Project description:Breast cancer is a heterogeneous disease and several distinct subtypes exist based on differential gene expression patterns. Molecular apocrine tumours were recently identified as an additional subgroup, characterised as oestrogen receptor negative and androgen receptor positive (ER_ AR+), but with an expression profile resembling ER+ luminal breast cancer. One possible explanation for the apparent incongruity is that ER gene expression programmes could be recapitulated by AR. Using a cell line model of ER_ AR+ molecular apocrine tumours (termed MDA-MB-453 cells), we map global AR binding events and find a binding profile that is similar to ER binding in breast cancer cells. We find that AR binding is a near-perfect subset of FoxA1 binding regions, a level of concordance never previously seen with a nuclear receptor. AR functionality is dependent on FoxA1, since silencing of FoxA1 inhibits AR binding, expression of the majority of the molecular apocrine gene signature and growth cell growth. These findings show that AR binds and regulates ER cis-regulatory elements in molecular apocrine tumours, resulting in a transcriptional programme reminiscent of ER-mediated transcription in luminal breast cancers.

Project description:Breast cancer is a heterogeneous disease comprised of at least five major subtypes. Luminal subtype tumors confer a more favourable patient prognosis, which is in part, attributed to the Estrogen Receptor-alpha (ER) positivity and anti-hormone responsiveness of these tumors. Expression of the forkhead box transcription factor, FOXA1, also correlates with the luminal subtype and patient survival, but is present in a subset of ER-negative tumors. Similarly, FOXA1 is consistently expressed in luminal breast cancer cell lines even in the absence of ER. In contrast, basal breast cancer cell lines do not express FOXA1, and loss of FOXA1 in luminal cells increases migration and invasion, characteristics of the basal subtype. To delineate an ER-independent role for FOXA1 in maintaining the luminal phenotype, and hence a more favourable prognosis, we performed cDNA microarray analyses on luminal FOXA1-positive, ER-positive (MCF7, T47D) and FOXA1-positive, ER-negative (MDA-MB-453, SKBR3) cell lines in the presence or absence of transient FOXA1 silencing. This resulted in three FOXA1 transcriptomes: (1) a luminal-signature (consistent across cell lines), (2) an ER-positive signature (restricted to MCF7 and T47D) and (3) an ER-negative signature (restricted to MDA-MB-453 and SKBR3). Use of Gene Set Enrichment Analyses (GSEA) as a phenotyping tool revealed that FOXA1 silencing resulted in a transcriptome shift from luminal to basal gene expression signatures. FOXA1 binds to both luminal and basal genes within luminal breast cancer cells, suggesting that it not only transactivates luminal genes, but also represses basal-associated genes. From these results we conclude that FOXA1 controls plasticity between basal and luminal cells, playing a dominant role in repressing the basal phenotype, and thus tumor aggressiveness, in luminal breast cancer cells. Although it has been proposed that FOXA1-targeting agents may be useful for treating luminal tumors, these data suggest that this approach may promote transitions toward a more aggressive cancer. FOXA1 siRNA treated breast cell lines compared directly to nonspecific siRNA treated cell lines using Agilent 4X44 microarrays.

Project description:Aim of this study is to unveil the global transcriptomic expression levels upon Knockout of Snai1 in triple negative breast cancer cells Hs578T.

Project description:Breast cancer is a heterogeneous disease comprised of at least five major subtypes. Luminal subtype tumors confer a more favorable patient prognosis, which is in part, attributed to the Estrogen Receptor-α (ER) positivity and anti-hormone responsiveness of these tumors. Expression of the forkhead box transcription factor, FOXA1, also correlates with the luminal subtype and patient survival, but is present in a subset of ER-negative tumors. Similarly, FOXA1 is consistently expressed in luminal breast cancer cell lines even in the absence of ER. In contrast, basal breast cancer cell lines do not express FOXA1, and loss of FOXA1 in luminal cells increases migration and invasion, characteristics of the basal subtype. To delineate an ER-independent role for FOXA1 in maintaining the luminal phenotype, and hence a more favorable prognosis, we performed cDNA microarray analyses on luminal FOXA1-positive, ER-positive (MCF7, T47D) and FOXA1-positive, ER-negative (MDA-MB-453, SKBR3) cell lines in the presence or absence of transient FOXA1 silencing. This resulted in three FOXA1 transcriptomes: (1) a luminal-signature (consistent across cell lines), (2) an ER-positive signature (restricted to MCF7 and T47D) and (3) an ER-negative signature (restricted to MDA-MB-453 and SKBR3). Use of Gene Set Enrichment Analyses (GSEA) as a phenotyping tool revealed that FOXA1 silencing resulted in a transcriptome shift from luminal to basal gene expression signatures. FOXA1 binds to both luminal and basal genes within luminal breast cancer cells, suggesting that it not only transactivates luminal genes, but also represses basal-associated genes. From these results we conclude that FOXA1 controls plasticity between basal and luminal cells, playing a dominant role in repressing the basal phenotype, and thus tumor aggressiveness, in luminal breast cancer cells. Although it has been proposed that FOXA1-targeting agents may be useful for treating luminal tumors, these data suggest that this approach may promote transitions toward a more aggressive cancer.

