Project description:Disruption of the MAPK pathway in cancer by kinase inhibition often fails due to pathway reactivation, causing clinical relapse. Among MAPK inhibitors, type I RAF inhibitors are only active against specific BRAF mutants; MEK inhibitor monotherapy is associated with limited clinical benefits but may serve as a foundation for combinatorial therapy. Here, we show that type II RAF plus allosteric MEK inhibitors durably blunt the development of acquired MEK inhibitor resistance among cancers with KRAS, NRAS, NF1, BRAFnon-V600 and BRAFV600 mutations, when compared to a combination of type II RAF plus ERK inhibitors. Type II RAF and MEK (versus ERK) inhibitors also display superior capacity to sequester MEK in RAF complexes and uncouple MEK and ERK interaction in acquired resistant tumor subpopulations. Systemically and intratumorally, type II RAF plus MEK inhibitors expand memory and activated/exhausted CD8+ T-cells. Whereas trametinib alone temporally reduces dominant intra-tumoral T-cell clones, type II RAF inhibitor co-treatment reverses this effect and promotes T-cell clonotypic expansion and convergence. Importantly, durably control of tumors by this combination requires CD8+ T-cells. Thus, the prolonged anti-tumor efficacy of type II RAF plus MEK inhibitors reveals exquisite MAPK addiction in common lethal cancer histologies, and the mechanisms include unexpected allosteric perturbation of the MAPK pathway and engagement of anti-tumor CD8+ T-cell immunity.

Project description:Disruption of the MAPK pathway in cancer by kinase inhibition often fails due to pathway reactivation, causing clinical relapse. Among MAPK inhibitors, type I RAF inhibitors are only active against specific BRAF mutants; MEK inhibitor monotherapy is associated with limited clinical benefits but may serve as a foundation for combinatorial therapy. Here, we show that type II RAF plus allosteric MEK inhibitors durably blunt the development of acquired MEK inhibitor resistance among cancers with KRAS, NRAS, NF1, BRAFnon-V600 and BRAFV600 mutations, when compared to a combination of type II RAF plus ERK inhibitors. Type II RAF and MEK (versus ERK) inhibitors also display superior capacity to sequester MEK in RAF complexes and uncouple MEK and ERK interaction in acquired resistant tumor subpopulations. Systemically and intratumorally, type II RAF plus MEK inhibitors expand memory and activated/exhausted CD8+ T-cells. Whereas trametinib alone temporally reduces dominant intra-tumoral T-cell clones, type II RAF inhibitor co-treatment reverses this effect and promotes T-cell clonotypic expansion and convergence. Importantly, durably control of tumors by this combination requires CD8+ T-cells. Thus, the prolonged anti-tumor efficacy of type II RAF plus MEK inhibitors reveals exquisite MAPK addiction in common lethal cancer histologies, and the mechanisms include unexpected allosteric perturbation of the MAPK pathway and engagement of anti-tumor CD8+ T-cell immunity.

Project description:Disruption of the MAPK pathway in cancer by kinase inhibition often fails due to pathway reactivation, causing clinical relapse. Among MAPK inhibitors, type I RAF inhibitors are only active against specific BRAF mutants; MEK inhibitor monotherapy is associated with limited clinical benefits but may serve as a foundation for combinatorial therapy. Here, we show that type II RAF plus allosteric MEK inhibitors durably blunt the development of acquired MEK inhibitor resistance among cancers with KRAS, NRAS, NF1, BRAFnon-V600 and BRAFV600 mutations, when compared to a combination of type II RAF plus ERK inhibitors. Type II RAF and MEK (versus ERK) inhibitors also display superior capacity to sequester MEK in RAF complexes and uncouple MEK and ERK interaction in acquired resistant tumor subpopulations. Systemically and intratumorally, type II RAF plus MEK inhibitors expand memory and activated/exhausted CD8+ T-cells. Whereas trametinib alone temporally reduces dominant intra-tumoral T-cell clones, type II RAF inhibitor co-treatment reverses this effect and promotes T-cell clonotypic expansion and convergence. Importantly, durably control of tumors by this combination requires CD8+ T-cells. Thus, the prolonged anti-tumor efficacy of type II RAF plus MEK inhibitors reveals exquisite MAPK addiction in common lethal cancer histologies, and the mechanisms include unexpected allosteric perturbation of the MAPK pathway and engagement of anti-tumor CD8+ T-cell immunity.

