2021
Roles of piRNAs in transposon and pseudogene regulation of germline mRNAs and lncRNAs
Wang C, Lin H. Roles of piRNAs in transposon and pseudogene regulation of germline mRNAs and lncRNAs. Genome Biology 2021, 22: 27. PMID: 33419460, PMCID: PMC7792047, DOI: 10.1186/s13059-020-02221-x.Peer-Reviewed Original ResearchConceptsPIWI-interacting RNAsPIWI proteinsRole of piRNAsPIWI-piRNA pathwayRNA-binding proteinSmall noncoding RNAsGermline mRNAsGermline developmentNoncoding RNAsRegulatory relationshipsGerm cellsRNAProteinTransposonMajor classesRNA levelsRecent studiesExpressionGenomeSubfamiliesGermlineLncRNAsMajor constituentsMRNARegulation
2016
Change point analysis of histone modifications reveals epigenetic blocks linking to physical domains
Chen M, Lin H, Zhao H. Change point analysis of histone modifications reveals epigenetic blocks linking to physical domains. The Annals Of Applied Statistics 2016, 10: 506-526. PMID: 27231496, PMCID: PMC4876974, DOI: 10.1214/16-aoas905.Peer-Reviewed Original ResearchHistone modificationsHistone marksLocal chromatin environmentDistribution of genesWhole-genome analysisRelevant biological functionsEnrichment patternsSimilar enrichment patternsHigh-throughput techniquesChromatin environmentChromatin organizationEpigenetic blockTranscriptional outputGene regulationTranscriptional controlOrchestrated regulationEpigenetic mechanismsGO enrichmentTranscription levelsBiological functionsCombinatorial patternsGenomeGenesRegulationEukaryotes
2015
Embryonic Stem Cells License a High Level of Dormant Origins to Protect the Genome against Replication Stress
Ge XQ, Han J, Cheng EC, Yamaguchi S, Shima N, Thomas JL, Lin H. Embryonic Stem Cells License a High Level of Dormant Origins to Protect the Genome against Replication Stress. Stem Cell Reports 2015, 5: 185-194. PMID: 26190528, PMCID: PMC4618655, DOI: 10.1016/j.stemcr.2015.06.002.Peer-Reviewed Original ResearchConceptsEmbryonic stem cellsStem/progenitor cellsNeural stem/progenitor cellsStem cellsProgenitor cellsTissue stem/progenitor cellsMCM2-7 complexDNA replication originsTissue-specific stem/progenitor cellsStem cell typesGenome integrityGenomic integrityReplication stressDormant originsReplication forksReplicative stressDNA replicationReplication originsNeural lineagesDNA damageS phaseCell typesAbnormal neurogenesisCellsGenomeReassessment of Piwi Binding to the Genome and Piwi Impact on RNA Polymerase II Distribution
Lin H, Chen M, Kundaje A, Valouev A, Yin H, Liu N, Neuenkirchen N, Zhong M, Snyder M. Reassessment of Piwi Binding to the Genome and Piwi Impact on RNA Polymerase II Distribution. Developmental Cell 2015, 32: 772-774. PMID: 25805139, PMCID: PMC4472434, DOI: 10.1016/j.devcel.2015.03.004.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsArgonaute ProteinsBase SequenceBinding SitesChromatin ImmunoprecipitationChromobox Protein Homolog 5Chromosomal Proteins, Non-HistoneDNA-Binding ProteinsDrosophila melanogasterDrosophila ProteinsGenomeHigh-Throughput Nucleotide SequencingHistone MethyltransferasesHistone-Lysine N-MethyltransferaseMethyltransferasesRNA InterferenceRNA Polymerase IIRNA, Small InterferingSequence Analysis, DNAConceptsRNA polymerase II distributionGenomic targetsHeterochromatin protein 1aRNA polymerase IICurrent bioinformatics methodsPiwi mutantsDrosophila PiwiPolymerase IIDevelopmental cellsPericentric regionsHistone methyltransferaseBioinformatics methodsBioinformatics pipelineProtein 1APiwiGenomePiRNAsEuchromatinMutantsMethyltransferaseSites
2013
A Major Epigenetic Programming Mechanism Guided by piRNAs
Huang XA, Yin H, Sweeney S, Raha D, Snyder M, Lin H. A Major Epigenetic Programming Mechanism Guided by piRNAs. Developmental Cell 2013, 24: 502-516. PMID: 23434410, PMCID: PMC3600162, DOI: 10.1016/j.devcel.2013.01.023.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAnimals, Genetically ModifiedArgonaute ProteinsChromatinChromatin ImmunoprecipitationChromobox Protein Homolog 5Chromosomal Proteins, Non-HistoneDNA Transposable ElementsDrosophilaDrosophila ProteinsEpigenomicsGenomeGenomicsMethyltransferasesMutationReal-Time Polymerase Chain ReactionReverse Transcriptase Polymerase Chain ReactionRNA Polymerase IIRNA, MessengerRNA, Small InterferingConceptsSpecific genomic sitesEpigenetic factorsGenomic sitesRNA polymerase II associationPiwi-piRNA complexDrosophila genomeEpigenetic stateEpigenetic landscapeComplex associatesPiwiGenomePiRNAsCentral enigmaMajor mechanismEctopic sitesSequenceHP1aDrosophilaPiRNASitesEpigeneticsMechanismProgramming mechanismAssociatesRecruitment
2007
Drosophila PIWI associates with chromatin and interacts directly with HP1a
Brower-Toland B, Findley SD, Jiang L, Liu L, Yin H, Dus M, Zhou P, Elgin SC, Lin H. Drosophila PIWI associates with chromatin and interacts directly with HP1a. Genes & Development 2007, 21: 2300-2311. PMID: 17875665, PMCID: PMC1973144, DOI: 10.1101/gad.1564307.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid MotifsAnimalsArgonaute ProteinsBinding SitesChromatinChromobox Protein Homolog 5Chromosomal Proteins, Non-HistoneDrosophila melanogasterDrosophila ProteinsEmbryo, NonmammalianFemaleGene SilencingMaleModels, MolecularNuclear ProteinsProtein BindingProteinsRNA-Induced Silencing ComplexConceptsHeterochromatin protein 1aPIWI-interacting RNAsEpigenetic changesChromatin-associated proteinsProtein family membersNormal silencingHeterochromatic genesFly genomeHeterochromatin componentsChromatin modifiersEpigenetic stateEpigenetic regulationRNA mechanismFruit flyPiwiTerminal domainProtein 1ACentral playerRNASpecific sequencesDirect interactionGenomeGenesMotifCellular systems