Project description:GATA3 transcription factor is considered critical for luminal development and differentiation in normal and malignant mammary epithelial cells (MECs). The androgen receptor (AR) has also been associated with luminal gene expression profiles in breast cancer, independent of the estrogen receptor (ER), and has been shown to promote a basal to luminal phenotype transition in mouse MECs. To date, the potential interaction of GATA3 and AR in transcriptional regulation of lineage driver genes in breast cancer has never been investigated. Our unbiased proteomic analysis identified GATA3 as a novel AR interacting protein in a variety of breast cancer cell types regardless of ER expression. We showed that AR and GATA3 interact in the cytoplasm and nucleus of normal and malignant breast epithelia, an interaction increased by androgen treatment. Androgen stimulation of breast cancer cells also induced nuclear translocation of AR and GATA3 and resulted in enrichment of co-localized AR and GATA3 chromatin binding events. Using ER+ and/or ER- breast cancer cell lines and ER+ patient-derived xenograft (PDX) models of breast cancer, we identified a conserved subset of AR agonist-induced AR and GATA3 co-occupied cis-regulatory elements across all models. Knockdown experiments indicated that GATA3 acts as an AR co-regulator to upregulate transcription of known luminal-lineage genes (e.g. EHF, AQP3, and KDM4B) and downregulate basal-lineage genes (e.g. SMAD3 and ELK3). Also, we showed an induction in the chromatin accessibility at those subsets of common AR-GATA3 cis-regulatory elements, which drive the luminal lineage identity in breast cancer upon androgen stimulation. Collectively, AR-GATA3 interaction and function provide a mechanism underpinning epithelial breast cancer cells that are classified as having a luminal mature transcriptome independent of ER status, through regulating the expression of lineage-restricted markers.

Project description:GATA3 transcription factor is considered critical for luminal development and differentiation in normal and malignant mammary epithelial cells (MECs). The androgen receptor (AR) has also been associated with luminal gene expression profiles in breast cancer, independent of the estrogen receptor (ER), and has been shown to promote a basal to luminal phenotype transition in mouse MECs. To date, the potential interaction of GATA3 and AR in transcriptional regulation of lineage driver genes in breast cancer has never been investigated. Our unbiased proteomic analysis identified GATA3 as a novel AR interacting protein in a variety of breast cancer cell types regardless of ER expression. We showed that AR and GATA3 interact in the cytoplasm and nucleus of normal and malignant breast epithelia, an interaction increased by androgen treatment. Androgen stimulation of breast cancer cells also induced nuclear translocation of AR and GATA3 and resulted in enrichment of co-localized AR and GATA3 chromatin binding events. Using ER+ and/or ER- breast cancer cell lines and ER+ patient-derived xenograft (PDX) models of breast cancer, we identified a conserved subset of AR agonist-induced AR and GATA3 co-occupied cis-regulatory elements across all models. Knockdown experiments indicated that GATA3 acts as an AR co-regulator to upregulate transcription of known luminal-lineage genes (e.g. EHF, AQP3, and KDM4B) and downregulate basal-lineage genes (e.g. SMAD3 and ELK3). Also, we showed an induction in the chromatin accessibility at those subsets of common AR-GATA3 cis-regulatory elements, which drive the luminal lineage identity in breast cancer upon androgen stimulation. Collectively, AR-GATA3 interaction and function provide a mechanism underpinning epithelial breast cancer cells that are classified as having a luminal mature transcriptome independent of ER status, through regulating the expression of lineage-restricted markers.

Project description:GATA3 transcription factor is considered critical for luminal development and differentiation in normal and malignant mammary epithelial cells (MECs). The androgen receptor (AR) has also been associated with luminal gene expression profiles in breast cancer, independent of the estrogen receptor (ER), and has been shown to promote a basal to luminal phenotype transition in mouse MECs. To date, the potential interaction of GATA3 and AR in transcriptional regulation of lineage driver genes in breast cancer has never been investigated. Our unbiased proteomic analysis identified GATA3 as a novel AR interacting protein in a variety of breast cancer cell types regardless of ER expression. We showed that AR and GATA3 interact in the cytoplasm and nucleus of normal and malignant breast epithelia, an interaction increased by androgen treatment. Androgen stimulation of breast cancer cells also induced nuclear translocation of AR and GATA3 and resulted in enrichment of co-localized AR and GATA3 chromatin binding events. Using ER+ and/or ER- breast cancer cell lines and ER+ patient-derived xenograft (PDX) models of breast cancer, we identified a conserved subset of AR agonist-induced AR and GATA3 co-occupied cis-regulatory elements across all models. Knockdown experiments indicated that GATA3 acts as an AR co-regulator to upregulate transcription of known luminal-lineage genes (e.g. EHF, AQP3, and KDM4B) and downregulate basal-lineage genes (e.g. SMAD3 and ELK3). Also, we showed an induction in the chromatin accessibility at those subsets of common AR-GATA3 cis-regulatory elements, which drive the luminal lineage identity in breast cancer upon androgen stimulation. Collectively, AR-GATA3 interaction and function provide a mechanism underpinning epithelial breast cancer cells that are classified as having a luminal mature transcriptome independent of ER status, through regulating the expression of lineage-restricted markers.