Project description:Glioblastoma multiforme (GBM) is the most malignant and most common tumor of the central nervous system characterized by rapid growth and extensive tissue infiltration. GBM results in more years of life lost than any other cancer type. Notch signaling has been implicated in GBM pathogenesis through several modes of action. Inhibition of Notch leads to a reduction of cancer-initiating cells in gliomas and reduces proliferation and migration. Deltex1 (DTX1) is part of an alternative Notch signaling pathway distinct from the canonical MAML1/RBPJκ-mediated cascade. In this study, we show that DTX1 activates both the RTK/PI3K/PKB as well as the MAPK/ERK pathway. Moreover, we found the anti-apoptotic factor Mcl-1 to be induced by DTX1. In accordance with this, the clonogenic potential and proliferation rates of glioma cell lines correlated with DTX1 levels. DTX1 knock down mitigated the tumorigenic potential in vivo, and overexpression of DTX1 increased cell migration and invasion of tumor cells accompanied by an elevation of the pro-migratory factors PKBβ and Snail1. Microarray gene expression analysis identified a DTX1-specific transcriptional program - including microRNA-21 - which is distinct from the canonical Notch signaling. We propose the alternative Notch pathway via DTX1 as oncogenic factor in malignant glioma and found low DTX1 expression levels to correlate with prolonged survival of GBM and early breast cancer patients in open source databases. We generated human glioma U373 cell lines stably expressing Enhanced Green Fluorescent Protein (EGFP), human Deltex1-Myc Tag (DTX1-myc), or Master Mind Like 1 - dominant negative (MAML1-dn) to compare differences in overall gene expression. We included 3x EGFP control samples, 3x DTX1-myc, and 3 MAML1-dn samples.

Project description:Glioblastoma multiforme (GBM) is the most malignant and most common tumor of the central nervous system characterized by rapid growth and extensive tissue infiltration. GBM results in more years of life lost than any other cancer type. Notch signaling has been implicated in GBM pathogenesis through several modes of action. Inhibition of Notch leads to a reduction of cancer-initiating cells in gliomas and reduces proliferation and migration. Deltex1 (DTX1) is part of an alternative Notch signaling pathway distinct from the canonical MAML1/RBPJκ-mediated cascade. In this study, we show that DTX1 activates both the RTK/PI3K/PKB as well as the MAPK/ERK pathway. Moreover, we found the anti-apoptotic factor Mcl-1 to be induced by DTX1. In accordance with this, the clonogenic potential and proliferation rates of glioma cell lines correlated with DTX1 levels. DTX1 knock down mitigated the tumorigenic potential in vivo, and overexpression of DTX1 increased cell migration and invasion of tumor cells accompanied by an elevation of the pro-migratory factors PKBβ and Snail1. Microarray gene expression analysis identified a DTX1-specific transcriptional program - including microRNA-21 - which is distinct from the canonical Notch signaling. We propose the alternative Notch pathway via DTX1 as oncogenic factor in malignant glioma and found low DTX1 expression levels to correlate with prolonged survival of GBM and early breast cancer patients in open source databases.

