2 was found. These results suggest that the molecular interactions regulating the dynamics of estrogen binding in the intact cell are similar at both physiological and low temperatures.     

Human progesterone receptor binding to mouse mammary tumor virus deoxyribonucleic acid: dependence on hormone and nonreceptor nuclear factor(s)

Using crude progesterone receptor preparations from T47D human breast cancer cells, we show by immunoprecipitation assay that receptor specifically and with high affinity recognizes the hormone response element (HRE) of the mouse mammary tumor virus (MMTV). The use of crude preparations minimizes alterations of receptors or loss of associated factors that may occur during purification. Specific binding was obtained at 1:1 molar ratios of receptor to DNA, and HRE sequences are recognized with an affinity at least 3 orders of magnitude greater than nonspecific DNA. We have compared the DNA-binding activities of different forms of progesterone receptors. The unliganded 8S cytosol receptor had low but detectable binding activity for MMTV DNA. Addition of hormone to cytosol produced a small but consistent 2.5-fold increase. In vitro methods of transforming cytosol receptors from an 8S to a 4S species failed to increase DNA-binding further. By contrast, 4S receptors bound by R5020 in whole cells and extracted from nuclei by salt, displayed a substantially higher (average, 11-fold) binding activity than an equal number of unliganded cytosol receptors. The dissociation constants for cytosol and nuclear receptor binding to MMTV DNA were similar (approximately 2 x 10(-9) M). Thus, nuclear receptors possess a higher capacity for binding to specific recognition sequences. These results suggest that hormone or a hormone-dependent mechanism increases the intrinsic DNA-binding activity of receptors independent of receptor transformation from 8S to 4S. Further experiments indicate that a nonreceptor activity in nuclear extracts can increase the sequence-specific DNA-binding activity of cytosol receptors. This activity is present in both T47D cells and receptor-negative MDA-231 cells. We conclude that the higher DNA-binding activity of the nuclear receptor-hormone complex is due in part to receptor interaction with other nuclear proteins or factors. Such interactions may function to maintain receptors in a disaggregated active complex or to stabilize their binding to specific DNA sites.     

Oestrogen receptors in chick oviduct. Characterization and subcellular distribution.

Macromolecular components with properties of oestrogen receptors have been identified in the 0.5 M KCl nuclear soluble, the nuclear insoluble and the cytosol fractions of laying hen and immature (2--4 weeks, untreated by hormone) chicken oviduct. 7n the 0.5 M KCl extract of laying hen oviduct nuclei, a receptor, of protein nature according to the effects of enzymic treatments, has been identified. It exhibits high affinity for oestradiol with an apparent equilibrium association constant KA = 4 - 109 M-1 at 4 degrees C. The binding of [3H] oestradiol is abolished by 1 muM oestriol, oestrone and diethylstilboestrol, but not by the same concentration of progesterone, testosterone, and cortisol. Sucrose gradient ultracentrifugation studies in the presence of 0.5 M KCl indicate a sedimentation coefficient of 4.3 S, and there is partial aggregation in low-ionic-strength medium. The estimated number of binding sites per nucleus is about 5000, as calculated from DNA content of chick diploid genome. Most of the binding sites were found to be occupied by endogenous oestrogen(s). Oestradiol dissociates from the receptor according to an apparent two-step mechanism. The half-life time for the faster dissociation step is 18 h at 0 degrees C, 25 min at 20 degrees C and 10 min at 30 degrees C, and for the slower one is 180 h, 115 min and 60 min, respectively. In the 0.5 M KCl extract of immature chicken oviduct nuclei, there are approximately 500 receptor sites per nucleus; their affinity for oestradiol is the same as in the case of laying hen soluble nuclear receptor. After repeated extractions of nuclei with 0.5 M KCl medium, a substantial quantity of oestrogen binding sites remains in the residual fraction. Binding characteristics of this insoluble nuclear receptor resemble those of the soluble nuclear receptor: high affinity for oestradiol (KA = 7 - 10(8) M-1 at 37 degrees C) and specificity for oestrogens. The estimated number of binding sites are approximately 2000/cell for laying hen, and approximately 1000/cell for immature chicken. In the high-speed supernatant fraction of laying hen oviduct homogenates, an oestrogen receptor is also present, but its concentration is low (less than or equal to 100 sites/cell) and at the limits of sensitivity of the methods used. In the cytosol of immature chicken oviduct, there are approximately 2500 oestradiol receptor sites per cell.     

