Project description:Inflammatory breast cancer (IBC) is a highly metastatic breast carcinoma with high frequency of estrogen receptor a (ERα) negativity and limited treatment options. We previously explored the second ER subtype, (ERβ) and reported correlation of its tumor expression with reduced metastasis in patients and in preclinical models of the disease. We initially associated the anti-metastatic function of the receptor with the inhibition of actin-based cell migration and the associated Rho GTPase signaling in IBC cells. We have now followed an integrated genomics approach to fully delineate the signaling underlying the anti-metastatic effects of ERβ. Through mapping binding sites in IBC cells that express endogenous and transfected ERβ in the presence of an agonist and interrogating this information with altered expression of protein coding mRNAs and miRNAs we have defined the interaction of a biologically active receptor with the cancer genome that controls metastatic signals. We reveal key regulatory chromatin binding sites and motifs and identify direct target genes and miRNAs and the associated biological functions. Our new findings implicate the regulation of metabolic pathways and signaling in development and tumor microenvironment in anti-metastatic activity of ERβ. Through a rigorous analysis of target genes in clinical datasets we also associate downstream factors with patient outcomes reporting new molecules with targeting potential and strengthening the relevance of ERβ signaling for the metastatic process in breast cancer. Our findings thus offer an opportunity to validate the tumor repressive role of ERβ through a better understanding of its mechanism of action.

Project description:Inflammatory breast cancer (IBC) is a highly metastatic breast carcinoma with high frequency of estrogen receptor a (ERα) negativity and limited treatment options. We previously explored the second ER subtype, (ERβ) and reported correlation of its tumor expression with reduced metastasis in patients and in preclinical models of the disease. We initially associated the anti-metastatic function of the receptor with the inhibition of actin-based cell migration and the associated Rho GTPase signaling in IBC cells. We have now followed an integrated genomics approach to fully delineate the signaling underlying the anti-metastatic effects of ERβ. Through mapping binding sites in IBC cells that express endogenous and transfected ERβ in the presence of an agonist and interrogating this information with altered expression of protein coding mRNAs and miRNAs we have defined the interaction of a biologically active receptor with the cancer genome that controls metastatic signals. We reveal key regulatory chromatin binding sites and motifs and identify direct target genes and miRNAs and the associated biological functions. Our new findings implicate the regulation of metabolic pathways and signaling in development and tumor microenvironment in anti-metastatic activity of ERβ. Through a rigorous analysis of target genes in clinical datasets we also associate downstream factors with patient outcomes reporting new molecules with targeting potential and strengthening the relevance of ERβ signaling for the metastatic process in breast cancer. Our findings thus offer an opportunity to validate the tumor repressive role of ERβ through a better understanding of its mechanism of action.

Project description:ERβ expression is associated with less metastasis in patients with IBC tumors. We investigated this association in preclinical models of IBC by knocking out ERβ in cells. Ablation of ERβ promotes migration and invasion of IBC cells and increases the metastatic potential of IBC tumors in vivo. We used microarrays to detail the global programme of gene expression underlying the increased migration of ERβ knockout cells and identified distinct classes of up-regulated genes during this process.

