Project description:Glioblastoma (GBM) is defined by heterogenous and resilient cell populations that closely reflect neurodevelopmental cell types. While it is clear that GBM echoes early and immature cell states, identifying the specific developmental programs disrupted in these tumors has been hindered by a lack of high-resolution trajectories of glial and neuronal lineages. Here, we delineate the course of human astrocyte maturation to uncover discrete developmental stages and attributes mirrored by GBM. We generated a transcriptomic and epigenomic map of human astrocyte maturation using cortical organoids maintained in culture for nearly two years. Through this approach, we chronicled a multi-phase developmental process orchestrated by a series of transcription factor and gene regulatory networks. Our time course of human astrocyte maturation includes a novel and molecularly distinct intermediate period that serves as a lineage commitment checkpoint upstream of mature quiescence. This intermediate stage acts as a site of developmental deviation separating IDH-wildtype neoplastic astrocyte lineage cells from quiescent astrocyte populations. Interestingly, IDH1-mutant tumor astrocyte lineage cells are the exception to this developmental perturbation, where immature properties are suppressed as a result of D2HG oncometabolite exposure. We propose that this defiance is likely a consequence of IDH1mt-associated epigenetic dysregulation and we identified biased DNA hydroxymethylation (5hmC) in maturation genes as a possible mechanism. Together, this study illustrates a novel cellular state aberration in GBM astrocyte lineage cells and presents new developmental targets for experimental and therapeutic exploration.
Project description:Glioblastoma (GBM) is defined by heterogenous and resilient cell populations that closely reflect neurodevelopmental cell types. While it is clear that GBM echoes early and immature cell states, identifying the specific developmental programs disrupted in these tumors has been hindered by a lack of high-resolution trajectories of glial and neuronal lineages. Here, we delineate the course of human astrocyte maturation to uncover discrete developmental stages and attributes mirrored by GBM. We generated a transcriptomic and epigenomic map of human astrocyte maturation using cortical organoids maintained in culture for nearly two years. Through this approach, we chronicled a multi-phase developmental process orchestrated by a series of transcription factor and gene regulatory networks. Our time course of human astrocyte maturation includes a novel and molecularly distinct intermediate period that serves as a lineage commitment checkpoint upstream of mature quiescence. This intermediate stage acts as a site of developmental deviation separating IDH-wildtype neoplastic astrocyte lineage cells from quiescent astrocyte populations. Interestingly, IDH1-mutant tumor astrocyte lineage cells are the exception to this developmental perturbation, where immature properties are suppressed as a result of D2HG oncometabolite exposure. We propose that this defiance is likely a consequence of IDH1mt-associated epigenetic dysregulation and we identified biased DNA hydroxymethylation (5hmC) in maturation genes as a possible mechanism. Together, this study illustrates a novel cellular state aberration in GBM astrocyte lineage cells and presents new developmental targets for experimental and therapeutic exploration.
Project description:Glioblastoma (GBM) is defined by heterogenous and resilient cell populations that closely reflect neurodevelopmental cell types. While it is clear that GBM echoes early and immature cell states, identifying the specific developmental programs disrupted in these tumors has been hindered by a lack of high-resolution trajectories of glial and neuronal lineages. Here, we delineate the course of human astrocyte maturation to uncover discrete developmental stages and attributes mirrored by GBM. We generated a transcriptomic and epigenomic map of human astrocyte maturation using cortical organoids maintained in culture for nearly two years. Through this approach, we chronicled a multi-phase developmental process orchestrated by a series of transcription factor and gene regulatory networks. Our time course of human astrocyte maturation includes a novel and molecularly distinct intermediate period that serves as a lineage commitment checkpoint upstream of mature quiescence. This intermediate stage acts as a site of developmental deviation separating IDH-wildtype neoplastic astrocyte lineage cells from quiescent astrocyte populations. Interestingly, IDH1-mutant tumor astrocyte lineage cells are the exception to this developmental perturbation, where immature properties are suppressed as a result of D2HG oncometabolite exposure. We propose that this defiance is likely a consequence of IDH1mt-associated epigenetic dysregulation and we identified biased DNA hydroxymethylation (5hmC) in maturation genes as a possible mechanism. Together, this study illustrates a novel cellular state aberration in GBM astrocyte lineage cells and presents new developmental targets for experimental and therapeutic exploration.
