Project description:Human neural stem cells (NSCs) hold great promise in reparative therapy for neural diseases and injuries. However, the isolation of NSCs from either fetal or adult tissue and their application remain difficult due to ethical and immune-rejection concerns. One promising solution is to generate patient specific induced pluripotent stem cells (iPSCs) and subsequently differentiate them into NSCs. Alternatively, induced neurons (iN) can be generated directly from fibroblasts by retroviral delivery of neural specific transcription factors or miroRNAs. The later two approaches remain inefficient and with safety concerns. Here, we describe a process to generate, from epithelial-like cells present in human urine, integration free and engraftable NSCs (UiNSC) efficiently. Using an episomal system to deliver reprogramming factors and microRNAs into human urine cells and subsequently culture them in a chemically defined medium supplemented with a cocktail of small molecules, we generated UiNSCs capable of proliferation and without the transgenes upon prolonged expansion. These transgene free UiNSCs express typical neural stem cell markers and are able to differentiate into all neuronal subtypes and glial cells in vitro and more importantly could engraft and differentiate in vivo upon transplantation into the brain of new born rat. Thus, our work provides an efficient and highly practical platform to generate patient specific NSCs for regenerative medicine. This is a general expression microarray design (NimbleGen platform). It includes 6 samples.

Project description:Neural stem cells (NSCs) generate neurons and glial cells throughout embryonic and postnatal brain development. The role of s-acylation, a reversible post-translational lipid modification of proteins, in regulating fate and activity of NSCs remains largely unknown. We here used an unbiased screening approach to identify proteins that are s-acylated in mouse NSCs.

Project description:Neural stem cells (NSCs) in the adult mammalian subependymal zone maintain a glial identity and the developmental potential to generate neurons during the lifetime. Production of neurons from these NSCs is not direct but follows an orderly pattern of cell progression which allows the gradual increase along the neurogenic lineage in the expression of pro-neural factors needed for neuronal specification. In this context, tightly regulated translation of existing transcriptional programs represents a potential mechanism to avoid the critical challenge posed by genes that encode proteins with conflicting functions, i.e. self-renew or differentiate. Here, we identify RNA-binding protein MEX3A as a post-transcriptional regulator of a set of stemness-associated transcripts at critical transitions in the subependymal neurogenic lineage. MEX3A binding to a set of quiescence-related RNAs in activated NSCs is needed for their return to quiescence, playing a role in the long-term maintenance of the NSC pool. Furthermore, it is required for the repression of the same program at the onset of neuronal differentiation. Our data indicate that MEX3A is a pivotal regulator of adult mammalian neurogenesis acting as a translational remodeller.

Project description:Primitive neural stem cells (NSCs) could be derived from pluripotent mouse embryonic stem (ES) cells, and then differentiate into definitive-type neural stem cells which resemble NSCs obtained from the central nervous system. Hence, primitive NSCs define an early stage of neural induction and provide a model to understand the mechanism that controls initial neural commitment. In this study, we performed microarray assay to analyze the global transcriptional profiles in mouse ES cell-derived primitive and definitive NSCs and to depict the molecular changes during the multi-staged neural differentiation process. Primitive NSCs derived directly from ESCs in Lif (p-NSC_L), primitive NSCs that were sub-cultured in the presence of Lif and FGF (p-NSC_LF), as well as definitive NSCs derived from primitive NSCs in medium containing FGF and EGF, were collected for RNA extraction and hybridization on Affymetrix microarrays. Mouse ESCs and NSCs obtained from mouse embryonic brain (E11.5) were included for controls. For each cell type, we collected two biological replicate samples for microarray analysis.

Project description:Primitive neural stem cells (NSCs) could be derived from pluripotent mouse embryonic stem (ES) cells, and then differentiate into definitive-type neural stem cells which resemble NSCs obtained from the central nervous system. Hence, primitive NSCs define an early stage of neural induction and provide a model to understand the mechanism that controls initial neural commitment. In this study, we performed microarray assay to analyze the global transcriptional profiles in mouse ES cell-derived primitive and definitive NSCs and to depict the molecular changes during the multi-staged neural differentiation process.

Project description:A cardinal property of neural stem cells (NSCs) is their ability to adopt multiple fates upon differentiation. The epigenome is widely seen as a read-out of cellular potential and a manifestation of this can be seen in embryonic stem cells (ESCs), where promoters of many lineage-specific regulators are marked by a bivalent epigenetic signature comprising trimethylation of both lysine 4 and lysine 27 of histone H3 (H3K4me3 and H3K27me3, respectively). Bivalency has subsequently emerged as a powerful epigenetic indicator of stem cell potential. Here, we have interrogated the epigenome during differentiation of ESC-derived NSCs to immature GABAergic interneurons. We show that developmental transitions are accompanied by loss of bivalency at many promoters in line with their increasing developmental restriction from pluripotent ESC through multipotent NSC to committed GABAergic interneuron. At the NSC stage, the promoters of genes encoding many transcriptional regulators required for differentiation of multiple neuronal subtypes and neural crest appear to be bivalent, consistent with the broad developmental potential of NSCs. Upon differentiation to GABAergic neurons, all non-GABAergic promoters resolve to H3K27me3 monovalency, whereas GABAergic promoters resolve to H3K4me3 monovalency or retain bivalency. Importantly, many of these epigenetic changes occur prior to any corresponding changes in gene expression. Intriguingly, another group of gene promoters gain bivalency as NSCs differentiate toward neurons, the majority of which are associated with functions connected with maturation and establishment and maintenance of connectivity. These data show that bivalency provides a dynamic epigenetic signature of developmental potential in both NSCs and in early neurons. Illumina Expresson BeadChip arrays (MouseRef-8v2.0) were used to assess gene expression changes in neural stem cells (n=5; derived from mouse embryonic stem cells) and their differentiated neuronal progeny (n=3; FACS-purified based on Tau-RedStar expression).

