Biochemical and immunological characterization of estrogen binding components in human neoplastic adrenocortical tissues

The estrogen binding components in human adrenocortical tissues were examined. Two adrenocortical cancer cytosols were found to contain the binder with a relative low affinity (Kd 5 X 10(-9) M) for estradiol. The association of [3H]estradiol to these cytosols was inhibited by a large dose of unlabeled estrone, estradiol or estriol, but neither by diethylstilbestrol nor by dihydrotestosterone. Incubation of cultured cells derived from these cancers with [3H]estradiol also showed the presence of this low-affinity estradiol binder. The addition of bovine serum albumin into these cytosols surprisingly resulted in a marked increase in estradiol binding capacity in a concentration-dependent manner. This component sedimented at 5 S in the low salt sucrose density gradient. This binding ability was found to be heat-labile in the absence of estradiol, but preformation of complexes with estradiol markedly stabilized its binding ability against thermal inactivation. In addition, experiments using monoclonal antibodies to human estrogen receptor revealed that the estrogen binder from one adrenocortical cancer cytosol shared antigenic determinants with human estrogen receptor. These results suggest that the unique estrogen binder in some adrenocortical cancer has the characteristics similar to estrogen receptors in terms of thermal stability and immunological cross-reactivity to antibodies.     

Significance of lipoidal estradiol in human mammary tumors

Incubations of p-nitrophenyl fatty acyl esters and estradiol-17 beta fatty acyl 17-esters with porcine esterase, human mammary tumor cytosol and rat uterine cytosol leads to ester hydrolysis of compounds with short chain fatty acids. Esters with long chain fatty acids show no hydrolysis except in the presence of Tween 80. Short chain fatty acid esters have a higher binding potency to the estrogen receptor than long chain fatty acid esters. Extraction of the nuclear receptor peak sedimenting at 4.6S and identification of the steroid showed that about 90% of the radioactivity was associated with estradiol and only 10% with estradiol esters. These studies show that estradiol fatty acyl esters act as a storage form from which estradiol is released by enzymatic hydrolysis.     

Characterization of an unusual sex steroid binding component from the chicken oviduct

In addition to the classical estrogen receptor, chick oviduct cytosol contains a sex steroid binding component (SSB) with specificity for steroidal estrogens, androgens and progestins. We have optimized the measurement of SSB and have further characterized this protein. It was possible to quantitate [3H]estradiol binding to SSB by performing the measurements in the presence of excess diethylstilbestrol, which saturates the estrogen receptor and does not bind to SSB, and by using excess progesterone to determine nonspecific binding. Since SSB appears to be quite unstable with rapid hormone dissociation kinetics, we determined that short incubation times (usually 2 h) at 0 degrees C with 20-30% glycerol in the buffer gave optimal SSB measurements. The affinity of SSB for estradiol (Kd = 20 nM) is about 5% that of the estrogen receptor. In addition to estradiol, several androgens and progestins bind to SSB. However, the nonsteroidal antiestrogen, H1285 does not bind to SSB even though it binds well to the avian estrogen receptor. The tissue content of SSB is about 15-fold greater than for estrogen receptor and is stimulated by estrogen treatment. Whereas labeled SSB cannot be readily resolved by ion-exchange chromatography due to rapid dissociation of hormone from SSB, post-labeling experiments yield binding activity eluting with 0.2 M KCl indicating that SSB is an acidic protein having a chromatography behavior similar to that of estrogen receptor. SSB binding was dramatically reduced by the chaotropic salt, NaSCN, whereas binding to the estrogen receptor was not disrupted. SSB is stabilized by sodium molybdate, a property which is characteristic of steroid receptors. Although the role of SSB in the chick oviduct is yet to be determined, an understanding of its properties is essential for accurate determinations of the estrogen receptor.     

Identification of estrogen receptors in granulosa cells of immature rats

Nuclear and cytoplasmic binding sites for estradiol (E2-17 beta) in granulosa cells of immature rats were characterized. These binding sites for estrogen were high affinity, low capacity with an affinity constant (Kd) of 1.9 X 10(-10)M (binding capacity, Ro = 80 pM) for nuclear sites and a Kd = 3.5 X 10(-10) M (Ro = 45 pM) for cytosol sites. Binding was specific for biologically active estrogens. The estrogen receptor in granulosa cells is a protein and heat-labile as treatment with protease or pre-incubation at 37 degrees C for 1 h significantly diminished binding. RNase and DNase had no effect on estrogen binding. Sedimentation coefficients for nuclear and cytosol binding components were 5S and 8S respectively, similar to values obtained with uteri. Finally, translocation was demonstrated after a s.c. injection of E2-17 beta. Forty-five minutes post-injection, cytosol binding sites for estradiol were depleted concomitant with accumulation of nuclear binding sites. We concluded that granulosa cells of immature rats have binding sites specific for estradiol which have characteristics similar to the classical estrogen receptor in uteri.     

