Estrogen regulation of methyl p-hydroxyphenyllactate hydrolysis: correlation with estrogen stimulation of rat uterine growth

We have recently demonstrated that methyl p-hydroxyphenyllactate (MeHPLA) is the endogenous ligand for nuclear type II binding sites in the rat uterus and other estrogen target and non-target tissues. MeHPLA binds to nuclear type II binding sites with a very high binding affinity (Kd approximately 4-5 nM), blocks uterine growth in vivo, and inhibits MCF-7 human breast cancer cell growth in vitro. Conversely, the free acid (p-hydroxyphenyllactic acid, HPLA) interacts with type II binding sites with a much lower affinity (Kd approximately 200 nM) and does not inhibit estrogen-induced uterine growth in vivo or MCF-7 cell growth in vitro. On the basis of these observations, we suggested that one way that estrogen may override MeHPLA inhibition of rat uterine growth may be to stimulate esterase hydrolysis of MeHPLA to HPLA. The present studies demonstrate that the rat uterus does contain an esterase (mol. wt approximately 50,000) which cleaves MeHPLA to HPLA, and that this enzyme is under estrogen regulation. This conclusion is supported by the observations that MeHPLA esterase activity is increased 2-3-fold above controls within 2-4 h following a single injection of estradiol, and is maintained at high levels for 16-24 h following hormone administration. This sustained elevation of MeHPLA esterase activity correlates with estradiol stimulation of true uterine growth and DNA synthesis.     

Uterine type II estrogen-binding sites are not of eosinophil origin

A recent report by Lyttle et al. (Lyttle, C. R., Medlock, R. L., and Sheehan, D. M. (1984) J. Biol. Chem. 259, 2697-2700) suggested that nuclear type II sites in the rat uterus are of eosinophil origin and may represent [3H]estradiol binding to eosinophil peroxidase. To further evaluate this hypothesis we examined the response of nuclear type II sites to estrogen under conditions where eosinophils are not present. Results of our experiments show that physiological levels of estradiol-17 beta (10 nM for 72 h) will stimulate nuclear type II sites in highly purified cultures (21-25 days; 4 passages) of rat uterine stromal and myometrial cells. The magnitude of the response of type II sites to estradiol in these stromal (4-fold) and myometrial (80-fold) cell cultures was essentially identical to that observed in the uterine cell types following in vivo estrogen treatment. Since these highly purified cultures of uterine cells were prepared from the uterus of a 21-day ovariectomized rat which is devoid of eosinophils, we conclude that estradiol stimulation of nuclear type II sites is a direct intracellular response to estrogen which occurs independent of eosinophil accumulation. Furthermore, we have found that type II sites in the rat uterus are not peroxidase. This was demonstrated by experiments which show type II sites are present in the 39,000 X g supernatant fraction of uterine cytosol, whereas peroxidase activity is quantitatively recovered in the crude mitochondrial (39,000 X g) pellet. Likewise, the small amount of peroxidase activity (approximately 10%) in the total homogenate which contaminates our nuclear pellet preparations was extracted (98-100%) with 0.5 M CaCl2. Type II estrogen-binding sites (95-100%) remained associated with the nuclear pellet fraction after peroxidase extraction. Therefore, stimulation of cytosol and nuclear type II sites by estrogen in the rat uterus is a direct intracellular response to the hormone unrelated to eosinophil accumulation and/or peroxidase activity.     

Methyl p-hydroxyphenyllactate. An inhibitor of cell growth and proliferation and an endogenous ligand for nuclear type-II binding sites

We previously described and partially characterized endogenous ligands for nuclear type II sites in normal and malignant tissues. Chromatography of these ligands on Sephadex LH-20 revealed that two peaks with binding activity (alpha and beta) could be resolved. The beta-peak component was present in all normal tissues that we examined, but not in malignant tissues, and it inhibited the growth of MCF-7 human breast cancer cells in vitro. Conversely, the alpha-peak component was found to be present in both normal and malignant tissues, and did not inhibit MCF-7 cell growth. The present studies describe the purification and identification of the alpha-peak and beta-peak components in bovine serum and an assessment of the effects of these compounds on normal and malignant cell growth. Gas chromatography-mass spectroscopy analysis of the purified beta-peak component demonstrated that the compound was methyl p-hydroxyphenyllactate (MeHPLA). Competition analysis revealed that MeHPLA binds to nuclear type II sites with a high binding affinity, while physiological levels of this compound blocked estradiol stimulation of uterine growth in vivo and inhibited the growth of MCF-7 human breast cancer cells in vitro. The alpha-peak component was found to be the corresponding acid, p-hydroxyphenyllactic acid (HPLA). This compound interacted with nuclear type II sites with a relatively low affinity and did not block uterotropic response to estradiol or inhibit MCF-7 cell growth. These studies demonstrate that HPLA and MeHPLA are ligands for nuclear type II sites and that MeHPLA may be a very important regulator of normal and malignant cell growth.     

