Project description:Plexin-B2 reduces glioma cell cohesion and regulates glioma-vascular interactions

Project description:During multicellular organization, individual cells need to constantly adjust intracellular contractility and junctional adhesive properties in order to maintain tissue cohesion and mechanotension. The membrane receptors linking external biochemical cues and internal cell mechanics are incompletely understood. Here, we reveal that the axon guidance receptor Plexin-B2 regulates intracellular mechanotension, and this in turn impacts cell-cell/cell-matrix adhesiveness during self-assembly of human embryonic stem cells (hESCs) and neuroprogenitor cells (hNPCs) into epithelial structures. The altered tissue mechanics caused by Plexin-B2 deficiency or over expression affects stem cell behaviors as well as β-catenin and YAP mechanosensing. Strikingly, Plexin-B2 deficiency results in accelerated neuronal differentiation, while proper levels of Plexin-B2 activity are required for maintaining cytoarchitectural integrity of the neuroepithelium as modeled in cerebral organoids. Mechanistically, Plexin-B2 engages its extracellular and Ras-GAP domains for mechanoregulation via RAP1/2. Our studies establish mechanoregulation as a key function of Plexin-B2 during multicellular organization, thereby solidifying the principle of force- mediated regulation of stem cell biology and tissue morphogenesis.

Project description:Tissue repair after spinal cord injury (SCI) requires mobilization of immune and glial cells to form a protective barrier that seals the wound and facilitates debris clearing, inflammatory containment, and matrix compaction. This process involves corralling, wherein phagocytic immune cells become confined to the necrotic core surrounded by an astrocytic border. Here, we elucidate a temporally distinct gene signature in injury-activated microglia/macrophages (IAM), which engages axon guidance pathways. Plexin-B2 is upregulated in IAM, which is required for motosensory recovery after SCI. Plexin-B2 deletion in myeloid cells impairs corralling, leading to diffuse tissue damage, inflammatory spillover, and hampered axon regeneration. Corralling begins early and requires Plexin-B2 in both microglia and macrophages. Mechanistically, Plexin-B2 promotes microglia motility, steers IAM away from colliding cells, and facilitates matrix compaction. Our data thus establish Plexin-B2 as an important link that integrates biochemical cues and physical interactions of IAM with the injury microenvironment during wound healing.

Project description:After central nervous system injury, a rapid neuroinflammatory response is induced. This response can be both beneficial and detrimental to neuronal survival in the first few days and increase the risk for neurodegeneration if it persists. Semaphorin4B (Sema4B), a transmembrane protein primarily expressed by cortical astrocytes, has been shown to play a role in neuronal cell death following injury. Our study shows that neuroinflammation is attenuated in Sema4B knockout mice and microglia/macrophage activation is reduced after cortical stab wound injury. In vitro, recombinant Sema4B enhances the activation of microglia following injury, suggesting astrocytic Sema4B functions as a ligand. Moreover, injury-induced activation of microglia is attenuated in the presence of Sema4B knockout astrocytes compared to heterozygous astrocytes. In vitro, experiments indicate Plexin-B2 is the Sema4B receptor on microglia. Consistent with this, microglia-specific Plexin-B2 knockout mice, similar to Sema4B knockout mice, also show a reduction in microglial activation after cortical injury. Finally, in Sema4B/Plexin-B2 double heterozygous mice, microglial activation is also reduced after injury, thus supporting the idea that both Sema4B and Plexin-B2 are part of the same signaling pathway. Taken together, we propose a model in which following injury, astrocytic Sema4B enhances the pro-inflammatory response of microglia/macrophages via Plexin-B2, leading to increased neuroinflammation.

Project description:To identify Plexin-B2-associated proteins, articular chondrocytes were untreated or treated with Sema4D. Plexin-B2-bound proteins were purified by immunoprecipitation using an anti-Plexin-B2 antibody, followed by mass spectrometry.

