Project description:It has been suggested that breast cancers are driven and maintained by a cellular subpopulation with stem cell properties. These breast cancer stem cells (BCSCs) mediate metastasis and by virtue of their resistance to radiation and chemotherapy, contribute to relapse. Although several BCSC markers have been described, it is unclear whether these markers identify the same or independent BCSC populations. Based on established breast cancer cell lines, as well as primary tumor samples and xenografts, we show that BCSCs exist in distinct mesenchymal-like (epithelial-mesenchymal transition, EMT) and epithelial-like (mesenchymal-epithelial transition, MET) states characterized by expression of distinct markers, proliferative capacity and invasive characteristics. The gene expression profiles of mesenchymal-like and epithelial-like BCSCs are remarkably similar across the different molecular subtypes of breast cancer and resemble those of distinct basal and luminal stem cells found in the normal breast. We propose that the plasticity of BCSCs allowing them to transition between EMT- and MET-like states endows these cells with the capacity for tissue invasion, dissemination and growth at metastatic sites. Breast cancer cells from patient were sorted using flow cytometry to select for cells that were ALDH+. Gene expression profiles of these cells were compared with profiles of ALDH- cells.

Project description:It has been suggested that breast cancers are driven and maintained by a cellular subpopulation with stem cell properties. These breast cancer stem cells (BCSCs) mediate metastasis and by virtue of their resistance to radiation and chemotherapy, contribute to relapse. Although several BCSC markers have been described, it is unclear whether these markers identify the same or independent BCSC populations. Based on established breast cancer cell lines, as well as primary tumor xenografts, we show that BCSCs exist in distinct mesenchymal-like (epithelial-mesenchymal transition, EMT) and epithelial-like (mesenchymal-epithelial transition, MET) states characterized by expression of distinct markers, proliferative capacity and invasive characteristics. The gene expression profiles of mesenchymal-like and epithelial-like BCSCs are remarkably similar across the different molecular subtypes of breast cancer and resemble those of distinct basal and luminal stem cells found in the normal breast. We propose that the plasticity of BCSCs allowing them to transition between EMT- and MET-like states endows these cells with the capacity for tissue invasion, dissemination and growth at metastatic sites. Breast cancer cell lines, primary xenografts and normal breast cells from patient were sorted using flow cytometry to select for cells that were CD24-,CD44+ and ALDH+. Gene expression profiles of CD24-CD44+ cells were compared with non-CD24-CD44+ cells. Gene expression profiles of ALDH+ cells were compared with ALDH- cells.

Project description:Emerging evidence suggest that miRNAs play an essential role in self-renewal and differentiation of normal and malignant stem cells by regulating the expression of key stem cell regulatory genes. Here we demonstrate that mir-100 expression is related to cellular differentiation state with lowest expression in cells displaying stem cell markers. Utilizing a tetracycline inducible lentivirus driving mir-100 expression, we found that mir-100 overexpression decreased breast cancer stem cells (BCSCs) and inhibited cancer cell proliferation in vitro and in mouse xenografts by targeting SMARCA5, SMARCD1 and BMPR2. In order to determine the cellular targets of mir-100 in BCSCs and non-BCSCs, ALDH-positive and -negative populations of pTRIPZ-SUM159-mir-100 cells were separated and cultured in suspension for ten hours in the presence or absence of DOX. Gene expression profiles of the four populations were determined utilizing Affymetrix microarrays

Project description:Self-renewal and differentiation are two epigenetic programs that regulate pluripotency of stem cells. During oncogenesis, dysregulation of these two programs leads to the development of cancer stem cells (CSCs). Here, we used a pan genomic promoter microarray to determine the DNA methylation portrait of breast cancer stem cells (bCSC) compared to non-bCSC

Project description:Background: Breast cancer stem cells (BCSCs) are considered responsible for cancer relapse and drug-resistance. Understanding the identity of BCSCs may open new avenues in breast cancer therapy. Although several discoveries have been made on BCSCs characterization, the factors critical to BCSCs is largely unclear. This study was aimed to determine whether genomic mutation contributes to the acquisition of cancer stem-like phenotype, and to investigate the genetic and transcriptional features of BCSCs. Methods: We detected the potential mutation hotspot regions by using whole genome sequencing on parental cancer cells and derived serial-generation spheroids in increasing order of BCSC frequency, and then performed target deep DNA sequencing in the level of bulk-cell and single-cell. To identify the transcriptional program associated with BCSCs, bulk-cell and single-cell RNA sequencing were performed. Results: By analyzing whole genome sequencing of bulk cells, potential BCSCs associated mutation hotspot regions were detected. Validation by target deep sequencing, in both bulk-cell and single-cell levels, revealed no genetic changes specifically associated with BCSC phenotype. Moreover, single-cell RNA sequencing showed that cancer cells display profound transcriptional variability at the single-cell level that predicts BCSC features. Notably, this transcriptomic variability is enriched in transcription of a number of genes, revealed as BCSC markers. Individuals with breast cancer in a high-risk recurrence group exhibited higher expression of these transcriptomic variabilities, highlighting their clinical significance. Conclusions: Transcriptional variability, not genetic mutations, distinguish BCSCs from non-BCSCs. The identified BCSCs markers can become novel targets for BCSCs.

