Search results for "Fate specification"

showing 2 items of 2 documents

On the roles of Notch, Delta, kuzbanian, and inscuteable during the development of Drosophila embryonic neuroblast lineages

2009

AbstractThe generation of cellular diversity in the nervous system involves the mechanism of asymmetric cell division. Besides an array of molecules, including the Par protein cassette, a heterotrimeric G protein signalling complex, Inscuteable plays a major role in controlling asymmetric cell division, which ultimately leads to differential activation of the Notch signalling pathway and correct specification of the two daughter cells. In this context, Notch is required to be active in one sibling and inactive in the other. Here, we investigated the requirement of genes previously known to play key roles in sibling cell fate specification such as members of the Notch signalling pathway, e.g…

Lineage (genetic)Embryo NonmammalianNotchCell divisionCell fate specificationDisintegrinsNeurogenesisContext (language use)BiologyCell fate determinationPolymerase Chain Reaction03 medical and health sciences0302 clinical medicineNeuroblastAsymmetric cell divisionAnimalsDrosophila ProteinsCell LineageMolecular Biology030304 developmental biologyDNA PrimersGeneticsNeurons0303 health sciencesBase SequenceReceptors NotchNeurogenesisIntracellular Signaling Peptides and ProteinsMembrane ProteinsMetalloendopeptidasesCell BiologyEmbryonic stem cellImmunohistochemistryCytoskeletal ProteinsAsymmetric cell divisionDrosophilakuzbanian030217 neurology & neurosurgerySignal TransductionDevelopmental BiologyDevelopmental Biology
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Human stem cells from single blastomeres reveal pathways of embryonic or trophoblast fate specification.

2015

Mechanisms of initial cell fate decisions differ among species. To gain insights into lineage allocation in humans, we derived ten human embryonic stem cell lines (designated UCSFB1-10) from single blastomeres of four 8-cell embryos and one 12-cell embryo from a single couple. Compared with numerous conventional lines from blastocysts, they had unique gene expression and DNA methylation patterns that were, in part, indicative of trophoblast competence. At a transcriptional level, UCSFB lines from different embryos were often more closely related than those from the same embryo. As predicted by the transcriptomic data, immunolocalization of EOMES, T brachyury, GDF15 and active β-catenin reve…

BlastomeresTranscription GeneticCellular differentiationMedical and Health SciencesEmbryo Culture TechniquesEpigenomeNeural Stem CellsDevelopmentalMyocytes Cardiacbeta CateninOligonucleotide Array Sequence AnalysisEndodermGene Expression Regulation DevelopmentalEmbryoCell DifferentiationBiological SciencesStem Cells and RegenerationTrophoblastsmedicine.anatomical_structureembryonic structuresStem Cell Research - Nonembryonic - Non-HumanStem cellEndodermCardiacTranscriptionBrachyuryGrowth Differentiation Factor 151.1 Normal biological development and functioningBiologyCell LineGeneticUnderpinning researchmedicineGeneticsHumansHuman embryoCell LineageBlastocystMolecular BiologyEmbryonic Stem CellsMyocytesBlastomereHuman embryonic stem cellGene Expression ProfilingTrophoblastFibroblastsDNA MethylationStem Cell ResearchHuman trophoblast stem cellEmbryonic stem cellMolecular biology102Fate specificationBlastocystGene Expression RegulationGeneric health relevanceTranscriptomeDevelopmental Biology
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