Project description:Niche-associated signals, essential for the maintenance of normal stem cells and tumor-initiating cells, are spatially confined and exert their influence locally among adjacent cells. Here, we demonstrate that CXCR4+ macrophages are enriched in the normal mammary ducts and enhance regenerative activity in basal cells in response to the CXCL12 secreted by luminal cells. Conditional knockout of CXCR4 in macrophages or CXCL12 in luminal cells results in similar phenotypes, including impaired branching morphogenesis, decreased regenerative functionality in basal cells, and diminished ductal association of macrophages. CXCL12 stimulation of macrophages triggers an AKT-mediated stabilization of β-catenin, increasing the expression of pro-migratory genes and multiple Wnt ligands, which enhances the infiltration of macrophages and their ability to support stem-like regenerative functions of basal cells. Importantly, the identical CXCR4+ niche macrophages also govern the tumor-initiating activity of breast tumors by promoting the survival and tumor-forming capacity of tumor-initiating cells and inducing early immune evasion through the accumulation of regulatory T cells. Our findings elucidate a crucial role of the CXCL12-CXCR4 axis in facilitating a complex interaction among niche macrophages, two mammary epithelial cell lineages, and other stromal components, thereby establishing a supportive environment for both normal tissue regeneration and mammary tumor initiation.

Project description:Niche-associated signals, essential for the maintenance of normal stem cells and tumor-initiating cells, are spatially confined and exert their influence locally among adjacent cells. Here, we demonstrate that CXCR4+ macrophages are enriched in the normal mammary ducts and enhance regenerative activity in basal cells in response to the CXCL12 secreted by luminal cells. Conditional knockout of CXCR4 in macrophages or CXCL12 in luminal cells results in similar phenotypes, including impaired branching morphogenesis, decreased regenerative functionality in basal cells, and diminished ductal association of macrophages. CXCL12 stimulation of macrophages triggers an AKT-mediated stabilization of β-catenin, increasing the expression of pro-migratory genes and multiple Wnt ligands, which enhances the infiltration of macrophages and their ability to support stem-like regenerative functions of basal cells. Importantly, the identical CXCR4+ niche macrophages also govern the tumor-initiating activity of breast tumors by promoting the survival and tumor-forming capacity of tumor-initiating cells and inducing early immune evasion through the accumulation of regulatory T cells. Our findings elucidate a crucial role of the CXCL12-CXCR4 axis in facilitating a complex interaction among niche macrophages, two mammary epithelial cell lineages, and other stromal components, thereby establishing a supportive environment for both normal tissue regeneration and mammary tumor initiation.

Project description:Mammary gland ductal morphogenesis depends on the differentiation of mammary stem cells (MaSCs) into basal and luminal lineages. The AP-2γ transcription factor, encoded by Tfap2c, has a central role in mammary gland development but its effect in mammary lineages and specifically MaSCs is largely unknown. Herein, we utilized an inducible, conditional knockout of Tfap2c to elucidate the role of AP-2γ in maintenance and differentiation of MaSCs. Loss of AP-2γ in the basal epithelium profoundly altered the transcriptomes and decreased the number of cells within several clusters of mammary epithelial cells, including adult MaSCs and luminal progenitors. AP-2γ regulated the expression of genes known to be required for mammary development including Cebpb, Nfkbia, and Rspo1. As a result, AP-2γ-deficient mice exhibited repressed mammary gland ductal outgrowth and inhibition of regenerative capacity. The findings demonstrate that AP-2γ can regulate development of mammary gland structures potentially regulating maintenance and differentiation of multipotent MaSCs.

Project description:Mammary epithelium is hierarchically organized, with multipotent basal mammary stem cells (MaSCs) producing both luminal and basal cells during development or upon transplantation. Recent studies suggested that most breast cancers, including Basal-Like breast cancer (BLBC), might originate from luminal cells, and oncogenic events, such as ectopic expression of PIK3CA(H1047R), could induce multipotency in committed luminal cells. p53 is the most commonly mutated gene in human breast cancer; in particular, its inactivating mutations are found in most BLBCs, raising a question as to whether p53-loss plays a key role in acquisition of multipotent MaSC-like properties by luminal cells. By in situ lineage-tracing, we found that induced loss of p53 in Keratin 8 (K8)+ luminal cells led to their clonal expansion, due to increased cell cycle activity and attenuated apoptosis control, but did not directly affect their luminal identity. All induced mice eventually developed either Claudin-Low mammary tumors with 9qA1 (Yap1) amplification or Basal-Like tumors with 6qA1-A2 (Met) amplification. These data suggest that although p53 does not directly control the luminal fate, its loss facilitates acquisition of MaSC-like properties by luminal cells and predisposes them to development of mammary tumors with loss of luminal identity.

