Morphological studies of prolactin-secreting cells in estrogen receptor alpha and estrogen receptor beta knockout mice

Estrogens play a major role in the regulation of prolactin (PRL) secretion through activation of pituitary and hypothalamic estrogen receptors (ERs). In order to evaluate the relative role of ERalpha and ERbeta in the control of PRL density in the pituitary gland, we performed immunocytochemical localization of PRL and ERs in pituitaries of wild-type (WT), ERalpha knockout (KO) and ERbetaKO mice. In WT and ERbetaKO anterior pituitaries, the vast majority of secretory cells contained ERalpha immunoreactivity, while no ERalpha immunostaining could be found in ERalphaKO pituitaries. No ERbeta immunoreactivity could be detected in pituitaries of WT, ERalphaKO or ERbetaKO mice. At the light microscopic level, a large number of cells staining for PRL were present in pituitaries of female WT, while in female ERalphaKO pituitaries, the density of PRL cells was much lower. In WT male pituitaries, the density of PRL cells was lower than observed in female WT, while PRL staining was markedly decreased in male ERalphaKO as compared to male WT. In ERbetaKO mice of both sexes, the results were identical to those observed in WT animals. At the electron microscopic level, in WT mice of both sexes, type 1 PRL cells exhibited a well-developed Golgi apparatus and a large number of strongly stained large mature and immature secretory granules. Type 2 PRL cells were also present in the pituitary. Type 2 PRL cells contain small poorly labelled granules. In ERalphaKO mice of both sexes, type 1 PRL cells were atrophied with poorly developed Golgi apparatus, and no type 2 PRL cells could be observed. In ERalphaKO pituitaries, typical gonadectomy cells were found. No ultrastructural changes were observed in PRL cells of ERbetaKO mice. The present data strongly suggest that the positive regulation of PRL expression at the pituitary level by estrogens is mediated by ERalpha and does not involve ERbeta activation.     

Stimulation of the novel estrogen receptor-alpha intronic TERP-1 promoter by estrogens, androgen, pituitary adenylate cyclase-activating peptide, and forskolin, and autoregulation by TERP-1 protein

The estrogen receptor-alpha (ERalpha) pituitary-specific variant, TERP-1, is regulated dramatically by physiological status. We examined hormonal regulation of the TERP-1 promoter in transient transfection assays in GH3 somatolactotrope cells. We found that 17beta-estradiol (E2), genistein, androgen, pituitary adenylate cyclase-activating peptide, and forskolin (FSK) all stimulated TERP-1 promoter activity, whereas progesterone had no effect. ERalpha bound to a palindromic estrogen response element (ERE) and two half-site EREs; mutation of any of these sites decreased basal expression and completely obliterated E2 stimulation. In contrast, mutation of an activator protein-1 site decreased basal and FSK-stimulated promoter activity, but not E2 or androgen stimulation. The pure antiestrogen ICI 182,780 suppressed E2 and genistein, but not FSK or androgen, stimulation. Similarly, mutation of the ERE palindrome or half-site EREs suppressed promoter stimulation by E2 and genistein, but not by androgen or FSK. Because TERP-1 levels regulate ERalpha function on model promoters, we tested TERP-1 modulation of its own and other physiological promoters. TERP-1 suppressed basal and E2-stimulated expression of its own promoter. TERP-1 suppression required the ERE regions of the promoter, and the dimerization domain of TERP-1. TERP-1 overexpression also suppressed E2 stimulation of the progesterone receptor and prolactin promoters. Thus, estrogens, androgen, and FSK can stimulate TERP-1 promoter activity, and increased TERP-1 expression modulates E2 stimulation of physiological promoters. These data suggest that TERP-1 regulation may play a significant role in modifying pituitary ERalpha responses.     

