Characterization of high affinity and low affinity dexamethasone binding sites on male rat liver nuclear envelopes

Steroids must traverse the nuclear envelope before exerting their action at the chromatin. However, few studies have been done to elucidate the mechanism by which steroids traverse this membrane barrier. As first steps towards investigating the mechanism, we have characterized the binding sites for dexamethasone on male rat liver nuclear envelopes. The nuclear envelopes, prepared in the presence of dithiothreitol, were isolated from purified nuclei after treatment with DNase 1 at high pH. Binding of dexamethasone to the nuclear envelopes was measured after 16 h of incubation at 0-4 degrees C. At pH 7.4, only a single high capacity, low affinity binding site for dexamethasone was identified. However, at pH 8.6, two sites were identified; a low capacity, high affinity site and a high capacity, low affinity site. Adrenalectomy of the animal before preparation of the membranes caused loss of the high affinity site and reduction in the number of the lower affinity sites. Acute dexamethasone treatment of adrenalectomized rats resulted in the reappearance of the high affinity site but long term treatment with dexamethasone was required for complete restoration of the high affinity sites and reappearance of any of the low affinity sites. The steroid specificity of these nuclear envelope binding sites was different from that of the cytosolic glucocorticoid receptor, generally showing broader specificity. However, triamcinolone acetonide, which is a potent competitor for binding to the glucocorticoid receptor, did not complete effectively. The binding sites were sensitive to protease treatment and salt extraction studies revealed that the dexamethasone binding sites do not represent proteins non-specifically bound to the nuclear envelope. The affinity and the hormone responsiveness of the high affinity site are similar to those of the nuclear glucocorticoid receptor. Therefore, the nuclear envelope may be a site of action of glucocorticoids.     

Interaction of glucocorticoid · receptor complexes with rat liver nuclei

Some previous reports on acellular binding of glucocorticoid · receptor complexes to rat liver nuclei have pointed to the conclusion that there exists a small number of high affinity nuclear “receptor” sites. Various investigations lead us to the opposite conclusion and suggest that these results were actually due to the presence, in the cytosol, of one or several macromolecules which inhibited the binding to nuclei of steroid · receptor complexes. The mechanism of this inhibition was examined. It appeared to be due not to a competition between both molecules for the same nuclear acceptor site but to an interaction in the cytosol between teh inhibitor and the steroid · receptor complex which prevented the binding of the latter to the nuclei. The search for high affinity specific acceptor sites was also negative for physiological saline conditions and for the non-salt-extractable fraction of the nuclear receptor. When 940-fold purified receptor · steroid complexes were used, very high concentrations of complexes could be achieved and saturation of nuclei was then observed, but only under physiological ionic strength conditions. However, the interaction was of relatively low affinity (K_A = 3.8 · 10⁷ M^?1) and to a great number of acceptor sites (N = 26.2 pmol/mg DNA), largely exceeding the cellular concentration of receptor (5.8 pmol/mg DNA).These results suggested that saturation of nuclei by steroid · receptor complexes should not occur in the intact liver cell. They were confirmed by studies on the distribution of steroid · receptor complexes in liver slices incubated with various concentrations of [³H]dexamethasone. For all hormone concentrations a constant proportion (90%) of the complexes was found in the nuclei, thus showing no saturation of the nuclear acceptor sites.     

Receptor binding in the rat liver nuclear matrix

3H-Dexamethasone (Dex)-receptor complexes prepared from the rat liver cytosol efficiently bound to the nuclear matrix from the same tissue. The binding was increased with the concentration of the 3H-Dex-receptor complex added and reached a maximum plateau. However, when the partially purified 3H-Dex-receptor complex was used, saturation of the binding sites in the nuclear matrix was not observed in the range of concentration of 3H-Dex-receptor complex used. Therefore, it was considered that the apparent saturability observed in the binding of the unpurified receptor complexes is caused by the translocation inhibitor(s) in the cytosol. When the binding capacity was expressed on the basis of unit weight of DNA, the nuclear matrix exhibited 20 times more of that of the unfractionated nuclei. However, no line of evidence of enrichment of the binding sites in the DNA isolated from the nuclear matrix was observed. These observations show that the role of the nuclear matrix in the action of glucocorticoid is quite uncertain.     