Project description:Glioblastoma (GBM) is defined by heterogenous and resilient cell populations that closely reflect neurodevelopmental cell types. While it is clear that GBM echoes early and immature cell states, identifying the specific developmental programs disrupted in these tumors has been hindered by a lack of high-resolution trajectories of glial and neuronal lineages. Here, we delineate the course of human astrocyte maturation to uncover discrete developmental stages and attributes mirrored by GBM. We generated a transcriptomic and epigenomic map of human astrocyte maturation using cortical organoids maintained in culture for nearly two years. Through this approach, we chronicled a multi-phase developmental process orchestrated by a series of transcription factor and gene regulatory networks. Our time course of human astrocyte maturation includes a novel and molecularly distinct intermediate period that serves as a lineage commitment checkpoint upstream of mature quiescence. This intermediate stage acts as a site of developmental deviation separating IDH-wildtype neoplastic astrocyte lineage cells from quiescent astrocyte populations. Interestingly, IDH1-mutant tumor astrocyte lineage cells are the exception to this developmental perturbation, where immature properties are suppressed as a result of D2HG oncometabolite exposure. We propose that this defiance is likely a consequence of IDH1mt-associated epigenetic dysregulation and we identified biased DNA hydroxymethylation (5hmC) in maturation genes as a possible mechanism. Together, this study illustrates a novel cellular state aberration in GBM astrocyte lineage cells and presents new developmental targets for experimental and therapeutic exploration.
Project description:Glioblastoma (GBM) is defined by heterogenous and resilient cell populations that closely reflect neurodevelopmental cell types. While it is clear that GBM echoes early and immature cell states, identifying the specific developmental programs disrupted in these tumors has been hindered by a lack of high-resolution trajectories of glial and neuronal lineages. Here, we delineate the course of human astrocyte maturation to uncover discrete developmental stages and attributes mirrored by GBM. We generated a transcriptomic and epigenomic map of human astrocyte maturation using cortical organoids maintained in culture for nearly two years. Through this approach, we chronicled a multi-phase developmental process orchestrated by a series of transcription factor and gene regulatory networks. Our time course of human astrocyte maturation includes a novel and molecularly distinct intermediate period that serves as a lineage commitment checkpoint upstream of mature quiescence. This intermediate stage acts as a site of developmental deviation separating IDH-wildtype neoplastic astrocyte lineage cells from quiescent astrocyte populations. Interestingly, IDH1-mutant tumor astrocyte lineage cells are the exception to this developmental perturbation, where immature properties are suppressed as a result of D2HG oncometabolite exposure. We propose that this defiance is likely a consequence of IDH1mt-associated epigenetic dysregulation and we identified biased DNA hydroxymethylation (5hmC) in maturation genes as a possible mechanism. Together, this study illustrates a novel cellular state aberration in GBM astrocyte lineage cells and presents new developmental targets for experimental and therapeutic exploration.
Project description:With HiRIEF LC-MS/MS shotgun proteomics, we analysed 6 patient-derived glioblastoma stem cells (BT stem cells) and compared them to an astrocyte line (CliniSciences, Guidonia Montecelio, Italy) and a more differentiated glioblastoma cell line (T98G). Each of the 8 cell line sample was run in triplicates in a total of three TMT10 sets, assigning each replicate in a separate TMT10 set, using 2 internal standards per set. The three TMT10 sets were ran in two experiments, first on immobilized pH gradient (IPG) 3-10 isoelectric focusing (IEF) strips, and then on IPG 3.7-4.9 IEF strips.