Expression of estrogen receptor subtypes in rat pituitary gland during pregnancy and lactation

The aim of this study was to examine whether the expression levels of mRNA of the three estrogen receptor (ER) subtypes, ERalpha, ERbeta, and truncated ER product-1 (TERP-1) found in the rat pituitary gland were modified during gestation, lactation, and postlactation periods. By using relative quantitative RT-PCR, we found that ERalpha mRNA significantly peaked in midpregnancy. However, the ERalpha protein level remained constant. ERbeta gene expression did not change throughout pregnancy, suggesting that it was not related to estradiol levels during this reproductive period. In contrast, both TERP-1 mRNA and protein levels dramatically increased throughout the second half of gestation, being faintly detectable in early pregnancy. TERP-1 expression was rapidly reversed by lactation, whereas neither pituitary ERalpha nor ERbeta relative levels were significantly altered. In addition, pup removal for 24-96 h on d 9 postpartum significantly reduced the expression of both ERalpha and ERbeta mRNA compared with that in lactating animals, but the expression of TERP-1 mRNA was no longer detected. Collectively, our data indicate that 1) TERP-1, ERalpha, and ERbeta expression levels are differentially regulated in the pituitary; 2) TERP-1 is variably expressed depending on the hormonal environment related to the estrous cycle, pregnancy, and lactation; and 3) TERP-1/ERalpha ratios dramatically change depending on reproductive periods, suggesting a critical role for TERP-1 in reproductive events.     

Effects of estrogen on the vascular injury response in estrogen receptor alpha, beta (double) knockout mice

The two known estrogen receptors, ERalpha and ERbeta, mediate the effects of estrogen in all target tissues, including blood vessels. We have shown previously that estrogen inhibits vascular injury response to the same extent in female wild-type (WT), ERalpha knockout (ERalphaKO(CH)), and ERbeta knockout (ERbetaKO(CH)) mice. We generated mice harboring disruptions of both ERalpha and ERbeta genes (ERalpha,betaKO(CH)) by breeding and studied the effect of 17beta-estradiol (E2) on vascular injury responses in ovariectomized female ERalpha,betaKO(CH) mice and WT littermates. E2 inhibited increases in vascular medial area following injury in the WT mice but not in the ERalpha,betaKO(CH) mice, demonstrating for the first time that the two known estrogen receptors are necessary and sufficient to mediate estrogen inhibition of a component of the vascular injury response. Surprisingly, as in WT littermates, E2 still significantly increased uterine weight and inhibited vascular smooth muscle cell (VSMC) proliferation following injury in the ERalpha,betaKO(CH) mice. These data support that the role of estrogen receptors differs for specific components of the vascular injury response in the ERalpha,betaKO(CH) mice. The results leave unresolved whether E2 inhibition of VSMC proliferation in ERalpha,betaKO(CH) mice is caused by a receptor-independent mechanism, an unidentified receptor responsive to estrogen, or residual activity of the ERalpha splice variant reported previously in the parental ERalphaKO(CH) mice. These possibilities may be resolved by studies of mice in which ERalpha has been fully disrupted (ERalphaKO(St)), which are in progress.     

Estrogen receptor beta regulates sexually dimorphic neural responses to estradiol

Estrogen receptors (ERs) mediate many sexual dimorphisms in the neuroendocrine system and in behavior. We examined the consequences of the loss of functional estrogen receptor beta (ERbeta) on two sexually differentiated neural responses to estrogen. In wild type (WT) male mice, but not in females, estradiol (E(2)) treatment decreased estrogen receptor alpha immunoreactive (ERalpha-ir) cell numbers in the arcuate nucleus (ARC), the preoptic area (POA), and the ventromedial nucleus (VMN). These sex differences were reversed in ERbeta knockout (ERbetaKO) mice. Castrated ERbetaKOs did not show any change in ERalpha-ir cell number after E(2) treatment. Yet, E(2) decreased ERalpha-ir cell number in ovariectomized ERbetaKOs. Estradiol treatment increased progesterone receptor immunoreactive (PR-ir) cell number in WT female VMN and POA, but no change was noted in brains of WT castrates. In ERbetaKO mice the opposite relationship was found, E(2) treatment increased PR-ir cell number in male, but not in female, brains. Our results show that ERbeta influences several sexually dimorphic neural responses to estrogen. Moreover the data clearly show that ERbeta can modulate neural expression of ERalpha.     

