Search results for "lineage tracing"

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Adult Neurogenesis Is Sustained by Symmetric Self-Renewal and Differentiation

2018

Somatic stem cells have been identified in multiple adult tissues. Whether self-renewal occurs symmetrically or asymmetrically is key to understanding long-term stem cell maintenance and generation of progeny for cell replacement. In the adult mouse brain, neural stem cells (NSCs) (B1 cells) are retained in the walls of the lateral ventricles (ventricular-subventricular zone [V-SVZ]). The mechanism of B1 cell retention into adulthood for lifelong neurogenesis is unknown. Using multiple clonal labeling techniques, we show that the vast majority of B1 cells divide symmetrically. Whereas 20%-30% symmetrically self-renew and can remain in the niche for several months before generating neurons, …

0301 basic medicineTime FactorsNeurogenesis1.1 Normal biological development and functioningCellventricular-subventricular zoneMice TransgenicCell Counttime-lapse imagingSelf renewalBiologyself-renewalRegenerative MedicineMedical and Health SciencesTransgenicMice03 medical and health sciencesLateral ventricleslineage tracingNeural Stem CellsInterneuronsUnderpinning researchGeneticsmedicineAnimalsHumansCell Self RenewalB1 cellsagingdivision modeNeurogenesisNeurosciencesCell DifferentiationCell BiologyBiological SciencesStem Cell ResearchNeural stem cellCell biologysymmetric divisionB-1 cell030104 developmental biologymedicine.anatomical_structureNeurologicalMolecular MedicineStem Cell Research - Nonembryonic - Non-HumanStem cellDevelopmental BiologyAdult stem cell
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Increasing Neural Stem Cell Division Asymmetry and Quiescence Are Predicted to Contribute to the Age-Related Decline in Neurogenesis.

2018

Summary: Adult murine neural stem cells (NSCs) generate neurons in drastically declining numbers with age. How cellular dynamics sustain neurogenesis and how alterations with age may result in this decline are unresolved issues. We therefore clonally traced NSC lineages using confetti reporters in young and middle-aged adult mice. To understand the underlying mechanisms, we derived mathematical models that explain observed clonal cell type abundances. The best models consistently show self-renewal of transit-amplifying progenitors and rapid neuroblast cell cycle exit. In middle-aged mice, we identified an increased probability of asymmetric stem cell divisions at the expense of symmetric di…

0301 basic medicineCell typeAgingNeurogenesisBiologyAdult Neurogenesis ; Computational Model ; Lineage Tracing ; Lineage Tree Simulation ; Model Averaging ; Moment EquationsModels BiologicalGeneral Biochemistry Genetics and Molecular Biology03 medical and health sciencesMiceNeuroblastNeural Stem CellsAnimalsCell LineageComputer SimulationProgenitor celllcsh:QH301-705.5Stochastic ProcessesNeurogenesisAsymmetric Cell DivisionCell CycleReproducibility of ResultsCell cycleNeural stem cellClone Cells030104 developmental biologylcsh:Biology (General)Stem cellNeuroscienceHomeostasisCell reports
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