2021
Regulation of RNA polymerase II activity is essential for terminal erythroid maturation
Murphy ZC, Murphy K, Myers J, Getman M, Couch T, Schulz VP, Lezon-Geyda K, Palumbo C, Yan H, Mohandas N, Gallagher PG, Steiner LA. Regulation of RNA polymerase II activity is essential for terminal erythroid maturation. Blood 2021, 138: 1740-1756. PMID: 34075391, PMCID: PMC8569412, DOI: 10.1182/blood.2020009903.Peer-Reviewed Original ResearchConceptsRNA polymerase IIRNA polymerase II activityTerminal erythroid maturationPolymerase II activityPolymerase IIErythroid maturationHuman erythroblastsGene expressionTerminal maturationII activityStage-specific regulationHistone posttranslational modificationsTransposase-accessible chromatinErythroid-specific genesAccumulation of heterochromatinHigh-throughput sequencingLevel of transcriptionLate-stage erythroblastsEssential biologic processesAccessible chromatinHistone marksTranscription elongationChromatin structureTranscriptional repressionChromatin immunoprecipitationImpairment of human terminal erythroid differentiation by histone deacetylase 5 deficiency
Wang Y, Li W, Schulz VP, Zhao H, Qu X, Qi Q, Cheng Y, Guo X, Zhang S, Wei X, Liu D, Yazdanbakhsh K, Hillyer CD, Mohandas N, Chen L, Gallagher PG, An X. Impairment of human terminal erythroid differentiation by histone deacetylase 5 deficiency. Blood 2021, 138: 1615-1627. PMID: 34036344, PMCID: PMC8554652, DOI: 10.1182/blood.2020007401.Peer-Reviewed Original ResearchConceptsTerminal erythroid differentiationChromatin condensationErythroid differentiationHuman erythroid cellsAcetylation of H4RNA sequencing analysisEnucleation of erythroblastsGroup of enzymesLate-stage erythroblastsErythroid cell culturesHDAC family membersActivation of p53Short hairpin RNAChromatin accessibilityATAC-seqMammalian erythropoiesisH4 deacetylationNonhistone proteinsH4 acetylationDiverse functionsHDAC inhibitor treatmentHuman erythropoiesisKnockdown of HDAC5Erythroid cellsGene expression
2020
Comprehensive proteomic analysis of murine terminal erythroid differentiation
Gautier EF, Leduc M, Ladli M, Schulz VP, Lefèvre C, Boussaid I, Fontenay M, Lacombe C, Verdier F, Guillonneau F, Hillyer CD, Mohandas N, Gallagher PG, Mayeux P. Comprehensive proteomic analysis of murine terminal erythroid differentiation. Blood Advances 2020, 4: 1464-1477. PMID: 32282884, PMCID: PMC7160260, DOI: 10.1182/bloodadvances.2020001652.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsErythroblastsErythroid CellsErythropoiesisHumansLeukemia, Erythroblastic, AcuteMiceProteomicsConceptsTerminal erythroid differentiationErythroid differentiationProteomic dataMurine terminal erythroid differentiationTerminal differentiationOverall cellular contentComprehensive proteomic dataComprehensive proteomic analysisMurine erythroid cellsTerminal differentiation processMost biologic processesProteome levelComparison of murineHuman proteomeProteomic analysisTranscriptomic changesChromatin condensationProteomeErythroid cellsFundamental mechanismsRed cell disordersDifferentiation processErythroid progenitorsFriend erythroleukemiaCellular model
2019
Identification and transcriptome analysis of erythroblastic island macrophages
Li W, Wang Y, Zhao H, Zhang H, Xu Y, Wang S, Guo X, Huang Y, Zhang S, Han Y, Wu X, Rice CM, Huang G, Gallagher PG, Mendelson A, Yazdanbakhsh K, Liu J, Chen L, An X. Identification and transcriptome analysis of erythroblastic island macrophages. Blood 2019, 134: 480-491. PMID: 31101625, PMCID: PMC6676133, DOI: 10.1182/blood.2019000430.Peer-Reviewed Original ResearchConceptsErythroblastic islandsEBI macrophagesErythroid cellsErythroblastic island macrophagesGene expression profilesTranscriptome analysisNonerythroid cellsMacrophage functionHematopoietic nicheExpression profilesSpecialized functionsCentral macrophageKnockin mouse modelFlow cytometry analysisEpoRKey moleculesIron recyclingBone marrowCytometry analysisFetal liverNicheEfficient erythropoiesisErythropoiesisIron sourceImportant resource
2016
Setd1a and NURF mediate chromatin dynamics and gene regulation during erythroid lineage commitment and differentiation
Li Y, Schulz VP, Deng C, Li G, Shen Y, Tusi BK, Ma G, Stees J, Qiu Y, Steiner LA, Zhou L, Zhao K, Bungert J, Gallagher PG, Huang S. Setd1a and NURF mediate chromatin dynamics and gene regulation during erythroid lineage commitment and differentiation. Nucleic Acids Research 2016, 44: 7173-7188. PMID: 27141965, PMCID: PMC5009724, DOI: 10.1093/nar/gkw327.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigens, NuclearCell LineageCells, CulturedChromatinChromatin Assembly and DisassemblyChromatin ImmunoprecipitationErythroblastsErythrocyte CountErythrocytesErythropoiesisFemaleGene Expression RegulationHemoglobinsHistone-Lysine N-MethyltransferaseHistonesHumansLysineMaleMethylationMiceMice, KnockoutMicrococcal NucleaseMultiprotein ComplexesNerve Tissue ProteinsPromoter Regions, GeneticSpleenTranscription FactorsUpstream Stimulatory FactorsConceptsNURF complexChromatin dynamicsErythroid genesLineage commitmentAdult β-globin geneErythroid gene promotersErythroid lineage differentiationCell context-dependent mannerErythroid lineage commitmentChromatin structural alterationsContext-dependent mannerΒ-globin geneChromatin architectureEnhancer accessibilityChromatin accessibilityNucleosome repositioningTranscription regulationChromatin structureH3K4 methylationGene regulationComplex occupancyMammalian cellsGene activationGene transcriptionLineage differentiation