Dynamic pattern of estradiol binding to uterine receptors of the rat. Inhibition and stimulation by unsaturated fatty acids

The binding of estradiol to uterine cytosoluble receptors from 24-day-old rats was reduced or potentiated by unsaturated fatty acids (NEFAs), depending on the concentrations of estradiol and unsaturated NEFAs. At estradiol concentrations of up to 1.5 x 10(-8) M, unsaturated NEFAs inhibited estradiol binding to the 8 S cytosol receptor. This inhibition was dose-dependent (10-70%, p less than 0.001) and a function of NEFA unsaturation. Scatchard analysis indicated that unsaturated NEFAs caused a large decrease in receptor affinity for estradiol. Polyunsaturated NEFAs had no apparent effect on estradiol binding at estradiol concentrations of 2-4 x 10(-8) M. At high estradiol concentrations (above 4 x 10(-8) M), estradiol binding was increased 130-250% (p less than 0.01) by polyunsaturated NEFAs. This increased binding was particularly associated with proteins sedimenting at 12.5 S and the 8 S binding was, in fact, reduced. Metabolic studies showed that the reduced binding in the presence of unsaturated fatty acids was correlated with a decrease in reversibly bound estradiol at low estradiol concentrations. The increase in estradiol binding at high estradiol concentrations is the result of a reduction in reversibly bound estradiol and an increase in nonorganic solvent-extractable (water-soluble) estradiol. The amounts of these water-soluble estradiol derivatives depended on both estradiol and unsaturated NEFA concentrations. 70% of the water-soluble estradiol derivatives were trichloroacetic acid-precipitable, suggesting a covalent protein-steroid link. Thus, changes in the hydrophobic fatty acid environment of the uterine cytosol estrogen receptor could modify estrogen-receptor function by altering binding site conformation and/or by inducing changes in estradiol metabolism.     

Differential binding of antiestrogens by rat uterine and chick oviduct cytosol

Analysis of the interactions of two synthetic estrogen antagonists, tamoxifen and CI 628, with rat uterine and chick oviduct cytosol revealed significant differences in the antiestrogen binding properties of these tissues. In the rat uterus CI 628, tamoxifen and estradiol were bound to a similar number of saturable binding sites and estradiol could completely inhibit the binding of tritiated antiestrogens to these sites. In contrast, high affinity, saturable antiestrogen binding sites in chick oviduct were present at three times the concentration of estradiol binding sites and estradiol could only partially inhibit the binding of tritiated antiestrogens to these sites. It is concluded that antiestrogens bind to the estrogen receptor in both tissues and that chick oviduct has an additional saturable antiestrogen binding site distinct from the classical estrogen receptor site.     

Evidence that invivo estradiol receptor translocated into nuclei is dephosphorylated and released into cytoplasm

Most of the estradiol binding activity is lost after the receptor-hormone complex migrates into the nuclei. We report that at the same time an equivalent amount of receptor unable to bind hormone appears in cytosol. ATP incubated with uterine cytosol from 17β-estradiol injected mice causes an increase in hormone binding activity. This activation is catalyzed by the ATP-dependent enzyme which reactivates hormone binding of estradiol receptor previously inactivated by a nuclear phosphatase (1). The inactive receptor retains the property to be activated by the ATP-dependent enzyme after a partial purification by heparin-Sepharose. A large dose of cycloheximide does not inhibit the appearance of ATP-activated cytosol receptor. Apparently the 17β-estradiol receptor which migrates into the nucleus is inactivated by the nuclear phosphatase and then released in an inactive, dephosphorylated form into the cyoplasm.     

Multiple estrogen binding sites in the uterus: stereochemistry of receptor and non-receptor binding of diethylstilbestrol and its metabolites

Indenestrol A (IA), an oxidative metabolite of the synthetic estrogen diethylstilbestrol (DES), has high binding affinity for estrogen receptor in mouse uterine cytosol but possesses weak biological activity. Racemic mixture of optically active [3H]indenestrol A (IA-Rac) was separated and purified into individual enantiomers on a semi-preparative scale by HPLC with a Chiralpak OP(+) column. The structure-activity relationship was investigated among the [3H]IA enantiomers (IA-R and IA-S) and [3H]DES through direct saturation binding assays using mouse uterine cytosol. Specific binding curves and Scatchard plots were obtained for each [3H]ligand; DES, IA-Rac, IA-R and IA-S. IA-S enantiomer (Kd = 0.67) binds to the estrogen receptor with the same affinity as DES (Kd = 0.71) and four times higher affinity than IA-R (Kd = 2.56). The number of binding sites for IA-S is approximately the same as estradiol, DES and IA-Rac while IA-R binds far fewer sites than the other ligands. Saturation binding assays indicated that [3H]DES and [3H]IA enantiomers exhibited a higher level of non-specific binding to the cytosol receptor compared to estradiol which has a low level of non-specific binding. These binding studies led to the detection of an additional binding component for the stilbestrol compounds in estrogen target tissue cytosol preparations. Sucrose density gradient separation assays under low salt conditions showed that both [3H]DES and [3H]IA compounds bound to the 8S form of the receptor, the same as E2. But, in addition both DES and IA bound to another binding component in 4S region. The binding to the 4S component were partially displaced by the addition of excess unlabeled E2 and DES. Further characterization of the 4S component is described.     

