2023
Phenotypic and proteomic characterization of the human erythroid progenitor continuum reveal dynamic changes in cell cycle and in metabolic pathways
Papoin J, Yan H, Leduc M, Le Gall M, Narla A, Palis J, Steiner L, Gallagher P, Hillyer C, Gautier E, Mohandas N, Blanc L. Phenotypic and proteomic characterization of the human erythroid progenitor continuum reveal dynamic changes in cell cycle and in metabolic pathways. American Journal Of Hematology 2023, 99: 99-112. PMID: 37929634, PMCID: PMC10877306, DOI: 10.1002/ajh.27145.Peer-Reviewed Original ResearchConceptsErythroid progenitor differentiationCell cycleErythroid progenitorsProgenitor differentiationMass spectrometry-based proteomicsFurther functional analysisSpectrometry-based proteomicsHuman erythroid progenitorsProtein machineryErythroid progenitor proliferationTerminal erythropoiesisProteomic characterizationHematopoietic stem cellsProteomic dataProgenitor populationsHuman erythropoiesisReticulocyte maturationFunctional analysisErythroid lineageOxidative phosphorylationProgenitor proliferationErythroid disordersMetabolic pathwaysAbsolute expressionStem cells
2022
Extramedullary hematopoietic stem cells
Gallagher P. Extramedullary hematopoietic stem cells. Blood 2022, 139: 3353-3354. PMID: 35679074, DOI: 10.1182/blood.2022015879.Peer-Reviewed Original Research
2019
A Unique Epigenomic Landscape Defines Human Erythropoiesis
Schulz VP, Yan H, Lezon-Geyda K, An X, Hale J, Hillyer CD, Mohandas N, Gallagher PG. A Unique Epigenomic Landscape Defines Human Erythropoiesis. Cell Reports 2019, 28: 2996-3009.e7. PMID: 31509757, PMCID: PMC6863094, DOI: 10.1016/j.celrep.2019.08.020.Peer-Reviewed Original ResearchMeSH KeywordsChromatinChromatin Assembly and DisassemblyDNA MethylationEpigenesis, GeneticErythroid CellsErythropoiesisGene Expression ProfilingGene Expression RegulationHematologic DiseasesHematopoietic Stem CellsHumansMultigene FamilyPolymorphism, Single NucleotideRegulatory Sequences, Nucleic AcidTranscriptomeConceptsChromatin accessibilityDNA methylationHuman erythropoiesisStage-specific gene regulationErythroid cellsPrimary human erythroid cellsChromatin state dynamicsCell typesCis-regulatory elementsGenome-wide studiesSpecialized cell typesHuman erythroid cellsCell phenotypic variationNonhematopoietic cell typesChromatin primingErythroid genesEpigenomic landscapeGene regulationMammalian erythropoiesisPhenotypic variationTranscriptome dataOrganismal needsRegulation of erythropoiesisNonpromoter sitesGene expression
2017
Distinct roles for TET family proteins in regulating human erythropoiesis
Yan H, Wang Y, Qu X, Li J, Hale J, Huang Y, An C, Papoin J, Guo X, Chen L, Kang Q, Li W, Schulz VP, Gallagher PG, Hillyer CD, Mohandas N, An X. Distinct roles for TET family proteins in regulating human erythropoiesis. Blood 2017, 129: 2002-2012. PMID: 28167661, PMCID: PMC5383871, DOI: 10.1182/blood-2016-08-736587.Peer-Reviewed Original ResearchConceptsMyelodysplastic syndromeErythroid differentiationHuman erythropoiesisErythroid progenitorsHuman erythroid differentiationTET family proteinsDistinct rolesKnockdown of TET2Terminal erythroid differentiationHuman erythroid cellsTET2 gene mutationsFamily proteinsTranslocation (TET) familyTET2 knockdownKnockdown experimentsErythroid cellsBiological processesDevelopment defectsTET3TET3 expressionOrthochromatic erythroblastsImpaired differentiationHuman CD34KnockdownTET2
2016
In vivo correction of anaemia in β-thalassemic mice by γPNA-mediated gene editing with nanoparticle delivery
Bahal R, Ali McNeer N, Quijano E, Liu Y, Sulkowski P, Turchick A, Lu YC, Bhunia DC, Manna A, Greiner DL, Brehm MA, Cheng CJ, López-Giráldez F, Ricciardi A, Beloor J, Krause DS, Kumar P, Gallagher PG, Braddock DT, Mark Saltzman W, Ly DH, Glazer PM. In vivo correction of anaemia in β-thalassemic mice by γPNA-mediated gene editing with nanoparticle delivery. Nature Communications 2016, 7: 13304. PMID: 27782131, PMCID: PMC5095181, DOI: 10.1038/ncomms13304.Peer-Reviewed Original ResearchConceptsNanoparticle deliveryGene correctionReversal of splenomegalyPeptide nucleic acidLow off-target effectsVivo correctionGenome editingOff-target effectsGene editingHaematopoietic stem cellsNucleic acidsDonor DNAStem cellsΓPNAΒ-thalassaemiaNanoparticlesDeliveryEditingSCF treatmentTriplex formationCTCF and CohesinSA-1 Mark Active Promoters and Boundaries of Repressive Chromatin Domains in Primary Human Erythroid Cells
