Project description:Background: Epigenetic dysregulations are linked to various diseases, including cancer. Among them, breast cancer is the second leading cause of cancer-related deaths in women with 50% of mortalities attributable to estrogen receptor-positive (ER+) tumors. Endocrine therapies targeting the Estrogen Receptor (ER) such as Tamoxifen, Fulvestrant and Aromatase inhibitors, are widely used in the clinic. Among these therapeutic agents, Fulvestrant has been shown to fully antagonize ER activity, primarily through the rapid degradation and elimination of ER from target tissues. However, recent findings indicate that ER, when engaged with Fulvestrant, retains the ability to translocate to the nucleus and bind DNA whereas appearing transcriptionally inert. Results: In this study we aimed to further investigate the effects of Fulvestrant and Estradiol, an ER natural ligand, on ER cistrome, chromatin accessibility, and H3K27ac genome-wide patterns in an ER+ breast cancer cell line. Using the innovative CUT&Tag technology, we first confirmed that both Fulvestrant and Estradiol promote ER binding to DNA. Our findings revealed that Estradiol not only enhances chromatin accessibility but also increases H3K27ac levels at ER binding sites. In contrast, while Fulvestrant does not significantly alter chromatin accessibility, it can induce increases in H3K27ac levels at a subset of ER binding sites. Our observations suggest that Fulvestrant may modulate breast cancer transcriptional landscape by impacting H3K27ac dynamics, even in the absence of changes in chromatin accessibility. Conclusions: This study provides new insights on the mechanistic impact of Fulvestrant on Estrogen Receptor activity and their potential implications on target gene expression, particularly highlighting a novel putative role of H3K27ac dynamics in these processes.

Project description:Estrogens have been shown to elicit anti-cancer effects against estrogen receptor alpha (ER)-positive breast cancer. We sought to determine the underlying mechanism of therapeutic response. Response to 17b-estradiol was assessed in ER+ breast cancer models with resistance to estrogen deprivation: WHIM16 patient-derived xenografts, C7-2-HI and C4-HI murine mammary adenocarcinomas, and long-term estrogen-deprived MCF-7 cells. As another means to reactivate ER, the anti-estrogen fulvestrant was withdrawn from fulvestrant-resistant MCF-7 cells. Transcriptional, growth, apoptosis, and molecular alterations in response to ER reactivation were measured. 17b-estradiol treatment and fulvestrant withdrawal induced transcriptional activation of ER, and cells adapted to estrogen deprivation or fulvestrant were hypersensitive to 17b-estradiol. ER transcriptional response was followed by an unfolded protein response and apoptosis. Such apoptosis was dependent upon the unfolded protein response, p53, and JNK signaling. Anti-cancer effects were most evident in models exhibiting genomic amplification of the gene encoding ER (ESR1), suggesting that engagement of ER at high levels is cytotoxic. These data indicate that long-term adaptation to estrogen deprivation or ER inhibition alters sensitivity to ER reactivation. In such adapted cells, 17b-estradiol treatment and anti-estrogen withdrawal hyperactivate ER, which drives an unfolded protein response activation and subsequent growth inhibition and apoptosis. 17b-estradiol treatment should be considered as an alternative therapy for anti-estrogen-resistant disease, particularly in patients with tumors harboring ESR1 amplification or overexpression. Furthermore, therapeutic strategies that enhance an unfolded protein response may enhance the therapeutic effects of ER reactivation.