Project description:Background: Signaling by receptor tyrosine kinases (RTK) is frequently dysregulated in gliomas. Inter-individual variability in the causes for dysregulated RTK signaling may have hampered the efficacy of targeted therapies. Using gene expression modules around key regulators in the RAS-RAF-MEK-MAPK cascade and in the phosphatidylinositol 3-kinase-AKT pathways, we developed a “RMPA” clustering scheme to distinguish gliomas with varying extents of RTK signaling. Results: We identified gene modules consistently co-expressed with NF1 (NF1-M), Sprouty (SPRY-M) and PTEN (PTEN-M) in gliomas. Their signatures enabled robust clustering of adult diffuse gliomas of WHO grades II-IV into RMPAhigh and RMPAlow phenotypes in a morphology-independent manner. In five independent data sets from three continents containing more than 1500 adult diffuse gliomas, RMPAhigh gliomas were associated with poor prognosis while RMPAlow gliomas were not. The RMPAhigh and RMPAlow glioma subtypes showed distinct levels of the activities of RAS-RAF-MEK-MAPK cascade and PI3K-AKT pathway and harbored unique sets of genomic alterations in the RTK signaling-related genes. The RMPAhigh gliomas contained large numbers of immature vessel cells and tumor associated macrophages and both cell types expressed high levels of pro-angiogenic RTKs including MET, VEGFR1, KDR, EPHB4 and NRP1. Conclusion: Inter-glioma variability in RTK signaling activities can be defined using the RMPA clustering scheme. The combined signatures of NF1-M, SPRY-M and PTEN-M reflect RTK signaling activity both in the glioma cells and in the glioma microenvironment. Our data show that RTK signaling in the glioma microenvironment may play a pivotal role in glioma progression. Transcriptome data from 22 fresh gliomas (2 astrocytoma II, 1 oligodendrocytoma II, 7 oligoastrocytoma II, 4 anaplastic oligoastrocytoma III and 8 GBM) were obtained using Affymetrix Human Gene 1.0 ST Array. Unsupervised hierarchical clustering of the expression data for the SPRY-M, NF1-M and PTEN-M was performed on these transcriptome data to identify samples with RMPAhigh or RMPAlow signature.

Project description:Carcinogenesis is a multistep process in which cells accumulate multiple genetic alterations, as they progress to a more malignant phenotype. It has been proposed that sequential accumulation of gene abnormalities in specific genes drives the transition from non-tumorous epithelia through preneoplastic lesion/benign tumor to cancer. Histologically, progression to invasive oral squamous cell carcinoma (OSCC) follows multistep ordered series beginning with mucosal epithelial cell hyperplasia, followed by dysplasia, carcinoma in situ and invasive carcinoma. It is therefore speculated that genetic alterations-mediated multistep carcinogenesis would be involved in OSCC development, but their detailed molecular mechanisms are unknown. Herein, we clarified the comprehensive gene expression patterns and carried out an enrichment analysis using DNA microarray data obtained from an OSCC pathological specimen, which consists of non-tumor region, carcinoma in situ lesion and invasive carcinoma lesion. Numerous numbers of gene expression and signal activation were altered in the OSCC development. Of them, the expression of p63 was increased and MEK/ERK-MAPK pathway was activated in carcinoma in situ lesion as well as in invasive carcinoma lesion. Immunohistochemical analyses revealed that p63 was initially upregulated in carcinoma in situ lesions and ERK was sequentially activated in invasive carcinoma lesions in OSCC specimens. ADP-ribosylation factor (ARF)-like 4c (ARL4C), the expression of which is reportedly induced by p63 and/or MEK/ERK-MAPK pathway in OSCC cells, has been shown to promote tumorigenesis. Immunohistochemically, in OSCC specimens, ARL4C was more frequently detected in tumor lesions, especially in invasive carcinoma lesions than in carcinoma in situ lesions. Additionally, ARL4C and phosphorylated ERK were merged at high frequency in invasive carcinoma lesions. Loss-of-function experiments using inhibitors and siRNAs revealed that p63 and EGFR-MEK/ERK-MAPK cooperatively induce ARL4C expression in OSCC cells. These results suggest that the stepwise activation of p63 and EGFR-MEK/ERK-MAPK contributes to OSCC tumor cell growth though regulation of ARL4C expression.

