Search results for "Neurosphere"

showing 10 items of 30 documents

Prox1 Is Required for Oligodendrocyte Cell Identity in Adult Neural Stem Cells of the Subventricular Zone

2016

Abstract Adult neural stem cells with the ability to generate neurons and glia cells are active throughout life in both the dentate gyrus (DG) and the subventricular zone (SVZ). Differentiation of adult neural stem cells is induced by cell fate determinants like the transcription factor Prox1. Evidence has been provided for a function of Prox1 as an inducer of neuronal differentiation within the DG. We now show that within the SVZ Prox1 induces differentiation into oligodendrocytes. Moreover, we find that loss of Prox1 expression in vivo reduces cell migration into the corpus callosum, where the few Prox1 deficient SVZ-derived remaining cells fail to differentiate into oligodendrocytes. Thu…

0301 basic medicineAdult neurogenesisMice0302 clinical medicineNeural Stem CellsCell MovementLateral VentriclesPromoter Regions GeneticCells CulturedMOUSE-BRAINReceptors NotchOligodendrocytesNeurogenesisCell DifferentiationLINEAGEAnatomyOlfactory BulbNeural stem cellCell biologyNeuroepithelial cellAdult Stem CellsOligodendrogliaDIFFERENTIATIONEnhancer Elements Geneticmedicine.anatomical_structureGene Knockdown TechniquesMolecular MedicineSPINAL-CORDStem cellSUBCELLULAR-LOCALIZATIONProtein BindingAdult stem cellOLIG2NeurogenesisSubventricular zoneBiology03 medical and health sciencesNeurosphereProx1medicineAnimalsCell LineageOLFACTORY-BULBBody PatterningHomeodomain ProteinsTumor Suppressor ProteinsCell BiologyMAMMALIAN BRAINOligodendrocyte Transcription Factor 2030104 developmental biologyNeuropoiesisPROGENITOR CELLSGene Expression Regulationnervous system030217 neurology & neurosurgeryDevelopmental BiologyStem Cells
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Isolation, culture and analysis of adult subependymal neural stem cells

2016

Individual cells dissected from the subependymal neurogenic niche of the adult mouse brain proliferate in medium containing basic fibroblast growth factor (bFGF) and/or epidermal growth factor (EGF) as mitogens, to produce multipotent clonal aggregates called neurospheres. These cultures constitute a powerful tool for the study of neural stem cells (NSCs) provided that they allow the analysis of their features and potential capacity in a controlled environment that can be modulated and monitored more accurately than in vivo. Clonogenic and population analyses under mitogen addition or withdrawal allow the quantification of the self-renewing and multilineage potency of these cells and the id…

0301 basic medicineCancer ResearchNeurogenesisCellular differentiationBasic fibroblast growth factorPopulationCell Culture TechniquesBiologyMice03 medical and health scienceschemistry.chemical_compoundNeural Stem CellsEpendymaNeurosphereSubependymal zoneAnimalsHumanseducationMolecular BiologyNeuronseducation.field_of_studyNeurogenesisCell DifferentiationCell BiologyNeural stem cellCell biologyAdult Stem Cells030104 developmental biologychemistryImmunologyDevelopmental BiologyAdult stem cellDifferentiation
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Conversion of Nonproliferating Astrocytes into Neurogenic Neural Stem Cells: Control by FGF2 and Interferon-gamma

2016

Abstract Conversion of astrocytes to neurons, via de-differentiation to neural stem cells (NSC), may be a new approach to treat neurodegenerative diseases and brain injuries. The signaling factors affecting such a cell conversion are poorly understood, and they are hard to identify in complex disease models or conventional cell cultures. To address this question, we developed a serum-free, strictly controlled culture system of pure and homogeneous “astrocytes generated from murine embryonic stem cells (ESC).” These stem cell derived astrocytes (mAGES), as well as standard primary astrocytes resumed proliferation upon addition of FGF. The signaling of FGF receptor tyrosine kinase converted G…

0301 basic medicineCell signalingNeurogenesisBiologyInterferon-gammaMice03 medical and health sciences0302 clinical medicineNeural Stem CellsNeurosphereddc:570medicineAnimalsCell ProliferationEpidermal Growth FactorMultipotent Stem CellsCell CycleNeurogenesisMouse Embryonic Stem CellsCell BiologyAnatomyCell DedifferentiationEmbryonic stem cellNeural stem cellCell biologyNeuroepithelial cell030104 developmental biologymedicine.anatomical_structureGene Expression RegulationAstrocytesMolecular MedicineFibroblast Growth Factor 2Stem cell030217 neurology & neurosurgerySignal TransductionDevelopmental BiologyAstrocyte
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Cyclin-Dependent Kinase 4 Regulates Adult Neural Stem Cell Proliferation and Differentiation in Response to Insulin