Cytosol type II sites in the rat uterus: interaction with an endogenous ligand

Previous studies from our laboratory demonstrated that normal, but not malignant tissues, contain a ligand which competes for [3H]estradiol binding to nuclear type II sites in the rat uterus. Since elevated nuclear levels of type II sites are correlated with estrogen stimulation of uterine growth and DNA synthesis, we believe this ligand may regulate cell growth. The present studies show that the ligand for nuclear type II sites also interacts with type II sites in uterine cytosol. This was demonstrated by dilution experiments which show that greater quantities of type II sites are measured in dilute (10 mg/ml) than in concentrated (40 mg/ml) uterine cytosol. Furthermore, stripping of uterine cytosol with 1% dextrancoated charcoal, or pre-binding cytosol type II sites to hydroxylapetite (HAP) prior to binding analysis, removed the ligand from these preparations such that high levels of type II sites were measured. Following charcoal stripping, cytosol type II sites demonstrated good specificity for estrogenic hormones but not progesterone, corticosterone, or the triphenylethylene anti-estrogen, nafoxidine. Since the level of type II sites in the cytosol always preceded and exceeded the level of this site measured in uterine nuclei at all times following estrogen treatment (0-96 h), we believe cytosol type II sites may function as an type II-ligand binding protein (LBP) which regulates the availability of the ligand for interaction with nuclear type II sites. This is consistent with our observation that type II sites are not depleted from uterine cytosol by estrogen treatment and nuclear type II sites are very tightly associated with the nuclear matrix.     

Nuclear type II [3H]estradiol binding site ligands: inhibition of ER-positive and ER-negative cell proliferation and c-Myc and cyclin D1 gene expression

These studies assessed the effects of 3,4-dihydroxybenzalacetone (ZN-1) and 1-(3,4-dihydroxyphenyl)-2-propanol (ZN-2) on MCF-7 cell proliferation. The compounds blocked [3H]estradiol binding to nuclear type II sites, but did not compete for [3H]estradiol binding to recombinant ERalpha or ERbeta. ZN-1 and ZN-2 inhibited the proliferation of ERalpha and ERbeta positive (MCF-7) and negative (MCF-10A) breast cells, further ruling out direct binding to ER in the mechanism of action of these compounds. Pre-loading type II sites with ZN-1 or ZN-2 reduced [3H]estradiol exchange, strongly suggesting the drugs were binding covalently. ZN-1 treatment resulted in complete occupancy of type II sites and sustained (9 days) inhibition of MCF-7 cell proliferation following its removal from the tissue culture medium. This cell growth inhibition was not due to non-specific toxicity, as the numbers of viable, attached cells per dish (determined by trypan blue dye exclusion) remained constant throughout this 9-day period and eventually reversed by day 19. ZN-2 effects on cell proliferation reversed more rapidly following discontinuation of treatment, a response consistent with the inability of the compound to totally block type II binding. Both ZN-1 and ZN-2 blocked estradiol stimulation of c-Myc and cyclin D1 gene expression in MCF-7 cells, two events that are clearly coupled to cell cycle progression. We suspect this may occur through ZN-1 or ZN-2 modification of nucleosome function and/or chromatin remodeling since nuclear type II sites are localized to a complex of histones H3 and H4 (Shoulars et. al, J Steroid Biochem. Mol. Biol. 96: 19-30, 2005).     

