Uterine estrogen receptor in rats during pubescence and the estrous cycle

Effect of endurance training on oestrogen receptor alpha transcripts in rat skeletal muscle

Endurance training induces, in female rats, alterations of oestrous cycle with decrease in plasma oestradiol levels. Moreover, it is well known that oestradiol concentrations modify oestrogen receptor levels. In order to further explain the effects of oestrogens on skeletal muscles, we hypothesized that endurance training modifies the levels of oestrogen receptor alpha messenger ribonucleic acid (ER alpha mRNA) in rat gastrocnemius muscle. Wistar rats were separated into four groups: male controls (C(m)) (n=7), female controls (C(f)) (n=6), male trained (E(m)) (n=7) and female trained (E(f)) (n=6). The endurance training programme was performed for 7 weeks, 5 days week-1 and consisted of 1 h of continuous running on an adapted motor-driven treadmill. At the end of the training session, the gastrocnemius muscle was isolated, weighed and semiquantification of ER alpha mRNA was performed using the reverse transcriptase-polymerase chain reaction (RT-PCR) technique. The citrate synthase (CS) activity of the gastrocnemius muscle was measured by a fluorimetric method. The CS activity of the male and female gastrocnemius muscle, respectively, 100 +/- 7% in C(m) (n=7) vs. 120 +/- 14% in E(m) (n=6, P < 0.01) and 100 +/- 13% in C(f) (n=6) vs. 138 +/- 23% in E(f) (n=6, P < 0.01) was significantly increased after 7 weeks of training. The ER alpha mRNA levels were significantly increased in E(f) compared with C(f) (0.49 +/- 0.15 vs. 0.31 +/- 0.11, P < 0.01) but not in E(m) compared with C(m) (0.37 +/- 0.15 vs. 0.37 +/- 0.13). In conclusion, these results demonstrate that 7 weeks of endurance training increased the level of transcripts encoding ER alpha in rats with the increase restricted to the females.

Effect of steroids and the estrous cycle on uterine neuromedin U receptor expression

We investigated the role of estrogen and progesterone on rat uterine NmU receptor expression in both intact and ovariectomized animals and examined receptor expression through the estrous cycle. Chronic administration of beta-estradiol 3-benzoate (E2) or progesterone in intact animals was devoid of any effect. RU486 caused a 2-fold up-regulation in NmU receptor density. Ovariectomy caused a 60% decrease in receptor density, but chronic E2 administration to ovariectomized rats significantly increased NmU receptor density. The estrous cycle had no significant effect on NmU receptor density. These results suggest that NmU receptor expression is estrogen-dependent, whereas progesterone or a progestin-induced factor is involved in the modulation of this expression.

Coexistence of cytoplasmic and nuclear estrogen receptors. A histochemical study on human mammary cancer and rabbit uterus

Consecutive serial cryostat-frozen sections of 157 human mammary carcinomas and the uteri of six immature New Zealand white rabbits were stained histochemically for cytoplasmic estrogen receptor (ER) and nuclear ER by a fluorescent estrogen compound (Fluorocep Estrogen, Zeus Technologies, Inc., Raritan, NJ) and by a monoclonal antibody immunoperoxidase technique (ER-ICA, Abbott Laboratories, North Chicago, IL), respectively. The percentage of the ER-positive cells in the cancer cell population under observation was estimated and recorded. The results of the cytoplasmic ER assay were compared with those of the nuclear ER assay in each tumor; all cancers with less than 10% ER-positive cancer cells were grouped together as ER-negative tumors, the cancers with 30% or more ER-positive cancer cells as ER-positive tumors, and those with 10% to 29% ER-positive cancer cells as borderline positive. According to this manner of classification, 94% to 97% of the ER-positive mammary carcinomas diagnosed by one histochemical assay would have been identified as such by the other with no more than 10% difference in the ER-positive cell counts. The majority of ER-positive breast cancer cells and practically all of the luminal lining cells of the immature rabbit endometrium had coexistent cytoplasmic and nuclear ER. In the mammary cancers containing less than 30% ER-positive cancer cells, there was a greater (up to 20%) discrepancy in positive cell counts between the cytoplasmic ER assay and the nuclear ER assay. This discrepancy may be due to sampling errors of small clones of ER-positive cancer cells in two adjacent sections, difference in antigenic determinants between the cytoplasmic and the nuclear ER, and the binding sites in the nuclear ER being preoccupied by estrogen. The findings of this study appear to support the hypothesis that there are ER in the cytoplasm and the nucleus of the mammary carcinoma cells and the epithelial cells of the endometrium.

