Estrogen-enhanced gene expression of lipoprotein lipase in heart is antagonized by progesterone

Although estrogen has effects on the heart, little is known regarding which genes in the heart are directly responsive to estrogen. We have shown previously that lipoprotein lipase (LPL) expression was increased in female hearts compared with male hearts. To test whether LPL gene expression in heart is regulated by estrogen, we perfused mouse hearts from ovariectomized females with 100 nM 17beta-estradiol or vehicle for 2 h, after which hearts were frozen, and RNA was isolated. The SYBR green real-time PCR method was used to detect LPL gene expression. We found that addition of 17beta-estradiol to hearts from ovariectomized females resulted in a significant increase in LPL mRNA. This estrogen effect on LPL gene expression in mouse heart can be blocked by the estrogen receptor (ER) antagonist ICI 182,780 or by progesterone. We also identified a potential estrogen receptor element (ERE) enhancer sequence located in the first intron of the mouse LPL gene. The potential ERE sequence was linked to a TATA-luciferase (LUC) reporter plasmid in HeLa cells. Both ERalpha and ERbeta stimulated strong activity on the heterologous promoter reporter in Hela cells upon estrogen addition. Both ERalpha and ERbeta activities on the LPL ERE reporter were abrogated by the ER antagonist ICI 182,780. Progesterone also dose dependently inhibited the estrogen-mediated increase in LPL ERE reporter activity. These results show that heart LPL is an estrogen-responsive gene exhibiting an intronic regulatory sequence.     

Estrogen modulates endothelial and neuronal nitric oxide synthase expression via an estrogen receptor beta-dependent mechanism in hypothalamic slice cultures

Although it is evident that estrogen has important physiological effects in the brain, the signaling mechanisms mediating these effects remain unclear. We recently showed that estrogen mediates attenuated blood pressure responses to psychological stress in ovariectomized female rats through brain nitric oxide (NO). An area likely to mediate these effects is the hypothalamic paraventricular nucleus (PVN), because here NO exerts inhibitory effects on autonomic output to the periphery. Because little is known about how estrogen acts on the NO system in the PVN, our aim was to study the effects of estrogen on the NO system in the PVN of hypothalamic slices cultures. We show that 17beta-estradiol (E2; 1 nm) increases endothelial NO synthase (eNOS) protein expression and decreases the numbers of neuronal NOS (nNOS)-positive neurons in the PVN after 8 and 24 h, respectively. Using the nonselective estrogen receptor (ER) antagonist, ICI 182,780 (10 nm), we determined that E2-induced changes in NOS expression in the PVN are ER dependent. Using the ERbeta agonist, genistein (0.1 microm), we determined that activation of ERbeta induces increased eNOS expression and a decreased number of nNOS-positive neurons. We used the selective ERalpha agonist, propyl-pyrazole-triol (10 nm), and antagonist, methyl-piperidino-pyrazole (1 microm), to exclude the possibility that ERalpha is involved in the E2-induced increase in eNOS and nNOS in the PVN. These results demonstrate that E2 induces changes in NOS expression in the PVN and that these effects are ERbeta dependent.     

17Beta-estradiol up-regulates vascular endothelial growth factor receptor-2 expression in human myometrial microvascular endothelial cells: role of estrogen receptor-alpha and -beta

Estrogen has a cardiovascular protective role in women due in part to its effect on the vasculature. The roles of the two estrogen receptors (ERs), ERalpha and ERbeta, in the vascular actions of estrogen are unclear, as are effects of estrogen on microvascular endothelial cells (MEC) derived from sex steroid-responsive tissues. The present study demonstrates that 17beta-estradiol, but not progesterone, increases vascular endothelial growth factor (VEGF) receptor (VEGFR) expression on human myometrial MEC measured using biotin-recombinant human (rh) VEGF(165) and flow cytometry. This response occurred in a time- and dose-dependent manner, with significantly increased rhVEGF(165) binding at 3 h and maximal responses between 0.1 and 10 nmol/liter 17beta-estradiol, which was blocked by the antiestrogen ICI 182,780. Approximately 60% of samples demonstrated this response to 17beta-estradiol. All samples of myometrial MEC expressed both ERbeta mRNA and protein demonstrated by semiquantitative RT-PCR and Western blotting. However, ERalpha mRNA and protein were expressed in only 13 of 21 MEC samples. There was a significant association between ERalpha expression in myometrial MEC and their ability to respond to 17beta-estradiol by increasing rhVEGF(165) binding. 17beta-estradiol increased VEGFR-2 expression in ERalpha-expressing MEC isolates, which also demonstrated increased rhVEGF(165) binding, but failed to have these effects on ERalpha negative samples. Similarly, 17beta-estradiol augmented VEGF-induced MEC proliferation in ERalpha-expressing MEC samples, which was blocked by ICI 182,780. These observations suggest that 17beta-estradiol increases VEGFR-2 expression on human myometrial MEC promoting endothelial cell proliferation, an effect that varies between subjects and appears to be mediated primarily by ERalpha.     

