Characterization of estrogen receptor in estrogen-dependent transplantable rat pituitary tumor MtT/F84

Properties of nuclear and cytosolic estrogen receptors (ERs) were examined in a new transplantable rat pituitary tumor designated as MtT/F84, of which growth is stimulated by estrogen. The optimal incubation conditions of both nuclear and cytosolic exchange were found to be at 37 degrees C for 15 min and at 25 degrees C for 2 hr, respectively. Molybdate increased a specific binding of estradiol (E2) as determined by [3H]E2-binding assay. Sucrose density gradient analyses of crude cytosol revealed specific peaks of radioactivity in both 4-5S and 8-10S areas. However, only a single 5S peak was present in 0.4M KCl-extractable nuclear ER. Molybdate also enhanced the stability of cytosolic 8-10S receptor in density gradient sedimentation behavior. Scatchard plot analysis for nuclear ER yielded a single class of binding sites with a dissociation constant (Kd) of 0.317 nM and the maximum number of binding sites (NBSmax) of 25.4 fmol/mg protein. Saturation analysis of [3H]estrogen binding to cytosolic ER also yielded a straight line with a Kd of 0.146 nM and NBSmax of 58.5 fmol/mg protein. The effect of E2 administration on the intracellular distribution of ER was also examined. A marked disappearance in the ER binding in cytosol with a concomitant increase in binding in nuclear fraction was found after the administration of the unlabeled E2 in vivo, whereas the total number of ER did not change. Thus, it is concluded that properties of ER in the MtT/F84 were very similar to those in other target organs such as uterus and pituitary gland.     

Characterization of estrogen and antiestrogen binding to the cytosol and microsomes of breast tumors

The binding of [3H]estradiol and [3H]hydroxytamoxifen to the cytosol and microsomal fractions of several human breast tumors was investigated. By washing microsomal membranes with a KCl-free or a KCl-containing medium we could distinguish between intrinsic, extrinsic and contaminant estradiol binding sites in these membranes. We observed that treatment of the microsomes with low salt medium removes about 80% of the total estradiol binding sites, whereas 20% are not extractable. The concentration of unextractable [3H]estradiol binding sites in the microsomes varies in proportion to the level of cytosolic estrogen receptors (ER). About 10% of the total extranuclear specific estrogen binding sites was consistently found tightly associated to the microsomal fraction, which displays an affinity for estradiol (Kd = 0.1-0.6 nM) similar to that of the cytosolic ER. The displacement of [3H]estradiol with unlabeled hormone or with the antiestrogens, nafoxidine, enclomiphene and tamoxifen (TAM) exhibits identical IC50 values either in the cytosol or in the microsomal membranes. On the other hand, the microsomal fraction of breast tumors also binds [3H]hydroxyTAM, but with higher capacity and lower affinity than those of the cytosolic fraction. Furthermore, we did not observe correlation between the concentrations of ER and of antiestrogen binding sites (AEBS) in the tumors. These results indicate that microsomal membranes of human breast tumors contain estrogen binding sites which may be related to the cytosol ER recycling and that specific AEBS are predominantly localized in this membrane system. Furthermore, it is shown that the magnitude of estradiol binding to microsomes depends on the ER positive degree of the tumors, whereas the magnitude of the antiestrogen binding to the microsomes is independent of the ER status of the tumors.     

Regulation of uterine progesterone receptors by the nonsteroidal anti-androgen hydroxyflutamide

We have recently reported that the anti-androgen hydroxyflutamide causes delayed implantation and exhibits antideciduogenic activity in the rat. The present experiments were conducted to examine whether hydroxyflutamide binds to the uterine progesterone receptors and/or alters the progesterone binding sites in the uterus. Cytosol and nuclear fractions from decidualized rat uterus were incubated with [3H]-R5020 without or with increasing concentrations of radioinert R5020, RU486, dihydrotestosterone, or hydroxyflutamide. From the log-dose inhibition curves, the relative binding affinity of both hydroxyflutamide and dihydrotestosterone was less than 0.1% and 2%, compared with R5020 (100%) for displacing [3H]-R5020 bound to uterine cytosol and nuclear fractions, respectively. Injection of estradiol-17 beta (1 microgram/rat) to ovariectomized prepubertal rats induced a 1.85-fold increase in uterine weight by 24 h. Hydroxyflutamide at 2.5 or 5.0 mg did not significantly alter the estrogen-induced increase in uterine weight. Compared to vehicle alone, estrogen induced an approximately 5-fold increase in uterine cytosolic progesterone binding sites. Hydroxyflutamide at both 2.5- and 5.0-mg doses significantly attenuated the estrogen-induced elevation in uterine progesterone binding sites. These studies demonstrate that hydroxyflutamide does not bind with high affinity to progesterone receptors, but suppresses the estrogen-induced elevation in progesterone receptor levels in the uterus.     

