Comparative Aspects of Estrogen Functions and Measurements in Oviparous and Viviparous Vertebrates

Concern for both humans and wildlife has prompted regulatory agencies to search for methods to screen chemicals for disruption of regulation and responses to estrogen and other reproductive hormones. It is not clear whether tests suitable for hazard assessment in mammals also apply to oviparous (egg-laying) animals, or vice versa. Although estrogenic structures are similar across species, estrogen receptor (ER) differences affecting binding affinity and gene activation do occur. The primary function of estrogen in all species is control of ovulation; secondary functions are gender determination, development of secondary sex characteristics, regulation of mating and breeding behaviors, and regulation of calcium and water homeostasis. Major differences between mammals and egg-layers are production of the egg yolk protein vitellogenin by rrthe liver of oviparous species and eggshell formation. Methods for measuring estrogenic activity include production of gene products, cell proliferation assays, tissue responses, vitellogenin induction, hormone assays, egg production and fertility studies, and development of secondary sex characteristics. General cellular/subcellular tests are proposed for initial chemical screening; those that show estrogenic effects would be tested further using species-specific in vitro assays (e.g., relative binding affinity to the ER). Only those chemicals that elicit effects in this second tier, might need to be tested in a higher tier of whole organism studies.     

Label-free sensing and atomic force spectroscopy for the characterization of protein-DNA and protein-protein interactions: application to estrogen receptors

In this paper we describe a new surface plasmon resonance (SPR) biosensor dedicated to potential estrogenic compounds prescreening, by developing an estrogen receptor (ER) specific DNA chip. Through the covalent binding of a DNA strain wearing the estrogen response element (ERE) to an activated 6-mercapto-1-hexadecanoic acid and 11-mercapto-1-undecanol self-assembled monolayer on gold surface, the SPR biosensor allows to detect specifically, quickly, and without any labeling the binding of ER in the presence of estrogen. In parallel, we investigated the ER interaction with itself, in order to study the formation of ER dimer apparently needed to activate the gene expression through ERE interaction. For that, we engaged force spectroscopy experiments that allowed us to prove that ER needs estrogen for its dimerization. Moreover, these ER/ER intermolecular measurements enabled to propose an innovative screening tool for anti-estrogenic compounds, molecules of interest for hormono-dependent cancer therapy.     

Development of methods for extraction and in vitro quantification of estrogenic and androgenic activity of wastewater samples

Chemicals released into the environment by anthropogenic activities have been linked to estrogenic or androgenic effects in exposed wildlife, and there is a need to develop and validate rapid and cost-effective methods to quantify the total estrogenic and androgenic activity of environmental water samples. In this study, estrogen receptors (ER) were isolated from sheep (Ovis aries) uteri and rainbow trout (Oncorhynchus mykiss) livers and androgen receptors (AR) were isolated from rainbow trout brains. The isolated receptors were used in competitive receptor binding assays to test the affinity of known estrogenic and androgenic chemicals for the receptor binding site, and results were compared with literature values for the rat uterine ER binding assay and the E-Screen. The relative binding affinities of the tested compounds to ER from different species were similar, and binding to the ER was a more responsive endpoint than the cellular effect measured in the E-Screen. Using the sheep ER binding assay in combination with solid-phase extraction, the estrogenic activity in a raw sewage sample from a municipal treatment plant in Brisbane (Queensland, Australia) was measured at 51-73 ng/L estradiol equivalents (EEq).     

Interactions of nuclear receptor coactivator/corepressor proteins with the aryl hydrocarbon receptor complex.

MCF-7 human breast cancer cells express the aryl hydrocarbon receptor (AhR), and treatment with AhR agonists such as 2,3,7, 8-tetrachlorodibenzo-p-dioxin (TCDD) inhibits estrogen receptor (ER)-mediated responses. This study investigates physical and functional interactions of the AhR complex with a prototypical coactivator (estrogen receptor associating protein 140, ERAP 140) and corepressor (silencing mediator for retinoic acid and thyroid hormone receptor, SMRT) for ER and other members of the nuclear receptor superfamily. The AhR, AhR nuclear translocator (Arnt), and AhR/Arnt proteins were coimmunoprecipitated with 35S-ERAP 140 and 35S-SMRT and, in gel mobility shift assays, AhR/Arnt binding to 32P-dioxin response element (DRE) was enhanced by ERAP-140 and inhibited by SMRT; supershifted bands were not observed. In transactivation assays, coactivator and corepressor proteins enhanced or inhibited AhR-mediated gene expression; however, these responses varied with the amount of coactivator/corepressor expression. These results confirmed functional and physical interactions of AhR/Arnt with ERAP 140 and SMRT in breast cancer cells.     