Project description:In this study, we explored the transcriptomic consequences of strong activation of the Notch pathway in embryonic human neural stem cells and in gliomas. For this we used a forced expression of the Notch intracellular domain (NICD). Glioblastoma multiforms (GBMs) are highly vascularized brain tumors containing a subpopulation of multipotent cancer stem cells. These cells closely interact with endothelial cells in neurovascular niches. In this study we have uncovered a close link between the Notch1 pathway and the tumoral vascularization process of GBM stem cells. We observed that although the Notch1 receptor was activated, the typical target proteins (HES5, HEY1, HEY2) were not or barely expressed in two explored GBM stem cell cultures. Notch1 signalling activation by expression of the intracellular form (NICD) in these cells was found to reduce their growth rate and migration which was accompanied by the sharp reduction of neural stem cell transcription factor expression (ASCL1, OLIG2, SOX2) while HEY1/2, KLF9, SNAI2 transcription factors were upregulated. Expression of OLIG2 and growth were restored after termination of Notch1 stimulation. Remarkably, NICD expression induced the expression of pericyte cell markers (NG2, PDGFRb and a-smooth muscle actin (aSMA)) in GBM stem cells. This was paralleled with the induction of several angiogenesis-related factors most notably cytokines (HB-EGF, IL8, PLGF), metalloprotease (MMP9) and adhesion proteins (VCAM-1, ICAM-1, ITGA9). In xenotransplantation experiments, contrasting with the infiltrative and poorly-vascularized tumors obtained with control GBM stem cells, Notch1 stimulation resulted in poorly-disseminating but highly-vascularized grafts containing large vessels with lumen. Notch1-stimulated GBM cells expressed pericyte cell markers and closely associated with endothelial cells. These results reveal an important role for the Notch1 pathway in regulating GBM stem cell plasticity and angiogenic properties. Embryonic human neural progenitors obtained from Lonza, the U87 glioma cell line, and glioma cancer stem cells (Gb4 and Gb7) characterized in Guichet et al. (Glia, 2013, 61(2), 225-39) were infected with lentiviruses expressing YFP or YFP-IRES-NICD (activated form of Notch receptor). After 48h, RNA were extracted for Affymetrix microarray analysis.

Project description:Malignant gliomas represent the most devastating group of brain tumors in adults, among which glioblastoma multiforme (GBM) exhibits the highest malignancy rate. Despite combined modality treatment, GBM recurs and is invariably fatal. A further insight into molecular background of gliomagenesis is required to improve patient outcome. The first aim of this study was to gain broad information on miRNA expression pattern in malignant gliomas, mainly GBM. We investigated the global miRNA profile of malignant glioma tissues by means of miRNA microarrays, deep sequencing and meta-analysis. We selected miRNAs the most frequently deregulated in glioblastoma tissues as well as peritumoral brain areas in comparison to normal human brain. We found candidate miRNAs contributing to progression from gliomas grade III to gliomas grade IV. The meta-analysis of miRNA profiling studies in GBM tissues summarizes the past and recent advances in an investigation of miRNA signature in GBM versus noncancerous human brain and provides a comprehensive overview. We proposed a set of 35 miRNAs which expression is the most frequently deregulated in GBM patients and 30 miRNA candidates recognized as novel GBM biomarkers. miRNA expression profile in the adult malignant gliomas, glioma peritumoral tissues and normal human brain.

Project description:In this study, we explored the transcriptomic consequences of strong activation of the Notch pathway in embryonic human neural stem cells and in gliomas. For this we used a forced expression of the Notch intracellular domain (NICD). Glioblastoma multiforms (GBMs) are highly vascularized brain tumors containing a subpopulation of multipotent cancer stem cells. These cells closely interact with endothelial cells in neurovascular niches. In this study we have uncovered a close link between the Notch1 pathway and the tumoral vascularization process of GBM stem cells. We observed that although the Notch1 receptor was activated, the typical target proteins (HES5, HEY1, HEY2) were not or barely expressed in two explored GBM stem cell cultures. Notch1 signalling activation by expression of the intracellular form (NICD) in these cells was found to reduce their growth rate and migration which was accompanied by the sharp reduction of neural stem cell transcription factor expression (ASCL1, OLIG2, SOX2) while HEY1/2, KLF9, SNAI2 transcription factors were upregulated. Expression of OLIG2 and growth were restored after termination of Notch1 stimulation. Remarkably, NICD expression induced the expression of pericyte cell markers (NG2, PDGFRb and a-smooth muscle actin (aSMA)) in GBM stem cells. This was paralleled with the induction of several angiogenesis-related factors most notably cytokines (HB-EGF, IL8, PLGF), metalloprotease (MMP9) and adhesion proteins (VCAM-1, ICAM-1, ITGA9). In xenotransplantation experiments, contrasting with the infiltrative and poorly-vascularized tumors obtained with control GBM stem cells, Notch1 stimulation resulted in poorly-disseminating but highly-vascularized grafts containing large vessels with lumen. Notch1-stimulated GBM cells expressed pericyte cell markers and closely associated with endothelial cells. These results reveal an important role for the Notch1 pathway in regulating GBM stem cell plasticity and angiogenic properties.

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:<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>