Effect of estradiol and other endocrine factors on the level and dynamics of estrogen receptors in the liver cells of rats

The authors studied the effects of different doses of estradiol (E2) on the level of estrogen receptors (ER) in female rat hepatocytes and the dynamics of ER distribution between the cytosol and nuclear cell fractions and compared the changes in the ER level in the liver in different endocrine states of the body. It was shown that the ER level in hepatocytes was far lower than in uterine cells and drastically increased during puberation and after ovariectomy. It was also found that the ER level in hepatocytes was dependent on pituitary functions. After a single injection of E2, the ER level in cytosol descended and that in the nucleus rose. The degree of ER reduction in cytosol and increase in the nucleus correlated with the dose of E2. The dynamics of intercombined changes in the levels of cytosol and nuclear ER was studied at different time intervals following the injection of different doses of the hormone. Some essential organ-specific features of E2 reception in the liver were revealed. Different mechanisms of the control of ER content in the liver and uterus are postulated.     

Nuclease sensitivity of estradiol-charged estrogen receptor binding sites in nuclei isolated from normal and neoplastic rat mammary tissues

The interaction of partially purified calf uterine estradiol-charged estrogen receptor ([3H]ER) with rat nuclei was studied in vitro. We previously observed a significantly greater number of [3H]ER binding sites (at saturation) in nuclei of R3230AC mammary tumors from intact vs ovariectomized (ovex) rats with no difference in the affinity of [3H]ER binding for these nuclei. We now report on the nuclease sensitivity of [3H]ER binding sites in nuclei from these tumors and from normal rat tissues. Digestion of tumor nuclei with deoxyribonuclease I (DNase I) prior to incubation with [3H]ER in vitro resulted in a progressive loss of [3H]ER binding capacity, which was not accompanied by alterations in the affinity of [3H]ER for the nuclei (Kd = 1-3 nM). A significantly lower concentration (P less than 0.005) of DNase I eliminated 50% of the [3H]ER binding sites in nuclei of tumors from intact hosts (8 unit.min/ml) compared to tumors from ovex hosts (22 unit.min/ml). These results indicate that DNA regions capable of binding ER are more susceptible to DNase I digestion in tumors from intact rats than those from ovex hosts, suggesting that the endogenous hormonal milieu is responsible, at least in part, for maintenance of nuclease-sensitive DNA conformations in this hormone-responsive mammary tumor. The amount of DNase I required to eliminate 50% of [3H]ER binding to nuclei from lactating mammary gland, liver, and kidney ranged from 14 to 56 unit.min/ml. Therefore, accessibility of [3H]ER binding sites to nuclease digestion in normal rat tissue is generally less than that of R3230AC tumors.     

Cytosolic Type II Estrogen Binding Site in Rat Uterus: Specific Photolabeling with Estrone

Abstract

A low affinity (Kd = 30 nM), large capacity (Bmax = 2.6 pmol/g tissue) estrogen binding site was photolabeled from estradiol-stimulated rat uterus cytosol. To maximize levels of this binding site and reduce those of the type I binding site, ovariectomized rats were injected with high doses of estradiol (10μg per day) for four days with the last injection two hours before sacrifice. This treatment depleted type I estrogen receptors from the cytosol (by 90%) and raised levels of type II sites in the nucleus without affecting cytosolic type II levels. The type II estradiol binding sites were distinguished from the type I sites on the basis of their dissociation kinetics, pH-sensitivity and their behavior towards potassium chloride, somatostatin, sodium thiocyanate, sulfhydryl reagents and ammonium sulfate precipitation. These type II binding sites could be covalently photolabeled with tritiated estrone. A molecular weight of 43 kDa was found on SDS PAGE.     