Nuclear acceptor sites for androgen-receptor complexes in seminal-vesicle epithelium.

An assay method in vitro was developed and applied to quantify acceptor binding of steroid-receptor complexes in nuclei from isolated epithelium of guinea-pig seminal vesicle. Steroid-receptor complex prepared from 1-day-castrated animals was incubated with purified nuclei from 1-28 day-castrated animals in a medium containing 0.15 M-KCl. Free and bound steroid-receptor complexes were measured and the data were submitted to Scatchard analysis. With nuclei from 1-day-castrated animals the Kd for binding of cytosolic [3H]dihydrotestosterone-receptor complexes was found to be 0.83 X 10(-10) M and the capacity for binding was 0.35 pmol/mg of nuclear DNA. Scatchard analysis consistently disclosed only a single line of constant slope and gave the same kinetic constants for nuclei obtained from animals castrated up to 28 days before assay. Administration of 2 mg of dihydrotestosterone, 3 alpha-androstanediol or androsterone or 100 microgram of oestradiol-17 beta 1 h before killing of the 1-day-castrated animals that provided the nuclei resulted in a significant decrease in nuclear acceptor binding of the steroid-receptor complex compared with untreated animals. Thus our assay method disclosed nuclear acceptor sites that may be involved in responses to androgens (and oestrogens) in vivo. We conclude that there is a class of nuclear accept or sites of high affinity and limited capacity that may be occupied by steroid-receptor complexes in vivo.     

Binding of glucocorticoid receptors to DNA.

DNA has been implicated as the nuclear acceptor for receptor-glucocorticoid complexes. The present study concerns the interaction of these complexes, isolated from cultured rat hepatoma cells, with purified DNA. This association is rapid, reaching a maximum within a few minutes at 0 degrees, whereas dissociation requires several hours. DNA binds neither free glucocorticoids nor those complexed with transcortin or cytosol proteins different from the receptor. Receptors which are not complexed by steroid have little or no affinity for DNA. "Activation," necessary for the binding of receptor-steroid complexes to isolated nuclei, also enhances DNA binding. The capacity of DNA for binding receptor-steroid complexes is large; saturation was not observed at the complex concentrations studied, using either crude or partially purified receptor preparations. The association of complexes with DNA is inhibited by divalent cations, at increasing ionic strengths, and by mercurial reagents. Complexes bind equally well to bacterial, bacteriophage, or rat DNA; however, there was either no or substantially reduced binding by bacterial 23 S rRNA. The binding of complexes to native DNA is roughly 3-fold greater than to denatured DNA. These characteristics are consistent with the possibility that DNA is the nuclear acceptor for receptor-glucocorticoid complexes; however, the actual composition of the acceptor sites remains unknown.     

Binding of [3H]triamcinolone acetonide-receptor complexes to chromatin from the B-cell leukemia line, BCL1

The binding characteristics of partially purified glucocorticoid receptor complexes from hormone sensitive, non-differentiating BCL1 cells to sequentially deproteinized BCL1 chromatin-cellulose was investigated. [3H]Triamcinolone acetonide (TA)-receptor complexes were purified (approx. 30-fold) from DEAE-cellulose columns by salt elution which allowed receptor activation only in the absence of molybdate. Addition of 10 mM molybdate completely blocked salt activation. The binding pattern of the activated [3H]TA-receptor complexes to chromatin-cellulose extracted with 0-8 M guanidine hydrochloride revealed three regions of increased binding activity (acceptor sites), at 2, 5 and 7 M guanidine hydrochloride. Acceptor site binding was markedly reduced for chromatin extracted with 3, 6 and 8 M guanidine hydrochloride. Non-activated receptor complexes demonstrated very low binding to deproteinized chromatin. It was also shown that chromatin binding required glucocorticoid receptors and that free ligand or ligand bound to other proteins did not bind significantly to chromatin. In addition, binding of [3H]TA-receptor complexes to partially deproteinized chromatin was competable by unlabeled TA-receptor complexes. Scatchard analysis demonstrated that chromatin from non-differentiating BCL1 cells possesses multiple, high-affinity binding sites which differ in their affinity for the glucocorticoid receptor. Partially deproteinized chromatin from lipopolysaccharide-stimulated BCL1 cells demonstrated a different pattern of receptor binding, i.e., receptor binding was significantly greater to chromatin previously extracted with 6-8 M guanidine hydrochloride. These results suggest that differentiation alters the state of chromatin and the interaction of non-histone protein/DNA acceptor sites with glucocorticoid receptors. These alterations may play a role in the acquisition of hormone resistance.     