Project description:Mammary epithelium is hierarchically organized, with multipotent basal mammary stem cells (MaSCs) producing both luminal and basal cells during development or upon transplantation. Recent studies suggested that most breast cancers might originate from luminal cells, and oncogenic events, such as ectopic expression of PIK3CAH1047R, could induce multipotency in committed luminal cells. p53 is the most commonly mutated gene in human breast cancer; in particular, its inactivating mutations are found in most triple-negative breast cancers, raising a question as to whether p53-loss plays a key role in acquisition of MaSC-like properties by luminal cells. By in situ lineage tracing, we found that induced loss of p53 in Keratin 8 (K8)+ luminal cells led to their clonal expansion, in part due to increased proliferation, but did not directly affect their luminal identity. Expansion of luminal cells, in particular oestrogen receptor-positive luminal cells, was observed 3-4 weeks after induced p53-loss, which was accompanied by increased expression of cell cycle genes and downregulation of genes related to immune microenvironment, p53 downstream pathway and apoptosis control. All induced mice eventually developed mammary tumours with 9qA1 (Yap1) amplification and/or 6qA2 (Met) amplification. The resulting tumours exhibited a MaSC-like expression signature and most closely resembled Claudin-Low breast cancer. Overall, these data suggest that although p53 does not directly control the luminal fate, its loss facilitates acquisition of MaSC-like properties by luminal cells and predisposes them to development of mammary tumours with loss of luminal identity. Our data also suggest that Claudin-Low breast cancer can originate from luminal cells, possibly upon transition through a basal-like state.

Project description:Long-lived quiescent mammary stem cells (MaSCs) are presumed to coordinate the dramatic expansion of ductal epithelium that occurs through the different phases of postnatal development, but little is known about the molecular regulators that underpin the activation of MaSCs. Here we show that ablation of the transcription factor Foxp1 in the mammary gland profoundly impairs ductal morphogenesis, resulting in a rudimentary tree throughout adult life. Foxp1-deficient glands were highly enriched for quiescent Tspan8hi MaSCs, which failed to become activated, even in competitive transplantation assays, and therefore harbor a cell-intrinsic defect. Luminal cells aberrantly expressed basal genes, suggesting that Foxp1 may also contribute to cell-fate decisions. Notably, Foxp1 was uncovered as a direct repressor of the Tspan8 gene in basal cells and deletion of Tspan8 could rescue the profound defects in ductal morphogenesis elicited by Foxp1 loss. Thus, a single transcriptional regulator, Foxp1, can control the exit of MaSCs from dormancy to orchestrate differentiation and development.

Project description:Long-lived quiescent mammary stem cells (MaSCs) are presumed to coordinate the dramatic expansion of ductal epithelium that occurs through the different phases of postnatal development, but little is known about the molecular regulators that underpin the activation of MaSCs. Here we show that ablation of the transcription factor Foxp1 in the mammary gland profoundly impairs ductal morphogenesis, resulting in a rudimentary tree throughout adult life. Foxp1-deficient glands were highly enriched for quiescent Tspan8hi MaSCs, which failed to become activated, even in competitive transplantation assays, and therefore harbor a cell-intrinsic defect. Luminal cells aberrantly expressed basal genes, suggesting that Foxp1 may also contribute to cell-fate decisions. Notably, Foxp1 was uncovered as a direct repressor of the Tspan8 gene in basal cells and deletion of Tspan8 could rescue the profound defects in ductal morphogenesis elicited by Foxp1 loss. Thus, a single transcriptional regulator, Foxp1, can control the exit of MaSCs from dormancy to orchestrate differentiation and development.

Project description:MaSC enriched P4 subpopulation with high/low expression of Dll1, were isolated from mammary gland of Dll1-mCherry mice, and sorted for high/low Dll1 expression based on mCherry red fluroscense. Mammary gland associated macrophages were isolated from Dll1cKO mice (C57/B6 strain) and the wild type littermates. Total RNA samples were prepared from these samples and the transcription profiles were compared between these samples to conclude that Dll1 in MaSC is critical to mediate interaction to macrophageal niche and in turn supports the proper MaSC function.

Project description:Skin-mammary specific knockout (SSKO) of Pygo2 (K14-cre; Pygo2 flox/-) , a WNT signaling co-activator, results in defective mouse mammary gland development. The FACS sorted mammary stem cell (MaSC)/basal population from Pygo2 SSKO mammary gland displays biased differentiation towards luminal/alveolar lineage in vitro, and reduced regeneration rate of new mammary gland in vivo To gain the insight into gene expression profiles in control and Pygo2 SSKO mammary epithelial cells (MECs), we sorted the freshly isolated mouse MECs into MaSC/basal (Lin-CD29hiCD24+) and mature luminal population (Lin-CD29lowCD24+CD61-), and extract total RNA for cDNA microarray analysis

Project description:In this study we mapped H3K27me3, H3K4me3 and H3K9me2 marks in three mammary epithelial subsets: MaSC/basal (MS), luminal progenitor (LP) and mature luminal (ML) in the steady-state. In addition, profiles were generated for H3K4me3 and H3K27me3 marks in the MaSC/basal and luminal populations from the glands of ovariectomized or mid-pregnant (12.5 days) mice as well as from control virgin mice.