Project description:Estrogens have been shown to elicit anti-cancer effects against estrogen receptor alpha (ER)-positive breast cancer. We sought to determine the underlying mechanism of therapeutic response. Response to 17b-estradiol was assessed in ER+ breast cancer models with resistance to estrogen deprivation: WHIM16 patient-derived xenografts, C7-2-HI and C4-HI murine mammary adenocarcinomas, and long-term estrogen-deprived MCF-7 cells. As another means to reactivate ER, the anti-estrogen fulvestrant was withdrawn from fulvestrant-resistant MCF-7 cells. Transcriptional, growth, apoptosis, and molecular alterations in response to ER reactivation were measured. 17b-estradiol treatment and fulvestrant withdrawal induced transcriptional activation of ER, and cells adapted to estrogen deprivation or fulvestrant were hypersensitive to 17b-estradiol. ER transcriptional response was followed by an unfolded protein response and apoptosis. Such apoptosis was dependent upon the unfolded protein response, p53, and JNK signaling. Anti-cancer effects were most evident in models exhibiting genomic amplification of the gene encoding ER (ESR1), suggesting that engagement of ER at high levels is cytotoxic. These data indicate that long-term adaptation to estrogen deprivation or ER inhibition alters sensitivity to ER reactivation. In such adapted cells, 17b-estradiol treatment and anti-estrogen withdrawal hyperactivate ER, which drives an unfolded protein response activation and subsequent growth inhibition and apoptosis. 17b-estradiol treatment should be considered as an alternative therapy for anti-estrogen-resistant disease, particularly in patients with tumors harboring ESR1 amplification or overexpression. Furthermore, therapeutic strategies that enhance an unfolded protein response may enhance the therapeutic effects of ER reactivation.

Project description:Oral selective estrogen receptor degraders (SERDs) could become the backbone endocrine therapy (ET) for estrogen receptor-positive (ER+) breast cancer, as they achieve greater inhibition of ER-driven cancers than current ETs and overcome key resistance mechanisms. This dataset was aimed at exploring the preclinical effects of the next-generation oral SERD camizestrant (AZD9833) on MCF7 and CAMA1 cell lines. Cells were treated with 1 nM estradiol and 100 nM fulvestrant, AZD9496, or camizestrant for 24 hours, with three replicates per condition and non-estradiol-treated controls.

Project description:Background: Epigenetic dysregulations are linked to various diseases, including cancer. Among them, breast cancer is the second leading cause of cancer-related deaths in women with 50% of mortalities attributable to estrogen receptor-positive (ER+) tumors. Endocrine therapies targeting the ER such as Tamoxifen, Fulvestrant (FULV) and Aromatase inhibitors, are widely used in the clinic. Among these therapeutic agents, FULV has been shown to fully antagonize ER activity, primarily through the rapid degradation and elimination of ER from target tissues. However, recent findings indicate that ER, when engaged with FULV, retains the ability to translocate to the nucleus and bind DNA whereas appearing transcriptionally inert. Results: In this study, we aimed to further investigate the effects of FULV and Estradiol (E2), the natural ER ligand, on ER cistrome, chromatin accessibility, gene transcription, and H3K27ac genome-wide patterns in ER+ breast cancer cell lines. Using the innovative CUT&Tag technology, we first confirmed that both FULV and E2 promote ER binding to DNA. Our findings revealed that E2 not only enhances chromatin accessibility and gene expression but also increases H3K27ac levels at ER binding sites. In contrast, FULV does not significantly alter chromatin accessibility or transcription but is not completely inert, as it induces increases in H3K27ac at a subset of ER binding sites. These observations indicate a decoupling between histone acetylation and transcriptional output under FULV treatment. Conclusions: This study provides new insights into the mechanistic impact of FULV on ER activity, highlighting its ability to modulate H3K27ac dynamics even in the absence of transcriptional changes. These findings underscore the complexity of ER signaling and suggest that FULV’s therapeutic effects may extend beyond simple antagonism of ER activity.

Project description:Goal: study the impact of estrogen receptor ligands on chromatin accessibility in MCF-7 cells Methods: Assay for Transposase-Accessible Chromatin using Sequencing (ATAC-Seq) Results: Ligand 4-OH tamoxifen, a selective ER modulator (SERM), significantly alters chromatin accessibility and partially mimics the effect of natural ligand E2 on chromatin accessibility in MCF-7 breast cells. Selective ER degraders (SERD) fulvestrant and GDC-0927 on the other hand have very little impact on chromatin accessibility.