Characterization of estrogen binding proteins in mouse liver cytosol: absence of sexual dimorphism

Estrogen binding proteins in mouse liver cytosol were characterized by separation on Sephadex G-75 columns, by Scatchard plot analysis, and by hormonal competition studies. A high affinity receptor (56-70 fmol/mg cytosolic protein) with a mol. wt greater than 75,000, Kd of 5.7-8.4 X 10(-10) M was identified in male and female C3H liver. A second high capacity low affinity (HCLA) binder (200-300 fmol/mg cytosolic protein) with a mol. wt of about 50,000, Kd of 1.7-7.2 X 10(-8) was also identified. Following partial purification of the estrogen binders by ammonium sulfate precipitation, Scatchard plot analysis revealed selective removal of HCLA. On Sephadex G-75 filtration, the purification also resulted in selective removal of the 17 beta-estradiol binding component with a mol. wt of 50,000. Comparison with rat cytosol separations show that the sexual dimorphism in HCLA binding proteins (5 times higher in male than female rat liver) was absent in the mouse liver. These studies document the presence of a specific high affinity estrogen binding protein in mouse liver and indicate that the sexual dimorphism in HCLA proteins is not a universal feature of all rodent species.     

Interaction of calf uterine estrogen receptors with chicken target cell nuclei

The calf uterine estrogen receptor (ER) was used to study the capacity and the characteristics of the acceptor sites in chicken target cell nuclei. The temperature-activated ER is bound at 0 degrees C with a high affinity to all chicken cell nuclei tested (Kd = 0.4-1.0 nM). The nuclear binding displayed tissue specificity: oviduct greater than liver, heart greater than spleen greater than erythrocytes and was salt-dependent. ER binding to liver nuclei measured in 0.15 M KCl varied between 3000 and 6000 acceptor sites per nucleus. Liver nuclei isolated from estrogen-treated cockerels showed a 2-fold lower binding capacity than nuclei from non-treated chickens. When nuclei were incubated with [3H]ER from embryo liver and increasing concentrations of uterine non-radioactive-ER a progressive inhibition of the binding of the liver ER was found. These experiments suggest that liver and uterine ER compete for a common acceptor site. Liver nuclei charged in vitro with calf uterine ER were digested at 0 degree C with DNAase I and micrococcal nuclease. Both enzymes excised the ER in the form of a chromatin-ER complex. A considerable portion was associated with nucleosomal subunits and a minor fraction was associated with a nuclease-sensitive, protein-poor fraction of the chromatin.     

Characterization of estrogen receptors in the hamster brain

Although the hamster is frequently used as an experimental animal for studying reproductive neuroendocrinology and sex behavior, estrogen receptors (ER) in the central nervous system have not been fully characterized. Using Sephadex LH-20 gel filtration and DNA-cellulose affinity chromatography, estrogen binding macromolecules having the physicochemical properties of classical ER were identified in cytosolic and nuclear extracts of brain tissues. These receptors exhibited high affinity for estradiol (Kd = 10(-9) M), limited capacity (30-50 fmol/g tissue), and estrogen specificity; however, competition studies indicate that brain and uterine ER have different binding kinetics. The neuroanatomic distribution of ER was similar in males and females with highest levels in the limbic brain and consistently low levels in remaining forebrain and mid/hindbrain. No sex differences in receptor number or other binding parameters were evident. Sucrose gradient centrifugation showed that cytosolic ER sedimented in the 7-8S region of a 5-20% linear gradient (no salt), whereas nuclear ER had a sedimentation coefficient of 5S under high ionic strength. On DNA-cellulose affinity columns, these receptors had an elution maximum of 0.18 M NaCl. After a single injection of estradiol, nuclear ER increased and cytosolic ER were depleted. The lower estradiol binding affinity and receptor levels in hamster brain as compared to the rat are consistent with observed species differences in neural sensitivity to estrogen. We expect these data in hamsters, a markedly photosensitive species, to provide a basis for future studies examining the role of receptors in mediating the effects of day-length on steroid dependent feedback and behavioral responses.     

