Sylvia W. Curtis scite author profile

Epidermal growth factor (EGF) reproduces many of the effects of estrogen on the murine female reproductive tract and may partially mediate estroged-induced growth and differentiation. This study was performed to investigate the mechanism by which EGF elicits estrogen-like actions in the whole animal. EGF was ad tered to adult ovariectomized mice by slow release pellets implanted under the kidney capsule. The induction ofuterine DNA synthesis and phosphatidylinositol lipid turnover by EGF or admintation of diethylstilbestrol (5 pg/kg), a potent estrogen, was attenuated by the estrogen receptor antagonist ICI 164,384. Furthermore, EGF mimicked the effects of estrogen on enhanced nuclear localization of the estrogen receptor and the formation of a unique form of the estrogen receptor found exclusively in the nucleus. These results suggest that EGF may induce effects similar to those of estrogen in the mouse uterus by an interaction between the EGF signaling pathway and the classical estrogen receptor. The demonstration of cross-talk between polypeptide growth factors and steroid hormone receptors may be of importance to our understanding of the regulation of normal growth and differentiation as well as the mechanisms of transmission of extracellular mitogen signals to the nucleus.It has been proposed that polypeptide growth factors may act as autocrine or paracrine mediators of estrogen-induced mitogenesis (1, 2). The observations that estrogen induces mRNA and protein for both epidermal growth factor (EGF) (3,4) and its receptor (5-7) in rodent uterus are consistent with this hypothesis and implicate a role for the EGF receptor signaling pathway in steroid hormone regulation of uterine tract growth. Furthermore, exogenous EGF administration to adult ovariectomized mice mimics the effects of estrogen on proliferation and differentiation in the murine female reproductive tract (8). EGF-induced mitogenesis in this model is not affected by adrenalectomy or hypophysectomy, which indicates that adrenal or pituitary hormones do not mediate the effects of EGF. In addition, the fact that an EGF-specific antibody administered prior to estradiol partially blocks estrogen-induced uterine epithelial cell proliferation (8) suggests that production of EGF may be necessary for estrogen-induced responses.Presently, the mechanism by which the actions of estrogens and EGF converge is unknown. This study addresses the intriguing possibility that some of the physiological actions of EGF, an extracellular ligand, may be mediated through a nuclear steroid hormone receptor, namely, the estrogen receptor (ER). Two recent reports by Power et al. (9,10) support such a hypothesis. These studies demonstrated that dopamine, an extracellular ligand, was able to stimulate transcriptional enhancement by three members of the steroid receptor superfamily [the progesterone receptor (PR), ER, and COUP (chicken ovalbumin upstream promoter) transcriptional enhancer], which were transfected into CV1 monkey kidney cells. Furthermore, in MCF-7 hu...

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Analysis of transcription and estrogen insensitivity in the female mouse after targeted disruption of the estrogen receptor gene.

Couse

Curtis

Washburn

et al. 1995

Molecular Endocrinology

211

200

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We employed homologous recombination in mouse embryonic stem cells to disrupt the estrogen receptor (ER) gene. Subsequently generated mice that are homozygous for the gene disruption, termed ERKO, possess no demonstrable wild-type ER by Western blot analysis. However, the presence of residual high affinity binding, as detected by [3H]estradiol binding assays and sucrose gradients in uterine extracts from ERKO females prompted further investigation of transcription and translation products from the disrupted ER gene. Analysis of ERKO uterine messenger RNA (mRNA) by reverse transcriptase-polymerase chain reaction demonstrated that although no full-length wild-type ER mRNA was present, two smaller transcripts, labeled E1 and E2, were identified and partially sequenced. Both ERKO transcripts are splicing variants that result in the disrupting NEO sequence being partially or completely removed from the mRNA. In the ERKO-E2 variant, this results in a frame shift and the creation of at least two stop codons downstream. In the ERKO-E1 variant, the ER reading frame is preserved and encodes for a smaller mutant ER that could be the source of the residual estradiol binding. When this mutant form is overexpressed and characterized in vitro, it results in a smaller protein of the predicted size that possesses significantly reduced estrogen-dependent transcriptional activity compared with that of the wild-type ER. Despite residual amounts of an impaired ER variant, estrogen insensitivity in the female ERKOs was confirmed by the failure of estrogen treatment to induce known uterine markers of estrogen action, such as increased DNA synthesis, and transcription of the progesterone receptor, lactoferrin, and glucose-6-phosphate dehydrogenase genes. Furthermore, serum levels of estradiol in the ERKO female are more than 10-fold higher than those in the wild type, consistent with a syndrome of hormone insensitivity.

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Vascular estrogen receptors and endothelium-derived nitric oxide production in the mouse aorta. Gender difference and effect of estrogen receptor gene disruption.

Rubanyi¹,

Freay²,

Kauser³

et al. 1997

J. Clin. Invest.

256

161

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The present study was designed to test the hypothesis that estrogen receptors (ER) in the blood vessel wall play a role in the modulation of the release of endothelium-derived nitric oxide (EDNO). Both basal and stimulated release of EDNO were determined in aortic rings isolated from female and male wild-type and male homozygous estrogen receptor knock-out (ERKO) mice.125 I-17 ␤ -estradiol binding in aortic tissue showed significantly more high affinity cytosolicnuclear-binding sites in male compared with female wildtype mice. Estrogen receptor transcripts were present in the aorta of male wild-type mice, but they were absent in male ERKO animals. Basal release of EDNO (determined by endothelium-dependent contraction caused by N G -nitro-Larginine) was significantly higher in aorta of wild-type male mice compared with wild-type female mice, and significantly lower in the aorta of male ERKO compared with male wild-type mice. Acetylcholine-induced endotheliumdependent relaxation was similar in all groups studied. No difference was observed in the activity of calcium-dependent nitric oxide synthase in homogenates of lungs and brain taken from male wild-type and ERKO mice. These studies show a significant association between the number of estrogen receptors and basal release of EDNO in the aorta of mice, and suggest that decreased vascular estrogen receptor number may represent a novel risk factor for cardiovascular diseases.

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Sylvia W. Curtis

Coupling of dual signaling pathways: epidermal growth factor action involves the estrogen receptor.

Analysis of transcription and estrogen insensitivity in the female mouse after targeted disruption of the estrogen receptor gene.

Vascular estrogen receptors and endothelium-derived nitric oxide production in the mouse aorta. Gender difference and effect of estrogen receptor gene disruption.

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