Project description:Efficient derivation of neural stem cells (NSCs) from human pluripotent stem cells (PSCs) is crucial for developmental biology and regenerative medicine. Here, we established a chemically defined system using CHIR99021 and TTNPB to generate advanced NSCs (ANSCs). Integrated chromatin accessibility, transcriptomic, and metabolomic analyses revealed molecular mechanisms underlying neural fate commitment. TTNPB synergistically enhanced CHIR99021-mediated neural induction by globally increasing chromatin accessibility and activating neural-specific transcription factors. Compared to NSCs and PSCs, ANSCs exhibited robust upregulation of neural markers and enhanced chromatin remodeling. Metabolomic profiling identified significant metabolic reprogramming during the PSC-to-ANSC transition, with specific enrichment of S-adenosylhomocysteine (SAH), ADP, and glutathione in ANSCs correlating with elevated neural gene expression. Functionally, choline supplementation—regulated via the PEMT pathway—enhanced NESTIN expression and promoted neuroectodermal fate commitment. Our findings establish CHIR99021/TTNPB as a potent synergistic pair for efficient NSC induction and identify choline metabolism as a critical axis governing neuroectodermal lineage specification.

Project description:Neural stem cells (NSCs) in the subventricular zone (SVZ) and the subgranular zone of the hippocampus continuously give rise to glial cells and neurons and are the most important source for new neurons in the adult mammalian brain1-4. It has been suggested that the NSCs in the adult brain form a heterogeneous population5,7, akin to other tissue-specific adult stem cells6. However, a molecular basis of the presumed NSC heterogeneity has been lacking. Here, we sequenced the transcriptomes of 131 individual adult NSCs from the mouse SVZ. After filtering, 117 cells were used for further analysis. We found that they consist of two distinct subgroups of about equal size, independent of the mouse’s age. These subgroups were separated by molecular markers of quiescence (quiescent NSCs, qNSCs) and cell-cycle progression (active NSCs, aNSCs). We identified novel cell surface markers belonging to the tetraspanin family of transmembrane proteins for the prospective purification of qNSCs and aNSCs. The individual NSC transcriptomes were ordered along a continuous progression from qNSCs to aNSCs, with the expression of molecular pathways decreasing (G-protein-coupled receptor signaling) or increasing (MAP kinase, PI3 kinase-mTOR, Hippo, and p53 pathways) in a coordinated manner. Within the aNSCs, transcription factors for neural cell lineage specification were expressed in patterns that indicate specific lineage commitment of individual aNSC. Together, these findings imply that the switch from qNSC to aNSC is irreversible in vivo, at least in a large fraction of cells, and is accompanied by lineage commitment already at the stem-cell stage. Thus our work reveals coherent patterns of molecular heterogeneity within adult NSCs that arise from the regulation of cell-cycle activity and differentiation pathways. We also sequenced 13 bulk populations.

Project description:The proto-oncogene MYCN is mis-expressed in various types of human brain tumors. To clarify how developmental and regional differences influence transformation, we transduced wild-type or mutationally-stabilized murine N-mycT58A into neural stem cells (NSCs) from perinatal murine cerebellum, brain stem and forebrain. Transplantation of Nmyc WT NSCs was insufficient for tumor formation. N-mycT58A cerebellar and brain stem NSCs generated medulloblastoma/primitive neuroectodermal tumors, whereas forebrain NSCs developed diffuse glioma. Expression analyses distinguished tumors generated from these different regions, with tumors from embryonic versus postnatal cerebellar NSCs demonstrating SHH-dependence and SHH-independence, respectively. These differences were regulated in-part by the transcription factor SOX9, activated in the SHH subclass of human medulloblastoma. Our results demonstrate context-dependent transformation of NSCs in response to a common oncogenic signal.

