Project description:Background: Aberrant DNA methylation is an epigenetic hallmark of most malignant tumors including breast cancer. However, the exact role of TET2-mediated DNA demethylation in ERα-positive luminal breast cancer is not well understood. Results: Here we showed by TCGA analyses that lower TET2 mRNA expression level is associated with worse clinical outcomes (i.e., overall survival) in ERα-positive but not ERα-negative breast cancer. Moreover, depletion of TET2 by CRISPR/Cas9 results in increased tumorigenesis capability of MCF7 cells in vitro. Whole genome bisulfite sequencing (WGBS) analysis revealed that DNA hypermethylation (gain-of-5mC) occurs within a subgroup of enhancers including estrogen responsive element (EREs) in MCF7 cells upon TET2 depletion. ChIP-seq and RNA-seq analysis showed that TET2 depletion impairs E2-induced ERα binding to these ‘gain-of-5mC’ EREs and gene transcription. Conclusions: Our data suggest that TET2-mediated enhancer DNA demethylation fine-tunes ERα-dependent and independent gene transcription in ERα-positive breast cancer cells.

Project description:The two estrogen receptors, ERα and ERβ function as ligand-inducible transcription factors. Most in vitro studies have reported that ERα drives breast cancer growth whereas ERβ, if expressed, suppresses growth. To dissect function and gene expression profile regulated by ERα or ERβ, respectively, we generated a novel cell model expressing only ERβ, by applying CRISPR-cas9 to delete ERα in MCF7 cells with stable Tet-Off-inducible ERβ expression. This model with ERβ expression only, exhibited regulation of known estrogen responsive genes in a ligand-dependent manner. By cell proliferation assay, we found that either ER was required for proliferation, and that while E2 increased proliferation of ERα (only) MCF7, it reduced proliferation of ERβ (only) MCF7 cells. RNA-Seq analysis revealed 768 and 984 specific target genes regulated by ERα and ERβ in response to E2, respectively. Furthermore, functional enrichment analysis showed that the two ER isoforms regulated cell proliferation in opposite direction. In conclusion, within the same cellular context the two ERs regulated cell proliferation in opposite manner by regulating distinct sets of target genes in response to E2. The novel developed cell model provides a novel and valuable resource to further complement the mechanistic understanding of the two different ER isoforms.

Project description:Endocrine therapies targeting the proliferative effect of 17β-estradiol (17βE2) through estrogen receptor α (ERα) are the most effective systemic treatment of ERα-positive breast cancer. However, most breast tumors initially responsive to these therapies develop resistance through a molecular mechanism that is not yet fully understood. The long-term estrogen-deprived (LTED) MCF7 cell model has been proposed to recapitulate acquired resistance to aromatase inhibitors (AIs) in postmenopausal women. To elucidate this resistance, genomic, transcriptomic and molecular data were integrated into the time course of MCF7-LTED adaptation. Dynamic and widespread genomic changes were observed, including amplification of the ESR1 locus consequently linked to an increase in ERα. Dynamic transcriptomic profiles were also observed that correlated significantly with genomic changes and were influenced by transcription factors known to be involved in acquired resistance or cell proliferation (e.g. IRF1 and E2F1, respectively) but, notably, not by canonical ERα transcriptional function. Consistently, at the molecular level, activation of growth factor signaling pathways by EGFR/ERBB/AKT and a switch from phospho-Ser118 (pS118)- to pS167-ERα were observed during MCF7-LTED adaptation. Evaluation of relevant clinical settings identified significant associations between MCF7-LTED and breast tumor transcriptome profiles that characterize ERα-negative status, early response to letrozole and recurrence after tamoxifen treatment. This study proposes a mechanism for acquired resistance to estrogen deprivation that is coordinated across biological levels and independent of canonical ERα function. LTED (long term estrogen deprived) cell line was generated from MCF-7 cells by long-term culture under estrogen deprivated conditions. And RNA samples were obtained after 3, 15, 30, 90, 120, 150 and 180 days.

Project description:Analysis of estrogen receptor (ER)-positive MCF7 cell total RNA expression and polysome-assiciated RNA expression following treatment with estradiol (E2) and vehicle (etoh). We used expression microarrays to measure polysome association and total RNA abundance in E2 treated MCF7. These data, along with previously published data, show that genes that are upregulated by estrogen treatment are biased towards association with polysomes.

