Project description:The Human Genome Project promised to promote large-scale functional analyses necessary for the diagnosis and treatment of complex diseases. Here we demonstrate an integrated approach to the study of a transcriptional regulatory cascade involved in the progression of breast cancer and we identify a protein associated with disease progression. Using chromatin immunoprecipitation and genome tiling arrays, whole genome mapping of transcription factor binding sites was combined with gene expression profiling to identify genes involved in the proliferative response to estrogen (E2). Using RNA interference, selected ERa and c-Myc gene targets were knocked down to identify mediators of E2-stimulated cell proliferation. Tissue microarray screening revealed that high expression of an epigenetic factor, the estrogen-inducible histone variant H2A.Z, is significantly associated with lymph node metastasis and decreased breast cancer survival. Detection of H2A.Z levels independently increased the prognostic power of biomarkers currently in clinical use. This integrated approach has accelerated the identification of a molecule linked to breast cancer progression, has implications for diagnostic and therapeutic interventions, and can be applied to a wide range of cancers. MCF7 cells treated with E2 (10nM) or Ctrl (vehicle) for 4, 12 or 24 hours. Each hormone treatment time was performed at least three times and hybridizations included dye swaps.

Project description:The initiation of breast cancer is associated with increased expression of tumor-promoting estrogen receptor M-NM-1 (ERM-NM-1) protein and decreased expression of tumor-suppressive ERM-NM-2 protein. However, the mechanism underlying this process is unknown. Here we show that Pescadillo/PES1, an estrogen-inducible protein that is over-expressed in breast cancer, can regulate the balance between ERM-NM-1 and ERM-NM-2. PES1 enhances transcriptional activity of ERM-NM-1 and reduces that of ERM-NM-2, and modulates many estrogen-responsive genes. Consistent with this regulation of ERM-NM-1 and ERM-NM-2 transcriptional activity, PES1 increases the stability of the ERM-NM-1 protein and decreases that of ERM-NM-2 through the ubiquitin-proteasome pathway, mediated by the carboxyl terminus of Hsc70-interacting protein (CHIP). Moreover, PES1 can transform normal human mammary epithelial cells and is required for estrogen-induced breast tumor growth in nude mice. Further analysis of clinical samples showed that expression of PES1 correlates positively with ERM-NM-1 expression and negatively with ERM-NM-2 expression, and predicts good clinical outcome in breast cancer. Our data demonstrate that PES1 contributes to breast tumor growth through regulating the balance between ERM-NM-1 and ERM-NM-2 and may be a better target for the development of drugs that selectively regulate ERM-NM-1 and ERM-NM-2 activities. Three samples: Control siRNA -E2 vs. Control siRNA +E2, Control siRNA -E2 vs. PES1 siRNA -E2,Control siRNA -E2 vs. PES1 siRNA +E2

Project description:We mapped the location of RNA-DNA hybrids in hormone-starved MCF7 breast cancer cells treated with the hormone estradiol (E2.) E2 is a potent transcriptional activator, and causes proliferation in hormone starved cells. We find a significant induction of hybrids at genes known to be regulated by the estrogen receptor.

Project description:MCF-7 is an estrogen receptor-positive breast cancer cell line. This experiment is designed to study (1) the effect of estradiol (E2) exposure and (2) lysine methyltransferase 2B (KMT2B) knockdown in MCF-7 cells. Cells were grown for 72 hours prior to treatment with vehicle or 10 nM E2 for 4 and 24 hours. Additionally, to assess the effect of KMT2B knockdown, MCF-7 cells were transfected with KMT2B targeting siRNA or scrambled control siRNA in the absence or presence of E2. RNA were isolated using Trizol and hybridized to Affymetrix GeneChip Human Genome U133 Plus 2.0 array.

Project description:The initiation of breast cancer is associated with increased expression of tumor-promoting estrogen receptor α (ERα) protein and decreased expression of tumor-suppressive ERβ protein. However, the mechanism underlying this process is unknown. Here we show that Pescadillo/PES1, an estrogen-inducible protein that is over-expressed in breast cancer, can regulate the balance between ERα and ERβ. PES1 enhances transcriptional activity of ERα and reduces that of ERβ, and modulates many estrogen-responsive genes. Consistent with this regulation of ERα and ERβ transcriptional activity, PES1 increases the stability of the ERα protein and decreases that of ERβ through the ubiquitin-proteasome pathway, mediated by the carboxyl terminus of Hsc70-interacting protein (CHIP). Moreover, PES1 can transform normal human mammary epithelial cells and is required for estrogen-induced breast tumor growth in nude mice. Further analysis of clinical samples showed that expression of PES1 correlates positively with ERα expression and negatively with ERβ expression, and predicts good clinical outcome in breast cancer. Our data demonstrate that PES1 contributes to breast tumor growth through regulating the balance between ERα and ERβ and may be a better target for the development of drugs that selectively regulate ERα and ERβ activities.