Nuclear interactions of retinoic acid-binding protein in chemically induced mammary adenocarcinoma.

Cellular retinoic acid-binding protein (CRABP) was detected in the nuclear fraction of N-methyl-N-nitrosourea-induced mammary cancers after the incubation of cytosol containing [3H]retinoic acid (RA)-bound CRABP with isolated nuclei. CRABP extracted from the nuclei in buffer containing 0.4 M-KCl sedimented as a 2 S component when subjected to sucrose-density-gradient analysis. [3H]RA-CRABP was found to be a prerequisite for the detection of nuclear binding, since the incubation of isolated nuclei or 0.4 M-KCl extract of the nuclei with [3H]RA did not result in any significant binding. Incubation of [3H]RA-CRABP at 25 or 30 degrees C before incubation with the nuclei neither altered the sedimentation coefficient nor enhanced the nuclear binding compared with 0 degrees C incubation. The tumour nuclei contained a saturable number of binding sites with a dissociation constant of 1.6 x 10(-9) M. These results indicate that the action of retinoic acid in the target organ may be mediated by its interaction with the nuclei.     

Limited proteolysis of cytoplasmic and nuclear uterine estradiol receptors yields identical estradiol-binding fragments.

Limited tryptic hydrolysis of the estradiol cytoplasmic receptor from calf uterus has been demonstrated to yield in a high-salt buffer a stable estradiol-binding molecule with the following characteristics: sedimentation coefficient 4.0 +/- 0.1 S; Stokes radius 3.5 +/- 0.05 nm; molecular weight 60000 (for an assumed v value of 0.73 ml g-1) and frictional ratio 1.36. Nuclear KCl extracts, prepared from uteri preincubated at 37 degrees C with labeled estradiol, were analysed by Sephadex G-200 chromatography and sucrose density gradient centrifugation. The following molecular parameters were found for the estradiol-receptor complex: sedimentation coefficient 4.4 +/- 0.1 S; Stokes radius 4.12 +/- 0.02 nm; molecular weight 77000 and frictional ratio 1.47 (v = 0.73 ml g-1). Limited tryptic proteolysis of this extract gave an estradiol-binding fragment with molecular characteristics identical to the trypsin-modified cytoplasmic receptor. In addition, mild tryptic digestion of whole labeled nuclei allowed us to solubilize almost quantitatively the nuclear [3H]estradiol in a macromolecular bound form. The molecule thus obtained showed molecular parameters very similar to the 60000-dalton trypsin fragments obtained from high-salt cytoplasmic and nuclear extracts. These molecules were undistinguishable by gel electrophoresis analysis at six different acrylamide concentrations. These results in conjunction with those derived from dissociation kinetics experiments and ligand specificity studies indicate the cytosolic protein is a functional part of the nuclear receptor. Based upon these and other studies we suggest that proteolytic cleavage of the estradiol-receptor complex, which results in the removal of the estradiol-binding sites from the nuclear recognition sites of the molecule, could play a role in the inactivation of the estradiol receptor in vivo.     

Protein kinases of the chick oviduct: a study of the cytoplasmic and nuclear enzymes.

Subcellular fractionation of oviduct tissue from estrogen-treated chicks indicated that the bulk of the protein kinase activity of this tissue is located in the cytoplasmic and nuclear fractions, DEAE-cellulose chromatography of cytosol revealed a major peak of cAMP stimulatable activity eluting at 0.2 M KCl. This peak was further characterized and found to exhibit properties consistent with cytoplasmic cAMP dependent protein kinases isolated from other tissues; it had a Km for ATP of 2 X 10(-5) M, preferred basic proteins such as histones, as substrate, and had a M of 165 000. Addition of 10(-6) M cAMP caused the holoenzyme to dissociate into cAMP binding regulatory subunit and a protein kinase catalytic subunit. Extraction of purified oviduct nuclei with 0.3 M KCl released greater than 80% of the kinase activity in this fraction. Upon elution from phospho-cellulose, the nuclear extract was resolved into two equal peaks of kinase activity (designated I and II). Peak I had a sedimentation coefficient of 3S and a Km for ATP of 13 muM. while peak II had a sedimentation coefficient of 6S and a Km for ATP of 9 muM. Both enzymes preferred alpha-casein as a substrate over phosvitin or whole histone, although they exhibited different salt-activity profiles. The cytoplasmic and nuclear enzymes were well separated on phospho-cellulose and this resin was used to quantitate the amount of cAMP dependent histone kinase activity in the nucleus and the amount of casein kinase activity in the cytosol. Protein kinase activity in nuclei from estrogen-stimulated chicks was found to be 40% greater than hormone-withdrawn animals. This increase in activity was not due to translocation of the cytoplasmic protein kinase in response to hormone, but to an increase in nuclear (casein) kinase activity. During the course of this work, we observed small but significant amounts of cAMP binding activity very tightly bound to the nuclear fraction. Solubilization of the binding activity by sonication in high salt allowed comparison studies to be performed which indicated that the nuclear binding protein is identical with the cytoplasmic cAMP binding regulatory subunit. The possible role of the nuclear binding activity is discussed.     