A new mechanism for steroid unresponsiveness: loss of nuclear binding activity of a steroid hormone receptor

The glucocorticoid, dexamethasone, binds to the specific cytosol receptors of a steroid-resistant mouse lymphoma cell line with the same affinity as to the receptors of the steroid-responsive parental cells. In the sensitive cells, the receptor-steroid complex translocates to the nucleus, whereas in the resistant cells nuclear transfer is greatly diminished. “Activated” receptor-dexamethasone complex from sensitive cells binds to isolated nuclei from both sensitive and resistant cell types, whereas the complex from the resistant cells binds to neither nuclei. Furthermore, the activated complex from sensitive cells binds to isolated homologous and heterologous DNA, whereas the complex from the resistant cells displays greatly reduced binding activity, implying that DNA plays a significant role in nuclear binding. These results suggest that the normal glucocorticoid receptor has two active domains: one for steroid binding, and the other for interaction with nuclear acceptor sites. The resistant cells described in this paper contain a receptor apparently defective in the latter activity.     

Binding of the glucocorticoid receptor to the rat liver nuclear matrix. The role of disulfide bond formation

The nuclear matrix is a putative skeletal structure which has been implicated in many nuclear functions. To assess a possible role of the nuclear matrix in glucocorticoid action, purified rat liver nuclei containing glucocorticoid-receptor complexes were treated with DNase I +/- RNase A followed by 1.6 M NaCl, thus yielding salt-extractable and salt-resistant (nuclear matrix) fractions. The subnuclear distribution of hormone-receptor complexes was determined by following the fate of unmetabolized radiolabel after injection of labeled triamcinolone acetonide into adrenalectomized animals and subjecting various subfractions to immunoblotting using a monoclonal antibody which recognizes the glucocorticoid receptor. Both techniques indicated that 50-70% of the total nuclear hormone-receptor complexes were recovered in the nuclear matrix fraction. Previous results (Kaufmann, S. H., and Shaper, J. H. (1984) Exp. Cell Res. 155, 477-495) suggest that a variety of nuclear polypeptides become nuclease- and salt-resistant as a result of the formation of intermolecular disulfide bonds. The following evidence suggests that disulfide bonds mediate the association between the glucocorticoid receptor and the nuclear matrix. When nuclei were isolated in the absence of sulfhydryl-blocking and -cross-linking reagents, sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions revealed that the receptor was present as a high molecular weight disulfide-cross-linked complex. When nuclei were isolated in the presence of the irreversible sulfhydryl-blocking reagent iodoacetamide, the disulfide bonds which cross-linked the receptor into high molecular weight complexes were absent; and 85-100% of the hormone-receptor complexes were salt-extractable. When nuclei (isolated in the absence of iodoacetamide) were treated with the sulfhydryl-cross-linking reagent sodium tetrathionate, greater than 95% of the nuclear hormone-receptor complexes became resistant to extraction with nucleases and 1.6 M NaCl. The implications of these results for other matrix-associated nuclear functions are discussed.     

Interaction of glucocorticoid receptor-steroid complexes with acceptor sites.