2017

Abstract Insulin is one of the standard components used to culture primary neurospheres. Although it stimulates growth of different types of cells, the effects of insulin on adult neural stem cells (NSCs) have not been well characterized. Here, we reveal that insulin stimulates proliferation, but not survival or self-renewal, of adult NSCs. This effect is mediated by insulin receptor substrate 2 (IRS2) and subsequent activation of the protein kinase B (or Akt), leading to increased activity of the G1-phase cyclin-dependent kinase 4 (Cdk4) and cell cycle progression. Neurospheres isolated from Irs2-deficient mice are reduced in size and fail to expand in culture and this impaired proliferati…

0301 basic medicineInsulin Receptor Substrate ProteinsNeurogenesisCellular differentiationBiologyAdult neurogenesisMice03 medical and health sciencesNeural Stem CellsCyclin-dependent kinaseNeurosphereAnimalsInsulinPhosphorylationNeuritogenesisProtein kinase BCell ProliferationCell CycleG1 PhaseCyclin-dependent kinaseCyclin-Dependent Kinase 4Cell DifferentiationCell BiologyIRS2Neural stem cellCell biology030104 developmental biologyVentricular-subventricular zoneInsulin Receptor Substrate Proteinsbiology.proteinMolecular MedicineNeurospheresbiological phenomena cell phenomena and immunityStem cellDevelopmental BiologyStem Cells
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Characterization of the canine rostral ventricular-subventricular zone: Morphological, immunohistochemical, ultrastructural, and neurosphere assay st…

2017

The mammalian ventricular-subventricular zone (V-SVZ) presents the highest neurogenic potential in the brain of the adult individual. In rodents, it is mainly composed of chains of neuroblasts. In humans, it is organized in layers where neuroblasts do not form chains. The aim of this study is to describe the cytoarchitecture of canine V-SVZ (cV-SVZ), to assess its neurogenic potential, and to compare our results with those previously described in other species. We have studied by histology, immunohistochemistry (IHC), electron microscopy and neurosphere assay the morphology, cytoarchitecture and neurogenic potential of cV-SVZ. Age groups of animals were performed. Histological and ultrastru…

0301 basic medicineMalePathologymedicine.medical_specialtyanimal diseasesSubventricular zoneBiology03 medical and health sciences0302 clinical medicineDogsNeuroblastNeural Stem CellsSpecies SpecificityNeurospheremedicineSubependymal zoneAnimalsStem Cell NicheCells CulturedGeneral NeuroscienceNeurogenesisBrainHistologyImmunohistochemistryMicroscopy Electron030104 developmental biologymedicine.anatomical_structurenervous systemCytoarchitectureImmunohistochemistryFemale030217 neurology & neurosurgeryThe Journal of comparative neurology
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Alexander Disease Mutations Produce Cells with Coexpression of Glial Fibrillary Acidic Protein and NG2 in Neurosphere Cultures and Inhibit Differenti…

2017

Background Alexander disease (AxD) is a rare disease caused by mutations in the gene encoding glial fibrillary acidic protein (GFAP). The disease is characterized by presence of GFAP aggregates in the cytoplasm of astrocytes and loss of myelin. Objectives Determine the effect of AxD-related mutations on adult neurogenesis. Methods We transfected different types of mutant GFAP into neurospheres using the nucleofection technique. Results We find that mutations may cause coexpression of GFAP and NG2 in neurosphere cultures, which would inhibit the differentiation of precursors into oligodendrocytes and thus explain the myelin loss occurring in the disease. Transfection produces cells that diff…

0301 basic medicinecaspase-3Cathepsin Dmacromolecular substancesHSP27lcsh:RC346-429oligodendrocyte precursors03 medical and health sciencesMyelin0302 clinical medicineAlexander diseaseNG2Neurosphereneurospheresmedicinecathepsinlcsh:Neurology. Diseases of the nervous systemOriginal ResearchGlial fibrillary acidic proteinbiologyNeurogenesisNestinGFAP stainmedicine.diseaseMolecular biologyAlexander disease030104 developmental biologymedicine.anatomical_structurenervous systemNeurologyglial fibrillary acidic proteinbiology.proteinNeurology (clinical)030217 neurology & neurosurgeryNeuroscienceFrontiers in Neurology
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Unique astrocyte ribbon in adult human brain contains neural stem cells but lacks chain migration

2003

The subventricular zone (SVZ) is a principal source of adult neural stem cells in the rodent brain, generating thousands of olfactory bulb neurons every day. If the adult human brain contains a comparable germinal region, this could have considerable implications for future neuroregenerative therapy. Stem cells have been isolated from the human brain, but the identity, organization and function of adult neural stem cells in the human SVZ are unknown. Here we describe a ribbon of SVZ astrocytes lining the lateral ventricles of the adult human brain that proliferate in vivo and behave as multipotent progenitor cells in vitro. This astrocytic ribbon has not been observed in other vertebrates s…

