2024
Dependence of lymphopoiesis on efficient β-catenin degradation
Cosgun K, Jumaa H, Robinson M, Klemm L, Oulghazi S, Fonseca-Arce D, Xu L, Xiao G, Khanduja D, Chan L, Lee J, Kume K, Song J, Chan W, Chen J, Taketo M, Kothari S. Dependence of lymphopoiesis on efficient β-catenin degradation. The Journal Of Immunology 2024, 212: 1195_4936-1195_4936. DOI: 10.4049/jimmunol.212.supp.1195.4936.Peer-Reviewed Original ResearchIkaros zinc fingersLymphoid cellsB-cateninChIP-seq analysisSuppression of MYC expressionRegulate lineage specificationInduce cell deathConstitutively low levelsDeletion of ApcChIP-seqTCF factorsZinc fingerProteasomal degradationBinding motifNucleosome remodelingDestruction complexSpecific genesWnt/b-catenin pathwayLineage specificationCell deathMYC expressionSuperenhancersLymphoid developmentEpithelial lineageEpithelial cells
2022
Multiparameter analysis of timelapse imaging reveals kinetics of megakaryocytic erythroid progenitor clonal expansion and differentiation
Scanlon VM, Thompson EN, Lawton BR, Kochugaeva M, Ta K, Mayday MY, Xavier-Ferrucio J, Kang E, Eskow NM, Lu YC, Kwon N, Laumas A, Cenci M, Lawrence K, Barden K, Larsuel ST, Reed FE, Peña-Carmona G, Ubbelohde A, Lee JP, Boobalan S, Oppong Y, Anderson R, Maynard C, Sahirul K, Lajeune C, Ivathraya V, Addy T, Sanchez P, Holbrook C, Van Ho AT, Duncan JS, Blau HM, Levchenko A, Krause DS. Multiparameter analysis of timelapse imaging reveals kinetics of megakaryocytic erythroid progenitor clonal expansion and differentiation. Scientific Reports 2022, 12: 16218. PMID: 36171423, PMCID: PMC9519589, DOI: 10.1038/s41598-022-19013-x.Peer-Reviewed Original ResearchConceptsMegakaryocytic-erythroid progenitorsFate specificationLineage commitmentUnderstanding of hematopoiesisProgenitor cell biologyPrimary human hematopoietic progenitorsSingle-cell trackingSingle-cell assaysSingle-cell levelHuman hematopoietic progenitorsProgenitor cell dynamicsLineage specificationCell fateColony-forming unit assaysTimelapse imagingSitu fluorescence stainingCell biologyLineage tracingDivision rateCytokine thrombopoietinHematopoietic progenitorsProgenitorsFluorescence stainingCell dynamicsUnit assays
2020
Analysis of accessible chromatin landscape in the inner cell mass and trophectoderm of human blastocysts
Yang M, Tao X, Titus S, Zhao T, Scott RT, Seli E. Analysis of accessible chromatin landscape in the inner cell mass and trophectoderm of human blastocysts. Molecular Human Reproduction 2020, 26: 702-711. PMID: 32663300, DOI: 10.1093/molehr/gaaa048.Peer-Reviewed Original ResearchConceptsInner cell massHuman preimplantation embryosEpigenetic regulationPreimplantation embryosCell lineage specificationChromatin accessibility landscapeAccessible chromatin landscapePreimplantation human blastocystsEarly embryonic developmentTranscription start siteCell massEarly embryo developmentHuman blastocystsDistal regionChromatin landscapeAccessible chromatinLineage specificationChromatin structureLow DNA inputATAC-seqTrophectoderm differentiationChromosome reorganizationAccessibility landscapeHuman embryonic materialEmbryonic development
2018
The Molecular Signature of Megakaryocyte-Erythroid Progenitors Reveals a Role for the Cell Cycle in Fate Specification
Lu YC, Sanada C, Xavier-Ferrucio J, Wang L, Zhang PX, Grimes HL, Venkatasubramanian M, Chetal K, Aronow B, Salomonis N, Krause DS. The Molecular Signature of Megakaryocyte-Erythroid Progenitors Reveals a Role for the Cell Cycle in Fate Specification. Cell Reports 2018, 25: 2083-2093.e4. PMID: 30463007, PMCID: PMC6336197, DOI: 10.1016/j.celrep.2018.10.084.Peer-Reviewed Original ResearchMeSH KeywordsBasic Helix-Loop-Helix Leucine Zipper Transcription FactorsCell CycleCell LineageGene Expression RegulationGene Regulatory NetworksHEK293 CellsHigh-Throughput Nucleotide SequencingHumansMegakaryocyte-Erythroid Progenitor CellsProto-Oncogene Proteins c-mycReproducibility of ResultsSignal TransductionTranscription, GeneticTumor Suppressor Protein p53ConceptsMegakaryocytic-erythroid progenitorsCommon myeloid progenitorsTranscription factorsCell cycleSingle-cell RNA sequencingRegulatory transcription factorsMegakaryocyte-erythroid progenitorsCell cycle regulatorsCell cycle activationFate specificationLineage specificationE lineageMalignant disease statesGenetic manipulationRNA sequencingE progenitorsErythroid maturationCycle regulatorsDifferential expressionHuman cellsHealthy human cellsCycle activationMegakaryocyte progenitorsMolecular signaturesMyeloid progenitorsUhrf1 regulates active transcriptional marks at bivalent domains in pluripotent stem cells through Setd1a