Estrogen receptor-alpha mediates the protective effects of estrogen against vascular injury

Blood vessel cells express the 2 known estrogen receptors, alpha and beta (ERalpha, ERbeta), which are thought to mediate estrogen inhibition of vascular injury and atherosclerosis, but the relative role of ERalpha and ERbeta in these events is controversial. Estrogen inhibits the vascular injury response to the same extent in ovariectomized female wild-type mice and in the original single gene knockout mice for ERalpha (ERalphaKO(Chapel Hill) [ERalphaKO(CH)]) and ERbeta (ERbetaKO(Chapel Hill) [ERbetaKO(CH)]). In double gene knockout mice generated by crossing these animals (ERalpha,betaKO(CH)), estrogen no longer inhibits medial thickening after vascular injury, but still inhibits vascular smooth muscle cell proliferation and increases uterine weight. The partial retention of estrogen responsiveness in ERalpha,betaKO(CH) mice could be due either to the presence of a novel, unidentified estrogen receptor or to functional expression of an estrogen receptor-alpha splice variant in the parental ERalphaKO(CH) mice. To distinguish between these possibilities, we studied recently generated mice fully null for estrogen receptor alpha (ERalphaKO(Strasbourg) [ERalphaKO(St)]) and examined the effect of estrogen on the response to vascular injury. In the present study, we show that after vascular injury in ovariectomized ERalphaKO(St) mice, estrogen has no detectable effect on any measure of vascular injury, including medial area, proteoglycan deposition, or smooth muscle cell proliferation. These data demonstrate that estrogen receptor-alpha mediates the protective effects of estrogen on the response to vascular injury.     

Gender-specific protection of estrogen against gastric acid-induced duodenal injury: stimulation of duodenal mucosal bicarbonate secretion

Because human duodenal mucosal bicarbonate secretion (DMBS) protects duodenum against acid-peptic injury, we hypothesize that estrogen stimulates DMBS, thereby attributing to the clinically observed lower incidence of duodenal ulcer in premenopausal women than the age-matched men. We found that basal and acid-stimulated DMBS responses were 1.5 and 2.4-fold higher in female than male mice in vivo, respectively. Acid-stimulated DMBS in both genders was abolished by ICI 182,780 and tamoxifen. Estradiol-17beta (E2) and the selective estrogen receptor (ER) agonists of ERalpha [1,3,5-Tris(4-hydroxyphenyl)-4-propyl-1H-pyrazole] and ERbeta [2,3-bis(4-hydroxyphenyl) propionitrile], but not progesterone, rapidly stimulated ER-dependent murine DMBS in vivo. E2 dose dependently stimulated murine DMBS, which was attenuated by a Cl(-)/HCO3(-) anion exchanger inhibitor 4,4'-didsothio- cyanostilbene-2, 2'-disulfonic acid, removal of extracellular Cl(-), and in cystic fibrosis transmembrane conductance regulator knockout female mice. E2 stimulated murine DMBS in vitro in both genders with significantly greater response in female than male mice (female to male ratio = 4.3). ERalpha and ERbeta mRNAs and proteins were detected in murine duodenal epithelium of both genders; however, neither ERalpha nor ERbeta mRNA and protein expression levels differed according to gender. E2 rapidly mobilized intracellular calcium in a duodenal epithelial SCBN cell line that expresses ERalpha and ERbeta, whereas BAPTA-AM abolished E2-stimulated murine DMBS. Thus, our data show that E2 stimulates DMBS via ER dependent mechanisms linked to intracellular calcium, cystic fibrosis transmembrane conductance regulator, and Cl(-)/HCO3(-) anion exchanger. Gender-associated differences in basal, acid- and E2-stimulated DMBS may have offered a reasonable explanation for the clinically observed lower incidence of duodenal ulcer in premenopausal women than age-matched men.     