Preliminary characterization of an endogenous inhibitor of [3H]estradiol binding in rat uterine nuclei

The rat uterus contains two classes of specific nuclear estrogen-binding sites which may be involved in estrogen action. Type I sites represent the classical estrogen receptor (Kd = 1 nM) and type II sites (Kd = 10-20 nM) are stimulated in the nucleus by estrogen under conditions which cause uterine hyperplasia. Dilution of uterine nuclear fractions from estrogen treated rats prior to quantitation of estrogen binding sites by [3H]estradiol exchange results in an increase (3- to 4-fold) in the measurable quantities of the type II site. Estimates of type I sites are not affected by dilution. These increases in type II sites following nuclear dilution occur independently of protein concentration and result from the dilution of a specific endogeneous inhibitor of [3H]estradiol binding to these sites. The inhibitor activity is present in cytosol preparations from rat uterus, spleen, diaphragm, skeletal muscle, and serum. Preliminary characterization of the inhibitor activity by Sephadex G-25 chromatography shows two distinct peaks which are similar in molecular weight (300). These components (alpha and beta) can be separated on LH-20 chromatography since the beta-peak component is preferentially retained on this lipophilic resin. Partial purification of the LH-20 beta inhibitor component by high performance liquid chromatography and gas-liquid chromatography-mass spectrometric analysis suggests the putative inhibitor activity is not steroidal in nature and consists of two very similar phenanthrene-like molecules (molecular weights 302 and 304). Analysis of cytosol preparations on LH-20 chromatography shows that non-neoplastic tissues (uterus, liver, lactating mammary gland) contain both and inhibitor components whereas estrogen-induced rat mammary tumors contain very low to nonmeasurable quantities of the beta-peak inhibitor activity.     

Effects of Salt Extraction on the Quantitation of Nuclear Estrogen Receptors: Interference by Secondary Estrogen Binding Sites

Abstract

The effects of salt-extraction on type I and type II estrogen binding sites were examined in uterine nuclei. Injection (10 ug) of estradiol or estriol in adult ovariectomized rats induced maximum numbers (80–100%, ~ 1 pmole/uterus) of 0.4 M KCL resistant type I estrogen complexes at 1 hour. Only estradiol, which sustained these levels for long periods of time (4–24 hours) stimulated true uterine growth.

Likewise, a single injection of estradiol, but not estriol, also elevated nuclear type II sites throughout the entire uterine growth period (1–48 hours). However extraction of these nuclei from estradiol injected rats with 0.4 M KCL increased the numbers of type II sites from ~ 1 pmole/uterus (non-extracted nuclei) to ~ 8 pmoles/uterus (salt resistant plus salt-extractable fractions). Sixty percent of these sites were resistant to salt-extraction. Continuous exposure to either estradiol or estriol by beeswax implants stimulated nuclear type II sites which were highly resistant (80%) to KCL-extraction, and additional sites were not exposed by high salt. Thus chronic treatment with both estrogens “locked in” nuclear type II sites such that they were resistant to KCL-extraction. This resistance of type II sites to salt-extraction correlated with the ability of estradiol and estriol implants to stimulate true uterine growth. The procedures presented here for nuclear preparation and assay have reduced non-specific binding considerably in the uterine system, and may eliminate the need to perform exchange assays on salt-extracted nuclei in other systems.     

Effect of estradiol on estrogen receptor expression in rat uterine cell types

In rodent uterus, both up- and down-regulation of estrogen receptor alpha (ERalpha) messenger ribonucleic acid (mRNA) and protein levels by estradiol has been demonstrated; however, it is not known which of the uterine compartments (endometrial epithelium, stroma, myometrium) respond to estradiol with autoregulation of ERalpha. The purpose of the present study was to investigate and compare the kinetics and cell type-specific effects of estradiol on uterine ERalpha expression in immature and adult rats. Ovariectomized female rats were injected s.c. with sesame oil or estradiol-17beta. Uteri were collected and analyzed for changes in ERalpha mRNA using RNase protection assays (RPA) and in situ hybridization using radiolabeled probes specific for ERalpha. Immunohistochemical analysis was performed with a polyclonal antibody specific to ERalpha. Expression of ERalpha in the uterine epithelial cells decreased at 3 and 6 h after estradiol administration to immature and adult rats, respectively. At 24 h, ERalpha mRNA levels in the immature and mature rat uterus were higher than pretreatment levels but returned to baseline by 72 h. Pretreatment with cycloheximide did not block the 3-h repressive effect of estradiol, suggesting that the estradiol-induced decrease in ERalpha mRNA occurs independent of new protein synthesis. A decrease in ERalpha mRNA and protein was also observed in uterine epithelia at 3 and 6 h after an estradiol injection to immature and adult rats, and intensity of both the in situ hybridization signal and the immunostaining in the epithelium increased at 24 and 72 h. However, the periluminal stromal cells in the adult uterus and the majority of stromal cells of the immature uterus appeared to have increased ERalpha expression. The results indicate that down-regulation of ERalpha in the epithelia and up-regulation of stromal ERalpha play a role in early events associated with estradiol-induced cell proliferation of the uterine epithelia.     