Project description:The cancer stem cell (CSC) hypothesis postulates that tumors are maintained by a self-renewing CSC population that is also capable of differentiating into non-self renewing cell populations that constitute the bulk of the tumor. Targeting breast CSC (BCSC) self-renewal represents an avenue for developing therapeutics; however, the molecular mechanisms that govern self-renewal of BCSCs are poorly understood. Our data show the small molecule ID8 decreases overall cell growth, but increases the self-renewal of Aldefluor+ BCSCs and increases functional metastatic BCSCs in a xenograft model. Microarray analysis showed that ID8 is a pleotropic molecule by increasing numerous pathways, including cytokines and chemokines. However, inhibition of those pathways does not abrogate the ID8-induced increase in Aldefluor+ BCSCs. Rather, ID8 is able to activate MAPK pathway through upregulation of the scaffold protein LAMTOR3 and inhibition of MEK prevented the increase in Aldefluor+ BCSCs. By using ID8 as a molecular tool, we identified a new function of the MAPK pathway in regulating BCSC growth and self-renewal.

Project description:It has been suggested that breast cancers are driven and maintained by a cellular subpopulation with stem cell properties. These breast cancer stem cells (BCSCs) mediate metastasis and by virtue of their resistance to radiation and chemotherapy, contribute to relapse. Although several BCSC markers have been described, it is unclear whether these markers identify the same or independent BCSC populations. Based on established breast cancer cell lines, as well as primary tumor xenografts, we show that BCSCs exist in distinct mesenchymal-like (epithelial-mesenchymal transition, EMT) and epithelial-like (mesenchymal-epithelial transition, MET) states characterized by expression of distinct markers, proliferative capacity and invasive characteristics. The gene expression profiles of mesenchymal-like and epithelial-like BCSCs are remarkably similar across the different molecular subtypes of breast cancer and resemble those of distinct basal and luminal stem cells found in the normal breast. We propose that the plasticity of BCSCs allowing them to transition between EMT- and MET-like states endows these cells with the capacity for tissue invasion, dissemination and growth at metastatic sites.

Project description:It has been suggested that breast cancers are driven and maintained by a cellular subpopulation with stem cell properties. These breast cancer stem cells (BCSCs) mediate metastasis and by virtue of their resistance to radiation and chemotherapy, contribute to relapse. Although several BCSC markers have been described, it is unclear whether these markers identify the same or independent BCSC populations. Based on established breast cancer cell lines, as well as primary tumor samples and xenografts, we show that BCSCs exist in distinct mesenchymal-like (epithelial-mesenchymal transition, EMT) and epithelial-like (mesenchymal-epithelial transition, MET) states characterized by expression of distinct markers, proliferative capacity and invasive characteristics. The gene expression profiles of mesenchymal-like and epithelial-like BCSCs are remarkably similar across the different molecular subtypes of breast cancer and resemble those of distinct basal and luminal stem cells found in the normal breast. We propose that the plasticity of BCSCs allowing them to transition between EMT- and MET-like states endows these cells with the capacity for tissue invasion, dissemination and growth at metastatic sites.

Project description:Breast cancer stem cell (BCSC) line #1 and #4 were grown in either stem cell medium or medium favoring the differentiation. Cells were genetically labeled with fluorescent protein expression cassettes and xenotransplanted into immunocompromised mice, giving rise to tumors. Tumors were explanted, dissociated and kept in culture so as to isolate growing cells. Cells were then sorted for fluorescent protein expression and RNA was extracted. Breast cancer stem (BCSC) and differentiated (dBCCs) cells, grown in opportune conditions, were transfected with lentiviral vector encoding luciferase/enhanced green fluorescent protein (Luc/EGFP-BCSCs) or luciferase/red fluorescent protein (Luc/RFP-dBCCs) reporter genes and orthotopically injected in defined ratios (1:1) into immunocompromised mice. Primary tumor growth and the onset of distant metastases was then observed in time. Following primary and metastatic lesions resection, labeled dBCCs, BCSCs and metastatic derivatives, thereafter referred to as fat pad differentiated cells (FPD), fat pad stem cells (FPS) and metastases (Ms) respectively, were consequently isolated from through fluorescent-activated cell sorting and RNA extracted. 14 samples, with at least 2 biological replicates for each category

Project description:Reprogramming of energy metabolism plays pivotal roles in cancer progression and immune surveillance. Here, we demonstrated that breast cancer cells showed positive feedback enhanced aerobic glycolysis in hypoxia condition. Further investigation suggested that breast cancer stem cells (BCSCs) induced by hypoxia stimulate aerobic glycolysis in bulk tumor cells. Cells cultured with hypoxic tumor cell- or BCSC-secretome exhibited similar gene expression patterns, with global remodeling of metabolism pathways, particularly glycolysis. BCSCs regulated glycolysis promoted breast cancer progression and evasion of immune surveillance. Screening of BCSC secretome identified MIF as a pivotal factor that potentiated glycolysis by increasing the expression of ALDOC. Breast cancer cell–intrinsic MIF depletion inhibited tumor progression and augmented intratumoral cytolytic CD8+ T cells and pro-inflammatory macrophages. Targeting MIF optimized immune checkpoint therapy of breast cancer in both syngeneic mouse models and humanized mouse model. Hence, this study delineates the contribution of BCSC regulated bulk tumor cell glycolysis in immune surveillance; and thereby proposes strategies to optimize immunotherapy in breast cancer.