Steiner LA, Schulz V, Makismova Y, Lezon-Geyda K, Gallagher PG. CTCF and CohesinSA-1 Mark Active Promoters and Boundaries of Repressive Chromatin Domains in Primary Human Erythroid Cells. PLOS ONE 2016, 11: e0155378. PMID: 27219007, PMCID: PMC4878738, DOI: 10.1371/journal.pone.0155378.Peer-Reviewed Original ResearchMeSH KeywordsBinding SitesCCCTC-Binding FactorCells, CulturedChromatinChromatin ImmunoprecipitationErythroid CellsErythropoiesisGene Expression ProfilingHematopoietic Stem CellsHigh-Throughput Nucleotide SequencingHumansK562 CellsNuclear ProteinsPromoter Regions, GeneticProtein BindingProtein Interaction MapsRepressor ProteinsSequence Analysis, RNAConceptsPrimary human erythroid cellsRepressive chromatin domainsHuman erythroid cellsChromatin domainsErythroid cellsChromatin architectureGene promoterGene expressionPrimary human hematopoietic stemCell type-specific mannerCritical cellular processesSites of CTCFGenome-wide dataHigh-throughput sequencingMRNA transcriptome analysisHuman hematopoietic stemRepressive chromatinCohesin sitesProtein occupancyInsulator functionRepressive domainsTranscriptional regulationCTCF sitesDomain architectureRelated gene expression
2015
Pomalidomide reverses γ-globin silencing through the transcriptional reprogramming of adult hematopoietic progenitors
Dulmovits BM, Appiah-Kubi AO, Papoin J, Hale J, He M, Al-Abed Y, Didier S, Gould M, Husain-Krautter S, Singh SA, Chan KW, Vlachos A, Allen SL, Taylor N, Marambaud P, An X, Gallagher PG, Mohandas N, Lipton JM, Liu JM, Blanc L. Pomalidomide reverses γ-globin silencing through the transcriptional reprogramming of adult hematopoietic progenitors. Blood 2015, 127: 1481-1492. PMID: 26679864, PMCID: PMC4797024, DOI: 10.1182/blood-2015-09-667923.Peer-Reviewed Original ResearchMeSH KeywordsAdultAnemia, Sickle CellBeta-GlobinsCarrier ProteinsErythroid Precursor CellsErythropoiesisFetal HemoglobinGamma-GlobinsGene Expression Regulation, DevelopmentalGenetic VectorsHematopoietic Stem CellsHistone DemethylasesHumansIkaros Transcription FactorKruppel-Like Transcription FactorsLentivirusMultiple MyelomaNeoplasm ProteinsNuclear ProteinsProteasome Endopeptidase ComplexRepressor ProteinsRNA InterferenceRNA, Small InterferingSOXD Transcription FactorsThalidomideTranscription, GeneticConceptsSickle cell anemiaCell anemiaΓ-globinThird-generation immunomodulatory drugAdult human erythroblastsMultiple myeloma patientsHematopoietic progenitorsΓ-globin levelsΓ-globin repressionCurrent therapeutic strategiesErythroid differentiation programFetal hemoglobinAdult hematopoietic progenitorsPomalidomide treatmentImmunomodulatory drugsMyeloma patientsTranscriptional reprogrammingFetal hemoglobin productionTranscription networksTherapeutic strategiesDifferentiation programPomalidomideHuman erythroblastsΒ-hemoglobinopathiesGenetic ablation
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
2000
Gene transfer to ankyrin-deficient bone marrow corrects spherocytosis in vitro
Dooner G, Barker J, Gallagher P, Debatis M, Brown A, Forget B, Becker P. Gene transfer to ankyrin-deficient bone marrow corrects spherocytosis in vitro. Experimental Hematology 2000, 28: 765-774. PMID: 10907638, DOI: 10.1016/s0301-472x(00)00185-5.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAnkyrinsBlotting, WesternBone MarrowCell LineElectrophoresis, Polyacrylamide GelErythropoietinGene Transfer TechniquesGenetic TherapyHematopoietic Stem CellsHumansIn Vitro TechniquesMiceMice, Inbred BALB CRetroviridaeReverse Transcriptase Polymerase Chain ReactionSpherocytosis, HereditaryConceptsMEL cellsAnkyrin promoterGene transferDependence of expressionMurine bone marrow cellsMurine erythroleukemia cellsNormal murine bone marrow cellsRetroviral vectorsNbs mutantsMutant bone marrowMurine 3T3 fibroblastsNB cellsAnkyrin proteinsMutant cellsPolymerase chain reactionErythroid differentiation culturesHuman hemolytic anemiasColony polymerase chain reactionRT-PCRErythroid expressionBone marrow progenitorsErythroleukemia cellsDifferentiation culturesAnkyrinWestern blot analysis