Estrogen-binding proteins of calf uterus. Purification to homogeneity of receptor from cytosol by affinity chromatography.

The estrogen receptor has been purified to homogeneity from calf uterus cytosol by sequential affinity chromatography by using heparin--Sepharose 4B and 17-hemisuccinyl-17beta-estradiol-ovalbumin--Sepharose 4B. The procedure yields about 1.2 mg of receptor protein from 1 kg of calf uteri, with a recovery of 53%. The receptor protein, as a complex with 17beta-[3H]estradiol, is purified more than 99%. A single band is seen on polyacrylamide gel ectrophoresis under nondenaturing conditions. 17beta-[3H]Estradiol comigrates with the protein band. As computed from the specific activity of radioactive hormone, 64,450 g of purified receptor protein binds 1 mol of 17beta-estradiol. 17beta-[3H]Estradiol bound to the protein is displaced by estrogenic steriods but not by progesterone, testosterone, or cortisone. As judged by chromatography on calibrated Sephadex G-200 columns, the purified receptor is identical with native receptor in crude cytosol: both show a Stokes radius of 6.4 nm. On sucrose gradient in low-salt buffer, the purified receptor sediments at 8 S. On electrophoresis in NaDodSO4 gels, the purified receptor migrates as a single protein band with an apparent molecular weight of 70,000. The sedimentation coefficient measured on sucrose gradients in the presence of chaotropic salts [1 M NaBr or NaSCN (0.1 M)] is 4.2 S. We conclude that the estrogen receptor of cytosol consists of a single subunit weighing about 70,000 daltons and endowed with one estrogen binding site. Under native conditions in cytosol, several subunits associate to form a quaternary structure with a Stokes radius of 6.4 nm.     

Recognition of two forms of the estrogen receptor in the guinea-pig uterus at different stages of development by a monoclonal antibody to the human estrogen receptor. Dynamics of the translocation of these two forms to the nucleus

Two forms of the estrogen receptor were recognised in the cytosol fraction of fetal uterus of guinea pig by a monoclonal antibody (D547Spγ) to the human estrogen receptor. It was observed that 60–65% of the total cytosol estrogen receptor (the α form) was bound to the antibody, increasing its sedimentation coefficient in a high ionic strength sucrose gradient (10–30% w/v sucrose, 0.4 M KCl) from 4.5 S to 7.4 S. The remaining fraction (the β form) has the classical sedimentation coefficient of 4.5 S. Dynamic studies of the translocation in vitro of the cytosol receptor to the nucleus as a function of time have shown that the a form decreases sharply while the β form is slightly affected when the cytosol was incubated with the nuclei. In contrast only one form, which is bound totally to the antibody, was found in the nuclear fraction. In addition, the presence of these two forms of the cytosol estrogen receptor was also demonstrated in newborn and immature animals.     

Glucocorticoid receptors in lung. Mechanism of specific glucocorticoid uptake by fetal rabbit lung nuclei.

After exposure of fetal rabbit lungs to glucocorticoid in vivo or in vitro, the hormone binds to specific receptors localized in the cytoplasm and in the nuclei. The present studies are compatible with a mechanism by which the nuclear receptor originates from the cytoplasm and arises from a hormone-, temperature-, and ionic strength-dependent transfer of the cytoplasmic receptor into the nucleus. This conclusion is reached from the following observations. Specific binding of glucocorticoid to nuclei from lungs not previously exposed to the hormone is not observed unless the cytosol is also present. In the presence of cytosol, nuclear uptake of the hormone is very slow at 0 degrees but is highly enhanced with increasing temperature. Concomitantly with the increased nuclear uptake there is an equiivalent loss of glucocortoid-receptor complex from the cytosol, indicating that the complex is transferred to the nuclei by a temperature-dependent process. Although the nuclei do not bind the cytoplasmic complex at 0 degrees, they do so provided that the cytosol is briefly heated in the presence of hormone prior to mixing with the nuclei. Thus the cytoplasmic complex must first be activated before it can bind to nuclei..     