Project description:In this study, we examined the effect of inorganic arsenic (iAs) on the estrogen response (E2) in MCF-7 cells that are estrogen receptor positive/progesterone receptor positive (ER+/PR+). Understanding the changes in the transcriptomic response after iAs exposure and the retention of such responses during recovery from iAs exposure can identify driver mechanisms of breast cancer progression and improve therapies for patients with ER+ cancers exposed to iAs.

Project description:To obtain an integrated view of gene regulation in response to environmental and endogenous estrogens on a genome-wide scale, we performed ChIP-seq, to identify estrogen receptor 1 (ER) binding sites, and RNA-seq in endometrial cancer cells exposed to bisphenol A (BPA; found in plastics), genistein (GEN; found in soybean), or 17β-estradiol (E2; an endogenous estrogen).  GEN and BPA treatment induces thousands of ER binding sites and >50 gene expression changes, representing a subset of E2‑induced gene regulation changes. Genes affected by E2 were highly enriched for ribosome-associated proteins; however, GEN and BPA failed to regulate most ribosome-associated proteins and instead enriched for transporters of carboxylic acids. Treatment-dependent changes in gene expression were associated with treatment-dependent ER binding sites, with the exception that many genes up-regulated by E2 harbored a BPA-induced ER binding site, but failed to show any expression change after BPA treatment. GEN and BPA exhibited a similar relationship to E2 in the breast cancer line T-47D, where cell type specificity played a much larger role than treatment specificity. Overall, both environmental estrogens clearly regulate gene expression through ER on a genome-wide scale, although with lower potency resulting in less ER binding sites and less gene expression changes compared to the endogenous estrogen, E2. RNA-seq of human cancer cell lines treated with estradiol, bisphenol A, genistein or DMSO (control)

Project description:In previous study, we found circFAT1(e2) was highly expressed in breast cancer tissues and cell lines. And this factor is also a crucial role in breast cancer genesis and development. So in this study, we knocked down circFAT1(e2) in MCF-7 cells. The viability and metastasis was significantly inhibited with circFAT1(e2) depletion. In order to explore the potential down-stream gene of circFAT1(e2) in breast cancer cells. We extracted the total RNA from circFAT1(e2) knockdown MCF-7 cells and negative control group by using TriZol reagent. Then, toal RNA was subjected to transcriptome sequencing to determine the potential down-stream targets of circFAT1(e2). We expect to reveal the underlied mechanism of the regulatory effect on breast cancer of circFAT1(e2).

Project description:In order to help determine the genes involved in resistance of breast cancer to endocrine therapy, we compared global gene expression profiles of tamoxifen-resistant MCF-7 WT xenograft tumors with E2-supplemented tumors. Experiment Overall Design: MCF7 xenografts were established in ovariectomized five to six week-old nu/nu athymic nude mice supplemented with 0.25 mg 21 day release estrogen pellets by inoculating subcutaneously (s.c.) 5E-6 cells. When tumors reached the size of 150-200 mm3 (3-5 weeks), the animals were randomly allocated to continued estrogen (E2) and estrogen withdrawal plus tamoxifen citrate. Tumors were harvested for molecular studies when they became resistant to treatment and reached the size of 1000 mm3 (n=7).

Project description:Altered expression of microRNAs (miRNAs), an abundant class of small non-protein-coding RNAs that mostly function as negative regulators of protein-coding gene expression, is common in cancer. Here we analyze the regulation of miRNA expression in response to estrogen, a steroid hormone that is involved in the development and progression of breast carcinomas and that is acting via the estrogen receptors (ER) transcription factors. We set out to thoroughly describe miRNA expression, by using miRNA microarrays and real time RTPCR experiments, in various breast tumor cell lines in which estrogen signaling has been induced by 17β-estradiol (E2). We show that the expression of a broad set of miRNAs decreases following E2 treatment in an ER-dependent manner. We further show that enforced expression of several of the repressed miRNAs reduces E2-dependent cell growth, thus linking expression of specific miRNAs with estrogen-dependent cellular response. In addition, a transcriptome analysis revealed that the E2-repressed miR-26a and miR-181a regulate many genes associated with cell growth and proliferation, including the progesterone receptor gene, a key actor in estrogen signaling. Strikingly, miRNA expression is also regulated in breast cancers of women who had received antiestrogen neoadjuvant therapy thereby showing an estrogen-dependent in vivo regulation of miRNA expression. Overall, our data indicates that the extensive alterations in miRNA regulation upon estrogen signalling pathway plays a key role in estrogen-dependent functions and highlights the utility of considering miRNA expression in the understanding of antiestrogen resistance of breast cancer. 9 samples analyzed. Triplicates were done. MCF-7+miR26a+E2 (n=1 to 3) ; MCF7+miRctrl+E2 (n=1 to 3) ; MCF7+miRctrl+vehicle (n=1 to 3). We generated pairwise comparisons using EASANA from GenoSplice technology: MCF-7+miR26a+E2 versus MCF7+miRctrl+E2 and MCF-7+miRctrl+E2 versus MCF7+miRctrl+vehicle. Fold change ≥1.5 were selected.