Binding of estradiol-peroxidase conjugate to estrogen receptor

The binding of estradiol-horseradish peroxidase conjugate to rat uterine cytosolic estrogen receptor was studied. The conjugate having a steroid to enzyme ratio of 2.8:1 was allowed to bind to protamine precipitated receptor in presence or absence of 100-fold excess of free estradiol. The bound enzyme activity was measured and the data subjected to Scatchard analysis to obtain the dissociation constant and the number of binding sites. Although the binding parameter so obtained differed from values obtained using radiolabelled estradiol, the method may be used for comparative studies.     

Two high affinity estrogen binding proteins of different specificity in the immature rat uterus cytosol

The presence of two high affinity estrogen binding proteins in the uterine cytosol of the immature rat has been observed.Besides the 8 S cytosol estrogen $\text{receptor}$, there is a 4–5 S fraction binding estradiol and estrone with a large capacity. In fact, the two binding systems have a different affinity for estradiol and estrone, the receptor binding more the former and the 4–5 S fraction more the latter. Exposure of the cytosol to specific anti-α₁-Fetoprotein antibodies suppresses a large part of the 4–5 S binder, if not the totality. Moreover the estrogen binding 4–5 S fraction decreases with increasing age until puberty, while the $\text{receptor}$ increases. These results suggest therefore that the estradiol-estrone binding 4–5 S peak of the uterine cytosol is mainly made up of Estradiol Binding Plasma Protein-α₁-Fetoprotein (EBP-AFP). Also they confirm that “cytosol” should be taken as an operational fraction which may include extracellular components.During the course of these experiments, it has been observed that the increase of the estradiol $\text{receptor}$ is more rapid than the other uterine cytosol proteins until the 8th day, and that there is a second period of growth when it follows the development of the uterus and of the animal, as if it had reached a constant number of binding sites per cell.     

Estradiol-17β receptors in the immature rat ovary

Estradiol binding components in the cytosol and nuclear fractions of the ovary from immature rats (22–28 days old) were characterized by $\text{in vitro}$ methods. Several of the biochemical characteristics of the estradiol binding components in the ovarian tissue were compared with the estradiol receptor from the uterus. The results suggest that the ovarian estradiol binding components are similar to the specific high affinity estradiol receptors in the uterus. In the cytosol of intact rat ovary a significant fraction of the total binding sites was found to be occupied, presumably by the endogenous estrogen. Following hypophysectomy there was a significant increase in the available cytosol binding sites. Evidence for translocation of cytosol receptor-estrogen (RE) complex to the nucleus was obtained for the ovary. The sedimentation properties of the RE complex of the ovary and the uterus are similar. The ovarian cytosol RE complex sediments at 7-8S in glycerol gradients at low ionic strength and at 4S in sucrose gradients at high ionic strength. Following extraction with 0.4 M KCl the ovarain nuclear RE complex sediments at 5S in sucrose gradients which is identical to that of the uterine nuclear receptor.     

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

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

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.     

Identification of immunoassayable estrogen receptor lacking hormone binding ability in tamoxifen-treated rat uterus

Using two different monoclonal antibodies to human estrogen receptor (ER), the enzymeimmunoassay was performed. The values of ER contents in human breast cancer and untreated rat uteri obtained by this procedure were correlated well with those by [3H] estradiol binding assay. When estradiol was injected to immature rats, the enzymeimmunoassay showed the uterine receptor dynamic pattern similar to those analyzed by exchange assays. In contrast, tamoxifen administration induced the immunoassayable but nonsteroid binding form of ER. This ER-like antigen was the heat-labile molecule with the sedimentation constant of 7 S while ER in untreated rat uterine cytosol sedimented at 9 S. These results suggest the presence of unique molecular state of ER induced by tamoxifen.     

Comparative analysis of the interaction of various estrogens with the estrogen-receptor system of the uterus

Equilibrium binding of labeled estron, estradiol, estriol and DES was studied in uterine cytosol of immature Wistar rats. The dissociation kinetics of the ligand complexes with specific high affinity sites suggested the homogeneity of estrogen receptors in rat uterine cytosol. The feasibility of intracellular regulation of estrogen action in target cells both at the receptor and post-receptor levels is discussed.     