Project description:Inflammatory breast cancer (IBC) is the most aggressive type of advanced breast cancer and is associated with a poor prognosis. We have developed a new model of IBC derivated from the pleural effusion of a 49-year-old woman with metastatic secondary IBC. FC-IBC02 tumor cells were isolated from the pleural effusion and cultured under non-adherent conditions, resulting in the formation of spheroids or mammospheres. FC-IBC02 are triple negative (estrogen receptor negative, progesterone receptor negative and ErbB2 negative) and strongly positive for E-cadherin, beta-catenin and vimentin. FC-IBC02 cells developed breast tumors when they were injected into the mammary fat pad of SCID mice and characteristic tumor emboli were detected. Breast tumor xenografts were poorly differentiated triple negative carcinomas and all injected mice developed metastasis in the lungs and lymph nodes. These IBC tumor cells showed genomic alterations in all chromosomes, with the gains/amplifications more common than the deletions/losses. Duplicated regions were on 1q, 2p, 3q, 8q and 18p and chromosomes 7 and 9. The 8q chromosome arm where the MYC oncogene resides was amplified up to seven fold. Chromothripsis (local chromosome shattering) was observed on chromosome 11q and losses were found on 8p, 11q, 16q and 17p (location of TP53). FC-IBC-02 cells expressed the stem cell marker CD44, EpCAM and strongly expressed EGFR and ALK. In summary, this novel preclinical model demonstrated that IBC is a disease enriched for highly tumorigenic cells which harbor a stem cell phenotype. This IBC model is ideal for the study of the metastatic process and to evaluate targeting therapeutic modalities. Total RNA were isolated from IBC-02, IBC-02 in mammosphere growth, IBC3, SUM149, SUM190, MDA-MB231, and MDA-MB468 cell lines. Affymetrix Human U133 Plus 2.0 arrays were used for whole-genome gene expression assays. Duplicate samples were analyzed for each cell line.

Project description:Inflammation is involved in both initiation and promotion of colorectal cancer (CRC), and patients with inflammatory bowel disease (IBC) have increased risk of developing CRC. Tumor necrosis factor alpha (TNFα) is a cytokine secreted by e.g. macrophages, and this signaling is deregulated in IBD and CRC. TNFα activates the pro-survival transcription factor complex NFκB, which is composed of several subunits including p65 (RELA). We recently characterized the genome-wide transcriptional impact by TNFα in two CRC cell lines, but how p65 binds the chromatin, its cistrome, in colorectal cancer cells has not been explored. We here used p65 chromatin immunoprecipitation followed by sequencing (ChIP-Seq) in HT29 and SW480 cells, and correlated with the transcriptomic impact of TNFα. Further, estrogen receptor beta (ERβ) has anti-inflammatory and anti-tumorigenic effects in colon cells and interacts with NFκB main targets. We have shown that ERβ impacts TNFα signaling in CRC cells and ERβ impacts the P65 cistrome.

Project description:Inflammatory breast cancer (IBC) is a unique clinical entity characterized by rapid onset of erythema and swelling of the breast often without an obvious breast mass. Many studies have examined and compared gene expression between IBC and non-IBC (nIBC), repeatedly finding clusters associated with receptor subtype, but no consistent gene signature associated with IBC has been validated. Here we examined microdissected IBC tumor cells compared to microdissected nIBC tumor cells matched based on estrogen and HER-2/neu receptor status. Genomic profiling of 20 inflammatory breast cancer (IBC), 20 non-IBC and 5 normal was studied.

Project description:Inflammatory breast cancer (IBC) is a unique clinical entity characterized by rapid onset of erythema and swelling of the breast often without an obvious breast mass. Many studies have examined and compared gene expression between IBC and non-IBC (nIBC), repeatedly finding clusters associated with receptor subtype, but no consistent gene signature associated with IBC has been validated. Here we examined microdissected IBC tumor cells compared to microdissected nIBC tumor cells matched based on estrogen and HER-2/neu receptor status. Gene expression profiling of 20 inflammatory breast cancer (IBC), 20 non-IBC and 5 normal was studied.

Project description:Inflammatory breast cancer (IBC) is a unique clinical entity characterized by rapid onset of erythema and swelling of the breast often without an obvious breast mass. Many studies have examined and compared gene expression between IBC and non-IBC (nIBC), repeatedly finding clusters associated with receptor subtype, but no consistent gene signature associated with IBC has been validated. Here we examined microdissected IBC tumor cells compared to microdissected nIBC tumor cells matched based on estrogen and HER-2/neu receptor status.

Project description:Inflammatory breast cancer (IBC) is a unique clinical entity characterized by rapid onset of erythema and swelling of the breast often without an obvious breast mass. Many studies have examined and compared gene expression between IBC and non-IBC (nIBC), repeatedly finding clusters associated with receptor subtype, but no consistent gene signature associated with IBC has been validated. Here we examined microdissected IBC tumor cells compared to microdissected nIBC tumor cells matched based on estrogen and HER-2/neu receptor status.

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.