Project description:The precise mechanisms by which hormone receptors bind to DNA in the context of chromatin remain unclear. Here we report that the genomic distributions of estrogen receptor (ER) and H3R26 deimination (H3R26Cit) in breast cancer cells are strikingly coincident, linearly correlated, and observed as early as 2 minutes following estradiol treatment. Paired-end MNase ChIP-seq indicates that the charge-neutral H3R26Cit modification facilitates ER binding to DNA by altering the fine structure of the nucleosome. Clinically, we find that PAD2 and H3R26Cit levels correlate with ER expression in breast tumors and that high PAD2 expression is associated with increased survival in ER+ breast cancer patients. Our study suggests that PAD2-mediated histone deimination is fundamental to ER signaling in breast cancer. We performed replicate H3R26Cit ChIP-seq experiments prior to estrogen treatment and 2min, 5min, 10min, 40min, and 160min after E2 treatment. Additionally, we performed H3R26Cit and H3K27ac ChIP on MNase digested chromatin.

Project description:More than two thirds of breast cancers express the estrogen receptor (ER) and depend on estrogen for growth and survival. Therapies targeting ER function including aromatase inhibitors that block the production of estrogens and ER antagonists that alter ER transcriptional activity play a central role in the treatment of ER+ breast cancers of all stages. In contrast to ER- breast cancers, which frequently harbor mutations in the p53 tumor suppressor, ER+ breast cancers are predominantly wild type for p53. Despite harboring wild type p53, ER+ breast cancer cells are resistant to chemotherapy-induced apoptosis in the presence of estrogen. Using genome-wide approaches we have addressed the mechanism by which ER antagonizes the pro-apoptotic function of p53. Interestingly both ER agonists such as estradiol and selective ER modulators (SERM) such as tamoxifen promote p53 antagonism. In contrast the full ER antagonist fulvestrant blocks the ability of ER to inhibit p53-mediated cell death. This suggests an improved strategy for the treatment of ER+ breast cancer utilizing antagonists that completely block ER action together with drugs that activate p53-mediated cell death.

Project description:More than two thirds of breast cancers express the estrogen receptor (ER) and depend on estrogen for growth and survival. Therapies targeting ER function including aromatase inhibitors that block the production of estrogens and ER antagonists that alter ER transcriptional activity play a central role in the treatment of ER+ breast cancers of all stages. In contrast to ER- breast cancers, which frequently harbor mutations in the p53 tumor suppressor, ER+ breast cancers are predominantly wild type for p53. Despite harboring wild type p53, ER+ breast cancer cells are resistant to chemotherapy-induced apoptosis in the presence of estrogen. Using genome-wide approaches we have addressed the mechanism by which ER antagonizes the pro-apoptotic function of p53. Interestingly both ER agonists such as estradiol and selective ER modulators (SERM) such as tamoxifen promote p53 antagonism. In contrast the full ER antagonist fulvestrant blocks the ability of ER to inhibit p53-mediated cell death. This suggests an improved strategy for the treatment of ER+ breast cancer utilizing antagonists that completely block ER action together with drugs that activate p53-mediated cell death. MCF7 cells were hormone-depleted for 3 days and then treated with 10 uM doxorubicin for 12 hours

Project description:Hormone therapy targeting estrogen receptor (ER) is the principal treatment for ER-positive breast cancers but many cancers develop resistance to anti-estrogens. Cyclin-dependent kinase 8 (CDK8) is a transcriptional regulator of several oncogenic pathways. Expression levels of CDK8 and ERα are inversely correlated in breast cancers suggesting a functional association between CDK8 and ER. CDK8 inhibition by selective small-molecule inhibitors, by shRNA knockdown or by CRISPR-Cas9 knockout suppressed estrogen-induced transcription, with no significant effects on ERα protein expression or phosphorylation. CDK8 inhibition also abrogated the mitogenic effect of estrogen on ER-positive breast cancer cells and potentiated growth inhibition by the ER antagonist fulvestrant. In vivo, administration of a CDK8 inhibitor suppressed ER-positive breast cancer xenograft growth and augmented the effects of fulvestrant with no apparent toxicity. CDK8 inhibitors also suppressed the development of estrogen independence in ER-positive breast cancer cells. These results identify CDK8 as a novel drug target for breast cancer therapy.