grant

Influences of DNA sequence and histone features on transcription factor binding to nucleosomes

Organization BRIGHAM AND WOMEN'S HOSPITALLocation BOSTON, UNITED STATESPosted 1 Sept 2022Deadline 30 Jun 2026
NIHUS FederalResearch GrantFY2025AffectAssayBasal Transcription FactorBasal transcription factor genesBindingBinding SitesBioassayBiochemicalBiological AssayBreathingCausalityCell BodyCell DifferentiationCell Differentiation processCellsChIP SequencingChIP-seqChIPseqChromatinCombining SiteComputer AnalysisCyclicityDNADNA BindingDNA Binding DomainDNA Binding InteractionDNA SequenceDNA boundDNA-Binding Protein MotifsDataDeoxyribonucleic AcidElementsEpigeneticEpigenetic ChangeEpigenetic MechanismEpigenetic ProcessEtiologyEukaryotaEukaryoteFamilyGatekeepingGene Action RegulationGene ExpressionGene Expression RegulationGene RegulationGene Regulation ProcessGene TranscriptionGeneral Transcription Factor GeneGeneral Transcription FactorsGenesGenetic TranscriptionGenetsGenomeGenomicsHeterochromatinHigh Throughput AssayHistone H2AHistonesHumanIn VitroIn vivo analysisInvadedManuscriptsModern ManMolecular InteractionMolecular Modeling Nucleic Acid BiochemistryMolecular Modeling Protein/Amino Acid BiochemistryMolecular ModelsNuclearNucleic Acid Regulator RegionsNucleic Acid Regulatory SequencesNucleosomesPeriodicityPlayPositionPositioning AttributePost-Translational Modification Protein/Amino Acid BiochemistryPost-Translational ModificationsPost-Translational Protein ModificationPost-Translational Protein ProcessingPosttranslational ModificationsPosttranslational Protein ProcessingPreparationPropertyProtein ModificationRNA ExpressionReactive SiteReaderRegulator GenesRegulatory ElementRegulatory RegionsRespiratory AspirationRespiratory InspirationRhythmicityRoleSiteSlideSpecificitySurvey InstrumentSurveysTechnologyTranscriptionTranscription Factor Proto-OncogeneTranscription factor genesTranscriptional Regulatory ElementsVariantVariationcausationcell typecellular differentiationchromatin immunoprecipitation coupled with sequencingchromatin immunoprecipitation followed by sequencingchromatin immunoprecipitation with sequencingchromatin immunoprecipitation-seqchromatin immunoprecipitation-sequencingcofactorcomputational analysescomputational analysiscomputer analysesdisease causationepigeneticallygatekeepergenetic regulatory elementgenetic trans acting elementgenomic datagenomic datasethigh throughput screeninghigh throughput technologyhistone modificationin vivoin vivo evaluationin vivo testinginspirationmolecular modelingnovelpreferencepreparationsprogramsreconstitutereconstitutionrecruitregulatory genesocial roletrans acting elementtranscription factor
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Full Description

Abstract
Gene expression programs are dynamically regulated by the accessibility of chromatin for
transcription factor (TF) binding, but how TFs recognize specific regulatory regions occluded by
nucleosomes remains unclear. Certain TFs, termed pioneer factors, can recognize their target
sites within nucleosomes, leading to the opening of chromatin. By priming cis-regulatory
elements for subsequent transcriptional regulatory activity, pioneers serve as gatekeepers to
cellular differentiation. Although pioneers can bind nucleosomal sites, they bind only a subset of
their potential recognition sites in the genome that typically varies across cell types, thus
indicating their interplay with sequence, epigenetic or other cellular features.
Despite the importance of pioneer factors, what restricts pioneer binding is poorly understood.
Little is known about how the sequence context of their sites in nucleosomes, the presence of
histone variants or post-translational modifications (PTMs) of histones, or interactions with
cofactors or chromatin readers that recognize those PTMs might influence pioneer binding to
nucleosomes. No high-throughput technologies have been developed to survey the impact of
these many parameters on TF pioneer binding.
In this project, we will develop novel, high-throughput biochemical assays to investigate how
nucleosomal sequence context, histone variants or histone PTMs influence pioneer binding of
human TFs to nucleosomes. We will also investigate the interplay of pioneers, cofactors, and
chromatin readers in pioneer binding. Results from these biochemical assays will be validated in
vitro and used in analysis of in vivo genomic data in human cells to understand how these
various features contribute to TF pioneer binding in cells.
As pioneer factors play crucial roles at the top of regulatory hierarchies, these results will aid in
understanding how gene regulation of cell states is encoded in the genome and the
mechanisms by which it is read out.

Grant Number: 5R01HG012246-04
NIH Institute/Center: NIH
Principal Investigator: MARTHA BULYK

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