The naturally occurring C-17 fatty acid esters of estradiol are long-acting estrogens

C-17 fatty acid esters of estradiol are naturally occurring biosynthetic metabolites of estradiol. A representative component of this family of esters, estradiol-17-stearate, was studied in order to determine the estrogenic properties of these unusual hydrophobic steroids. Following the classical estrogen bioassay, a solution of this ester in oil was injected subcutaneously into immature rats once a day for 3 days. There was little effect on the uterus on the first day after the third injection. However, on subsequent days a large stimulation of uterine growth occurred. The course of this estrogenic effect was exactly opposite to that obtained with estradiol. In order to eliminate the possibility that this effect on the time course of estrogenic stimulation was caused by increased solubility of the hydrophobic esters in the carrier oil, the steroids were administered to adult ovariectomized animals in aqueous medium via a single intravenous injection. The uterotrophic response to estradiol was maximal at 12 h and was completely dissipated in 48-60 h. Estradiol-17-stearate produced a uterotrophic effect of twice the duration of estradiol. In the immature rat, aqueous intravenous injections of estradiol-17-stearate produced a greater uterotrophic effect than estradiol and this effect was still maximal 96 h later. In addition, this single injection of estradiol-17-stearate advanced the time of vaginal opening, a marker for puberty in the female rat. The mechanism of the prolonged estrogenic stimulation was investigated by studying the steroidal content of the uterus after injecting [3H]estradiol and [3H]estradiol-17 -stearate i.v. into immature rats. At 1 and 4 h there was significantly more radioactivity in the uteri of the [3H]estradiol treated animals. At later times (8 h and onwards) the total radioactivity in the uterus did not differ appreciably between the two groups. However at these later times, the amount of [3H]estradiol was far greater in the uteri of animals receiving [3H]estradiol-17-stearate. Consequently, the prolonged estrogenic effects of the endogenous C-17 fatty acid esters of estradiol are caused by the increased duration of the estrogenic signal. It is hypothesized that one of the roles of the fatty acid is to protect the steroid nucleus from metabolism and thereby prolong the life of the parent C18 steroid. Thus, the results of these experiments are consistent with the family of endogenous alkyl esters of estradiol having a physiological role as long-acting estrogens.     

Estrogen receptor ligands. Part 10: Chromanes: old scaffolds for new SERAMs

The discovery, synthesis, and SAR of chromanes as ER alpha subtype selective ligands are described. X-ray studies revealed that the origin of the ER alpha-selectivity resulted from a C-4 trans methyl substitution to the cis-2,3-diphenyl-chromane platform. Selected compounds from this class demonstrated very potent in vivo antagonism of estradiol in an immature rat uterine weight assay, effectively inhibited ovariectomy-induced bone resorption in a 42 days treatment paradigm, and lowered serum cholesterol levels in ovx'd adult rat models. The best antagonists 8F and 12F also exhibited potent inhibition of MCF-7 cell growth and were shown to be estrogen receptor down-regulators (SERDs).     

Interaction of DP-TAT-59, an active metabolite of new triphenylethylene-derivative (TAT-59), with estrogen receptors.