Project description:The goal is to identify estrogen-dependent gene expression patterns using RNAseq for 3 different ERα forms in human osteoblasts. We analyzed 3 different forms of estrogen receptor alpha (ERα), 1) Wild-type, 2) NERKI (DNA-binding mutant) and 3) NOER (Nuclear Only ERα, not membrane). Each was infected into hFOB (human osteoblast) cells and treated with either vehicle or E2 (10nM) (n=3 for each group/treatment). RNAseq was then performed.

Project description:The Estrogen Receptor alpha (ERα) controls key cellular functions in hormone responsive breast cancer by assembling in large functional multiprotein complexes. ERα ligands are classified as agonists and antagonist, according to the response they elicit, thus the molecular characterization of the of ERα nuclear iteractome composition following estrogen and antiestrogen stimulation whose is needed to understand their effects on estrogen target tissues, in particular breast cancer. To this aim interaction proteomics coupled to mass spectrometry (MS) was applied to map the ERα nuclear interacting partners in MCF7 breast cancer cell nuclei following estrogen and antiestrogen stimuli.

Project description:The estrogen receptor-alpha (ERα) determines breast cancer cell phenotype and is a prognostic indicator. A better understanding of the mechanisms controlling ERα function may uncover improved strategies for the treatment of breast cancer. Proteasome inhibition was previously reported to regulate estrogen-induced transcription but the mechanisms by which it influences ERα function remain controversial. In this study we investigated the transcriptome-wide effects of the proteasome inhibitor Velcade on estrogen-regulated transcription in MCF7 human breast cancer cells and demonstrate a specific global decrease in estrogen-induced transcription. This set contains 12 microarray samples. 3 controls, 3 estrogen stimulated, 3 Bortezomib stimulated, 3 Bortezomib + estrogen stimulated

Project description:Estrogen receptor-alpha (ER) drives tumour development and metastasis in ER positive (ER+) breast cancer. GATA3 is a transcription factor that has been closely linked to ER function, but the role of GATA3 in ER-transcriptional activity is not clear. We sought to identify the contribution of GATA3 to the ER complex, by conducting quantitative multiplexed rapid immunoprecipitation mass spectrometry of endogenous proteins (qPLEX-RIME), to assess changes to the ER complex in response to GATA3 depletion. Unexpectedly, very few proteins were dissociated from the ER complex in the absence of GATA3, with the only major change being loss of TET2 in the ER complex. In breast cancer cells and Patient-Derived Xenograft (PDX) tissue, TET2 binding events were shown to constitute a near-total subset of ER binding events, and loss of TET2 was functionally associated with reduced activation of proliferative pathways. To investigate the TET2-ER relationship, the role of TET2 in regulating DNA modifications in ER+ breast cancer cells was examined. TET2 knockdown did not appear to result in changes to global DNA methylation, however, oxidation of methylated DNA to 5-hydroxymethylcytosine (5hmC) was significantly reduced after TET2 depletion and these events occurred at ER enhancers. These findings implicate TET2 in the production and maintenance of 5hmC at ER sites, providing a potential mechanism for TET2-mediated regulation of ER target genes.

Project description:The epithelial to mesenchymal transition (EMT) is implicated in the metastatic spread of breast cancer cells. EMT transcription factors (TF) regulate different stages of EMT states. In breast cancers, estrogen receptor α (ERα) maintains the epithelial characteristics of breast tumors and is indispensable for efficient endocrine therapy. In this study we investigate whether and how ZEB1, an EMT-TF affects ERα signaling at early stages of EMT and metastasis. We did ERα ChIP-seq in wild type MCF7-V cells for comparative studies. We also did ERα ChIP-seq in cells stably expressing a doxycycline-inducible construct to express ZEB1. This was to determine the impact of ZEB1 on the ERα cistrome in MCF7-V breast cancer cells induced with DMSO, 17-beta estradiol (E2), and forskolin + 3-isobutyl-1-methylxanthine (IBMX) (FI).

Project description:Estrogen-receptor alpha (ERα)-dependent enhancers in the human breast cancer cell line MCF7 are a well-studied model system that allows high temporal resolution tracking of the different molecular events after hormone treatment and in which the enhancer and their target genes, as well as many of the molecular mechanisms operating in enhancer activation, are well defined. We use Capture-C to look at enhancer-promoter contact frequencies of GREB1 and NRIP1 genes across a time course (5, 30 and 60 min) after E2 addition to MCF7 cells which had been extensively starved of hormone. Additionally, ee look at the E2-dependent enhancer-promoter contact frequencies at these two loci in different contexts: in cells where the enhancer regions have been deleted; in cells treated with tamoxifen as well as with estradiol to assess the effect of different ERα ligands; and in cells pre-treated with the transcription inhibitors Flavopiridol and Triptolide to assess the role of active transcription.