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.     

Relationship between occupied form of nuclear estrogen receptor and cytosolic progesterone receptor or DNA synthesis in uteri of estradiol implanted rats

The effect of 17 beta-estradiol (E2) implantation on the cytosolic progesterone receptor (RcP), DNA and occupied form of nuclear estrogen receptor (o- Rn) content in the uterus of ovariectomized adult rats, is described. Animals were implanted with oil or E2-oil solution in Silastic capsules. The latter group animals were divided into two subgroups: in subgroup (a), capsules remained in situ until decapitation time. In subgroup (b) they were removed 48 h after implantation. The E2 implantation caused a significant increase in uterine weight, RcP and o-Rn content 48 h later. However, the DNA content increased significantly only after 72 h, but there was no significant difference in the t-Rn concentration in relation to the non-estrogenized animals. In subgroup (a) animals, these values remained unchanged until 96 h. In subgroup (b), the removal of E2 implants 48 h later caused an almost complete return to the values before the E2 implantation in terms of uterine weight, RcP and o-Rn content. However the DNA concentration remained higher and the t-Rn level was lower than those values that were obtained for the non- estrogenized rats. These results suggest that the RcP and DNA synthesis induced by E2 would be connected to the level of o-Rn, although a closer dependency over time seems to exist between the o-Rn and RcP levels than between the o-Rn and DNA concentrations.     

Estrogen receptors in quail brain: a functional relationship to aromatase and aggressiveness

Estradiol (E2) mediates many of the activational effects of testosterone (T) on masculine reproductive and aggressive behaviors. Using Japanese quail (Coturnix coturnix japonica) as an animal model, together with a newly devised procedure for quantifying aggressiveness, we recently showed that aggression is E2-dependent and that individual differences in behavioral intensity are correlated with aromatase in the hypothalamus/preoptic area (HPOA). In this study we characterized estrogen receptors (ER) in quail brain and tested the hypothesis that aromatase in brain regulates T-induced behavioral responsiveness by regulating the quantity of E2 available for receptor binding. Based on standard binding assays and Sephadex LH-20 chromatography, quail brain ER was shown to be estrogen-specific, of high affinity (Kd = 0.88 nM), and of limited capacity with highest concentrations in limbic brain areas (Bmax 23-27 fmoles/gm HPOA). In addition, this ER adhered to DNA-cellulose under activating conditions. The quantitative relationship between aromatization, ER, and aggressiveness was tested in reproductively inactive (nonaggressive) males by treatment with T +/- the aromatase inhibitor 4-hydroxyandrostenedione (OHA). After 5 days, T markedly stimulated aggressiveness, and elevated aromatase and nuclear (occupied) ER in HPOA. Simultaneous treatment with OHA blocked effects on aggressiveness and aromatase, and lowered nuclear ER, but increased cytosolic (empty) ER. Total ER (nuclear plus cytosolic) was higher after T treatment whether or not OHA was administered, suggesting that androgen per se induces ER in quail HPOA.(ABSTRACT TRUNCATED AT 250 WORDS)     

A membrane model for cytosolic calcium oscillations. A study using Xenopus oocytes.

Cytosolic calcium oscillations occur in a wide variety of cells and are involved in different cellular functions. We describe these calcium oscillations by a mathematical model based on the putative electrophysiological properties of the endoplasmic reticulum (ER) membrane. The salient features of our membrane model are calcium-dependent calcium channels and calcium pumps in the ER membrane, constant entry of calcium into the cytosol, calcium dependent removal from the cytosol, and buffering by cytoplasmic calcium binding proteins. Numerical integration of the model allows us to study the fluctuations in the cytosolic calcium concentration, the ER membrane potential, and the concentration of free calcium binding sites on a calcium binding protein. The model demonstrates the physiological features necessary for calcium oscillations and suggests that the level of calcium flux into the cytosol controls the frequency and amplitude of oscillations. The model also suggests that the level of buffering affects the frequency and amplitude of the oscillations. The model is supported by experiments indirectly measuring cytosolic calcium by calcium-induced chloride currents in Xenopus oocytes as well as cytosolic calcium oscillations observed in other preparations.     