Project description:The proto-oncogene MYCN is mis-expressed in various types of human brain tumors. To clarify how developmental and regional differences influence transformation, we transduced wild-type or mutationally-stabilized murine N-mycT58A into neural stem cells (NSCs) from perinatal murine cerebellum, brain stem and forebrain. Transplantation of Nmyc WT NSCs was insufficient for tumor formation. N-mycT58A cerebellar and brain stem NSCs generated medulloblastoma/primitive neuroectodermal tumors, whereas forebrain NSCs developed diffuse glioma. Expression analyses distinguished tumors generated from these different regions, with tumors from embryonic versus postnatal cerebellar NSCs demonstrating SHH-dependence and SHH-independence, respectively. These differences were regulated in-part by the transcription factor SOX9, activated in the SHH subclass of human medulloblastoma. Our results demonstrate context-dependent transformation of NSCs in response to a common oncogenic signal. 9 (total) orthotopic tumors generated from E16C, P0C, and P0F NSCs transduced with a mutation-stabilized N-Myc were compared to transduced (but not transplanted) NSCs, NSCs transduced with GFP, and cells derived from the orthotopic tumors. These were also compared to 5 normal P7 cerebella, and 32 medulloblastoma tumors from the GTML mouse model. A cell line derived from a tumor from the GTML mouse model is also included in the comparison.

Project description:Neural stem cells were isolated from embryonic (E18) cortex and from adult mouse subventricular zone and transduced with a Bmi1-overexpressing lentiviral vector or an empty vector control. Cells were grown as neurospheres (in non-adherent culture conditions) for two passages for eNSCs and three passages for aNSCs and RNA purified (after three weeks for eNSCs and four weeks for aNSCs).

Project description:We demonstrate induction and long-term maintenance of totipotent stem cells (TotiSCs) from mouse pluripotent stem cells (PSCs) by a combination of three small molecules, TTNPB, 1-Azakenpaullone, and WS6. These cells, which we designated as ciTotiSCs (chemically induced totipotent stem cells), resembled mouse totipotent 2C-embryo stage cells at both transcriptome and epigenome level.

Project description:We demonstrate induction and long-term maintenance of totipotent stem cells (TotiSCs) from mouse pluripotent stem cells (PSCs) by a combination of three small molecules, TTNPB, 1-Azakenpaullone, and WS6. These cells, which we designated as ciTotiSCs (chemically induced totipotent stem cells), resembled mouse totipotent 2C-embryo stage cells at both transcriptome and epigenome level.

Project description:We demonstrate induction and long-term maintenance of totipotent stem cells (TotiSCs) from mouse pluripotent stem cells (PSCs) by a combination of three small molecules, TTNPB, 1-Azakenpaullone, and WS6. These cells, which we designated as ciTotiSCs (chemically induced totipotent stem cells), resembled mouse totipotent 2C-embryo stage cells at both transcriptome and epigenome level.

Project description:We demonstrate induction and long-term maintenance of totipotent stem cells (TotiSCs) from mouse pluripotent stem cells (PSCs) by a combination of three small molecules, TTNPB, 1-Azakenpaullone, and WS6. These cells, which we designated as ciTotiSCs (chemically induced totipotent stem cells), resembled mouse totipotent 2C-embryo stage cells at both transcriptome and epigenome level.

Project description:The clinical translation of induced pluripotent stem cells (iPSCs) holds great potential for personalized therapeutics. However, the current workflow to generate iPSCs is expensive, time-consuming, and requires standardization. We present a simplified microfluidic approach for reprogramming fibroblasts into iPSCs and their subsequent differentiation into neural stem cells (NSCs). Our method exploits microphysiological technology, providing a 100-fold reduction in reagents for reprogramming and a 9-fold reduction in number of input cells. The iPSCs generated from microfluidic reprogramming of fibroblasts show upregulation of pluripotency markers and downregulation of fibroblast markers, on par with those reprogrammed in the standardized well-conditions. The NSCs differentiated in microfluidic chips show upregulation of neuroectodermal markers (ZIC1, PAX6, SOX1), highlighting their propensity for nervous system development. We then compare the cells obtained on conventional well plates and microfluidic chips for reprogramming and neural induction by bulk RNA sequencing. Pathway enrichment analysis of NSCs generated in the chip showed neural stem cell development enrichment and boosted commitment to the neural stem cell lineage in the initial phases of neural induction, attributed to the confined environment in a microfluidic chip. This method provides a cost-effective pipeline to reprogram and differentiate iPSCs which can be made compliant with the current good manufacturing practices for therapeutics.