DP-TAT-59, (Z)-2-(4-(1-(4-hydroxyphenyl)-2-(4-isopropylphenyl)-1-butenyl) phenoxy)-N, N-dimethylethylamine, has been reported to inhibit estrogen-stimulated growth of MCF-7 cells as well as rat uterus at lower concentrations than the hydroxymetabolite of tamoxifen (4-OH-TAM). In the present study, the growth of mouse Leydig cell tumor, B-1F cells were also more effectively inhibited by DP-TAT-59 than 4-OH-TAM. Additionally, the expression of estrogen responsive element ligated CAT gene transfected into B-1F cells was also suppressed by DP-TAT-59. Thus, the interaction of DP-TAT-59 with estrogen receptor (ER) was characterized and compared with that of 4-OH-TAM using immature rat and bovine uteri. The dissociation constant of DP-TAT-59 to ER of immature rat uterus was 0.24 nM and was similar to that of 4-OH-TAM (Kd = 0.20 nM) and estradiol (Kd = 0.29 nM). Using sucrose density gradients, the sedimentation constant of DP-TAT-59 with bovine uterus was 4.9S, which was similar to that of estradiol (5.1S) and 4-OH-TAM (5.3S). However, the elution profile of the DP-TAT-59-ER complex from a DEAE-Sephadex column was different for both estradiol-and 4-OH-TAM-ER complexes. These results suggest that ER forms different complexes with DP-TAT-59 than estradiol or 4-OH-TAM, while the ER binding affinity of these compounds are similar to each other.     

Reconstitution of the type II [3H]estradiol binding site with recombinant histone H4

Previously, we identified the rat uterine nuclear type II [3H]estradiol binding site as histone H4 and an unknown 35 kDa protein with histone H4 immunoreactivity. Studies using calf thymus histones indicated that the 35 kDa protein was likely a dimer of histone H3 and H4. Further study of the type II site required methodology for producing sufficient quantities of recombinant histones, which retained ligand-binding properties. A variety of production methods produce sufficient quantities of histone for binding analyses were evaluated prior to finding a successful technique. The present studies describe techniques for the production of recombinant histones that retain the ligand binding properties of type II binding site. Binding studies with recombinant protein mirrored [3H]estradiol binding assays with rat uterine nuclear preparations. Histone H4 specifically binds [3H]estradiol with a low affinity (Kd approximately 20 nM) and in a cooperative fashion (curvilinear Scatchard plot; Hill coefficient approximately 4). Although histone H3 does not appear to bind ligand, regeneration of the histone H3/H4 pair produced a 35 kDa protein equivalent to the 35 kDa protein labeled with [3H]luteolin in rat uterine nuclear extracts and calf thymus histones. These data confirm the identification of histone H4 as a key component of the type II site. Future studies with recombinant proteins will lead to the identification of the "nucleosomal ligand-binding domain" for methyl-p-hydroxyphenyllactate (MeHPLA) and related ligands and delineation of their epigenetic control of gene expression and cell proliferation.     

Estrogen dependent induction of low affinity binding sites in the nuclear fraction of rat uterus

Type II estradiol binding sites characterized by lower affinity and higher capacity than type I receptor sites have been described in rat uterine nuclei. These sites appeared to be dependent on estrogen stimulation. Reducing agents prevented estradiol binding to these sites. In the present study, the situation prevailing in adult rats (Ad) was studied and compared to ovariectomized (Ox) and ovariectomized estrogen prestimulated rats (OxPS). Nuclear precipitate from Ad, Ox and OxPS rats were incubated with tritiated estradiol (E2(3)H) in the presence and in the absence of mercaptoethanol as reducing agent. In the presence of mercaptoethanol, saturation was attained at E2(3)H concentrations above 16 nM. In the absence of reducing agents, a secondary binding was observed in Ad and OxPS which was not saturated at E2(3)H levels up to 80 nM. Non-specific binding obtained with paired aliquots containing 100-fold excess of DES as competitor was not linear but showed a saturation profile, distorting the saturation curve of the specific sites, obtained by subtracting non-specific from total E2(3)H binding. Increasing DES concentrations up to 10,000 nM did not allow to reach complete exchange with E3(3)H ligand bound to specific sites, preventing measurement of binding sites concentration. Incubation of nuclear fractions with increasing concentrations of E2(3)H (up to 6,000 nM) gave a saturation curve with a linear kinetics above 1-2,000 nM, which represented saturation concentration of the specific sites. From this, non-specific and specific moieties could be estimated. Binding capacity of specific sites was of the order of 50-80 pmol uterus. Half saturation was attained between 300 and 600 nM E2(3)H, which approximated the Kdiss of these sites, at variance with the Kdiss of 15-30 nM originally reported for type II binding sites. In conclusion, these results show that secondary binding sites were present in uterine nuclei of Ad and OxPS rats. Binding capacity was about 30-fold higher than that of type I sites. Affinity was however very low, and casts some doubt on the role of these sites as active estradiol binders in physiological situations. Their increase under the influence of estrogen may however be related to some as yet undetermined role.     

