Project description:Glioblastoma (GBM) cells’ stemness-like features and lineage plasticity promote tumor progression. Here, we demonstrate that Clemastine, a drug for treating hay fever and allergy symptoms, effectively attenuated the stemness and suppressed the propagation of primary GBM cultures bearing PDGFRA amplification. We show that these effects of GBM cells were accompanied by altered gene expression profiling indicative of a more differentiated state of tumor cells, in resonating with Clemastine’s activity in promoting the differentiation of normal oligodendrocyte progenitors (OPCs) into mature oligodendrocyte. Functional assays for proteins that can be pharmacologically targeted by Clemastine, including histamine receptors, muscarinic receptors, and Emopamil binding protein (EBP), revealed the essential roles of these proteins in sustaining GBM cell propagation and suggested that Clemastine likely impairs tumor cells via targeting multiple pathways. Finally, we showed that a PDGFB-driven mouse glioma model, representing the proneural subtype GBMs, was similarly susceptible to Clemastine treatment. Collectively, these results identify pathways that are essential for maintaining the proneural progenitor features of GBMs, and suggest that non-oncology, low toxicity drugs with OPC differentiation promoting effects, such as Clemastine, can be exploited for targeting GBM cell’s progenitor property.

Project description:Glioblastoma multiforme (GBM), the most common and aggressive primary brain tumor in adults, can be divided into several molecular subtypes including proneural GBM. Most clinical strategies aimed at directly targeting glioma cells in these tumors have failed. A promising alternative is to target stromal cells in the brain microenvironment, such as tumor-associated microglia and macrophages (TAMs). Macrophages are dependent upon colony stimulating factor (CSF)-1 for differentiation and survival; therefore, we used an inhibitor of its receptor, CSF-1R, to target macrophages in a mouse proneural GBM model. CSF-1R inhibition dramatically increased survival in mice and regressed established GBMs. Tumor cell apoptosis was significantly increased, and proliferation and tumor grade markedly decreased. Surprisingly, TAMs were not depleted in tumors treated with the CSF-1R inhibitor. Instead, analysis of gene expression in TAMs isolated from treated tumors revealed a decrease in alternatively activated/ M2 macrophage markers, consistent with impaired tumor-promoting functions. These gene signatures were also associated with better survival specifically in the proneural subtype of patient gliomas. Collectively, these results establish macrophages as valid therapeutic targets in proneural gliomas, and highlight the clinical potential for CSF-1R inhibitors in GBM. RNA was isolated from sorted tumor associated macrophages (TAMs) from murine gliomas following either 7 days of vehicle or BLZ945 treatment. Samples were collected from 16 total tumor burdened mice, with 8 replicates for each treatment group. BLZ945: a Colony-Stimulating Factor 1 Receptor (CSF-1R) inhibitor

Project description:Glioblastoma multiforme (GBM), the most common and aggressive primary brain tumor in adults, can be divided into several molecular subtypes including proneural GBM. Most clinical strategies aimed at directly targeting glioma cells in these tumors have failed. A promising alternative is to target stromal cells in the brain microenvironment, such as tumor-associated microglia and macrophages (TAMs). Macrophages are dependent upon colony stimulating factor (CSF)-1 for differentiation and survival; therefore, we used an inhibitor of its receptor, CSF-1R, to target macrophages in a mouse proneural GBM model. CSF-1R inhibition dramatically increased survival in mice and regressed established GBMs. Tumor cell apoptosis was significantly increased, and proliferation and tumor grade markedly decreased. Surprisingly, TAMs were not depleted in tumors treated with the CSF-1R inhibitor. Instead, analysis of gene expression in TAMs isolated from treated tumors revealed a decrease in alternatively activated/ M2 macrophage markers, consistent with impaired tumor-promoting functions. These gene signatures were also associated with better survival specifically in the proneural subtype of patient gliomas. Collectively, these results establish macrophages as valid therapeutic targets in proneural gliomas, and highlight the clinical potential for CSF-1R inhibitors in GBM.