Project description:GATA3 transcription factor is considered critical for luminal development and differentiation in normal and malignant mammary epithelial cells (MECs). The androgen receptor (AR) has also been associated with luminal gene expression profiles in breast cancer, independent of the estrogen receptor (ER), and has been shown to promote a basal to luminal phenotype transition in mouse MECs. To date, the potential interaction of GATA3 and AR in transcriptional regulation of lineage driver genes in breast cancer has never been investigated. Our unbiased proteomic analysis identified GATA3 as a novel AR interacting protein in a variety of breast cancer cell types regardless of ER expression. We showed that AR and GATA3 interact in the cytoplasm and nucleus of normal and malignant breast epithelia, an interaction increased by androgen treatment. Androgen stimulation of breast cancer cells also induced nuclear translocation of AR and GATA3 and resulted in enrichment of co-localized AR and GATA3 chromatin binding events. Using ER+ and/or ER- breast cancer cell lines and ER+ patient-derived xenograft (PDX) models of breast cancer, we identified a conserved subset of AR agonist-induced AR and GATA3 co-occupied cis-regulatory elements across all models. Knockdown experiments indicated that GATA3 acts as an AR co-regulator to upregulate transcription of known luminal-lineage genes (e.g. EHF, AQP3, and KDM4B) and downregulate basal-lineage genes (e.g. SMAD3 and ELK3). Also, we showed an induction in the chromatin accessibility at those subsets of common AR-GATA3 cis-regulatory elements, which drive the luminal lineage identity in breast cancer upon androgen stimulation. Collectively, AR-GATA3 interaction and function provide a mechanism underpinning epithelial breast cancer cells that are classified as having a luminal mature transcriptome independent of ER status, through regulating the expression of lineage-restricted markers.

Project description:GATA3 transcription factor is considered critical for luminal development and differentiation in normal and malignant mammary epithelial cells (MECs). The androgen receptor (AR) has also been associated with luminal gene expression profiles in breast cancer, independent of the estrogen receptor (ER), and has been shown to promote a basal to luminal phenotype transition in mouse MECs. To date, the potential interaction of GATA3 and AR in transcriptional regulation of lineage driver genes in breast cancer has never been investigated. Our unbiased proteomic analysis identified GATA3 as a novel AR interacting protein in a variety of breast cancer cell types regardless of ER expression. We showed that AR and GATA3 interact in the cytoplasm and nucleus of normal and malignant breast epithelia, an interaction increased by androgen treatment. Androgen stimulation of breast cancer cells also induced nuclear translocation of AR and GATA3 and resulted in enrichment of co-localized AR and GATA3 chromatin binding events. Using ER+ and/or ER- breast cancer cell lines and ER+ patient-derived xenograft (PDX) models of breast cancer, we identified a conserved subset of AR agonist-induced AR and GATA3 co-occupied cis-regulatory elements across all models. Knockdown experiments indicated that GATA3 acts as an AR co-regulator to upregulate transcription of known luminal-lineage genes (e.g. EHF, AQP3, and KDM4B) and downregulate basal-lineage genes (e.g. SMAD3 and ELK3). Also, we showed an induction in the chromatin accessibility at those subsets of common AR-GATA3 cis-regulatory elements, which drive the luminal lineage identity in breast cancer upon androgen stimulation. Collectively, AR-GATA3 interaction and function provide a mechanism underpinning epithelial breast cancer cells that are classified as having a luminal mature transcriptome independent of ER status, through regulating the expression of lineage-restricted markers.

Project description:Emerging data indicate that breast epithelial stem cells and progenitors, particularly those in the luminal epithelial cell lineage, are the cells-of-origin of breast carcinomas, and factors that influence breast cancer risk may alter the number and/or properties of these cells. We hypothesize that a subset of p27+ cells represent hormone-responsive progenitors that are quiescent due to the high activity of TGFβ signaling in these cells. The Estrogen-induced mammary tumor model in ACI inbred rats is physiologically relevant rodent model of breast cancer. In the present study we successfully generated Cdkn1b knockout ACI rats and performed comprehensive phenotypic assessment and RNAseq profiling using FACS sorted basal (CD24+CD29high) and luminal (CD24+CD29low) cell populations to characterize Cdkn1b+/+ and Cdkn1b-/- females in prepubertal and adult cohorts. We found that p27KO rats exhibited mammary differentiation phenotype and reduced numbers of mammary epithelial progenitor pool, Interestingly, p27 ablation has the most pronounced effect on luminal progenitor cell gene expression, and milk protein genes and pStat5 were dramatically upregulated, while PR and FoxA1 were greatly downregulated in Cdkn1b-/- luminal cells. Further characterization of mammary glands of prepubertal Cdkn1b knockout rats by fat pad transplantation illustrated p27 deletion in the mammary cancer susceptible ACI rat strain induced mammary epithelial cell differentiation through cell non-autonomous mechanisms.