The binding of the "activated" receptor-glucocorticoid complexes of cultured rat hepatoma cells to nuclei, chromatin, and DNA has been studied under cell-free conditions. A critical factor in determining the shape of the binding curve is shown to be an inhibitory material which is present in crude cytosol and which can be removed without destroying the receptor-steroid complex. These and other results argue that the apparent saturation observed in earlier experiments may have been due to the inhibitors. Thus, the actual number of acceptor sites in hepatoma tissue culture cell nuclei is much larger than previously estimated and their affinity for the complex is lower. Nuclear binding experiments indicate that the inhibitory material interacts with the receptor-steroid complex. The inhibitors appear to be macromolecular; but their effects cannot be mimicked by albumin or hemoglobin. The acceptor capacity at low ionic strength for binding receptor-glucocorticoid complexes increases when proceeding from nuclei to DNA. An analysis of the kinetics of association and dissociation and of the relative binding behavior of nuclei and DNA argues that the affinity of complex for nuclei is much greater than for DNA. DNA-associated histones reduce the amount of complex that binds to DNA. These and perhaps other chromosomal proteins may be responsible for the ordering of acceptor capacity. Evidence is presented that the difference in affinities of nuclear and DNA acceptors could also be due to chromosomal proteins. In nuclei, these proteins may thus both reduce the amount of complex binding by rendering regions of DNA less accessible and increase the binding affinity of some, or all, of those DNA binding sites which remain exposed.     

Nuclear oestrogen receptors in rat liver. Development of assay conditions, characterization and the translocation of oestrogens in vivo.

A method for the determination of specific oestrogen-receptor binding sites in rat liver nuclei is described. Nuclear receptors showed a high affinity for oestradiol (Kd approximately 3 x 10(-9)M), a low capacity, and a distinct specificity for substances with known oestrogenic and anti-oestrogenic activity. No sex differences were seen in the concentrations of nuclear receptors from either vehicle- or ethynyloestradiol-pretreated rats. Only a limited number of binding sites could be extracted with 0.4 M-KCl. The remaining sites, which were solubilized by sonication and treatment with deoxyribonuclease I, sedimented at 3-4 S. Of four oestrogens tested (oestradiol, ethynyloestradiol, diethylstilboestrol, tri-p-anisylchloroethylene), ethynyloestradiol was the most effective translocation agent in vivo, nuclear uptake occurring at doses below 1 microgram/rat; changes in salt extractability of nuclear receptors occurred at doses lower than those required to achieve absolute increases in nuclear receptor concentrations.     

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.     

Transformation in vitro and covalent modification with biotin of steroid-affinity-purified rat-liver glucocorticoid-hormone-receptor complex

The molybdate-stabilized rat liver glucocorticoid receptor complex was purified 9000-fold with a 46% yield by steroid-affinity chromatography and DEAE-Sephacel ion-exchange chromatography. The purified glucocorticoid receptor was identified as a 90-92-kDa protein by SDS/polyacrylamide gel electrophoresis. Raising the temperature to 25 degrees C in the absence of molybdate resulted in increased binding of the receptor complex to DNA-cellulose or nuclei, similar to the effect on the cytosolic complex. The purified complex has a sedimentation coefficient of 9-10 S before and after heat treatment in the absence of molybdate. The appearance of smaller 3-4-S species was unrelated to the extent of DNA-cellulose binding of the complex. The process termed 'transformation', i.e. increasing the affinity for DNA, is not concomitant with subunit dissociation or loss of RNA. Highly purified glucocorticoid receptor could be covalently modified with biotin to retain its steroid-binding activity but with a 50% decrease in nuclear binding capacity. The biotin-modified complex reacts with streptavidin in solution without losing its steroid.     

Multiple species of estrogen binding sites in the nuclear fraction of the rat prostate

Specific estrogen-binding sites have been demonstrated in purified nuclear fractions of prostates from intact rats. Saturation analysis of nuclei over a wide range of [³H]-estradiol concentrations (0.15 to 90 nM) has shown two different types of binding sites: a) one with high affinity (Kd of 0.5–0.8 nM) and low capacity for estradiol (approximately 162 fmole/mg DNA); b) a second with a lower affinity (Kd of 30–40 nM), which shows a higher capacity (approximately 860 fmole/mg DNA), and displays a saturation curve that is sigmoidal and that appears to be similar to those for Type II estrogen-binding sites in rat uterus. These results suggest that the actions of estradiol in the prostate are mediated by specific nuclear binding sites.     

Phosphorylation and nuclear processing of the androgen receptor.