Project description:Glioblastoma (GBM) is a lethal brain cancer exhibiting high levels of drug resistance, a feature partially imparted by tumor cell stemness. Recent work shows that homozygous MTAP deletion, a genetic alteration occurring in about half of all GBMs, promotes stemness in GBM cells. Exploiting MTAP loss-conferred deficiency in purine salvage, we demonstrate that purine synthesis blockade via treatment with L-Alanosine (ALA), an inhibitor of de novo purine synthesis, attenuates stemness and mitochondrial function of MTAP-deficient GBM cells. Here, we use RNA-Seq with ALA-treated patient-derived GBM cells to investigate the transcriptomic impact of long-term ALA treatment.

Project description:<p>Dysregulated metabolism in glioblastoma (GBM), the deadliest brain tumor of adults, offers an opportunity to deploy metabolic interventions as precise therapeutic strategies. To identify the molecular drivers and the modalities by which different molecular subgroups of GBM exploit metabolic rewiring to sustain tumor progression, we interrogated the transcriptome, the metabolome and the glycoproteome of human subgroup-specific GBM stem cells (GSCs).</p><p>Here we report that L-Fucose abundance and core fucosylation activation are more highly enhanced in mesenchymal (MES) than in proneural (PN) GSCs; this pattern is retained in subgroup-specific xenografts and, most significantly, retrieved in subgroup-affiliated human patients’ samples. Genetic and pharmacological inhibition of core fucosylation in MES GBM preclinical models results in significant reduction in tumor burden. LC/MS-based glycoproteomic screening indicates that most MES-restricted core fucosylated proteins are involved in therapeutically relevant GBM pathological processes, such as extracellular matrix interaction, cell adhesion and integrin-mediated signaling. Notably, selective L-Fucose accumulation in MES GBMs is demonstrated by pre-clinical minimally-invasive positron emission tomography (PET), implying this metabolite as a potential subgroup-restricted biomarker.</p><p>Overall, these findings indicate that L-Fucose pathway activation in MES GBM offers subgroup-specific, GSC-restricted dependencies to be exploited as diagnostic markers and actionable therapeutic targets.</p><p><br></p><p><strong>Stem cell and cell line assays</strong> are reported in the current study <strong>MTBLS4708</strong></p><p><strong>Xenograft assays</strong> are reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS730' rel='noopener noreferrer' target='_blank'><strong>MTBLS730</strong></a></p>

Project description:<p>Dysregulated metabolism in glioblastoma (GBM), the deadliest brain tumor of adults, offers an opportunity to deploy metabolic interventions as precise therapeutic strategies. To identify the molecular drivers and the modalities by which different molecular subgroups of GBM exploit metabolic rewiring to sustain tumor progression, we interrogated the transcriptome, the metabolome and the glycoproteome of human subgroup-specific GBM stem cells (GSCs).</p><p>Here we report that L-Fucose abundance and core fucosylation activation are more highly enhanced in mesenchymal (MES) than in proneural (PN) GSCs; this pattern is retained in subgroup-specific xenografts and, most significantly, retrieved in subgroup-affiliated human patients’ samples. Genetic and pharmacological inhibition of core fucosylation in MES GBM preclinical models results in significant reduction in tumor burden. LC/MS-based glycoproteomic screening indicates that most MES-restricted core fucosylated proteins are involved in therapeutically relevant GBM pathological processes, such as extracellular matrix interaction, cell adhesion and integrin-mediated signaling. Notably, selective L-Fucose accumulation in MES GBMs is demonstrated by pre-clinical minimally-invasive positron emission tomography (PET), implying this metabolite as a potential subgroup-restricted biomarker.</p><p>Overall, these findings indicate that L-Fucose pathway activation in MES GBM offers subgroup-specific, GSC-restricted dependencies to be exploited as diagnostic markers and actionable therapeutic targets.</p><p><br></p><p><strong>Xenograft assays</strong> are reported in the current study <strong>MTBLS730</strong></p><p><strong>Stem cell and cell line assays</strong> are reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS4708' rel='noopener noreferrer' target='_blank'><strong>MTBLS4708</strong></a></p>

Project description:Characterization of the tumor border microenvironment is critical for improving prognosis in patients with GBM. Here, we compared microRNA (miRNA) expression in samples from the tumor, tumor border, and peripheral region far from tumor mass by miRNA microarray. The top three of miRNAs showing higher expression in the tumor border were related to oligodendrocyte differentiation, and pathologically oligodendrocyte lineage cells were increased in the border, where numbers of macrophages and microglia also colocalized. Medium cultured with oligodendrocyte progenitor cells (OPCs) and macrophages induced stemness and chemo-radioresistance in GBM cells. Thus, OPCs and macrophages/microglia may form a glioma stem cell niche at the tumor border, representing a novel promising target for prevention of recurrence.