Influence of danazol on cytoplasmic and nuclear estrogen binding capacity in the uterus

Sprague-Dawley rats with estrous cycles were exposed to danazol (Danocrine) at a single dose of 10 mg/kg for either 6 or 24 hours, or daily until a pattern of no cycles (6 days) was noted on vaginal smears. The animals were individually housed and exposed to a 14-hour light/10-hour dark environment. Prior to drug administration, daily vaginal smears were obtained to ensure cycle normalcy. After the appropriate exposure to medication, the animals were killed, the uterine horns were removed, and determination was made of cytoplasmic and nuclear estrogen receptors. The animals in the control group (6 and 24 hours, and daily injected) received vehicle only (mineral oil). The influence of danazol on sex-steroid receptor levels appeared to be related to the phase of the estrous cycle at the time of sacrifice. At both 6 and 24 hours of exposure to danazol, there was a slight decrease in specific estrogen binding capacity of cytosols, with no alteration in the levels of nuclear receptors in the uteri of rats with cycles. In the groups with no cycles, there was an increase in cytosolic estrogen binding capacity at 1 and 6 days of danazol treatment, with a slight decrease in nuclear receptor binding when compared with treated rats with cycles. Statistical evaluation revealed a significant difference in cytosolic estrogen binding capacity between the series with cycles and the series without cycles (p less than 0.01). This study provides further information in regard to danazol action on cytosol and nuclear receptors correlated with phase of the estrous cycle.

Factors affecting the target site uptake selectivity of estrogen radiopharmaceuticals: serum binding and endogenous estrogens

The binding affinity of various substituted estrogens for human sex steroid binding protein (SBP) and rat alpha-fetoprotein (AFP) have been measured by hydroxylapatite adsorption (relative to estradiol = 100%). While 17 alpha-ethynyl and 11 beta-methoxy substituents reduce the affinity of estrogens for these serum binding proteins markedly, a 16 alpha-bromo or a 16 alpha-iodo substituent actually increases their affinity for AFP, though lowering it for SBP. As a consequence, the uterine uptake selectivity of 16 alpha [77Br]-bromoestradiol (relative affinity for AFP = 230%) and 16 alpha [125 I]-iodoestradiol (relative affinity for AFP = 180%) in young rats (day 19-23), when AFP levels are still substantial, is considerably less than in older animals (day 24-27). 11 beta-Methoxy-16 alpha [77Br]-bromoestradiol, which has lower affinity for AFP (5.1%), does not show this age-dependent uptake selectivity. In adult cycling female rats bearing dimethylbenz(a)anthracene(DMBA)-induced mammary tumors, there is a strong dependence of uterine and tumor uptake selectivity on the stage of the estrous cycle: uptake is maximal during diestrus and minimal during estrus. The effective use of estrogen radiopharmaceuticals as receptor-based imaging agents requires careful consideration of not only the binding affinity of the agent for the estrogen receptor, but also its interaction with non-receptor binding proteins. The modulation of receptor concentrations by endogenous ligands during endocrine cycles and physiological differences between animals will also affect markedly certain measures of the extent of receptor-mediated uptake by target sites.

Uterine epithelial and eosinophil estrogen receptors in rats during the estrous cycle

In the uterus of the adult females rats, the luminal epithelial cells and the eosinophil leukocytes are rich in cytoplasmic estrogen receptors. During the estrous cycle, the epithelial estrogen receptor concentration reaches its peak level in proestrus, drops precipitously in estrus, and hits the trough at metestrus. Repopulation of the cytoplasm with estrogen binding sites occurs during diestrus. This pattern of cyclic change is indicative of a rapid turnover of estrogen receptors inthe epithelial cells and its regulation by endogenous estrogens. The concentration of estrogen receptors in the cytoplasm of the eosinophils does not appear to fluctuate during the cycle. But the intrauterine distribution of these leukocytes is clearly cyclic in pattern, ostensibly influenced by estrogens. While progesterone binding activity is consistently demonstrated in tandem with estrogen receptors in the cytoplasm of the epithelial cells, it had not been observed in the eosinophil leukocytes. These findings support the claim that there are two estrogen receptor systems in the rat uterus, one mediating the intracellular events of the genomic response to estrogens, and the other being concerned with non-genomic responses.