Cadmium induces mitogenic signaling in breast cancer cell by an ERalpha-dependent mechanism

Breast cancer (BC) is linked to estrogen exposure. Estradiol (E2) stimulates BC cells proliferation by binding the estrogen receptor (ER). Hormone-related cancers have been linked to estrogenic environmental contaminants. Cadmium (Cd) a toxic pollutant, acts as estrogens in BC cells. Purpose of our study was to evaluate whether Cd regulates MCF-7 cell proliferation by activating ERK1/2, Akt and PDGFRalpha kinases. Cd increased cell proliferation and the ER-antagonist ICI 182,780 blunted it. To characterize an ER-dependent mechanism, ERalpha/beta expression was evaluated. Cd decreased ERalpha expression, but not ERbeta. Cd also increased ERK1/2, Akt and PDGFRalpha phosphorylation while ICI blocked it. Since stimulation of phosphorylation was slower than expected, c-fos and c-jun proto-oncogenes, and PDGFA were analyzed. Cd rapidly increased c-jun, c-fos and PDGFA expression. Cells were also co-incubated with the Cd and specific kinases inhibitors, which blocked the Cd-stimulated proliferation. In conclusion, our results indicate that Cd increases BC cell proliferation in vitro by stimulating Akt, ERK1/2 and PDGFRalpha kinases activity likely by activating c-fos, c-jun and PDGFA by an ERalpha-dependent mechanism.     

Enhancement of collagen-induced arthritis in female mice by estrogen receptor blockage

OBJECTIVE: To determine whether estrogen-mediated suppression of collagen-induced arthritis (CIA) in mice acts via the nuclear estrogen receptors (ERs). METHODS: CIA was induced in noncastrated normal (B10.Q x DBA/1)F1 (QD) female mice. The mice were treated with the ER antagonist ICI 182,780, which binds to both ERalpha and ERbeta, either on days 2, 6, 10, and 14 or on days 14, 18, 22, and 26 after type II collagen (CII) immunization. The effects of treatment and development of arthritis were correlated with the estrus cycle by inspection of vaginal smears (VS). By a combination of treatments with both estriol (E3) and ICI 182,780 during the time of expected onset of CIA in castrated QD female mice, the protective effect of E3 in CIA was analyzed. RESULTS: Treatment with ICI 182,780 of QD female mice immunized with CII triggered an earlier onset of arthritis during the period when the estrus cycle was blocked. The arthritis-modulating effect of ICI 182,780 was even obtained at doses that were insufficient to block estrus cycling, as observed in the VS response. E3 is an estrogen with low estrogenic potency but with a relatively potent antiarthritis effect. Doses of ICI 182,780 that were suboptimal for blocking estrus cycling blocked the E3-mediated suppression of CIA in castrated female mice. CONCLUSION: These findings show that estrogen-induced suppression of CIA is mediated via the nuclear ERs and is operating at physiologic, possibly even subphysiologic, levels of estrogens.     

Estrogen and raloxifene induce apoptosis by activating p38 mitogen-activated protein kinase cascade in synthetic vascular smooth muscle cells

Proliferation of vascular smooth muscle cells (VSMC) plays a major role as an initiating event of atherosclerosis. Although estrogen directly inhibits the proliferation of VSMC, the mechanism has not been firmly established. In addition, the effect of raloxifene on VSMC remains unknown. 17Beta-estradiol (E(2)) and raloxifene significantly inhibited the growth of VSMC under growth-stimulated conditions. Since mitogen-activated protein (MAP) kinases have been implicated in VSMC proliferation, the role of MAP kinases in both the E(2)- and raloxifene-induced growth inhibition of VSMC was studied. Both E(2) and raloxifene caused rapid, transient phosphorylation and activation of p38 that was not affected by actinomycin D and was blocked by ICI 182,780. In contrast with p38 phosphorylation, extracellular signal-regulated protein kinase (ERK) phosphorylation was significantly inhibited and c-Jun N-terminal kinase (JNK) phosphorylation was not changed by E(2). Because VSMC expressed both estrogen receptor (ER) alpha and ERbeta, it is not known which of them mediates the E(2)-induced phosphorylation of p38. Although E(2) did not affect the p38 phosphorylation in A10 smooth muscle cells, which express ERbeta but not ERalpha, transfection of ERalpha expression vector into A10 cells rendered them susceptible to induction of p38 phosphorylation by E(2). We then examined whether E(2) and raloxifene induce apoptosis through a p38 cascade. Both E(2) and raloxifene induced apoptosis under growth-stimulated conditions. The p38 inhibitor SB 203580 completely blocked the E(2)-induced apoptosis. Our findings suggest that both E(2)- and raloxifene-induced inhibition of VSMC growth is due to induction of apoptosis through a p38 cascade whose activation is mediated by ERalpha via a nongenomic mechanism.     

