Project description:Chromosomal rearrangements and gene fusions are the initial events in the development of many cancers. Astroblastoma (ABM), a challenging brain cancer of unknown cellular origin, is associated with diverse in-frame gene fusions, including MN1:BEND2 and MN1:CXXC5. However, it remains unclear if these gene fusions contribute to tumorigenesis. Here, we show that the two ABM-associated fusions converge on similar molecular activities and initiate malignancy specifically in ventral telencephalon neural progenitors. BEND2 and CXXC5 recognized similar DNA motifs, suggesting a convergence on downstream gene regulation. Expressing MN1:BEND2 in ventral telencephalon neural progenitors results in aberrant cell proliferation, impaired differentiation, a perivascular occupancy pattern of cells reminiscent of ABM, and acquisition of an ABM-associated transcriptional signature. In stark contrast, MN1:BEND2 expression in dorsal telencephalon neural progenitors leads to extensive cell death. This cell-type specific malignancy is dependent on Olig2 expression. Mechanistically, both ABM-associated fusion proteins (MN1:BEND2 and MN1:CXXC5) induce overlapping transcriptional responses, including the activation of a therapeutically targetable PDGFRα pathway. Collectively, our data suggests that distinct ABM-associated fusions upregulate shared transcriptional networks, thereby disrupting the normal development of ventral telencephalon neural progenitors and culminating in oncogenic transformation. These findings uncover new avenues for targeted ABM treatment.

Project description:Chromosomal rearrangements and gene fusions are the initial events in the development of many cancers. Astroblastoma (ABM), a challenging brain cancer of unknown cellular origin, is associated with diverse in-frame gene fusions, including MN1:BEND2 and MN1:CXXC5. However, it remains unclear if these gene fusions contribute to tumorigenesis. Here, we show that the two ABM-associated fusions converge on similar molecular activities and initiate malignancy specifically in ventral telencephalon neural progenitors. BEND2 and CXXC5 recognized similar DNA motifs, suggesting a convergence on downstream gene regulation. Expressing MN1:BEND2 in ventral telencephalon neural progenitors results in aberrant cell proliferation, impaired differentiation, a perivascular occupancy pattern of cells reminiscent of ABM, and acquisition of an ABM-associated transcriptional signature. In stark contrast, MN1:BEND2 expression in dorsal telencephalon neural progenitors leads to extensive cell death. This cell-type specific malignancy is dependent on Olig2 expression. Mechanistically, both ABM-associated fusion proteins (MN1:BEND2 and MN1:CXXC5) induce overlapping transcriptional responses, including the activation of a therapeutically targetable PDGFRα pathway. Collectively, our data suggests that distinct ABM-associated fusions upregulate shared transcriptional networks, thereby disrupting the normal development of ventral telencephalon neural progenitors and culminating in oncogenic transformation. These findings uncover new avenues for targeted ABM treatment.

Project description:Chromosomal rearrangements and gene fusions are the initial events in the development of many cancers. Astroblastoma (ABM), a challenging brain cancer of unknown cellular origin, is associated with diverse in-frame gene fusions, including MN1:BEND2 and MN1:CXXC5. However, it remains unclear if these gene fusions contribute to tumorigenesis. Here, we show that the two ABM-associated fusions converge on similar molecular activities and initiate malignancy specifically in ventral telencephalon neural progenitors. BEND2 and CXXC5 recognized similar DNA motifs, suggesting a convergence on downstream gene regulation. Expressing MN1:BEND2 in ventral telencephalon neural progenitors results in aberrant cell proliferation, impaired differentiation, a perivascular occupancy pattern of cells reminiscent of ABM, and acquisition of an ABM-associated transcriptional signature. In stark contrast, MN1:BEND2 expression in dorsal telencephalon neural progenitors leads to extensive cell death. This cell-type specific malignancy is dependent on Olig2 expression. Mechanistically, both ABM-associated fusion proteins (MN1:BEND2 and MN1:CXXC5) induce overlapping transcriptional responses, including the activation of a therapeutically targetable PDGFRα pathway. Collectively, our data suggests that distinct ABM-associated fusions upregulate shared transcriptional networks, thereby disrupting the normal development of ventral telencephalon neural progenitors and culminating in oncogenic transformation. These findings uncover new avenues for targeted ABM treatment.