The differential fate of mesonephric tubular-derived efferent ductules in estrogen receptor-alpha knockout versus wild-type female mice

We investigated mesonephric tubular-derived efferent ductules in female wild-type (WT) and estrogen receptor-alpha knockout (ERalphaKO) mice from late fetal to adult life. On gestational day 17, efferent ductules in both fetal WT and ERalphaKO females were well developed and morphologically similar, although one third the size of the male counterpart. Unexpectedly, efferent ductules with a ciliated epithelium were still present on postnatal day 10 in WT and ERalphaKO females. By day 23, however, marked phenotypic differences occurred in efferent ductules of WT and ERbetaKO vs. ERalphaKO female mice. In the latter, efferent ductules became hypertrophied and dilated, whereas only small tubules remained in WT and ERbetaKO adult mice. The serum testosterone concentrations were similar in 21- to 25-day-old ERalphaKO, heterozygous, and WT female mice, suggesting that increased testosterone was not inducing enlargement of efferent ductules in ERalphaKO females. In conclusion, remnants of efferent ductules persisted in normal adult female mice, although these structures were greatly reduced in size compared with efferent ductules in ERalphaKO female mice. The underlying mechanism inducing hypertrophy and dilation of efferent ductules in ERalphaKO females is not clear, but secretory and/or reabsorptive function of female efferent ductules may involve ERalpha.     

Estradiol regulates corticotropin-releasing hormone gene (crh) expression in a rapid and phasic manner that parallels estrogen receptor-alpha and -beta recruitment to a 3',5'-cyclic adenosine 5'-monophosphate regulatory region of the proximal crh promoter

In the central nervous system, CRH regulates several affective states. Dysregulation of neuronal crh expression in the paraventricular nucleus of the hypothalamus correlates with some forms of depression, and amygdalar crh expression may modulate levels of anxiety. Because estrogens modulate these states, we sought to determine 17beta-estradiol (E2) effects on crh expression. CRH mRNA levels were measured in the AR-5 amygdaloid cell line by RT-PCR analysis. They increased by 1 min of E2 treatment, suggesting that crh behaves as an immediate-early gene. After peaking at 3 min, CRH mRNA returned to basal levels and then increased by 60 min. To dissect some of the molecular mechanisms underlying these events, we measured occupancy of the crh promoter by estrogen receptors (ERs) and coactivators, using chromatin immunoprecipitation. Because this promoter does not contain palindromic estrogen response elements, we targeted the region of a cAMP regulatory element (CRE), implicated in crh regulation. The temporal pattern of the mRNA response was mimicked by recruitment of ERalpha and -beta, phospho-CRE-binding protein, coactivators steroid receptor coactivator-1 and CRE-binding protein-binding protein (CBP), and an increase in histone 3 and 4 acetylation. Lastly, ERalpha and -beta loading were temporally dissociated, peaking at 1 and 3 min, respectively. The ER peaks were associated with coactivators and acetylation patterns. ERalpha associated with phospho-CRE-binding protein, CBP, steroid receptor coactivator-1, and increased acetylated histone 3. ERbeta associated with CBP and increased acetylated histone 4. The tight temporal correlation between E2-induced CRH mRNA levels and promoter occupancy by ERs strongly suggest that E2 regulates crh expression through an ERalpha- and/or ERbeta-CRE alternate pathway.     