Ligand-binding properties of estrogen receptor proteins after interaction with surface-immobilized Zn(II) ions: evidence for localized surface interactions and minimal conformational changes

The site- or domain-specific immobilization of steroid receptor proteins with preserved structure and function would facilitate the identification and purification of receptor-associated regulatory components and nucleic acids. We have demonstrated previously that restricted surface regions of the estrogen receptor protein contain high affinity binding sites for immobilized Zn(II) ions. Possible conformational changes in receptor at the stationary phase immobilized metal ion interface were evaluated by monitoring alterations in the equilibrium dissociation constant (Kd) for [3H]estradiol. Soluble estrogen receptor proteins (unliganded) present in immature calf uterine cytosol were immobilized via surface-exposed Zn(II)-binding sites to beads of agarose derivatized with iminodiacetate (IDA)-Zn(II) ions. The IDA-Zn(II) bound receptor was incubated with increasing concentrations of [3H]estradiol (0.01-20 nM) in the presence and absence of unlabeled competitor (diethylstilbestrol) to determine the level of specific hormone binding. Steroid-binding experiments were performed in parallel with identical aliquots of soluble receptor. Analyses of the equilibrium binding data revealed the presence of a single class of high-affinity (Kd = 2.44 +/- 1.5 nM, n = 10) steroid-binding sites which were only marginally affected by receptor immobilization via surface-exposed Zn(II) bindings sites (Kd = 2.58 +/- 0.56 nM, n = 4). These data are consistent with the location of surface accessible Zn(II) binding site(s) on the receptor at or near the DNA binding domain which, upon occupancy, do not influence the steroid binding domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Human estrogen receptor forms multiple protein-DNA complexes

A baculovirus expression system was used to overproduce the human estrogen receptor in insect cells. The estrogen receptor made in this system is full-length, binds estrogen specifically, and is recognized by a monoclonal antibody to the human estrogen receptor. The recombinant estrogen receptor binds the estrogen response element (ERE) in both the absence and presence of estrogen if the binding is carried out in the absence of Mg2+. In the presence of Mg2+, the estrogen receptor binds the ERE in a hormone-dependent fashion. This effect is more pronounced at higher temperatures. Tamoxifen, a nonsteroidal anti-estrogen, is able to stimulate ERE binding to the same extent and under the same conditions as estradiol. Estradiol stimulates formation of an estrogen receptor-ERE complex with an increased mobility in native gels as compared with the complex formed without hormone or with tamoxifen. These results demonstrate that specific DNA binding of the estrogen receptor is not absolutely dependent on the presence of hormone and that estradiol but not tamoxifen is able to induce a change in the estrogen receptor. This differential effect of estradiol and tamoxifen may be important in understanding the role of the receptor to activate target genes differentially.     

ATP-dependent enzyme activating hormone binding of estradiol receptor

Mouse uterus estradiol receptor undergoes a inactivation-reactivation process “in vitro”. The specific estrogen binding activity inactivated by nuclei, apparently through a dephosphorylation process (1,2,3), is reactivated by an ATP-dependent process. The enzyme reactivating the receptor has been purified from calf uterus cytosol. It shows high affinity for the inactive receptor (K_m of ～ 0.3 × 10^?9 mol of 17β-estradiol binding sites/l); it is simulated by MgCl₂ and CaCl₂. Present and previous results suggest that in cytoplasm of intact cells a phosphorylation process makes the receptor able to bind hormone and in nuclei dephosphorylation of receptor causes loss of hormone binding activity.     

Melatonin blocks the activation of estrogen receptor for DNA binding.

The present study shows that melatonin prevents, within the first cell cycle, the estradiol-induced growth of synchronized MCF7 breast cancer cells. By using nuclear extracts of these cells, we first examined the binding of estradiol-estrogen receptor complexes to estrogen-responsive elements and found that the addition of estradiol to whole cells activates the binding of the estrogen receptor to DNA whereas melatonin blocks this interaction. By contrast, melatonin neither affects the binding of estradiol to its receptor nor the receptor nuclear localization. Moreover, we also show that addition of estradiol to nuclear extracts stimulates the binding of estrogen receptor to DNA, but this activation is also prevented by melatonin. The inhibitory effect caused by melatonin is saturable at nanomolar concentrations and does not appear to be mediated by RZR nuclear receptors. The effect is also specific, since indol derivatives do not cause significant inhibition. Furthermore, we provide evidence that melatonin does not interact with the estrogen receptor in the absence of estradiol. Together, these results demonstrate that melatonin interferes with the activation of estrogen receptor by estradiol. The effect of melatonin suggests the presence of a receptor that, upon melatonin addition, destabilizes the binding of the estradiol-estrogen receptor complex to the estrogen responsive element.