Estrogen receptor in uteri of mice of different H-2 genotypes

A relationship between the amount of available estradiol receptors in uteri of inbred mice and their H-2 genotype is suggested by study in congenic animals.

The oestrogen receptor in the rat uterus in relation to intra-uterine devices and the oestrous cycle

We investigated the binding characteristics, content and intracellular distribution of nuclear and cytosolic oestrogen receptors in the uteri of rats bearing a unilateral intrauterine device, fitted 14--18 days earlier, at four phases of a 5-day oestrous cycle. The patterns of changes in wet weight and content of cytosolic and nuclear receptor that normally occur during the oestrous cycle were not altered by the presence of the device. At all stages of the cycle the intra-uterine-device-containing horn had a greater wet weight and a correspondingly higher content of cytosolic receptor than its contralateral control horn, the cellular concentration of cytosolic receptor being apparently maintained. However, the intra-uterine-device-containing horn had significantly lower cellular concentrations (i.e. per mg of DNA) of nuclear receptor, particularly at late dioestrus and pro-oestrus. Thus the treated horn showed a decreased translocation of receptor in response to increases in circulating oestrogens. Both horns contained equivalent amounts of an activating factor implicated in translocation and measured in vitro by binding of cytosol receptor to oligo(dT)-cellulose. The presence of an intra-uterine device neither altered the dissociation constants (Kd) of the nuclear and cytosolic oestrogen-receptor complexes nor the stability of the nuclear receptor complex in vitro. The decreased translocation cannot thus be directly attributed to changes in the physical properties of the receptor. This decrease may be responsible for the anti-fertility effect of the intra-uterine device (which affects only the treated horn of the bicornuate rat uterus), since implantation of the blastocyst requires correct concentrations of nuclear oestrogen receptor.

Intracellular relationships of the oestrogen receptor in the rat uterus and hypothalamus during the oestrous cycle

Simultaneous measurements were made of the specific oestrogen receptor in the nuclear and cytosol fractions prepared from the uterus and hypothalamus of 50--81-day-old female rats undergoing a 4-day oestrous cycle. In the uterus, the content of nuclear receptor fluctuated in concert with known cyclic changes in the secretion of oestrogen, being maximal at pro-oestrus. Over the period of 50--81 days, the nuclear content at all phases increased with age, again corresponding to known age-related increases in ovarian secretion of oestrogen. This age-related increase in nuclear content, averaged from the values of the different phases in each age group, was related to equivalent increases in uterine wet weight, an increase of 1 pmol of receptor being accompanied by an increase of 80--90 mg. The concentration of cytosol receptor was maintained constant, with respect to wet weight, throughout the cycle and with age, irrespective of changes in nuclear content. In the uterus of normal mature females, translocation of receptor into the nucleus did not lead to depletion of cytosol receptor, suggesting a process of continuous replenishment/synthesis. In the hypothalamus, the nuclear content of oestrogen receptor was also maximal at pro-oestrus. In contrast with the uterus, the content of hypothalamic cytosol receptor was minimal at this phase and reflects depletion of the cytosol receptor, possibly as a result of translocation. The extent of translocation was low compared with that in the uterus and did not alter with age during the age-period studied. This low nuclear binding of the receptor in vivo is discussed in relation to the presence of a cytosol factor, present in limiting amounts, which in vitro mediates the binding of cytosol receptor to oligo(dT)-cellulose. The difference in the physiological response of the uterus and of the hypothalamus to oestrogens may be related to the extent of nuclear binding of receptor.

Receptor-estrogen complex in the nuclear fraction of rat uterine cells during the estrous cycle

A quantitative method was used to determine the concentration of receptor-estrogen complex in the nuclear fraction of rat uterine cells throughout the estrous cycle. The concentrations of nuclear receptor-estrogen complex were: metestrus, 0.22; diestrus, 0.75; proestrus, 1.29; and estrus, 0.31 picomoles per milligram of DNA. This cyclic fluctuation in the nuclear complex closely parallels the secretion of ovarian estrogen during the estrous cycle, an indication that the accumulation of receptor-estrogen complex by the nuclear fraction of uterine cells may be of physiological significance, and under the control of endogenous estrogen.

Estrogen receptor in the rabbit corpus luteum

The rabbit corpus luteum contains a cytoplasmic estrogen receptor substance in concentrations comparable to those found in the uterus. Receptor in corpora lutea of nonpregnant rabbits was highest at midluteal phase and decreased before physical regression of corpora was evident. These results support the view that the corpus luteum in this species is an estrogen-responsive tissue.