A panel of luminescent Saccharomyces cerevisiae cell-based nuclear receptor assays, consisting of human estrogen receptors α and β, androgen receptor, and aryl hydrocarbon receptor, was miniaturized from the standard 96-well microplate format to high-throughput 384- and 1536-well microplate formats. In these assays, firefly luciferase lacking the peroxisome targeting sequence was used as a reporter and D-luciferin substrate was pre-mixed with the yeast cells before the incubation step, eliminating cell lysis and substrate addition steps, and allowing multiple readings at any desired time point. All of the assays were highly functional in the 384-well format, and most functioned well in the 1536-well format. The detection limit of the estrogen receptor α assay was even lower in the miniaturized microplate formats than in the original 96-well format. The panel of yeast-cell-based nuclear receptor assays can be used for high-throughput chemical testing and environmental monitoring of potential endocrine-disrupting activity of compounds and samples.
Directed evolution has become a successful approach to alter ligand binding properties of nuclear receptors. In this study, directed evolution was used to generate a mutant human estrogen receptor α library, which was then used to screen for receptors having enhanced responses to the known endocrine-disrupting chemical, bisphenol A (BPA). A single round of multi-site mutation was combined with an efficient positive/negative library screening method in which positive growth-based selection for the desired activity with BPA was combined with flow cytometric removal of cells having undesired activity with the natural ligand, 17β-estradiol. The screening steps were performed in a Saccharomyces cerevisiae yeast strain containing a genome-integrated his3-yEGFP reporter gene fusion construct. A single round of mutation and screening yielded nine mutants with enhanced responses towards BPA but no detectable induction by 17β-estradiol (up to 90 nM). These BPA-specific mutant receptors may prove useful in the field of environmental analytics, where they could be used to monitor and evaluate the proportion of BPA in hormonally active samples.
Bioluminescent Saccharomyces cerevisiae yeast-based bioreporters were used to monitor bisphenol A and other estrogenic chemicals in thermal paper samples collected mainly from Finland on two occasions in 2010/2011, and 2013. The bisphenol A-targeted (BPA-R) and the human oestrogen receptor (hERα) bioreporters were applied to analyse both non-treated and extracted paper samples. Bisphenol A was readily bioavailable to the yeast bioreporters on the non-treated paper samples without any pre-treatment. Detected concentrations ranged from a detection limit of 9-142 μg/g to over 20 mg/g of bisphenol A equivalents in the thermal papers. Low bisphenol A like activities were detected in many samples, and were considered to be caused by residual bisphenol A or other types of bisphenols, such as bisphenol S. Most of the thermal paper samples were toxic to the yeast bioreporters. The toxicity did not, however, depend on the bisphenol A concentration of the samples. The yeast bioreporters were demonstrated to be a robust and cost-efficient method to monitor thermal paper samples for their bisphenol A content and estrogenicity. Thermal paper was considered as a potential BPA source for both human exposure and environmental emission.
Organotin compounds are toxic and endocrine disrupting compounds, which have been intensively used as antifouling paints for ship hulls and thus are widely spread in the environment. They are suspected to cause imposex, the formation of male characteristics in female gastropods, because of the activation of retinoid X receptor (RXR) at very low environmental concentrations. Here we report the development and optimization of a bioluminescent yeast assay for the detection of organotin compounds based on the interaction with a hybrid RXR and subsequent expression of a reporter luciferase gene. This assay is highly specific toward organotin compounds and natural ligands of the RXR. It detects tributyltin and triphenyltin in nanomolar concentrations (detection limits were found to be 30 nM and 110 nM, respectively) and allows small-scale high-throughput analyses. Furthermore it was possible to measure tributyltin directly in untreated spiked sediments. Thus, the results provided within one working day can be used for the assessment of bioavailability and mixture effect of organotin compounds in environmental samples.
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