Abstract Disclosure: H. Kim: None. T.S. Nandu: None. W.L. Kraus: None. Estrogens are steroid hormones that play a key role in a wide range of physiological and pathological processes. The predominant nuclear receptor for estrogens, estrogen receptor-alpha (ERɑ), functions primarily as a nuclear transcription factor (TF) through ligand-dependent activation by 17β-estradiol (E2), the major naturally-occurring estrogen. The physiological levels of E2 are regulated by production, sequestration, and degradation, which can limit the amount of bioavailable E2. However, many studies examining the genomic effects of E2-regulated signaling in cell-based assays used supraphysiological levels of hormone. While this has allowed us to understand the extremes of E2 signaling, it limits our ability to examine cellular functions which operate at lower hormone concentrations. The genomic actions of ligand-bound ERɑ are mediated through transcriptional enhancer formation and function. Alterations in protein and DNA components dictate different enhancer molecular subtypes that specify distinct regulatory mechanisms and downstream cellular phenotypes. How the amount of available hormone affects these genomic processes is unknown. In order to understand the genomic effects of physiological low-dose levels of E2, we have treated MCF-7 ERɑ-positive human breast cancer cells with a range of E2 concentrations and examined the global regulation of gene expression using a multi-omics approach (RNA-seq, ERɑ ChIP-seq, H3K27ac ChIP-seq, PRO-seq, ATAC-seq). Interestingly, we identified gene sets that are preferentially expressed maximally at picomolar or nanomolar concentrations. We are using these genes sets to explore the mechanisms of estrogen-regulated gene expression at physiologically relevant of E2 concentrations. Analysis of nascent RNA transcription using PRO-seq indicates regulation at the transcriptional level. Preliminary ERɑ chromatin binding assays show that while many loci require high levels of E2 for maximum ERɑ binding, others show maximum ERɑ binding at lower doses of E2. Further analyses show distinct enhancer features, such as chromatin accessibility and H3K27ac enrichment, may play a role in determining the response to E2 dosage. We are now determining the molecular mechanisms of dosage sensitivity using a multipronged approach integrating genomics, molecular biology, and cell-based assays. With these studies, we hope to understand a long overlooked physiological aspect of E2 with a comprehensive and global analysis of signal-dependent genomic responses. Presentation: 6/3/2024
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