Intracellular signaling involved in estrogen regulation of serotonin reuptake

17beta-estradiol (E2) regulates neuronal activity via genomic and rapid, non-genomic mechanisms. The rat serotonergic neuronal cell line (RN46A) was used to investigate the rapid effects of E2 on serotonin (5-HT) reuptake and on potential intracellular signaling pathways. RN46A cells express the serotonin transporter (SERT) and estrogen receptor (ER)beta, but not ERalpha. Fifteen minute E2 treatment (10(-9)M) decreased 5-HT uptake. Intracellular cAMP levels were not increased by 15 min E2 treatment; however, E2 caused an increase in intracellular Ca2+ levels, with a maximum response within the first minute. The response was E2 specific, since other steroids (17alpha-estradiol, testosterone, and progesterone) had no effect. The ER antagonist ICI 182,780 blocked the rapid E2 effects on intracellular Ca2+ levels as did the selective ER modulator tamoxifen. In summary, changes in intracellular Ca2+ levels caused by E2 and mediated through ERbeta may be responsible for observed rapid effects of E2 on SERT activity.     

Differential effects of estrogen receptor antagonists on pituitary lactotroph proliferation and prolactin release

Anti-estrogens act by inhibiting estrogen receptor (ER) function. Unlike raloxifene and tamoxifen which exhibit both antagonist and agonist properties, ICI 182,780 (ICI) is considered a "pure" anti-estrogen devoid of any agonistic activities. Whereas there is ample information on the effects of anti-estrogens on the breast and uterus, little is known about their action on the pituitary, the estrogen-sensitive master endocrine gland. Our objectives were to: (1) compare the effects of ICI, tamoxifen and raloxifene on lactotroph proliferation in the absence of estrogen, (2) determine whether their action is mediated through the ER, and (3) compare their effects on prolactin (PRL) release. We are reporting that ICI is a potent inhibitor of lactotroph proliferation (both GH3 and MMQ cells) with maximal inhibition of 45-50% seen with 1nM. ICI is several orders of magnitude more potent than raloxifene while tamoxifen has no effect. Neither anti-estrogen affects T47D breast cancer cell proliferation. GH3 cell incubation with ICI for 1h only causes maximal suppression of cell proliferation, an effect which is reversed by co-incubation with estrogen. Such a short exposure to ICI is sufficient to cause rapid and persistent downregulation of ERalpha protein, whereas downregulation of ERbeta is significantly delayed; tamoxifen and raloxifene have no appreciable effects on ER(s) levels. The ability of ICI to inhibit GH3 cell proliferation is dependent upon ERalpha, since an ERalpha, but not ERbeta, specific agonist reverses the effect of ICI. PRL release is differentially regulated by the anti-estrogens. ICI at 0.1nM suppresses PRL release from GH3 cells by 80%, with a similar strong suppression also seen with 10nM raloxifene. However, tamoxifen at 0.01nM inhibits PRL release but has no effect at 10nM. Cell co-incubation with ICI and estradiol results in a four-fold increase in PRL release. Taken together, our study shows that ICI, in the absence of exogenous estrogens, inhibits lactotroph proliferation and PRL release by downregulating or inactivating ERalpha. The dissimilar responses of cell proliferation and PRL release to the anti-estrogens suggest that both processes are regulated by different mechanisms. These data highlight the importance of studying the effects of anti-estrogens in multiple systems.     

