Project description:The tyrosine kinase ErbB2 positive breast tumors have more aggressive tumor growth, poorer clinical outcome, and more resistance to radiotherapy, chemotherapy and hormone therapy. A humanized anti-ErbB2 monoclonal antibody Herceptin and a small molecules inhibitor Lapatinib were developed and approved by FDA to treat patients with ErbB2 amplification and overexpression. Unfortunately, most ErbB2+ breast cancers do not respond to Herceptin and Lapatinib, and the majority of responders become resistant within 12 months of initial therapy (defined as secondary drug resistance). Such differences in response to Lapatinib treatment is contributed by substantial heterogeneity within ErbB2+ breast cancers. To address this possibility, we carried out transcriptomic analysis of mammary tumors from genetically diverse MMTV-ErbB2 mice. This will help us to have a better understanding of the heterogeneous response to ErbB2 targeted therapy and permit us to design better and more individualized (personalized) treatment strategies for human ErbB2 positive breast cancer. 214 MMTV-ErbB2 mammary tumors and 8 normal mammary glands were analyzed by Affymetrix microarrays.

Project description:Human mammary epithelial cells sorted by cell cycle

Project description:Bovine mammary epithelial cells in response to artemisinin treatment

Project description:Tumorpsheres and mammospheres were used to propagate mouse breast tumor-initiating cells and their normal stem/progenitor counterparts, respectively. Mammospheres induced to differentiate were used to model the more differentiated cells of the mouse mammary gland. We used microarrays to find differentrially expressed genes between tumorspheres, mammospheres, and mammospheres induced to differentiate Primary cells were isolate from either mouse mammary glands (FVB/N) or mouse mammary tumors and placed in stem cell media (MMTV-Neu [N2O2]. Spheres were passaged every 7 days for 3-5 passages and harvested for RNA isolation

Project description:The following data comes from two separate experiments. In the initial experiment, luminal and basal murine mammary epithelial cells were analyzed by reduced representation bisulfite sequencing (RRBS) to generate methylome profiles. In the second experiment, luminal and basal murine mammary epithelial cells were analyzed by ATAC-seq.

Project description:Breast cancer is a highly heterogeneous disease that is categorized into distinct tumor subtypes based on specific molecular attributes, which ultimately influence therapeutic options. Unlike ER+ and/or HER2+ cancers that are subject to specific targeted therapies, triple negative breast cancers (TNBCs) do not express these receptors, which leaves patients with limited treatment options. Thus, significant focus has been placed on identifying molecular attributes of basal-like disease that could be used to develop and/or direct novel treatment regimens. Activation of MYC signaling and inactivation of the RB-pathway are frequent events in many types of human cancers. These pathways influence many biological processes, such as cell proliferation, that contribute to the aggressiveness and therapeutic response of tumors. The current study examines the interaction of the MYC and RB pathways in mammary epithelial cell tumorigenesis. Mouse mammary epithelial cells were isolated and sub-cultured. Adenoviral expression of Cre-recombinase was used to delete the RB and/or p53 genes, and retrovirus was used to achieve MYC overexpression (OE). Proliferating cells were harvested for each condition, and RNA was isolated for analyses.

Project description:The mammary gland is a highly dynamic organ that mainly develops during puberty. Based on morphology and proliferation analysis, mammary stem cells (MaSCs) are thought to be close to or reside in the terminal end buds (TEBs) during pubertal development. However, exclusive stem cell markers are lacking, and therefore the true identity of MaSCs, including their location, multiplicity, dynamics and fate during branching morphogenesis, has yet to be defined. To gain more insights into the molecular identity and heterogeneity of the MaSC pool, we performed single cell transcriptome sequencing of mammary epithelial cells micro-dissected from ducts and TEBs during puberty. These data show that the behaviour of MaSCs cannot be directly linked to a single expression profile. Instead, morphogenesis of the mammary epithelium relies upon a heterogeneous population of MaSCs that functions long-term as a single equipotent pool of stem cells.

Project description:Gene expression differences, combined with distinct patterns of genomic rearrangements and epigenetic modifications constitute the bases of molecular classification of breast cancer. Molecular subtypes may originate from different cell lineages in the mammary gland, but also from the early activation of oncogenes that may drive the establishment of these molecular subtypes. However, in the natural history of human cancer, it is difficult to discriminate between these two factors : cell lineage and initial oncogenic alterations. In this work, we designed an experimental strategy aiming at determining whether activation of distinct oncogenic pathways in human mammary epithelial cells (HMEC) could lead to different patterns of genetic and epigenetic changes. This work suggests that the early activation of oncogenes is an important determinant of the establishment of breast cancer molecular subtypes along with cell lineage origin. In this work, we overexpressed by retroviral transduction three oncogenes WNT1, CCNE1 and RASv12, known to activate different oncogenic pathways, in shp53 immortalized human HMECs and monitored epigenetic and genetic changes at different steps of cell progression.Submitted publication : Distinct Oncogenic events induces different DNA methylation and copy number changes in human mammary epithelial cells.Claire Fonti, Anne Saumet, Amanda Abi-Khalil, Béatrice Orsetti,..., J. Colinge, Michael Weber, Claude Sardet, Stanislas du Manoir, Charles Theillet.

Project description:Molecular/cellular events that associate with epithelial-to-mesenchymal transition (EMT) are linked to acquisition of cancer stem cell traits, but whether EMT mechanisms regulate tissue epithelial cell fate and stem cell activity in vivo remains ambiguous. Using single-cell RNA sequencing, we detect heterogeneous EMT gene expression in stem cell-containing mammary basal/myoepithelial cells that normally possess both epithelial and smooth muscle characteristics. We show that EMT-inducing transcription factor Zeb1 is required within the mammary epithelium for ductal branching morphogenesis and regeneration, and that it promotes basal cell fate and regulates stem cell proliferation dynamics. We provide genetic and molecular evidence for EMT-dependent and -independent mechanisms of Zeb1 function, and show that Zeb1 cooperates with YAP to directly activate targets that inhibit Wnt signaling or control cell cycle. Together, our findings underscore Zeb1-mediated EMT control in governing mammary basal cell fate and proliferative activity, but with an interesting turn that involves mechanisms beyond EMT.

Project description:Molecular/cellular events that associate with epithelial-to-mesenchymal transition (EMT) are linked to acquisition of cancer stem cell traits, but whether EMT mechanisms regulate tissue epithelial cell fate and stem cell activity in vivo remains ambiguous. Using single-cell RNA sequencing, we detect heterogeneous EMT gene expression in stem cell-containing mammary basal/myoepithelial cells that normally possess both epithelial and smooth muscle characteristics. We show that EMT-inducing transcription factor Zeb1 is required within the mammary epithelium for ductal branching morphogenesis and regeneration, and that it promotes basal cell fate and regulates stem cell proliferation dynamics. We provide genetic and molecular evidence for EMT-dependent and -independent mechanisms of Zeb1 function, and show that Zeb1 cooperates with YAP to directly activate targets that inhibit Wnt signaling or control cell cycle. Together, our findings underscore Zeb1-mediated EMT control in governing mammary basal cell fate and proliferative activity, but with an interesting turn that involves mechanisms beyond EMT.