Project description:Crosstalk and complexity within signaling pathways has limited our ability to devise rational strategies for using network biology to treat human disease. This is particularly problematic in cancer where oncogenes that drive or maintain the tumorigenic state alter the normal flow of molecular information within signaling networks that control growth, survival and death. Understanding the architecture of oncogenic signaling pathways, and how these networks are re-wired by ligands or drugs, could provide opportunities for the specific targeting of oncogene-driven tumors. Here we use a systems biology-based approach to explore synergistic therapeutic strategies to optimize the killing of triple negative breast cancer cells, an incompletely understood tumor type with a poor treatment outcome. Using targeted inhibition of oncogenic signaling pathways combined with DNA damaging chemotherapy, we report the surprising finding that time-staggered EGFR inhibition, but not simultaneous co-administration, can dramatically sensitize the apoptotic response of a subset of triple-negative cells to conventional DNA damaging agents. A systematic analysis of the order and timing of inhibitor/genotoxin presentation—using a combination of high-density time-dependent activity measurements of signaling networks, gene expression profiles, cell phenotypic responses, and mathematical modeling—revealed an approach for altering the intrinsic oncogenic state of the cell through dynamic re-wiring of oncogenic signaling pathways. This process converts these cells to a less tumorigenic state that is more susceptible to DNA damage-induced cell death, through re-activation of an extrinsic apoptotic pathway whose function is suppressed in the oncogene-addicted state. Three or 4 replicates of 3 different cell lines at time points 0minutes, 30minutes, 6 hours and 1 day after EGFR inhibition with erlotinib

Project description:Dynamic re-wiring of apoptotic signaling networks enhances tumor cell killing by DNA damage

Project description:By utilizing single-cell analysis at different stages of tumorigenesis, we demonstrated a developmental hierarchy of dynamic progenitor pools in murine sonic hedgehog-(SHH) MBs. We identified Olig2+ progenitors as transit-amplifying cells during initial tumorigenic phases. These cells are quiescent stem-like progenitors in full-blown tumors but enriched in therapy-resistant as well as recurrent medulloblastomas. Olig2 ablation or depletion of mitotic Olig2+ progenitors abrogated tumorigenesis. Transcriptome profiling and chromatin occupancy assays revealed that Olig2 activates oncogenic networks including HIPPO- Yap/Taz signaling and Aurora-A/MycN pathways. Co-targeting these oncogenic pathways induced sustained tumor growth arrest. Together, our single-cell analyses uncover unexpected glia-lineage-related Olig2+ progenitor pools critical for medulloblastoma initiation and suggest targeting Olig2-regulated oncogenic pathways as an avenue for therapy.

Project description:By utilizing single-cell analysis at different stages of tumorigenesis, we demonstrated a developmental hierarchy of dynamic progenitor pools in murine sonic hedgehog-(SHH) MBs. We identified Olig2+ progenitors as transit-amplifying cells during initial tumorigenic phases. These cells are quiescent stem-like progenitors in full-blown tumors but enriched in therapy-resistant as well as recurrent medulloblastomas. Olig2 ablation or depletion of mitotic Olig2+ progenitors abrogated tumorigenesis. Transcriptome profiling and chromatin occupancy assays revealed that Olig2 activates oncogenic networks including HIPPO- Yap/Taz signaling and Aurora-A/MycN pathways. Co-targeting these oncogenic pathways induced sustained tumor growth arrest. Together, our single-cell analyses uncover unexpected glia-lineage-related Olig2+ progenitor pools critical for medulloblastoma initiation and suggest targeting Olig2-regulated oncogenic pathways as an avenue for therapy.

Project description:By utilizing single-cell analysis at different stages of tumorigenesis, we demonstrated a developmental hierarchy of dynamic progenitor pools in murine sonic hedgehog-(SHH) MBs. We identified Olig2+ progenitors as transit-amplifying cells during initial tumorigenic phases. These cells are quiescent stem-like progenitors in full-blown tumors but enriched in therapy-resistant as well as recurrent medulloblastomas. Olig2 ablation or depletion of mitotic Olig2+ progenitors abrogated tumorigenesis. Transcriptome profiling and chromatin occupancy assays revealed that Olig2 activates oncogenic networks including HIPPO- Yap/Taz signaling and Aurora-A/MycN pathways. Co-targeting these oncogenic pathways induced sustained tumor growth arrest. Together, our single-cell analyses uncover unexpected glia-lineage-related Olig2+ progenitor pools critical for medulloblastoma initiation and suggest targeting Olig2-regulated oncogenic pathways as an avenue for therapy.