Kim KY, Tanaka Y, Su J, Cakir B, Xiang Y, Patterson B, Ding J, Jung YW, Kim JH, Hysolli E, Lee H, Dajani R, Kim J, Zhong M, Lee JH, Skalnik D, Lim JM, Sullivan GJ, Wang J, Park IH. Uhrf1 regulates active transcriptional marks at bivalent domains in pluripotent stem cells through Setd1a. Nature Communications 2018, 9: 2583. PMID: 29968706, PMCID: PMC6030064, DOI: 10.1038/s41467-018-04818-0.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCCAAT-Enhancer-Binding ProteinsCellular ReprogrammingCellular Reprogramming TechniquesChimeraDNA MethylationEpigenesis, GeneticFemaleFibroblastsGene Knockout TechniquesHEK293 CellsHistone CodeHistone-Lysine N-MethyltransferaseHistonesHumansMaleMesodermMiceMouse Embryonic Stem CellsNeural PlateNuclear ProteinsPrimary Cell CultureRecombinant ProteinsUbiquitin-Protein LigasesConceptsEmbryonic stem cellsUnique epigenetic statesBivalent histone modificationsRecruitment of DNMT1Bivalent histone marksCell typesDNA-binding proteinsSpecialized cell typesStem cellsPluripotent stem cellsTrithorax groupBivalent domainsMesoderm specificationCOMPASS complexHeterochromatin formationEpigenetic stateCell specificationHistone marksLineage specificationHistone modificationsEpigenetic regulationSpecific lineagesDNA methylationTranscriptional marksEpigenetic changes
2016
Dnmt1 regulates the myogenic lineage specification of muscle stem cells
Liu R, Kim KY, Jung YW, Park IH. Dnmt1 regulates the myogenic lineage specification of muscle stem cells. Scientific Reports 2016, 6: 35355. PMID: 27752090, PMCID: PMC5082760, DOI: 10.1038/srep35355.Peer-Reviewed Original ResearchConceptsImportant epigenetic markKnockout mouse approachesDNA methylation patternsMuscle stem cellsDaughter DNA strandsDNMT1 regulationEpigenetic marksLineage specificationCellular identityDNA methylationMethylation patternsDNMT1 depletionMyogenic genesMyogenic differentiationLineage fidelityNegative regulatorGene expressionDNMT1Osteogenic lineageFunctional roleFunctional consequencesMouse approachDNA strandsId-1Stem cells
2013
Notch-HES1 signaling axis controls hemato-endothelial fate decisions of human embryonic and induced pluripotent stem cells
Lee JB, Werbowetski-Ogilvie TE, Lee JH, McIntyre BA, Schnerch A, Hong SH, Park IH, Daley GQ, Bernstein ID, Bhatia M. Notch-HES1 signaling axis controls hemato-endothelial fate decisions of human embryonic and induced pluripotent stem cells. Blood 2013, 122: 1162-1173. PMID: 23733337, DOI: 10.1182/blood-2012-12-471649.Peer-Reviewed Original ResearchMeSH KeywordsApoptosisBasic Helix-Loop-Helix Transcription FactorsBiomarkersBlotting, WesternCell DifferentiationCell MovementCell ProliferationCells, CulturedDermisEmbryonic Stem CellsEndothelium, VascularFibroblastsFlow CytometryGene Expression ProfilingGene Expression RegulationHematopoiesisHematopoietic Stem CellsHomeodomain ProteinsHumansImmunoenzyme TechniquesInduced Pluripotent Stem CellsOligonucleotide Array Sequence AnalysisReceptor, Notch1Receptors, NotchRNA, Small InterferingSignal TransductionTranscription Factor HES-1ConceptsCell fate decisionsFate decisionsPluripotent stem cellsHematopoietic lineage specificationEarly human hematopoiesisFunction of NotchStem cellsHuman pluripotent stem cellsInduced pluripotent stem cellsRole of NotchEarly human developmentCommitted hematopoietic progenitorsFate specificationLineage specificationCellular processesNotch receptorsNotch signalingHematopoietic lineagesNotch pathwayBipotent precursorsNotch ligandsHuman hematopoiesisHuman embryonicUnappreciated roleToggle switchDNA methylation: roles in mammalian development
Smith ZD, Meissner A. DNA methylation: roles in mammalian development. Nature Reviews Genetics 2013, 14: 204-220. PMID: 23400093, DOI: 10.1038/nrg3354.Peer-Reviewed Original ResearchConceptsEmbryonic stem cellsDNA methylationMammalian developmentPaternal genomeEmbryonic lineagesEpigenetic mechanismsPrimordial germ cell specificationDNA methylation erasureDNA methylation functionsKey PointsDNA methylationGerm cell specificationGermline-specific genesGlobal nuclear organizationSimilar epigenetic mechanismsTranscription factor bindingStem cellsPre-implantation stagesAdult stem cellsCpG island methylationMethylation erasureHeritable memoryMethylation functionsCell specificationCpG densityLineage specification
