Project description:High grade serous ovarian cancers (HGSC) are deadly malignancies that relapse despite carboplatin chemotherapy. Many commercially ovarian cancer cell lines are not good models for HGSC. Here we demonstrate that 3 low passage cell lines derived from HGSC have similar transcriptomes to their parental bulk tumors. These cell lines recapitulated tumor characteristics of the primary cancer and had responded to therapy in the same manner as primary HGSC cells, demonstrating they are accurate models for HGSCs. mRNA profiles of low passage high grade serous tumor cell lines and their parental tumors, generated by next generation sequencing, were compared.

Project description:High grade serous ovarian cancers (HGSC) are deadly malignancies that relapse despite carboplatin chemotherapy. Many commercially ovarian cancer cell lines are not good models for HGSC. Here we demonstrate that 3 low passage cell lines derived from HGSC have similar transcriptomes to their parental bulk tumors. These cell lines recapitulated tumor characteristics of the primary cancer and had responded to therapy in the same manner as primary HGSC cells, demonstrating they are accurate models for HGSCs.

Project description:Migration of human glioma stem cells (hGSCs) within the brain parenchyma makes glioblastoma one of the most aggressive and lethal tumors. Studies of the cellular and molecular mechanisms underlying hGSC migration are hindered by the limitations of existing migration models. Here we developed a dorsal root ganglion axon-oligodendrocyte-hGSC co-culture to study in real time the migration and interaction of hGSCs with their microenvironment. hGSCs interact with myelinated and non-myelinated axons through the formation of pseudopodia. Isolation of pseudopodia-localized polysome-bound RNA reveals transcripts of Lck, Paxillin, Crk-II and Rac1 that undergo local translation. Inhibition of Lck blocks the activation of this pathway, the formation of pseudopodia and the migration of hGSCs. In vivo intraventricular administration of a Lck inhibitor using an orthotopic xenograft mouse model results in significant inhibition of tumor growth and significant down-regulation of stemness gene expression. Targeting this Lck pathway constitutes a novel treatment paradigm for human glioblastomas.

Project description:We report that monocytes contribute to the maintenance of BAT macrophages in a dynamic manner at steady state, and allow tissue remodelling during BAT expansion. Using scRNA-Seq, we explored monocyte and macrophage diversity in BAT at steady state and during BAT expansion.

Project description:High grade serous ovarian cancers (HGSC) are deadly malignancies that relapse despite carboplatin chemotherapy. Here we show that 16 independent primary HGSCs contain a CA125 negative population enriched for carboplatin resistant cancer initiating cells. Transcriptome analysis reveals up-regulation of homologous recombination DNA repair and anti-apoptotic signals in this population. While treatment with carboplatin enriches for CA125 negative cells, co-treatment with carboplatin and birinapant eliminates these cells in HGSCs expressing high levels of the inhibitor of apoptosis protein cIAP in the CA125 negative population. Birinapant sensitizes CA125 negative cells to carboplatin by mediating degradation of cIAP causing cleavage of caspase-8 and restoration of apoptosis. This co-therapy significantly improved disease free survival in vivo compared to either therapy alone in tumor-bearing mice. These findings suggest that therapeutic strategies that target CA125 negative cells may be useful in the treatment of HGSC. mRNA profiles of CA125 positive and negative populations, generated by next generation sequencing of populations FACS isolated from 10 independent dissociated primary human high grade serous ovarian cancers, were compared.

Project description:Monocytes and macrophages are central to host defense but also contribute to inflammation-associated pathology. Efforts to manipulate monocyte and macrophage function are limited by our ability to effectively quantify the functional programs of these cells. We identified the gene Fth1, which encodes the Ferritin heavy chain, as highly predictive of alveolar macrophage transcriptomic states during LPS-induced lung inflammation and developed a novel Fth1-mScarlet reporter mouse. In the steady state lung, high Fth1-mScarlet expression is restricted to alveolar macrophages. In response to LPS-induced lung inflammation, Fth1 reporter activity is robustly increased in monocytes, with its expression reporting genes that are differentially expressed in monocytes versus macrophages. Consistent with this reporter associated gene profile, within the Lyz2-GFP+CD11b+Ly6C+ gate the highest Fth1 reporter expression was observed CD11c+ cells, indicative of monocyte-to-macrophage differentiation. While Fth1-mScarlet was induced in monocytes responding to either TLR4 ligation or M-CSF induced macrophage differentiation in vitro, TLR4-dependent expression occurred with greater speed and magnitude. Considering this, we suggest that Fth1-mScarlet expression reports monocyte-to-macrophage differentiation, with increased expression in pro-inflammatory states. Dissecting macrophage differentiation from inflammatory programs will be enhanced when combining Fth1-mScarlet with other reporter systems. Thus, the Fth1-mScarlet model addresses an important lack of tools to report the diverse spectrum of monocyte and macrophage states in vivo.