Project description:Chromosomal rearrangements and gene fusions are the initial events in the development of many cancers. Astroblastoma (ABM), a challenging brain cancer of unknown cellular origin, is associated with diverse in-frame gene fusions, including MN1:BEND2 and MN1:CXXC5. However, it remains unclear if these gene fusions contribute to tumorigenesis. Here, we show that the two ABM-associated fusions converge on similar molecular activities and initiate malignancy specifically in ventral telencephalon neural progenitors. BEND2 and CXXC5 recognized similar DNA motifs, suggesting a convergence on downstream gene regulation. Expressing MN1:BEND2 in ventral telencephalon neural progenitors results in aberrant cell proliferation, impaired differentiation, a perivascular occupancy pattern of cells reminiscent of ABM, and acquisition of an ABM-associated transcriptional signature. In stark contrast, MN1:BEND2 expression in dorsal telencephalon neural progenitors leads to extensive cell death. This cell-type specific malignancy is dependent on Olig2 expression. Mechanistically, both ABM-associated fusion proteins (MN1:BEND2 and MN1:CXXC5) induce overlapping transcriptional responses, including the activation of a therapeutically targetable PDGFRα pathway. Collectively, our data suggests that distinct ABM-associated fusions upregulate shared transcriptional networks, thereby disrupting the normal development of ventral telencephalon neural progenitors and culminating in oncogenic transformation. These findings uncover new avenues for targeted ABM treatment.

Project description:Chromosomal rearrangements and gene fusions are the initial events in the development of many cancers. Astroblastoma (ABM), a challenging brain cancer of unknown cellular origin, is associated with diverse in-frame gene fusions, including MN1:BEND2 and MN1:CXXC5. However, it remains unclear if these gene fusions contribute to tumorigenesis. Here, we show that the two ABM-associated fusions converge on similar molecular activities and initiate malignancy specifically in ventral telencephalon neural progenitors. BEND2 and CXXC5 recognized similar DNA motifs, suggesting a convergence on downstream gene regulation. Expressing MN1:BEND2 in ventral telencephalon neural progenitors results in aberrant cell proliferation, impaired differentiation, a perivascular occupancy pattern of cells reminiscent of ABM, and acquisition of an ABM-associated transcriptional signature. In stark contrast, MN1:BEND2 expression in dorsal telencephalon neural progenitors leads to extensive cell death. This cell-type specific malignancy is dependent on Olig2 expression. Mechanistically, both ABM-associated fusion proteins (MN1:BEND2 and MN1:CXXC5) induce overlapping transcriptional responses, including the activation of a therapeutically targetable PDGFRα pathway. Collectively, our data suggests that distinct ABM-associated fusions upregulate shared transcriptional networks, thereby disrupting the normal development of ventral telencephalon neural progenitors and culminating in oncogenic transformation. These findings uncover new avenues for targeted ABM treatment.

Project description:Chromosomal rearrangements and gene fusions are the initial events in the development of many cancers. Astroblastoma (ABM), a challenging brain cancer of unknown cellular origin, is associated with diverse in-frame gene fusions, including MN1:BEND2 and MN1:CXXC5. However, it remains unclear if these gene fusions contribute to tumorigenesis. Here, we show that the two ABM-associated fusions converge on similar molecular activities and initiate malignancy specifically in ventral telencephalon neural progenitors. BEND2 and CXXC5 recognized similar DNA motifs, suggesting a convergence on downstream gene regulation. Expressing MN1:BEND2 in ventral telencephalon neural progenitors results in aberrant cell proliferation, impaired differentiation, a perivascular occupancy pattern of cells reminiscent of ABM, and acquisition of an ABM-associated transcriptional signature. In stark contrast, MN1:BEND2 expression in dorsal telencephalon neural progenitors leads to extensive cell death. This cell-type specific malignancy is dependent on Olig2 expression. Mechanistically, both ABM-associated fusion proteins (MN1:BEND2 and MN1:CXXC5) induce overlapping transcriptional responses, including the activation of a therapeutically targetable PDGFRα pathway. Collectively, our data suggests that distinct ABM-associated fusions upregulate shared transcriptional networks, thereby disrupting the normal development of ventral telencephalon neural progenitors and culminating in oncogenic transformation. These findings uncover new avenues for targeted ABM treatment.

Project description:Astroblastoma (AB) is an unusual brain tumor of unknown origin. We performed an integrated clinicogenomic analysis of 36 AB-like tumors. Lesions with MN1-BEND2 fusions demonstrated decreased promoter methylation and increased expression of IGF2-H19 and DLK1-DIO3 imprinted region genes. They also relatively overexpressed genes highly expressed during fetal brain development prior to 25 post-conception weeks (pcw), including genes enriched in ventricular zone radial glia (vRG), and generally presented in young children. Other tumors highly expressed MAP kinase pathway, PI3K pathway and X-inactivation escape genes. These and a third group of tumors tended to occur in young adults and showed enriched expression of outer radial glia (oRG) and truncated radial glia (tRG) genes, and genes highly expressed after 25 pcw. Many of the latter are involved in axonal migration or synaptic plasticity and are implicated in autism, schizophrenia and other cognitive disorders. Findings suggest that AB-like tumors arise in the context of epigenetic and genetic changes in neural progenitors during fetal and later brain development: early ependymal tumors with MN1-BEND2 fusions (EET-MN1) from vRG-derived progenitor cells, and MAPK/PI3K and classic astroblastomas from oRG- and tRG-derived progenitors, respectively. Lastly, we found that like EET-MN1, immature ependymal cells express IGF2 and may represent an important source of this growth factor in the fetal lateral ventricular zone neural stem cell niche.

