In Vivo Quantitation of Estrogen Receptor ß Subtype Expression in Ovarian Surface Epithelium Using Immunofluorescence Profiling and Confocal Microscopy.

Immunohistochemistry using formalin-fixed, paraffin-embedded tissue, chromogen label, and light microscopy has traditionally been used to semiquantify estrogen receptor (ER) to guide diagnosis and management of breast cancer. Quantitation of ER for this purpose currently only assesses levels of the ER-alpha subtype. Considerable variability in results reported has been due to protocol and fixation variability, intraobserver and interobserver variability, and different scoring systems and thresholds for scoring ER positivity. Results can also vary with low expression levels of ER. ER-beta expression is reduced in breast and ovarian cancers and requires quantitation.Herein we describe a novel approach to quantifying ERß using older mouse ovarian surface epithelium, where ERß is expressed at lower levels than ERα and is therefore harder to detect. We use an antibody highly specific to the ERß1 isoform, together with immunofluorescence, confocal microscopy, and imaging and statistical software to achieve clear, reproducible, and unbiased quantitation of ERß.

Xenobiotics and the Glucocorticoid Receptor.

Glucocorticoid Receptor (GR) is present in virtually every human cell type. Representing a nuclear receptor superfamily, GR has several different isoforms essentially acting as ligand-dependent transcription factors, regulating glucocorticoid-responsive gene expression in both a positive and a negative manner. Although the natural ligand of the Glucocorticoid Receptor, glucocorticoids (GC) represent only some of the multiple ligands for GR. Xenobiotics, ubiquitous in the environment, bind to GR and are also capable of activating or repressing GR gene expression, thereby modulating GR cell and tissue-specific downstream effects in a multitude of ways that include responses to inflammatory, allergic, metabolic, neoplastic and autoimmune processes. Many xenobiotics, if inadequately metabolized by xenobiotic metabolizing enzymes and not wholly eliminated, could have deleterious toxic effects with potentially lethal consequences. This review examines GR, the genomic and non-genomic actions of natural and synthetic GC and the body's handling of xenobiotic compounds, before reviewing what is presently known about GR's interactions with many of the more commonly encountered and some of the less well known GR-associated xenobiotics. GR promiscuity and crosstalk with other signaling pathways is discussed, alongside novel roles for GR that include mood disorder and addiction. A knowledge of GR interactions with xenobiotics is increasingly relevant when considering aging populations and the related prevalence of neoplastic disease, together with growing concerns around human exposure to mixtures of chemicals in the environment. Furthermore, escalating rates of obesity, Type 2 diabetes; autoimmune, allergy, addiction and mood disorder-related pathologies, require novel targeted interventions and GR appears a promising pharmacological candidate.

Repeat estradiol exposure differentially regulates protein expression patterns for estrogen receptor and E-cadherin in older mouse ovarian surface epithelium: implications for replacement and adjuvant hormone therapies?

BACKGROUND: Estrogen replacement therapy increases risk for ovarian epithelial cancer, a cancer of mainly older women, yet the response of older ovarian surface epithelium (OSE) to repeat estrogen exposure overtime has not been studied. We have previously reported significant reductions in estrogen receptor (ER) protein expression, particularly the ERß1 isoform, in older mouse OSE following a single depot estradiol injection. The current study examined OSE from older mice following a single, and repeat estradiol injection, given 14 days apart over 28 days. METHODS: Cohorts of mice were sacrificed 48 hours following each estradiol injection, and at three other equidistant time points. Serum and ovarian tissue estradiol concentration was correlated to immunohistochemical and morphometric parameters used to identify evidence of OSE hyperplasia and hypertrophy. Using immunohistochemistry, E-cadherin expression was investigated in OSE 48 hours following both estradiol injections, while ERα and ERß1 expression was examined in OSE following repeat estradiol exposure only. RESULTS: First exposure to exogenous estradiol resulted in OSE hypertrophy and hyperplasia, and high levels of E-cadherin expression. In contrast, repeat estradiol exposure resulted in no OSE hyperplasia or hypertrophy, low levels of E-cadherin expression, high ERα and reduced ERß1 protein expression in OSE, and low stromal ERα expression. Blood and ovarian tissue estradiol levels following repeat estradiol injection were half those recorded after a first dose equivalent injection, but remained significantly elevated above controls. CONCLUSION: Repeat estradiol exposure leads to accumulation of estradiol in ovarian tissue, differentially regulating protein expression patterns for E-cadherin in OSE and ER in OSE and stroma.

Novel approaches to quantify estradiol-induced loss of ERß1 protein in older mouse ovarian surface epithelium: new tools to assess the role of ER protein subtypes in predisposing to ovarian epithelial cancer?

Loss of estrogen receptor-beta (ERß) occurs in ovarian epithelial cancer (OEC), a cancer of mainly older women. OEC is linked epidemiologically to hormone replacement therapy, predominantly with estrogen-only formulations. This study introduces a novel, non-biased method to quantify levels of estradiol-induced loss of ERß1 protein, and defines, for the first time, normal OSE expression patterns for ERα and ERß1 with advancing age. Older (7-10 months) Swiss Webster mice were injected with estradiol valerate (EV) while age-matched diestrous controls received oil. Mice were culled after 48 h, and blood and one ovary were frozen for estradiol RIA. Contralateral ovaries were paraffin-embedded for immunohistochemistry. Subsets of serial sections, triple-labeled with immunofluroescent tags, were imaged with confocal microscopy to provide optimal visualization of ER protein subtype expression in OSE. Immunofluorescence emission profiles distinct to ERß1 in OSE were standardized and quantified in control mice then compared to profiles from EV-exposed mice. Estradiol levels were significantly elevated in EV-treated mice, both in blood (p < 0.0001) and ovarian tissue (p < 0.001), resulting in 11-fold reduction in OSE expression of ERß1 protein (p < 0.0001). In aging OSE, expression patterns of both ER subtypes varied within cells and with cell shape. ER co-localization appeared predominantly cytoplasmic and was infrequent in columnar compared to cuboidal-shaped OSE cells. Immunofluorescence emission profiling and multiple-label immunofluorescent tagging of ER using confocal microscopy, provides sharp definition of ER locus enabling concurrent qualitative and quantitative analysis of ER protein. It offers significant potential for assessing ER protein subtype status in predisposition to OEC.