Phosphorylation of serine 212 confers novel activity to human estrogen receptor α

Estrogen receptor α (ERα) can be phosphorylated at various residues, one of which is serine 212 in the DNA binding domain. The majority of human nuclear receptors conserves, as a motif, this serine residue within their DNA binding domain. Among these nuclear receptors, phosphorylation of the corresponding threonine 38 in the nuclear receptor CAR is essential for determining its activity [9]. Here, we have investigated the role of phosphorylated serine 212 in the regulation of ERα activity by comparing it with serine 236, another potential phosphorylation site within the DNA binding domain, and demonstrated that phosphorylation of serine 212 confers upon ERα a distinct activity regulating gene expression in Huh-7 cells. In Western blot analysis, wild type ERα and mutants ERα S212A, ERα S212D, ERα S236A and ERα S236D were equally expressed in the nucleus, thus indicating that phosphorylation does not determine nuclear localization of ERα. ERα S212D, but not ERα S236D, retained its capability of activating an ERE-reporter gene in luciferase assays. Similar results were also obtained for human ERβ; the ERβ S176D mutant retained its trans-activation activity, but the ERβ S200D mutant did not. cDNA microarray and Ingenuity Pathway Analysis, employed on Huh-7 cells ectopically expressing either ERα S212A or ERα S212D, revealed that phosphorylation of serine 212 enabled ERα to regulate a unique set of genes and cellular functions.     

Synthesis and evaluation of aryl-substituted diarylpropionitriles,selective ligands for estrogen receptor β, as positron-emission tomographic imaging agents

We have investigated halogen-substituted non-steroidal estrogens with selective binding affinity for the estrogen receptor β (ERβ that might be used for imaging the levels of this ER-subtype in breast tumors by positron emission tomography (PET). Based on diarylpropionitrile (DPN, 1a), a compound previously reported that has a 72-fold binding selectivity for ERβ, we developed a series of DPN analogs having methyl-, hydroxyl-, and halogen substituents, including fluoroethyl and fluoropropyl groups. In competitive radiometric binding assays with [³H]estradiol, all of these DPN analogs showed high ERβ/ERα selectivity; while the selectivity varied, in some cases it reached nearly 300-fold (RBA: ERα, 0.023%; ERβ, 6.25%). The absolute ERβ binding affinities, however, were not sufficient to merit further consideration for developing these ligands as PET imaging agents.     

Effects of environmental estrogenic chemicals on AP1 mediated transcription with estrogen receptors alpha and beta

There has been much discussion concerning endocrine disrupting chemicals suspected of exerting adverse effects in both wildlife and humans. Since the majority of these compounds are estrogenic, a large number of in vitro tests for estrogenic characteristics have been developed for screening purpose. One reliable and widely used method is the reporter gene assay employing estrogen receptors (ERs) and a reporter gene with a cis-acting estrogen responsive element (ERE). Other elements such as AP1 also mediate estrogenic signals and the manner of response could be quite different from that of ERE. Since this has yet to be explored, the ER mediated AP1 activity in response to a series of environmental estrogens was investigated in comparison with ERE findings. All the compounds exhibited estrogenic properties with ERE-luc and their AP1 responses were quite similar. These was one exception, however, p,p'-DDT (1,1,1,-trichloro-2,2-bis(p-chlorophenyl)ethane) did not exert any AP1-luc activity, while it appeared to be estrogenic at 10(-7) to 10(-5)M with the ERE action. None of the compounds demonstrated ER beta:AP1 activity. These data suggest that significant differences can occur in responses through the two estrogen pathways depending on environmental chemicals.