Project description:Astroblastoma (AB) is an unusual brain tumor of unknown origin. We performed an integrated clinicogenomic analysis of 36 AB-like tumors. Lesions with MN1-BEND2 fusions demonstrated decreased promoter methylation and increased expression of IGF2-H19 and DLK1-DIO3 imprinted region genes. They also relatively overexpressed genes highly expressed during fetal brain development prior to 25 post-conception weeks (pcw), including genes enriched in ventricular zone radial glia (vRG), and generally presented in young children. Other tumors highly expressed MAP kinase pathway, PI3K pathway and X-inactivation escape genes. These and a third group of tumors tended to occur in young adults and showed enriched expression of outer radial glia (oRG) and truncated radial glia (tRG) genes, and genes highly expressed after 25 pcw. Many of the latter are involved in axonal migration or synaptic plasticity and are implicated in autism, schizophrenia and other cognitive disorders. Findings suggest that AB-like tumors arise in the context of epigenetic and genetic changes in neural progenitors during fetal and later brain development: early ependymal tumors with MN1-BEND2 fusions (EET-MN1) from vRG-derived progenitor cells, and MAPK/PI3K and classic astroblastomas from oRG- and tRG-derived progenitors, respectively. Lastly, we found that like EET-MN1, immature ependymal cells express IGF2 and may represent an important source of this growth factor in the fetal lateral ventricular zone neural stem cell niche.

Project description:Astroblastoma (AB) is an unusual brain tumor of unknown origin. We performed an integrated clinicogenomic analysis of 36 AB-like tumors. Lesions with MN1-BEND2 fusions demonstrated decreased promoter methylation and increased expression of IGF2-H19 and DLK1-DIO3 imprinted region genes. They also relatively overexpressed genes highly expressed during fetal brain development prior to 25 post-conception weeks (pcw), including genes enriched in ventricular zone radial glia (vRG), and generally presented in young children. Other tumors highly expressed MAP kinase pathway, PI3K pathway and X-inactivation escape genes. These and a third group of tumors tended to occur in young adults and showed enriched expression of outer radial glia (oRG) and truncated radial glia (tRG) genes, and genes highly expressed after 25 pcw. Many of the latter are involved in axonal migration or synaptic plasticity and are implicated in autism, schizophrenia and other cognitive disorders. Findings suggest that AB-like tumors arise in the context of epigenetic and genetic changes in neural progenitors during fetal and later brain development: early ependymal tumors with MN1-BEND2 fusions (EET-MN1) from vRG-derived progenitor cells, and MAPK/PI3K and classic astroblastomas from oRG- and tRG-derived progenitors, respectively. Lastly, we found that like EET-MN1, immature ependymal cells express IGF2 and may represent an important source of this growth factor in the fetal lateral ventricular zone neural stem cell niche.

Project description:Aims and methods: astroblastoma is a rare glial brain tumor with singular morphology. Recurrent MN1-BEND2 fusions have been recently identified in most of pediatric cases. Adolescent and adult cases, however, remain molecularly poorly defined. Here, we performed clinical and molecular characterization of a retrospective cohort of 14 adult and one adolescent gliomas with astroblastic features. Results: strikingly, we found MN1 fusions a rare event in this age group (1/15). Using methylation profiling and targeted sequencing, most cases were reclassified as either pleomorphic xanthoastrocytomas (PXA) or high-grade glioma (HGG). PXA-like ABM show BRAF mutation (6/7 with V600E mutation and 1/7 with G466E mutation) and CD34 expression. Conversely, HGG-like ABM harbored specific mutations of diffuse midline glioma (2/5) or glioblastoma (3/5). These latter patients showed an unfavorable clinical course with significantly shorter overall survival (p = 0.027). MAPK pathway alterations (including FGFR fusion, BRAF and NF1 mutations) were present in 10 of 15 patients and overrepresented in the HGG group (3/5) compared to previously reported prevalence of these alterations in GBM and diffuse midline glioma. Conclusion: We suggest that astroblastoma comprises a variety of molecularly sharply defined entities. Adults’ astroblastomas harboring molecular features of PXA and HGG should be reclassified. CNS high-grade neuroepithelial tumors with MN1 alterations appears to be a truly pediatric entity and is uncommon in adult cases with a histology of astroblastoma. Astroblastic morphology in adults should thus prompt thorough molecular investigation aiming at a clear histomolecular diagnosis and identifying actionable drug targets, especially in MAPK pathway.