Global transcription profiling of estrogen activity: estrogen receptor alpha regulates gene expression in the kidney

Estrogen receptors (ERs) are expressed in numerous organs, although only a few organs are considered classical targets for estrogens. We have completed a systematic survey of estrogen regulation of approximately 10,000 genes in 13 tissues from wild-type and ERbetaKO mice treated sc with vehicle or 17beta-estradiol (E2) for 6 wk. The uterus and pituitary had the greatest number of genes regulated by E2, whereas the kidney had the third largest number of regulated genes. In situ hybridizations localized E2 regulation in the kidney to the juxtamedullary region of the cortex in both the mouse and rat. The ED(50) for gene inductions in the kidney was 3 micro g/kg.d, comparable with the 2.4 micro g/kg.d ED(50) for c-fos induction in the uterus. E2 regulations in the kidney were intact in ERbetaKO mice, and the ERalpha-selective agonist propylpyrazole triol acted similarly to E2, together suggesting an ERalpha-mediated mechanism. Several genes were induced within 2 h of E2 treatment, suggesting a direct activity of ERalpha within the kidney. Finally, the combination of the activation function (AF)1-selective agonist tamoxifen plus ERalphaKO(CH) mice expressing an AF1-deleted version of ERalpha allowed delineation of genes with differing requirements for AF1 or AF2 activity in the kidney.     

Role of estrogen receptor beta in uterine stroma and epithelium: Insights from estrogen receptor beta-/- mice

In this study, we compared the uterine tissue of estrogen receptor (ER)beta(-/-) mice and their WT littermates for differences in morphology, proliferation [the percentage of labeled cells 2 h after BrdUrd injection and EGF receptor (EGFR) expression], and differentiation (expression of progesterone receptor, E-cadherin, and cytokeratins). In ovariectomized mice, progesterone receptor expression in the uterine epithelium was similar in WT and ERbeta(-/-) mice, but E-cadherin and cytokeratin 18 expression was lower in ERbeta(-/-) mice. The percentage of cells in S phase was 1.5% in WT mice and 8% in ERbeta(-/-) mice. Sixteen hours after injection of 17beta-estradiol (E(2)), the number of BrdUrd-labeled cells increased 20-fold in WT mice and 80-fold in ERbeta(-/-) mice. Although ERalpha was abundant in intact mice, after ovariectomy, ERalpha could not be detected in the luminal epithelium of either WT or ERbeta(-/-) mice. In both untreated and E(2)-treated mice, ERalpha and ERbeta were colocalized in the nuclei of many stromal and glandular epithelial cells. However, upon E(2) + progesterone treatment, ERalpha and ERbeta were not coexpressed in any cells. In WT mice, EGFR was located on the membranes and in the cytoplasm of luminal epithelium, but not in the stroma. In ERbeta(-/-) mice, there was a marked expression of EGFR in the nuclei of epithelial and stromal cells. Upon E(2) treatment, EGFR on cell membranes was down-regulated in WT but not in ERbeta(-/-) mice. These findings reveal an important role for ERbeta in response to E(2) and in the organization, growth, and differentiation of the uterine epithelium.     

Estrogen receptor beta modulates estradiol induction of progestin receptor immunoreactivity in male, but not in female, mouse medial preoptic area

The medial preoptic area (mPOA) of the hypothalamus contains many neurons that express estrogen receptor alpha (ER) and/or ERbeta. We examined the distribution of these receptors and assessed responses to estradiol (E2) in the adult mouse mPOA. Gonadectomized adult male and female mice were killed, and brains were processed for immunocytochemistry for ERalpha and ERbeta. More ERalpha immunoreactive (-ir) than ERbeta-ir neurons were present in the mouse mPOA. Numbers of ERalpha-ir cells were equivalent between males and females, but males had significantly more ERbeta-ir neurons than females. Using breeders that were heterozygous for disrupted ERalpha and ERbeta genes, we produced offspring with varying numbers (0, 1, or 2) of functional and disrupted ERalpha and ERbeta genes. After gonadectomy, half the mice received E2 for 5 d before they were killed. Estradiol treatment, sex, and genotype each had independent effects on numbers of PR-ir neurons in the mPOA. In all cases, brains that lacked at least one functional copy of ERalpha had reduced PR-ir cell numbers. In gonadectomized, untreated mice, one functional copy of the ERbeta gene was correlated with the largest amount of PR-ir. After E2 treatment, both sexes had greatly enhanced numbers of PR-ir containing neurons. In females, maximal PR induction required the presence of at least one functional copy of ERalpha, whereas in males, at least a single copy of both functional ERbeta and ERalpha genes was needed for maximal PR-ir induction. We hypothesize that the two ERs have dependent and independent roles in sexual differentiation of neuroendocrine function.     