Effect of Quinoline-Type Antimalarial Drugs on the Binding of Oestradiol-17β and Progesterone by Rabbit and Human Uterine Cytosols

Abstract

Rabbit and human uterine cytosol, prepared and tested in phosphate buffer, bound less oestradiol-17β or progesterone than cytosol from the same source prepared and tested in Tris-HCl buffer. Dissociation constants were the same in both buffer systems, and the difference in binding was due to a difference in the number of binding sites. Three quinoline-type antimalarial drugs, chloroquine, quinine and mefloquine, and the quinoline derivative, 4-(4'-hydroxy-l'-methylbutylamino)-7-chloroquinoline, increased the steroid binding capacity of phosphate-buffered cytosol to that of Tris-buffered cytosol, the optimal concentration of quinoline derivative being 1.4–1.6 mM. Tris (50 mM) increased the binding capacity of phosphate-buffered cytosol to that of Tris-buffered cytosol. The effects of Tris and quinoline derivatives were not additive. By gel chromatography and sucrose density gradient centrifugation it was shown that the molecular size and sedimentation behaviour of the oestradiol and progesterone receptors were not affected by the quinoline derivatives. Two types of binding site are proposed, one requiring the presence of low molecular weight, basic compounds. The uterine levels of chloroquine attained by normal pharmacological doses of the drug are potentially capable of influencing the binding of oestradiol-17β and progesterone in the uterine cytosol.     

The inhibition of prolactin synthesis in GH3 rat pituitary tumor cells by monohydroxytamoxifen is associated with changes in the properties of the estrogen receptor

E2 (1 nM) stimulated the synthesis of PRL in GH3 cells. OH TAM (100 nM) did not affect basal PRL synthesis, but completely inhibited the increase produced by 1 nM E2. [3H]E2 and [3H]OH TAM both bound to the cytosolic 8S ER and these were split into 4S subunits on sucrose gradients containing 0.4 M KCl. By comparison, ER complexes extracted from nuclei of GH3 cells cultured in media containing [3H]E2 or [3H]OH TAM both sedimented at 5S on sucrose gradients containing 0.4 M KCl. Both 4S and 5S ER complexes were recognized by the monoclonal antibody D547 which increased their sedimentation coefficients to 8-9S. In contrast, a polyclonal antibody raised to calf uterine ER in the goat, interacted with the cytosolic ER so that the binding of [3H]E2 was inhibited but the binding of [3]OH TAM was only slightly reduced. A molecular model is proposed to describe the binding of E2 and OH TAM to the ER that might contribute to an understanding of estrogen and antiestrogen action.     

Estrogen receptor binding to a DNA response element in vitro is not dependent upon estradiol

Gel shift assays were employed to distinguish between the contribution of 17 beta-estradiol (E2) and a short heating step to the ability of the rat uterine cytosolic estrogen receptor (ER) to bind to the estrogen response element (ERE) from the vitellogenin A2 gene (vitERE). Despite the popularity of models in which the ER is a ligand-activated DNA-binding protein, these studies find that estrogen does not significantly contribute to receptor-DNA complex formation. An avidin-biotin complex with DNA (ABCD) assay was utilized to obtain quantitative measurement of the affinities of the ER for the vitERE and a mutant sequence. Scatchard analysis gave a dissociation constant of 390 +/- 40 pM for the E2-occupied, heated ER to the vitERE. The data fit a one-site model and evidence for cooperatively was not observed. A dissociation constant of 450 +/- 170 pM was obtained for the unoccupied, heated ER, leading to the conclusion that estrogen was not necessary for specific binding to DNA. The percentage of ER capable of binding vitERE varied with each cytosol preparation, ranging from 60 to 100% and estrogen did not appear to affect this variation. Competition against the vitERE with a 2-bp mutant sequence showed a 250-fold lower relative binding affinity of the receptor for the mutant over the vitERE sequence. This ability of the ER to discriminate between target and nonspecific DNA sequences was also not dependent on the presence of estrogen.