AdultBiopsyanimal diseasesSubventricular zoneBiologyCell MovementNeurospheremedicineHumansCells CulturedNeuronsMultidisciplinaryMultipotent Stem CellsNeurogenesisBrainCell DifferentiationAnatomyOlfactory BulbNeural stem cellNeuroepithelial cellNeuropoiesismedicine.anatomical_structurenervous systemAstrocytesAutopsyStem cellNeuroscienceCell DivisionAdult stem cellNature
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Intra-operatively obtained human tissue: Protocols and techniques for the study of neural stem cells

2009

The discoveries of neural (NSCs) and brain tumor stem cells (BTSCs) in the adult human brain and in brain tumors, respectively, have led to a new era in neuroscience research. These cells represent novel approaches to studying normal phenomena such as memory and learning, as well as pathological conditions such as Parkinson's disease, stroke, and brain tumors. This new paradigm stresses the importance of understanding how these cells behave in vitro and in vivo. It also stresses the need to use human-derived tissue to study human disease because animal models may not necessarily accurately replicate the processes that occur in humans. An important, but often underused, source of human tissu…

BiopsyBrain tumorCell Culture TechniquesNerve Tissue ProteinsBiologyArticleIntraoperative PeriodIn vivoNeurosphereSpheroids CellularmedicineElectron microscopyHumansProcess (anatomy)NeuronsNeural stem cellsBrain NeoplasmsGeneral NeuroscienceStem CellsBrain tumor stem cellsHuman brainmedicine.diseaseImmunohistochemistryNeural stem cellCulture MediaMicroscopy Electronmedicine.anatomical_structureCell cultureAstrocytesNeoplastic Stem CellsTissue and Organ HarvestingNeurospheresStem cellNeuroscienceBiomarkersImmunocytochemistry
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Cell fate specification in an in vitro model of neural development

1998

We have studied in an in vitro model of neural development the effect of neighboring cells on the fate of single fluorescently labeled precursor cells. In one line of experiments, PCC7-Mz1 embryonal carcinoma cells were transiently transfected with "green fluorescent protein" (GFP) and, following incubation with 0.1 microM all-trans retinoic acid (RA), the number and morphology of derivatives (neuronal or non-neuronal) was determined that form groups of GFP-expressing cells in a surrounding of unlabeled cells. Because single PCC7-Mz1 cells can produce single-lineage and mixed-lineage derivatives, they are individually pluripotent. In another line of experiments, we have analyzed the fate of…

Cell typeHistologyCell SurvivalCellular differentiationGreen Fluorescent ProteinsCell fate determinationBiologyPathology and Forensic MedicineMiceProsencephalonNeurosphereTumor Cells CulturedAnimalsNeuronsExtracellular Matrix ProteinsNeurogenesisCell Differentiation3T3 CellsCell BiologyGeneral MedicineEmbryonic stem cellCell biologyLuminescent ProteinsP19 cellCOS CellsImmunologyStem cellEuropean Journal of Cell Biology
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EGF converts transit-amplifying neurogenic precursors in the adult brain into multipotent stem cells.

2002

AbstractNeural stem cells in the subventricular zone (SVZ) continue to generate new neurons in the adult brain. SVZ cells exposed to EGF in culture grow to form neurospheres that are multipotent and self-renewing. We show here that the majority of these EGF-responsive cells are not derived from relatively quiescent stem cells in vivo, but from the highly mitotic, Dlx2+, transit-amplifying C cells. When exposed to EGF, C cells downregulate Dlx2, arrest neuronal production, and become highly proliferative and invasive. Killing Dlx2+ cells dramatically reduces the in vivo response to EGF and neurosphere formation in vitro. Furthermore, purified C cells are 53-fold enriched for neurosphere gene…

Cellular differentiationNeuroscience(all)Mice TransgenicBiology03 medical and health sciencesMice0302 clinical medicineCell MovementNeurosphereSpheroids CellularAnimalsCell LineageCells Cultured030304 developmental biologyHomeodomain ProteinsNeurons0303 health sciencesEpidermal Growth FactorGeneral NeuroscienceStem CellsBrainCell DifferentiationImmunohistochemistryNeural stem cellCell biologyUp-RegulationNeuroepithelial cellEndothelial stem cellErbB ReceptorsMicroscopy ElectronPhenotypenervous systemMultipotent Stem CellAstrocytesStem cellNeuroscience030217 neurology & neurosurgeryCell DivisionAdult stem cellTranscription FactorsNeuron
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