Estrogen receptor transcription and transactivation: Estrogen receptor knockout mice - what their phenotypes reveal about mechanisms of estrogen action

Natural, synthetic and environmental estrogens have numerous effects on the development and physiology of mammals. Estrogen is primarily known for its role in the development and functioning of the female reproductive system. However, roles for estrogen in male fertility, bone, the circulatory system and immune system have been established by clinical observations regarding sex differences in pathologies, as well as observations following menopause or castration. The primary mechanism of estrogen action is via binding and modulation of activity of the estrogen receptors (ERs), which are ligand-dependent nuclear transcription factors. ERs are found in highest levels in female tissues critical to reproduction, including the ovaries, uterus, cervix, mammary glands and pituitary gland. Since other affected tissues have extremely low levels of ER, indirect effects of estrogen, for example induction of pituitary hormones that affect the bone, have been proposed. The development of transgenic mouse models that lack either estrogen or ER have proven to be valuable tools in defining the mechanisms by which estrogen exerts its effects in various systems. The aim of this article is to review the mouse models with disrupted estrogen signaling and describe the associated phenotypes

Anti-estrogen activity in the yeast transcription system: estrogen receptor mediated agonist response.

The mouse estrogen receptor was expressed in yeast cells to study the mechanism of action of anti-estrogens. Tamoxifen and hydroxytamoxifen, estrogen antagonists in mammalian tissues, failed to antagonize estradiol-induced expression of a VitA2-ERE-CTC1-lacZ reporter gene construct and exhibited full agonist activity, while nafoxidine exhibited partial antagonism as well as partial agonism. ICI 164,384 is a potent anti-estrogen in both mouse and human estrogen receptor systems. Our previous studies in the mouse uterus indicated that rapid degradation of the estrogen receptor accounted for the loss of estrogen responsiveness. In yeast however, ICI 164,384 or an isomer ICI 182,780 were unable to antagonize estradiol at concentration of 200 microM. On the contrary, both ICI compounds exhibited partial agonist activity by stimulating beta-galactosidase activity to 50% that of estradiol. We examined the level of estrogen receptor in the yeast after treatment with estradiol, ICI 164,384 or vehicle by Western blot and found no ICI-induced reduction of estrogen receptor levels, but observed an increase in estrogen receptor following estradiol treatment. This indicates that the proteolytic activity responsible for degrading estrogen receptor in ICI 164,384-treated uteri or eukaryotic cells is not present in yeast. The agonist activity seen with ICI indicated that ICI-bound estrogen receptor is able to induce expression of an estrogen-responsive reporter gene. In support of this, estrogen receptor from ICI 164,384-treated yeast was able to bind an estrogen-responsive element in a gel-shift assay