Project description:The current paradigm in the development of high-grade serous carcinomas (HGSCs) proposes that the majority of HGSCs arise from precursor serous tubal intraepithelial carcinoma (STIC) lesions of the fallopian tube. The goal of this study is to identify genomic regions that exhibit high-specificity differential hypermethylation for potential use as biomarkers for detecting STIC and HGSC at stages when curative intervention likely remains feasible.

Project description:Two types of monocytes, inflammatory and patrolling, infiltrate the hearts in both human myocarditis and murine experimental autoimmune myocarditis (EAM) model. The fates and functions of these infiltrating monocytes governing the progression of heart failure remain unclear. Here, we created parabiotic EAM and naïve mice to show that cardiac inflammation facilitate monocyte-to-macrophage differentiation. Using a combination of flow cytometry, time lapsed imaging and transmission electron microscopy, we demonstrated in vitro that cardiac fibroblasts interact with monocytes and are instrumental in facilitating monocyte-to-macrophage differentiation. Moreover, IL-17A stimulated cardiac fibroblasts completely arrested Ly6Clo monocyte proliferation and inhibited both Ly6Chi and Ly6Clo monocyte-to-macrophage differentiation both in vitro and in vivo after intracardiac injections of monocytes into the hearts. Intriguingly, IL-17A signaling through cardiac fibroblasts also significantly downregulated Mer tyrosine kinase (MerTK) expressions on Ly6Chi monocyte-derived macrophages, thus jeopardizing their phagocytic abilities. Collectively, our results implicate divergent fates and functions of heart-infiltrating monocytes influenced by cardiac fibroblasts.

Project description:Recent evidence suggests that ovarian high-grade serous carcinoma (HGSC) originates from the epithelium of the fallopian tube. However, most mouse models are based on the previous prevailing view that ovarian cancer develops from the transformation of the ovarian surface epithelium. Here, we report the extensive histological and molecular characterization of the mogp-TAg transgenic mouse, which expresses the SV40 large T-antigen (TAg) under the control of the mouse müllerian-specific Ovgp-1 promoter. Histologic analysis of the fallopian tubes of mogp-TAg mice identified a variety of neoplastic lesions analogous to those described as precursors to ovarian HGSC. We identified areas of normal appearing p53-positive epithelium that are similar to “p53 signatures” in the human fallopian tube. More advanced proliferative lesions with nuclear atypia and epithelial stratification were also identified that were morphologically and immunohistochemically reminiscent of human serous tubal intraepithelial carcinoma (STIC), a potential precursor of ovarian HGSC. Beside these noninvasive precursor lesions, we also identified invasive adenocarcinoma in the ovary of 56% of the mice. Microarray analysis revealed several genes differentially expressed between the fallopian tube of mogp-TAg and WT C57BL/6. One of these genes, Top2a, which encodes topoisomerase II-alpha, was shown by immunohistochemistry to be concurrently expressed with elevated p53 and specifically elevated in mouse STICs, but not in surrounding tissues. TOP2A protein was also found elevated in human STICs, low-grade, and high-grade serous carcinoma. The mouse model reported here displays a progression from normal tubal epithelium to invasive HGSC in the ovary, and therefore closely simulates the current emerging model of human ovarian HGSC pathogenesis. This mouse therefore has the potential to be a very useful new model for elucidating the mechanisms of serous ovarian tumorigenesis, as well as for developing novel approaches for the prevention, diagnosis, and therapy of this disease. Keywords: transgenic mouse model, ovarian cancer, fallopian tube, intraepithelial carcinoma 6 mouse fallopian tubes (FT) were analyzed with experimental repeats; 3 wildtype C57BL6 mice (FT) and 3 transgenic mogp-TAg (FT), with one set of each at 7, 8 and 9 weeks of age.

Project description:High grade serous ovarian cancers (HGSC) are deadly malignancies that relapse despite carboplatin chemotherapy. Here we show that 16 independent primary HGSCs contain a CA125 negative population enriched for carboplatin resistant cancer initiating cells. Transcriptome analysis reveals up-regulation of homologous recombination DNA repair and anti-apoptotic signals in this population. While treatment with carboplatin enriches for CA125 negative cells, co-treatment with carboplatin and birinapant eliminates these cells in HGSCs expressing high levels of the inhibitor of apoptosis protein cIAP in the CA125 negative population. Birinapant sensitizes CA125 negative cells to carboplatin by mediating degradation of cIAP causing cleavage of caspase-8 and restoration of apoptosis. This co-therapy significantly improved disease free survival in vivo compared to either therapy alone in tumor-bearing mice. These findings suggest that therapeutic strategies that target CA125 negative cells may be useful in the treatment of HGSC.