The novel estrogen receptor, G protein-coupled receptor 30, mediates the proliferative effects induced by 17beta-estradiol on mouse spermatogonial GC-1 cell line

Many studies have indicated that estrogens could have a role in the regulation of testicular function. However, it remains uncertain whether estrogens are able to directly activate signaling pathways in male germ cells. Estrogens are synthesized by the enzyme aromatase and classically act by binding to estrogen receptors (ERs)-alpha and ERbeta. Knockout mice for both receptor isoforms exhibit a testicular phenotype that is less severe than aromatase knockout mice, suggesting the existence of an estrogen-binding receptor that may compensate for the lack of ERs. Recently studies using estrogen-sensitive tumor cell lines have demonstrated that the G-protein-coupled receptor (GPR)-30 binds and mediates estrogen action through the activation of the epidermal growth factor receptor (EGFR)/ERK/fos transduction pathway. The present study investigated the ability of 17beta-estradiol (E2) to activate this pathway in the mouse spermatogonial cell line (GC-1). Using the GC-1 cell line as a model system, we demonstrated that GC-1 cells express GPR30 and ERalpha but not ERbeta. E2, the selective GPR30 agonist G1, and the selective ERalpha agonist 4,4',4'-(4-propyl-[1H]pyrazole-1,3,5-triyl) trisphenol activated the rapid ERK1/2-fos signaling cascade. This response was abrogated by the EGFR inhibitor AG1478, ERK inhibitor PD98059 and ER inhibitor ICI 182780, or by silencing GPR30 expression. Moreover, E2 and G1 up-regulated cyclin D1 expression and GC-1 cell proliferation. Our results indicate for the first time that estrogens, through a cross talk between GPR30 and ERalpha, activate the rapid EGFR/ERK/fos pathway, which in turn stimulate mouse GC-1 cell proliferation. Further studies to elucidate the involvement of rapid estrogen signaling pathways in the regulation of male fertility are warranted.     

Expression and role of estrogen receptor alpha and beta in medullary thyroid carcinoma: different roles in cancer growth and apoptosis

Medullary thyroid carcinoma (MTC) originates from parafollicular C cells. Estrogen receptor beta(ERbeta) expressionwas detected in normal parafollicular C cells and MTC tumor tissue, but ERalpha expression in MTC tumors still remains undetermined. The appearance and loss of ERalpha or ERbeta expression has been known to play a role in the development and progression of many human cancers. We performed immunohistochemical studies of ERalpha, ERbeta, and Ki67, a mitotic index, in 11 human MTC tissue samples. ERalpha was detected in 10 cases (91%), and ERbeta expression was observed in 8 cases (72.7%). A majority (8/10) of ERalpha-positive tumors showing ERbeta Ki67 expression was detected in three cases (27.3%). Neither clinical parameters nor tumor node metastasis (TNM) tumor staging was correlated with the positivity for ERs or Ki67. To investigate the biological role of each ER, we used ER-negative MTC TT cells and adenoviral vectors carrying ERalpha (Ad-ERalpha), ERbeta (Ad-ERbeta), estrogen response element (ERE)-Luc (Ad-ERE-Luc), and activator protein 1 (AP1)-Luc (Ad-AP1-Luc). Estrogen stimulated and anti-estrogen, ICI 182 780, suppressed ERE reporter activity in TT cells expressing ERalpha or ERbeta, suggesting that both ERs use the same classical ERE-mediated pathway. Ad-ERalpha infection stimulated TT cell growth; in contrast, Ad-ERbeta infection suppressed their growth. Apoptosis was detected in Ad-ERbeta-infected TT cells. Estrogen and anti-estrogen suppressed AP1 activity in Ad-ERalpha-infected cells, whereas upon Ad-ERbeta infection estrogen further stimulated AP1 activity which in turn is suppressed by anti-estrogen, suggesting that each ER acts differently through a non-ERE-mediated pathway. Our results suggest that ERalpha and ERbeta may play different roles in MTC tumor growth and progression.     