Expression of functional estrogen receptor beta in locus coeruleus-derived Cath.a cells

Estrogen may have an important role in the brain beyond the development and regulation of reproductive function. Gender differences in the incidence of depression suggest that regulation of mood represents one such action. The locus coeruleus, a brain stem noradrenergic nucleus implicated in mood regulation, concentrates [(3)H]estradiol, but expression of the two estrogen receptor (ER) subtypes (ERalpha and ERbeta) varies across species. Further, the role of each subtype in estrogen action on noradrenergic neurons is unknown. We examined the expression of ERs in the Cath.a (central-adrenergic-tyrosine-hydroxylase-expressing) cell line derived from mouse brain stem and found that they express ERbeta protein but not ERalpha protein. Transient transfection assays using an estrogen-responsive reporter gene indicate that ERbeta is functional. The pure estrogen antagonist ICI 182,780 completely abolished estrogen's effects. Selective ER modulator results suggest that ER in Cath.a cells behaves in a manner consistent with ERbeta pharmacology. R,R-Tetrahydrochrysene, an ERalpha agonist, had no effect on luciferase-driven activity in Cath.a cells. This study provides the first report of a cell line that spontaneously expresses functional ERbeta protein. Cath.a cells may prove to be a useful tool in elucidating basic pharmacologic properties of ERbeta. It may also help reveal the molecular mechanisms involved in mood regulation by estrogen.     

Estrogen receptor alpha, but not beta, plays a major role in 17beta-estradiol-induced murine cholesterol gallstones

BACKGROUND & AIMS: Cholesterol gallstones are more common in women than men, and exposure to oral contraceptive steroids and conjugated estrogens increases the risk for gallstones. It is hypothesized that estrogen enhances cholesterol cholelithogenesis by augmenting functions of hepatic estrogen receptors (ERs). METHODS: To investigate molecular mechanisms of how estrogen influences cholesterol gallstones, we studied gonadectomized AKR/J mice of both genders that were implanted subcutaneously with pellets releasing 17beta-estradiol at 0, 3, or 6 microg/day and that were fed a lithogenic diet for 12 weeks. To test the hypothesis that ERs play a pivotal role in mediating lithogenic actions of estrogen and to dissect the potential pathophysiologic roles of each receptor subtype, ERalpha and ERbeta, in the formation of gallstones, we investigated gonadectomized mice treated with synthetic ER subtype-selective agonists or antagonists. RESULTS: 17beta-estradiol promoted gallstone formation by up-regulating hepatic expression of ERalpha but not ERbeta, and the lithogenic actions of estrogen can be blocked completely by the antiestrogenic ICI 182,780. The ERalpha-selective agonist propylpyrazole, but not the ERbeta-selective agonist diarylpropionitrile, augmented hepatic cholesterol output that resulted in cholesterol supersaturated bile and gallstones. Similar to the 17beta-estradiol treatment, tamoxifen significantly increased biliary cholesterol secretion and gallstone prevalence in both gonadectomized females and males. CONCLUSIONS: The hepatic ERalpha, but not ERbeta, plays a critical role in 17beta-estradiol-induced cholesterol gallstones. Our findings may offer a new approach to treat gallstones by inhibiting hepatic ER activity with a liver-specific, ERalpha-selective antagonist.     

Estrogen receptor alpha and endothelial nitric oxide synthase are organized into a functional signaling module in caveolae

Estrogen causes nitric oxide (NO)-dependent vasodilation due to estrogen receptor (ER) alpha-mediated, nongenomic activation of endothelial NO synthase (eNOS). The subcellular site of interaction between ERalpha and eNOS was determined in studies of isolated endothelial cell plasma membranes. Estradiol (E(2), 10(-8) mol/L) caused an increase in eNOS activity in plasma membranes in the absence of added calcium, calmodulin, or eNOS cofactors, which was blocked by ICI 182,780 and ERalpha antibody. Immunoidentification studies detected the same 67-kDa protein in endothelial cell nucleus, cytosol, and plasma membrane. Plasma membranes from COS-7 cells expressing eNOS and ERalpha displayed ER-mediated eNOS stimulation, whereas membranes from cells expressing eNOS alone or ERalpha plus a myristoylation-deficient mutant eNOS were insensitive. Fractionation of endothelial cell plasma membranes revealed ERalpha protein in caveolae, and E(2) caused stimulation of eNOS in isolated caveolae that was ER-dependent; noncaveolae membranes were insensitive. Acetylcholine and bradykinin also activated eNOS in isolated caveolae. Furthermore, the effect of E(2) on eNOS in caveolae was prevented by calcium chelation. Thus, a subpopulation of ERalpha is localized to endothelial cell caveolae where they are coupled to eNOS in a functional signaling module that may regulate the local calcium environment. The full text of this article is available at http://www.circresaha.org.