Project description:This is a Phase 1b/2, multi-center, open label umbrella study of patients ≥12 years of age with recurrent, progressive, or refractory melanoma or other solid tumors with alterations in the key proteins of the RAS/RAF/MEK/ERK pathway, referred to as the MAPK pathway.

Project description:Glioblastoma (GBM) is an incurable cancer despite aggressive treatment paradigms. Current immunotherapies, such as CTLA-4 and/or PD-1 blockade, have yet to demonstrate benefits for GBM. A key barrier is the immunologically “cold” nature of GBM defined by insufficient tumor antigen presentation and lack of T cells infiltration. We previously demonstrated that pharmacologic inhibition of Protein Phosphatase-2A (PP2A), using a small molecule inhibitor, synergized with PD1 blockade in multiple preclinical tumor models including GBM. However, PP2A is ubiquitously expressed in many cell types and regulates many cellular pathways. The cell type or molecular mechanism responsible for PP2A-modulated tumor immunity is poorly understood. Here, we demonstrate that genetic ablation of PP2A in glioma cells sufficiently promotes tumor immunogenicity by enhancing 1) dsDNA production and thereby cGAS-Type I interferon (IFN) signaling, 2) MHC-I expression and 3) tumor mutational burden. PP2A deficient glioma enhances DC activation and cross presentation to promote clonal expansion of tumor antigen specific CD8 cells. PP2A deficiency also markedly sensitize tumors to immune checkpoint blockade and radiotherapy. Single cell analysis of murine glioma demonstrates that PP2A deficient tumors have 1) increased infiltration of CD8+ T cell, NK cell and cDC1 cells, 2) reduced infiltration of immunosuppressive tumor associated macrophages, 3) promotion of IFN signaling in both myeloid and tumor cells, and 4) reduced glioma-associated gene signature that predicts poor prognosis in glioma patients. This is the first study to establish a role for PP2A in regulating dsDNA-cGAS-STING signaling and collectively, our results suggest that PP2A is a promising novel target to enhance anti-tumor immunity for glioma.

Project description:Glioblastoma (GBM) is an incurable cancer despite aggressive treatment paradigms. Current immunotherapies, such as CTLA-4 and/or PD-1 blockade, have yet to demonstrate benefits for GBM. A key barrier is the immunologically “cold” nature of GBM defined by insufficient tumor antigen presentation and lack of T cells infiltration. We previously demonstrated that pharmacologic inhibition of Protein Phosphatase-2A (PP2A), using a small molecule inhibitor, synergized with PD1 blockade in multiple preclinical tumor models including GBM. However, PP2A is ubiquitously expressed in many cell types and regulates many cellular pathways. The cell type or molecular mechanism responsible for PP2A-modulated tumor immunity is poorly understood. Here, we demonstrate that genetic ablation of PP2A in glioma cells sufficiently promotes tumor immunogenicity by enhancing 1) dsDNA production and thereby cGAS-Type I interferon (IFN) signaling, 2) MHC-I expression and 3) tumor mutational burden. PP2A deficient glioma enhances DC activation and cross presentation to promote clonal expansion of tumor antigen specific CD8 cells. PP2A deficiency also markedly sensitize tumors to immune checkpoint blockade and radiotherapy. Single cell analysis of murine glioma demonstrates that PP2A deficient tumors have 1) increased infiltration of CD8+ T cell, NK cell and cDC1 cells, 2) reduced infiltration of immunosuppressive tumor associated macrophages, 3) promotion of IFN signaling in both myeloid and tumor cells, and 4) reduced glioma-associated gene signature that predicts poor prognosis in glioma patients. This is the first study to establish a role for PP2A in regulating dsDNA-cGAS-STING signaling and collectively, our results suggest that PP2A is a promising novel target to enhance anti-tumor immunity for glioma.