The AF-1 activation-function of ERalpha may be dispensable to mediate the effect of estradiol on endothelial NO production in mice

Two isoforms of estrogen receptor (ER) have been described: ERalpha and ERbeta. The initial gene targeting of ERalpha, consisting in the introduction of a Neo cassette in exon 1 [alphaERKO, hereafter called ERalpha-Neo KO (knockout)], was reported in 1993. More recently, another mouse deficient in ERalpha because of the deletion of exon 2 (ERalphaKO, hereafter called ERalpha-delta2 KO) was generated. In ovariectomized ERalpha-wild-type mice, estradiol (E(2)) increases uterine weight and basal production of endothelial nitric oxide (NO). Both of these effects are abolished in ERalpha-delta2 KO mice. In contrast, we show here that both of these effects of E(2) are partially (uterine weight) or totally (endothelial NO production) preserved in ERalpha-Neo KO. We also confirm the presence of two ERalpha mRNA splice variants in uterus and aorta from ERalpha-Neo KO mice. One of them encodes a chimeric ERalpha protein (ERalpha55), partially deleted in the A/B domain, that was detected in both uterus and aorta by Western blot analysis. The other ERalpha mRNA splice variant codes for an isoform deleted for the A/B domain (ERalpha46), which was detected in uterus of ERalpha-Neo KO, and wild-type mice. This protein isoform was not detected in aorta. The identification of these two N-terminal modified isoforms in uterus, and at least one of them in aorta, probably explains the persistence of the E(2) effects in ERalpha-Neo KO mice. Furthermore, ERalpha-Neo KO mice may help in the elucidation of the specific functions of full-length ERalpha (ERalpha66) and ERalpha46, both shown to be physiologically generated in vivo.     

Ontogenetic changes in the expression of estrogen receptor alpha and beta in rat pituitary gland detected by immunohistochemistry

The physiological effects of estrogen on the pituitary, including cellular proliferation and regulation of hormone synthesis, are mediated by the nuclear estrogen receptor (ER). The purpose of this study was to determine ontogenetic expression of two types of ERs (ERalpha and ERbeta) in the pituitary using specific antibodies, monoclonal antibody (1D5) for ERalpha and polyclonal antibody generated against ERbeta. First, we confirmed the detection of 66- and 55-kDa bands for ERalpha and ERbeta, respectively, in the rat pituitary extract by Western blotting. Then immunostaining with these antibodies was performed using fetal and adult Wistar rat tissues, combined with PRL or LHbeta immunohistochemistry. Intense ERbeta signal was detected throughout the pituitary from day 12 of gestation. However, staining for ERalpha only became detectable from day 17 of gestation. In contrast with the fetal period, nuclei stained for ERalpha were widely distributed in the anterior lobe in the adult rat, whereas ERbeta-positive cells were restricted in the anterior lobe. LHbeta, but not PRL, was colocalized in ERbeta-positive cells. Our results indicated that the major population of ER subtypes in the rat pituitary gland has changed around the day of birth and that the expression of ERbeta may be involved in the differentiation of pituitary cell function to synthesize a specific hormone.