Effect of colchicine on estrogen action. II. Translocation of 17 beta-estradiol cytosol receptor complex into the nucleus

Colchicine has previously been shown in our laboratory to inhibit 17 beta-estradiol stimulation of uterine water uptake in the immature rat measured 6 h after administration of the agents. We sought to determine whether this effect was mediated through colchicine action on translocation of estradiol receptor complex into the uterine cell nucleus. The time course of estradiol effect on uterine water uptake was followed with and without concurrent colchicine administration up to 6 h after administration. At no time during this period did there appear to be any influence of colchicine on translocation of the estradiol receptor complex into the nucleus. Examination of physical chemical characteristics of the nuclear estradiol receptr complex after estradiol and estradiol plus colchicine treatments revealed no observable differences. Thus, colchicine inhibition of estradiol-stimulated uterine water retention does not appear to be mediated through inhibition of nuclear translocation of estradiol-receptor complex nor to be due to any reduced retention time of estradiol-receptor complex in uterine nuclei.     

Basic fibroblast growth factor (bFGF): mitogenic activity and binding sites in human breast cancer.

We investigated binding characteristics of basic fibroblast growth factor (bFGF) on membranes prepared from 4 human breast cancer cell lines and 38 primary BC biopsies. Competitive binding experiments were performed and analyzed using the "Ligand" program. Furthermore bFGF mitogenic activity was measured by [3H]thymidine incorporation into DNA from breast cancer cell lines. The presence of high-affinity binding sites was demonstrated in each cell type (MCF-7: Kd = 0.60 nM; T-47D: Kd = 0.55 nM; BT-20: Kd = 0.77 nM; MDA-MB-231: Kd = 0.34 nM). The presence of these high-affinity binding sites was confirmed with saturation experiments. A second class of low-affinity binding sites was detected in the 2 hormone-independent cells (BT-20: Kd = 2.9 nM; MDA-MB-231: Kd = 2.7 nM). bFGF stimulated the proliferation of MCF-7, T-47D, BT-20 but not MDA-MB-231 cell lines. With competition experiments, binding sites were detectable in 36/38 breast cancers; high-affinity binding sites (Kd less than 1 nM) were present in 19/36 cases and low-affinity binding sites (Kd greater than 2 nM) were present in 29/36 cases (the two classes of binding sites were present in 12 breast cancers). No relation between bFGF binding sites and node involvement, histologic type or grading of the tumor was evidenced. There were negative correlations (Spearman test) between total bFGF binding sites and estradiol receptor (P = 0.05) or progesterone receptor (P = 0.009). The demonstration of (1) bFGF specific binding sites in breast cancer membranes, and (2) bFGF growth stimulation of some breast cancer cell lines indicates that this factor may be involved directly in the growth of some breast cancers.     

In vitro effects of cytosolic inhibitor and opiates on the binding of [3H]oestradiol to nuclear type II binding sites of rat uterus and hypothalamus

The effect of cytosolic ultrafiltrates prepared from intact rat uteri, brain hemispheres and hypothalami and of some opiate analogues on oestradiol binding to nuclear type II sites in rat uterus and hypothalamus was studied. Opiate binding in nuclear fraction of rat uteri was also evaluated. Both uterine and hypothalamic low affinity nuclear oestradiol binding was inhibited by filtrate from uteri, while only hypothalamic nuclear binding was decreased in presence of hypothalamic filtrate. Filtrate from brain was ineffective on nuclear oestradiol binding of the studied tissues. Concentration dependent inhibition of uterine nuclear oestradiol binding could be demonstrated by some opiate analogues in vitro. Specific low affinity nuclear binding of opiate antagonist naloxone and agonist dihydromorphine was observed in rat uteri which could be inhibited by uterine filtrate and oestradiol but not by hypothalamic filtrate or other steroids. Present findings support the probable intracellular interplay of opiates and oestradiol action and suggest that cytosolic inhibitor factor might be involved.     

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.