A protease acting on the estrogen receptor may modify its action in the adult rabbit epididymis

We have previously shown that the cytosolic estrogen receptor in adult rabbit epididymides sediments as an congruent to 3 S species on sucrose gradients containing 0.01 M KCl while that from immature rabbit epididymides sediments at congruent to 9 S. This age-dependent decrease in sedimentation coefficient is attributable to the appearance of a leupeptin-sensitive protease as the animals mature. We now show that if adult epididymides are homogenized in buffer containing leupeptin, the 9 S receptor can be demonstrated, indicating inhibition of receptor degradation. In vitro nuclear uptake studies conducted in the absence of leupeptin indicated that the proteolyzed receptor was not an efficient nuclear binder. When leupeptin was present, nuclear uptake increased 6-fold and it was accompanied by depletion of receptor from the cytosol. Binding of the receptor to nuclei was specific since it could be inhibited by unlabeled estrogens but not by unlabeled 5 alpha-dihydrotestosterone or progesterone. In vitro mixing experiments indicated that the proteolytic activity was associated with the crude nuclear fraction since, in the absence of leupeptin, they had reduced ability to bind estrogen receptor present in immature epididymal cytosol. Specific in vivo binding of [3H]estradiol by adult and immature rabbit epididymides could be demonstrated. The time course of in vivo binding of [3H]estradiol by adult rabbit epididymal nuclei indicated maximum binding (70 fmol/g tissue) at 30 min following injection. By 60 min, the amount of binding had decreased to about 25 fmol. The accessory sex organs, which do not contain the protease, also exhibited maximum binding (150 fmol/g tissue) at 30 min. However, at the 60 min period binding was still about 140 fmol. Processing the tissues in buffers containing leupeptin had no effect on the results obtained. These results are interpreted to indicate that the presence of the protease decreases nuclear binding of the estrogen receptor and shortens nuclear occupancy. This combination of factors may be responsible for the decrease in estrogen action in the adult rabbit epididymis.     

RNase A effects on sedimentation and DNA binding properties of dexamethasone-receptor complexes from HeLa cell cytosol

Dexamethasone-receptor complexes from HeLa cell cytosol sediment at 7.4S in low salt sucrose gradients, and at 3.8S in high salt gradients. If cytosol is heated at 25 degrees C, receptor complexes sediment at 6.9S in low salt, and at 3.6S in high salt gradients. RNase A treatment at 25 degrees C, instead, results in receptor complexes which sediment in low salt gradients as two major forms at 6.5 and 4.8S. Receptor complexes from RNase A-treated cytosols sediment as their counterparts from untreated cytosols in high salt gradients. Although the shift in sedimentation properties of receptor complexes at 2 degrees C is induced by RNase A, and not by other low molecular weight basic proteins or RNase T1, the effect can be also obtained by inactive RNase A. The catalytically active enzyme, however, is required to observe 6.5 and 4.8S complexes after cytosol incubations at 25 degrees C. Placental ribonuclease inhibitor prevents the appearance of RNase A-induced receptor forms at 25 degrees C, but not at 2 degrees C. Moreover, this inhibitor can prevent the 7.4 to 6.9S shift in sedimentation coefficient of receptor complexes caused by cytosol heating. Dexamethasone-receptor complexes from HeLa cell cytosol show low levels of binding to DNA-cellulose, and heating at 25 degrees C is required to observe a six-fold increase in DNA binding levels. RNase A treatment of cytosols at 2 degrees C does not result in significant enhancement in receptor complex binding to DNA. If RNase A treatment is carried out at 25 degrees C, however, DNA binding levels of receptor complexes increased by 25% over the values observed with control heated cytosol. This effect cannot be observed if RNase T1 substitutes for RNase A. Placental ribonuclease inhibitor can prevent the temperature-dependent increase in DNA binding properties of dexamethasone-receptor complexes either in the presence or absence of exogenous RNase A. These findings indicate that exogenous RNases can perturb the structure of dexamethasone-receptor complexes without being involved in the transformation process.     