2012
Teleost growth factor independence (gfi) genes differentially regulate successive waves of hematopoiesis
Cooney JD, Hildick-Smith GJ, Shafizadeh E, McBride PF, Carroll KJ, Anderson H, Shaw GC, Tamplin OJ, Branco DS, Dalton AJ, Shah DI, Wong C, Gallagher PG, Zon LI, North TE, Paw BH. Teleost growth factor independence (gfi) genes differentially regulate successive waves of hematopoiesis. Developmental Biology 2012, 373: 431-441. PMID: 22960038, PMCID: PMC3532562, DOI: 10.1016/j.ydbio.2012.08.015.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAnimalsCloning, MolecularConserved SequenceDNA-Binding ProteinsEmbryo, NonmammalianEpistasis, GeneticErythropoiesisEvolution, MolecularGene Expression Regulation, DevelopmentalHematopoiesisHematopoietic Stem CellsHematopoietic SystemModels, BiologicalMolecular Sequence DataZebrafishZebrafish ProteinsConceptsHematopoietic stem cellsTranscription factorsDefinitive hematopoiesisRUNX-1Hematopoietic stem/progenitor cell developmentKey hematopoietic transcription factorsC-MybDefinitive hematopoietic progenitorsHematopoietic transcription factorsProgenitor cell developmentLineage specificationPrimitive hematopoiesisGfi1aaEpistatic relationshipErythroid developmentTranscriptional programsGFI1BHematopoietic lineagesFunctional analysisCritical regulatorCell developmentZebrafishHematopoietic progenitorsDistinct rolesPrimitive progenitors
2008
MicroRNA-Mediated Control of Cell Fate in Megakaryocyte-Erythrocyte Progenitors
Lu J, Guo S, Ebert BL, Zhang H, Peng X, Bosco J, Pretz J, Schlanger R, Wang JY, Mak RH, Dombkowski DM, Preffer FI, Scadden DT, Golub TR. MicroRNA-Mediated Control of Cell Fate in Megakaryocyte-Erythrocyte Progenitors. Developmental Cell 2008, 14: 843-853. PMID: 18539114, PMCID: PMC2688789, DOI: 10.1016/j.devcel.2008.03.012.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigens, CD34Bone Marrow CellsCell DifferentiationCell LineageCells, CulturedErythroid CellsErythropoietinGene Expression RegulationGenes, ReporterHematopoietic Stem CellsHumansIntegrin beta3K562 CellsMegakaryocytesMiceMice, Inbred C57BLMicroRNAsModels, BiologicalPlatelet Membrane Glycoprotein IIbProto-Oncogene Proteins c-mybThrombopoietinConceptsMegakaryocyte-erythrocyte progenitorsLineage specificationTranscription factor MYBMiR-150Cell fateLineage fateRegenerative biologyErythroid cellsFunction experimentsMultipotent cellsMegakaryocytic lineageMiRNA expressionPrimary cellsCritical targetModel systemMicroRNAsProgenitorsFateRegulationCellsImportant participantsMYBLineagesMiRNAsBiologyPiecing Together the Mosaic of Early Mammalian Development through MicroRNAs*
Blakaj A, Lin H. Piecing Together the Mosaic of Early Mammalian Development through MicroRNAs*. Journal Of Biological Chemistry 2008, 283: 9505-9508. PMID: 18272516, PMCID: PMC2442291, DOI: 10.1074/jbc.r800002200.Peer-Reviewed Original ResearchConceptsRole of miRNAsES cellsEarly mammalian developmentMammalian ES cellsDozens of miRNAsRNase III enzymeCluster of miRNAsES cell differentiationEmbryonic stem cellsRNA biogenesisMammalian embryogenesisMammalian developmentLineage specificationMicroRNA pathwayMiR-290MiRNA biogenesisEmbryonic developmentNuclear proteinsCell differentiationMiRNAsStem cellsBiogenesisEarly developmentCellsCrucial role
1997
Multilineage gene expression precedes commitment in the hemopoietic system.
Hu M, Krause D, Greaves M, Sharkis S, Dexter M, Heyworth C, Enver T. Multilineage gene expression precedes commitment in the hemopoietic system. Genes & Development 1997, 11: 774-785. PMID: 9087431, DOI: 10.1101/gad.11.6.774.Peer-Reviewed Original ResearchConceptsGene expression programsMultilineage gene expressionLineage specificationExpression programsGene activityLocus activationMultipotential stateGene expressionCytokine receptorsHemopoietic stemGranulocytic lineageProgenitor cellsSingle-cell RT-PCRSame cellsHemopoietic systemRT-PCRExclusive commitmentCell RT-PCRCellsLineagesCoexpressionDifferentiationExpressionStemActivation
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