2015
Transcriptome Signature and Regulation in Human Somatic Cell Reprogramming
Tanaka Y, Hysolli E, Su J, Xiang Y, Kim KY, Zhong M, Li Y, Heydari K, Euskirchen G, Snyder MP, Pan X, Weissman SM, Park IH. Transcriptome Signature and Regulation in Human Somatic Cell Reprogramming. Stem Cell Reports 2015, 4: 1125-1139. PMID: 26004630, PMCID: PMC4471828, DOI: 10.1016/j.stemcr.2015.04.009.Peer-Reviewed Original ResearchMeSH KeywordsAlternative SplicingAnimalsBase SequenceCellular ReprogrammingCyclin EEmbryonic Stem CellsGene Expression RegulationHumansInduced Pluripotent Stem CellsKruppel-Like Factor 4Kruppel-Like Transcription FactorsMiceMolecular Sequence DataOctamer Transcription Factor-3Oncogene ProteinsPolymorphism, Single NucleotidePrincipal Component AnalysisProto-Oncogene Proteins c-mycRNASequence Analysis, RNASOXB1 Transcription FactorsTranscriptomeConceptsHuman somatic cell reprogrammingMonoallelic gene expressionSomatic cell reprogrammingPrevious transcriptome studiesHuman iPSC reprogrammingPluripotent stem cellsCell reprogrammingIPSC reprogrammingTranscriptome dataEarly reprogrammingTranscriptome studiesTranscriptome changesBiallelic expressionRNA-seqSomatic cellsExpression analysisGene expressionSpliced formsReprogrammingTranscriptome signaturesStem cellsInvaluable resourceCellular surface markersBiomedical researchCells
2014
Histone Variant H2A.X Deposition Pattern Serves as a Functional Epigenetic Mark for Distinguishing the Developmental Potentials of iPSCs
Wu T, Liu Y, Wen D, Tseng Z, Tahmasian M, Zhong M, Rafii S, Stadtfeld M, Hochedlinger K, Xiao A. Histone Variant H2A.X Deposition Pattern Serves as a Functional Epigenetic Mark for Distinguishing the Developmental Potentials of iPSCs. Cell Stem Cell 2014, 15: 281-294. PMID: 25192463, DOI: 10.1016/j.stem.2014.06.004.Peer-Reviewed Original ResearchConceptsEmbryonic stem cellsLineage gene expressionHistone variant H2A.XCell lineage commitmentDevelopmental potentialMouse iPSC linesIPSC linesPluripotent stem cell (iPSC) technologyEpigenetic marksLineage genesEpigenetic mechanismsLineage commitmentLineage differentiationExtraembryonic differentiationStem cell technologyGene expressionTetraploid complementationIPSC clonesIPSC qualityStem cellsFunctional markersH2A.XDifferentiationIPSCsComplementation
2013
Transcriptional regulation in pluripotent stem cells by methyl CpG-binding protein 2 (MeCP2)
Tanaka Y, Kim KY, Zhong M, Pan X, Weissman SM, Park IH. Transcriptional regulation in pluripotent stem cells by methyl CpG-binding protein 2 (MeCP2). Human Molecular Genetics 2013, 23: 1045-1055. PMID: 24129406, PMCID: PMC3900111, DOI: 10.1093/hmg/ddt500.Peer-Reviewed Original ResearchConceptsPluripotent stem cellsMutant MECP2X chromosomeMethyl-CpGStem cellsGene expressionLong-range chromatin interactionsFundamental cellular physiologyRett syndromeMitochondrial membrane proteinInactive X chromosomeProtein 2Chromatin interactionsTranscriptional regulationTranscription regulatorsCellular physiologyTranscriptome analysisLoss of functionMembrane proteinsMeCP2 resultsDe novo mutationsRegulatory mechanismsMeCP2ChromosomesRTT patients
2010
Integrative Analysis of the Caenorhabditis elegans Genome by the modENCODE Project
Gerstein MB, Lu ZJ, Van Nostrand EL, Cheng C, Arshinoff BI, Liu T, Yip KY, Robilotto R, Rechtsteiner A, Ikegami K, Alves P, Chateigner A, Perry M, Morris M, Auerbach RK, Feng X, Leng J, Vielle A, Niu W, Rhrissorrakrai K, Agarwal A, Alexander RP, Barber G, Brdlik CM, Brennan J, Brouillet JJ, Carr A, Cheung MS, Clawson H, Contrino S, Dannenberg LO, Dernburg AF, Desai A, Dick L, Dosé AC, Du J, Egelhofer T, Ercan S, Euskirchen G, Ewing B, Feingold EA, Gassmann R, Good PJ, Green P, Gullier F, Gutwein M, Guyer MS, Habegger L, Han T, Henikoff JG, Henz SR, Hinrichs A, Holster H, Hyman T, Iniguez AL, Janette J, Jensen M, Kato M, Kent WJ, Kephart E, Khivansara V, Khurana E, Kim JK, Kolasinska-Zwierz P, Lai EC, Latorre I, Leahey A, Lewis S, Lloyd P, Lochovsky L, Lowdon RF, Lubling Y, Lyne R, MacCoss M, Mackowiak SD, Mangone M, McKay S, Mecenas D, Merrihew G, Miller DM, Muroyama A, Murray JI, Ooi SL, Pham H, Phippen T, Preston EA, Rajewsky N, Rätsch G, Rosenbaum H, Rozowsky J, Rutherford K, Ruzanov P, Sarov M, Sasidharan R, Sboner A, Scheid P, Segal E, Shin H, Shou C, Slack FJ, Slightam C, Smith R, Spencer WC, Stinson EO, Taing S, Takasaki T, Vafeados D, Voronina K, Wang G, Washington NL, Whittle CM, Wu B, Yan KK, Zeller G, Zha Z, Zhong M, Zhou X, Consortium M, Ahringer J, Strome S, Gunsalus KC, Micklem G, Liu XS, Reinke V, Kim SK, Hillier LW, Henikoff S, Piano F, Snyder M, Stein L, Lieb JD, Waterston RH. Integrative Analysis of the Caenorhabditis elegans Genome by the modENCODE Project. Science 2010, 330: 1775-1787. PMID: 21177976, PMCID: PMC3142569, DOI: 10.1126/science.1196914.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCaenorhabditis elegansCaenorhabditis elegans ProteinsChromatinChromosomesComputational BiologyConserved SequenceEvolution, MolecularGene Expression ProfilingGene Expression RegulationGene Regulatory NetworksGenes, HelminthGenome, HelminthGenomicsHistonesModels, GeneticMolecular Sequence AnnotationRegulatory Sequences, Nucleic AcidRNA, HelminthRNA, UntranslatedTranscription FactorsConceptsAccurate gene modelsGenome-wide identificationTranscription factor-binding sitesKey model organismTranscription factor bindingAlternative splice formsFactor-binding sitesChromatin compositionModENCODE projectChromatin organizationHistone modificationsGenome annotationModel organismsNematode CaenorhabditisChromosomal locationPutative functionsGene modelsTranscriptome profilingChromosome armsTranscription factorsNoncoding RNAsFactor bindingSplice formsX chromosomeGene expression