Although transformed androgen receptor (AR) complexes derived from cytosol and nuclear AR complexes have been shown to bind with high affinity to nuclei and DNA, we have shown that the binding characteristics of the two receptor populations to rat ventral prostate nuclei are different. To account for these differences, we investigated the possibility that the two receptor populations differed in phosphorylation status. Significantly, an anti-phosphotyrosine antibody immunoprecipitated androgen binding from the nuclear AR preparation but not from the transformed cytosolic receptor preparation. These studies suggest that (i) further processing of the AR complex takes place after it has become transformed, and (ii) phosphorylation of the complex is one modification which occurs during the processing of the nuclear receptor.     

DNA binding properties of glucocorticosteroid receptors bound to the steroid antagonist RU-486.

RU-486 is an anti-fertility steroid which also has anti-glucocorticosteroid effects. RU-486 is shown to be a strong antagonist of the glucocorticosteroid-induced cytolytic response of the murine thymoma lines W7TB and T1M1b , and of the induction of mouse mammary tumor virus (MMTV) mRNA in T1M1b cells. The glucocorticosteroid receptor of W7 cells has high affinity for RU-486 (Kd = 3 X 10(-9) M) but the complex formed has low nuclear transfer capacity. Binding of RU-486, as compared with the glucocorticosteroid agonist triamcinolone acetonide, to mouse receptor results in a decreased affinity for DNA in general and a reduced specific recognition of a site in the promoter region of MMTV proviral DNA. The RU-486 complex formed with rat liver receptor exhibits the same behavior; in addition, it is shown that only a fraction of these complexes are activated by temperature and these form highly salt-sensitive interactions with DNA. These results indicate that the binding of RU-486 to glucocorticosteroid receptors mimics pharmacologically the properties of a class of receptor variants (nt-) which are non-functional and have reduced nuclear transfer and altered DNA binding capacity. These results substantiate the importance of DNA binding in receptor function.     

Binding of corticosteroid receptors to rat hippocampus nuclear matrix.

In rat hippocampus, the mineralocorticoid receptor and the glucocorticoid receptor bind corticosterone with high affinity. We have studied the association of these receptors with the nuclear matrix both after in vivo and in vitro administration of radiolabelled corticosterone to hippocampus cells. It was found that in vivo 100% and in vitro 60% of the corticosterone that specifically bound to rat hippocampus nuclei was attached to the nuclear matrix. A selective glucocorticoid receptor agonist did not compete for corticosterone binding. This indicates that this binding was mediated by the mineralocorticoid receptor rather than the glucocorticoid receptor.     

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

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

Binding of [3H]triamcinolone acetonide-receptor complexes to chromatin from the B-cell leukemia line,BCL1

The binding characteristics of partially purified glucocorticoid receptor complexes from hormone sensitive, non-differentiating BCL₁ cells to sequentially deproteinized BCL₁ chromatin-cellulose was investigated. [³H]Triamcinolone acetonide (TA)-receptor complexes were purified (approx. 30-fold) from DEAF-cellulose columns by salt elution which allowed receptor activation only in the absence of molybdate. Addition of 10 mM molybdate completely blocked salt activation. The binding pattern of the activated [³H]TA-receptor complexes to chromatin-cellulose extracted with 0–8 M guanidine hydrochloride revealed three regions of increased binding activity (acceptor sites), at 2, 5 and 7 M guanidine hydrochloride. Acceptor site binding was markedly reduced for chromatin extracted with 3, 6 and 8 M guanidine hydrochloride. Non-activated receptor complexes demonstrated very low binding to deproteinized chromatin. It was also shown that chromatin binding required glucocortical receptors and that free ligand or ligand bound to other proteins did not bind significantly to chromatin. In addition, binding of [³H]TA-receptor complexes to partially deproteinized chromatin was competable by unlabeled TA-receptor complexes. Scatchard analysis demonstrated that chromatin from non-differentiating BCL₁ cells possesses multiple, high-affinity binding sites which differ in their affinity for the glucocorticoid receptor. Partially deproteinized chromatin from lipopolysaccharide-stimulated BCL₁ cells demonstrated a different pattern of receptor binding, i.e., receptor binding was significantly greater to chromatin previously extracted with 6–8 M guanidine hydrochloride. These results suggest that differentiation alters the state of chromatin and the interaction of non-histone protein/DNA acceptor sites with glucocorticoid receptors. These alterations may play a role in the acquisition of hormone resistance.