Project description:Development of model systems that recapitulate the molecular heterogeneity observed amongst GBM tumors will expedite the testing of targeted molecular therapeutic strategies for GBM treatment. In this study, we profiled DNA copy number and mRNA expression in 21 independent GBM tumor lines maintained as subcutaneous xenografts (GBMX), and compared GBMX molecular signatures to those observed in GBM clinical specimens derived from The Cancer Genome Atlas (TCGA). The predominant copy number signature in both tumor groups was defined by chromosome-7-gain/chromosome-10-loss, a poor prognosis genetic signature. We also observed, at frequencies similar to that detected in TCGA GBMs genomic amplification and overexpression of known GBM oncogenes such as EGFR, MDM2, CDK6 and MYCN, and novel genes including NUP107, SLC35E3, MMP1, MMP13 and DDX1. The transcriptional signature of GBMX tumors, which was stable over multiple subcutaneous passages, was defined by overexpression of genes involved in M-phase, DNA Replication, and Chromosome organization (MRC) and was highly similar to the poor-prognosis mitosis-and-cell-cycle-module (MCM) in GBM. Assessment of gene expression in TCGA-derived GBMs revealed overexpression of MRC cancer genes AURKB, BIRC5, CCNB1, CCNB2, CDC2, CDK2, and FOXM1, which form a transcriptional network important for G2/M- progression and/or -checkpoint activation. In conclusion, our study supports propagation of GBM tumors as subcutaneous xenografts as a useful approach for sustaining key molecular characteristics of patient tumors, and highlights therapeutic opportunities conferred by this GBMX tumor panel for testing targeted therapeutic strategies for GBM treatment. Keywords: Disease state analysis RNA expression was assessed in 38 samples: 34 GBM xenograft tumors (29 independent tumors with hybridization replicates for 5 tumors) and 4 non-neoplastic control brain samples

Project description:Therapeutic resistance after multimodal therapy is the most relevant cause of glioblastoma (GBM) recurrence. Extensive cellular heterogeneity, mainly driven by the presence of GBM stem-like cells (GSC), strongly correlates with patients’ prognosis and limited response to therapies. Defining the mechanisms which drive stemness and control responsiveness to therapy in a GSC-specific manner is therefore mandatory. Here we investigated the role of integrin a6 (ITGA6) in controlling stemness and resistance to radiotherapy in proneural and mesenchymal GSCs subtypes. Using cell sorting, gene silencing, RNA-Seq and in vitro assays, we verified that ITGA6 expression seems crucial for proliferation and stemness of proneural GSCs, while it appears not to be relevant in mesenchymal GSCs under basal conditions. However, when challenged with a fractionated protocol of radiation therapy, comparable to that employed in the clinical setting, mesenchymal GSCs turned out to be dependent on integrin a6 for survival. Specifically, GSCs with reduced levels of ITGA6 displayed a clear reduction of DNA-damage response and perturbation of cell cycle pathways. These data indicate that ITGA6 inhibition is able to overcome the radioresistance of mesenchymal GSCs, while it reduces proliferation and stemness in proneural GSCs. Therefore, integrin a6 controls crucial characteristics across GBM subtypes in GBM heterogeneous biology and thus may represent a promising target to improve patient outcomes

Project description:Medulloblastomas (MBs) and Glioblastomas (GBMs) are high-incidence central nervous system tumors. Different origin sites and changes in the tissue microenvironment have been associated with onset and progression. Here, we describe differences between the ECM signature of these tumors. We compared the proteomic profiles of MB and GBM decellularized tumor samples among each other and their normal decellularized brain site counterparts. Our analysis reveals that 19 proteins were differentially expressed in MBs, 28 proteins in GBMs, and 11 proteins in both MBs and GBMs. Next, we validated key findings by protein tissue array with 53 MB and 55 GBM cases and evaluated the clinical relevance of the identified differentially expressed proteins through their analysis on publicly available datasets, 763 MB samples from microarray-GSE50161, and 115 GBM samples from RNAseq-TCGA. We report a shift towards a denser fibrillary ECM as well as a clear alteration in the glycoprotein signature, which influences the tumor pathophysiology.