Deciphering estrogen receptor alpha-driven transcription in human endometrial stromal cells via transcriptome, cistrome, and integration with chromatin landscape.

F&S science Pub Date : 2025-08-11 DOI:10.1016/j.xfss.2025.08.002

Skylar G Montague Redecke, Austin Bell-Hensley, Shuyun Li, MyeongJin Yi, Akshadha Jain, Abdull J Massri, Francesco J DeMayo

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Abstract

Objective: To investigate estrogen receptor gene 1 (ESR1) and estrogen-driven transcription in human endometrial stromal cells.

Design: RNA sequencing (RNA-seq) and Cleavage Under Targets and Release Using Nuclease (Cut&Run) were performed on telomerase-immortalized human endometrial stromal cells with Clustered Regularly Interspaced Short Palindromic Repeats-mediated ESR1 activation. Hi-C-based chromatin architecture analysis (H3K27ac HiChIP) was conducted in primary endometrial stromal cells.

Subjects: Biopsies from two healthy, reproductive-aged volunteers with regular menstrual cycles and no history of gynecological malignancies.

Exposure: The ESR1-activated and control endometrial stromal cells were treated with estradiol (E2) or vehicle. Primary endometrial stromal cells were treated with vehicle or a decidualization cocktail.

Main outcome measures: Differential gene expression analysis (RNA-seq) identified ligand-independent and -dependent ESR1 activity. Cut&Run profiled ESR1 genomic binding in ESR1-activated cells. H3K27ac HiChIP mapped hormone-induced changes in chromatin looping in primary cells.

Results: Among seven tested guide RNAs (gRNA), the ESR1-3 gRNA induced robust ESR1 activation and restored E2 responsiveness. Bulk RNA-seq revealed both ligand-dependent and -independent ESR1 transcriptional programs regulating inflammation, proliferation, and cancer-related pathways. Notably, 72% of differentially expressed genes overlapped with genes active in human endometrial tissue during the proliferative estrogen-dominant phase, supporting their physiological relevance. The Cut&Run-seq identified genome-wide ESR1 binding sites, with most binding sites located at distal regulatory elements. Integration of Cut&Run data with H3K27ac HiChIP chromatin loops linked distal ESR1 binding sites to gene promoters, including genes involved in decidualization (e.g., FOXO1) and endometrial cancer (e.g., ERRFI1, NRIP1, and EPAS1). Functional assays showed that ESR1 promotes cell viability and, in the presence of E2, enhances migration.

Conclusion: The CRISPR-mediated ESR1 activation restores estrogen responsiveness in endometrial stromal cells. Combined transcriptomic, cistromic, and chromatin architecture analyses reveal ESR1's role in regulating decidualization and inflammation-related gene networks, with relevance to endometrial pathologies including endometrial cancer. This model serves as a powerful tool to study estrogen signaling in endometrial stromal cell biology and related pathologies.

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通过转录组、池质和染色质景观整合，解读人类子宫内膜基质细胞中esr1驱动的转录。

目的：探讨ESR1基因在人子宫内膜基质细胞中的表达及雌激素驱动的转录。设计：通过crispr介导的ESR1激活，对端粒酶永生化的人子宫内膜基质细胞进行RNA-seq和Cut&Run。在原发性子宫内膜间质细胞中进行了基于hi - c的染色质结构分析（H3K27ac HiChIP）。研究对象：两名健康的育龄志愿者，月经周期规律，无妇科恶性肿瘤史。暴露：esr1激活和对照的子宫内膜基质细胞用雌二醇（E2）或对照物处理。原发子宫内膜间质细胞用载体或去个体化混合物处理。主要结果测量：差异基因表达分析（RNA-seq）鉴定了与配体无关和依赖的ESR1活性。Cut&Run分析了ESR1激活细胞中的ESR1基因组结合。H3K27ac HiChIP绘制了原代细胞中激素诱导的染色质环变化。结果：在7个测试的引导rna （gRNA）中，ESR1-3 gRNA诱导了ESR1的强大激活并恢复了E2的响应性。Bulk RNA-seq揭示了配体依赖性和非依赖性ESR1转录程序调节炎症、增殖和癌症相关途径。值得注意的是，在增殖性雌激素优势期，72%的差异表达基因与人子宫内膜组织中活跃的基因重叠，支持它们的生理相关性。Cut&Run-seq鉴定了全基因组ESR1结合位点，大多数结合位点位于远端调控元件。将Cut&Run数据与H3K27ac HiChIP染色质环结合，将远端ESR1结合位点与基因启动子连接，包括与去个体化相关的基因（如FOXO1）和子宫内膜癌（如ERRFI1、NRIP1、EPAS1）。功能分析显示ESR1促进细胞活力，并在E2存在下增强迁移。结论：crispr介导的ESR1激活可恢复子宫内膜基质细胞的雌激素反应性。转录组学、胞浆学和染色质结构的综合分析揭示了ESR1在调节脱个体化和炎症相关基因网络中的作用，并与子宫内膜癌等子宫内膜病理相关。该模型为研究雌激素信号在子宫内膜间质细胞生物学和相关病理中的作用提供了有力的工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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