Project description:Like embryonic stem cells, induced pluripotent stem cells (iPSCs) can differentiate into all three germ layers in an in vitro system. Here, we developed a new technology for obtaining neural stem cells (NSCs) from iPSCs through chimera formation, in an in vivo environment. iPSCs contributed to the neural lineage in the chimera, which could be efficiently purified and directly cultured as NSCs in vitro. The iPSC-derived, in vivo-differentiated NSCs expressed NSC markers, and their gene-expression pattern more closely resembled that of brain-derived NSCs than in vitro-differentiated NSCs. This system could be applied for differentiating pluripotent stem cells into specialized cell type whose differentiation protocols are not well established.

Project description:A cardinal property of neural stem cells (NSCs) is their ability to adopt multiple fates upon differentiation. The epigenome is widely seen as a read-out of cellular potential and a manifestation of this can be seen in embryonic stem cells (ESCs), where promoters of many lineage-specific regulators are marked by a bivalent epigenetic signature comprising trimethylation of both lysine 4 and lysine 27 of histone H3 (H3K4me3 and H3K27me3, respectively). Bivalency has subsequently emerged as a powerful epigenetic indicator of stem cell potential. Here, we have interrogated the epigenome during differentiation of ESC-derived NSCs to immature GABAergic interneurons. We show that developmental transitions are accompanied by loss of bivalency at many promoters in line with their increasing developmental restriction from pluripotent ESC through multipotent NSC to committed GABAergic interneuron. At the NSC stage, the promoters of genes encoding many transcriptional regulators required for differentiation of multiple neuronal subtypes and neural crest appear to be bivalent, consistent with the broad developmental potential of NSCs. Upon differentiation to GABAergic neurons, all non-GABAergic promoters resolve to H3K27me3 monovalency, whereas GABAergic promoters resolve to H3K4me3 monovalency or retain bivalency. Importantly, many of these epigenetic changes occur prior to any corresponding changes in gene expression. Intriguingly, another group of gene promoters gain bivalency as NSCs differentiate toward neurons, the majority of which are associated with functions connected with maturation and establishment and maintenance of connectivity. These data show that bivalency provides a dynamic epigenetic signature of developmental potential in both NSCs and in early neurons. Neural stem cells derived from mouse embryonic stem cells were differentiated into neurons and FACS purified based on RedStar fluorescence driven by the Tau promoter. Chromatin was prepared from NSCs and neurons (n=1), sonicated to roughly 300bp and immunoprecipitated with antibodies against H3K4me3, H3K27me3, total Histone H3 and total IgG, alongside a 5% input sample. K4/K27 and corresponding input samples were analysed by ChIPSeq

Project description:BACKGROUND: The polycomb group protein Ezh2 is an epigenetic repressor of transcription originally found to prevent untimely differentiation of pluripotent embryonic stem cells. We previously demonstrated that Ezh2 is also expressed in multipotent neural stem cells (NSCs). We showed that Ezh2 expression is downregulated during NSC differentiation into astrocytes or neurons. However, high levels of Ezh2 remained present in differentiating oligodendrocytes until myelinating. This study aimed to elucidate the target genes of Ezh2 in NSCs and in premyelinating oligodendrocytes (pOLs). METHODOLOGY/PRINCIPAL FINDINGS: We performed chromatin immunoprecipitation followed by high-throughput sequencing to detect the target genes of Ezh2 in NSCs and pOLs. We found 1532 target genes of Ezh2 in NSCs. During NSC differentiation, the occupancy of these genes by Ezh2 was alleviated. However, when the NSCs differentiated into oligodendrocytes, 393 of these genes remained targets of Ezh2. Analysis of the target genes indicated that the repressive activity of Ezh2 in NSCs concerns genes involved in stem cell maintenance, in cell cycle control and in preventing neural differentiation. Among the genes in pOLs that were still repressed by Ezh2 were most prominently those associated with neuronal and astrocytic committed cell lineages. Suppression of Ezh2 activity in NSCs caused loss of stem cell characteristics, blocked their proliferation and ultimately induced apoptosis. Suppression of Ezh2 activity in pOLs resulted in derangement of the oligodendrocytic phenotype, due to re-expression of neuronal and astrocytic genes, and ultimately in apoptosis. CONCLUSIONS/SIGNIFICANCE: Our data indicate that the epigenetic repressor Ezh2 in NSCs is crucial for proliferative activity and maintenance of neural stemness. During differentiation towards oligodendrocytes, Ezh2 repression continues particularly to suppress other neural fate choices. Ezh2 is completely downregulated during differentiation towards neurons and astrocytes allowing transcription of these differentiation programs. The specific fate choice towards astrocytes or neurons is apparently controlled by epigenetic regulators other than Ezh2. Examination of Ezh2 target sites in 2 different primary cells types

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.