The nonactivated progesterone receptor is a nuclear heterooligomer

The discovery of the nuclear localization of estradiol and progesterone receptors in the absence of the steroid hormone has led to reconsideration of the model of cytoplasmic to nuclear translocation of these receptors upon exposure to hormone. Unoccupied nonactivated receptors are thought to be weakly bound to nuclei of target cells from which they are leaking during tissue fractionation and thus found in the cytosol fraction of homogenates in a nontransformed heterooligomeric "8-9 S" form, which includes hsp90. However, no direct biochemical evidence has yet been obtained for the presence of such heterooligomers in the target cell nucleus, possibly because it dissociates in high ionic strength medium used for extraction of the nuclear receptor. We took advantage of the combined stabilizing effects of tungstate ions and antiprogestin RU486 to extract a nuclear non-DNA binding nontransformed 8.5 S-RU486-progesterone receptor complex from estradiol-treated immature rabbit uterine explants incubated with the antagonist. As demonstrated by immunological criteria and by irreversible cross-linking with dimethylpimelimidate, the complex contained, in addition to the hormone binding unit, hsp90, and p59, another nonhormone binding protein. Control experiments carried out with the progestin R5020 yielded the expected nuclear transformed DNA binding 4.5 S-R5020-progesterone receptor complex. These results offer evidence for two distinct forms of steroid receptor in target cell nuclei. Besides the classical "4 S" agonist-receptor complex, tightly bound to the DNA-chromatin structure and in all probability able to trigger the hormonal response, we have observed in the RU486-bound state a non-DNA binding nontransformed 8.5 S form, presumably already present in the nucleus in the absence of hormone and representing the native nonactive form of the receptor.     

Properties of triiodothyronine binding sites in cerebral cortical cytosol

Some properties of brain cytosol components that specifically bind L-triiodothyronine (T3) were examined in order to resolve their relevance and relationship to nuclear receptors. A marked variation in T3 binding activity was apparent among different brain areas. Binding exhibited temperature dependence and was maximal at 0 degrees C. The binding component was shown to be a protein that migrated as a single included peak on Sephadex G-100 columns at a position corresponding to a Stokes radium of 30A degrees and a M.W. of 54,000. On a linear glycerol gradient the T3-macromolecular complex was estimated to have a sedimentation constant of .4.2S. By combining sedimentation and gel filtration data the calculated M.W. was 53,000. With DEAE-cellulose chromatography the T3 complex eluted as a single peak at 115mM KH2PO4. The results indicate that the properties of the cytosol thyronine-binding protein are similar in many respects to those reported for nuclear receptors. In addition, the regional and developmental binding parameters parallel those for nuclei. We conclude that cytosolic recognition sites may function in the modulation of nuclear receptors and in addition serve to distinguish target from non-target tissue.     

Interaction of the calf uterine estrogen receptor with acceptor sites in heterologous chicken target cell nuclei

Estrogen receptor (ER) from chicken liver and calf uterus were used to study the capacity and the characteristics of the receptor binding sites (acceptor sites) in chicken target cell nuclei. Binding studies were performed at a physiological salt concentration of 0.15 M KCl. Binding of liver ER to liver nuclei was temperature-dependent, showing a 9-fold increase between 0 and 28 degrees C. The maximal number of acceptor sites measured in this cell-free system (280 sites/nucleus) was considerably lower than measured in nuclei after in vivo administration of estrogen (820 sites/nucleus). Moreover incubation of nuclei with the liver ER preparation resulted in a substantial breakdown of nuclear DNA, making this ER less suitable for DNA binding studies. The temperature-activated calf uterine receptor bound to liver nuclei at 0 degrees C, at which temperature no DNA degradation was measured. To all chicken cell nuclei tested, the receptor bound with a high affinity (Kd = 0.4-1.0 nM). Nuclear binding displayed tissue specificity: oviduct greater than heart, liver greater than spleen greater than erythrocytes and was salt dependent. Calf uterine ER binding in liver nuclei ranged from 3000-6000 acceptor sites per nucleus when assayed under conditions of a constant protein or a constant DNA concentration. Nuclei isolated from estrogen-treated cockerels bound a 2-fold lower number of calf uterine ER complexes when compared to control nuclei. Incubation of nuclei with a fixed concentration of [3H]ER from liver and increasing concentrations of uterine non-radioactive-ER also resulted in a reduced binding of the liver receptor. Both types of experiments suggest that liver and uterine ER compete for a common nuclear acceptor site. Our data demonstrate that the ER from calf uterus is very useful as a probe to examine the nature of the acceptor sites in heterologous chicken target cell nuclei. The assay system functions at 0 degrees C, a temperature at which no DNA degradation occurs.     

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.