Project description:By utilizing single-cell analysis at different stages of tumorigenesis, we demonstrated a developmental hierarchy of dynamic progenitor pools in murine sonic hedgehog-(SHH) MBs. We identified Olig2+ progenitors as transit-amplifying cells during initial tumorigenic phases. These cells are quiescent stem-like progenitors in full-blown tumors but enriched in therapy-resistant as well as recurrent medulloblastomas. Olig2 ablation or depletion of mitotic Olig2+ progenitors abrogated tumorigenesis. Transcriptome profiling and chromatin occupancy assays revealed that Olig2 activates oncogenic networks including HIPPO- Yap/Taz signaling and Aurora-A/MycN pathways. Co-targeting these oncogenic pathways induced sustained tumor growth arrest. Together, our single-cell analyses uncover unexpected glia-lineage-related Olig2+ progenitor pools critical for medulloblastoma initiation and suggest targeting Olig2-regulated oncogenic pathways as an avenue for therapy.

Project description:By utilizing single-cell analysis at different stages of tumorigenesis, we demonstrated a developmental hierarchy of dynamic progenitor pools in murine sonic hedgehog-(SHH) MBs. We identified Olig2+ progenitors as transit-amplifying cells during initial tumorigenic phases. These cells are quiescent stem-like progenitors in full-blown tumors but enriched in therapy-resistant as well as recurrent medulloblastomas. Olig2 ablation or depletion of mitotic Olig2+ progenitors abrogated tumorigenesis. Transcriptome profiling and chromatin occupancy assays revealed that Olig2 activates oncogenic networks including HIPPO- Yap/Taz signaling and Aurora-A/MycN pathways. Co-targeting these oncogenic pathways induced sustained tumor growth arrest. Together, our single-cell analyses uncover unexpected glia-lineage-related Olig2+ progenitor pools critical for medulloblastoma initiation and suggest targeting Olig2-regulated oncogenic pathways as an avenue for therapy.

Project description:Triple negative breast cancer (TNBC) is characterized by an aggressive biologic behavior without specific targeted agent. Nicotinamide has recently been proven as a novel therapeutic agent for skin tumors in ONTRAC trial. Here we performed in-depth proteomes to characterize network of molecular interactions in TNBC cells treated by nicotinamide. Proteome profiles identified nicotinamide drives significant functional alterations related to major cellular pathways, including cell cycle, DNA replication, apoptosis and DNA damage repair. We further elaborated global signaling networks of molecular events with nicotinamide inducible expression changes in protein levels. This approach reveals that nicotinamide treatment rewires signaling networks towards dysfunction of DNA damage repair and away form a pro-growth state in TNBC. To our knowledge, our results of high resolution signaling network interactions provides the first evidence to comprehensively support the hypothesis of nicotinamide as a novel therapeutic agent in TNBC.

Project description:The four main medulloblastoma subgroups are characterized by distinct biology, clinicopathological features and clinical outcomes. While the WNT and SHH subgroups are characterized by clearly defined aberrant signaling of developmental pathways, the underlying biology of Group 3 and 4 remains poorly understood. Here, we delineate distinct post-translational regulation orchestrating active oncogenic signaling networks in Groups 3 and 4. Specifically, aberrant ERBB4-SRC signaling constitutes a novel hallmark feature of Group 4, with great promise as a novel oncogenic mechanism and potential vulnerability for therapeutic intervention in the most common subgroup. Altogether, this novel integrative proteogenomic landscape demonstrates the added value of proteomics and phosphoproteomics analysis to discover and exploit unexpected oncogenic mechanisms in medulloblastoma and beyond.

Project description:ZHX2 Promotes HIF1a Oncogenic Signaling in Triple-Negative Breast Cancer