grant

Project 1. Regulation of Mast Cell Homeostasis in Type 2 Immunopathology

Organization BRIGHAM AND WOMEN'S HOSPITALLocation BOSTON, UNITED STATESPosted 15 Jul 2011Deadline 31 Oct 2026
NIHUS FederalResearch GrantFY202521+ years old3-D3-Dimensional3DAcetylsalicylic AcidAdultAdult HumanAnatomic SitesAnatomic structuresAnatomyAspirinAsthmaAutomobile DrivingAutoregulationB Cell-Activating Factor ReceptorB cell differentiation factorB cell stimulating factor 2B-Cell Differentiation FactorB-Cell Differentiation Factor-2B-Cell Stimulatory Factor-2BCDFBSF-2BSF2Body TissuesBronchial AsthmaCD124 AntigensCDw124 AntigenCOX-1COX-1 proteinCell BodyCell CommunicationCell Communication and SignalingCell CountCell FunctionCell Growth in NumberCell InteractionCell MultiplicationCell NumberCell PhysiologyCell ProcessCell ProliferationCell SignalingCell-to-Cell InteractionCellsCellular FunctionCellular PhysiologyCellular ProcessCellular ProliferationCharacteristicsChymaseCollaborationsConsumptionCuesCyclo-Oxygenase-1Cyclooxygenase 3Cytokine Signal TransductionCytokine SignalingDataDevelopmentDiagnosticDinoprostoneDiseaseDisorderDrugsDysfunctionEffector CellEosinophiliaEpitheliumEthicsFatty Acid CyclooxygenaseFibroblastsFunctional disorderGP130Gene TranscriptionGenetic TranscriptionGoalsHPGFHealth ExpendituresHepatocyte-Stimulating FactorHeterogeneityHomeostasisHumanHybridoma Growth FactorIFN-beta 2IFNB2IL-4 ReceptorsIL-6IL4 ReceptorsIL6 ProteinIL6STIL6ST geneIgEImmuneImmune responseImmunesImmunoglobulin EIndividualInterleukin 4 ReceptorInterleukin 6 Signal TransducerInterleukin-4 Receptor AlphaInterleukin-6Intracellular Communication and SignalingLipidsMGI-2MMCP-1MapsMarrow Mast CellMast-Cell DiseaseMediatorMedicationModern ManMolecularMucosaMucosal TissueMucous MembraneMultiple PolypsMyeloid Differentiation-Inducing ProteinNasalNasal Cavity PolypNasal Passages NoseNasal PolypsNetwork AnalysisNoseObstructionOnset of illnessOrganPGE2PGE2 alphaPGE2alphaPGH Synthase 1PathogenesisPathway AnalysisPathway interactionsPatientsPharmaceutical PreparationsPhenotypePhysiological HomeostasisPhysiopathologyPlasmacytoma Growth FactorPopulationProgenitor CellsProliferatingProliferation MarkerProstaglandin E2Prostaglandin E2 alphaProstaglandin E2alphaProstaglandin G/H Synthase 1Prostaglandin H2 SynthaseProstaglandin H2 Synthase 1Prostaglandin-Endoperoxide Synthase 1Pulmonary Body SystemPulmonary Organ SystemRNA ExpressionReactionRegulationRespiratory DiseaseRespiratory SystemRespiratory System DiseaseRespiratory System DisorderRespiratory System, Nose, Nasal PassagesRespiratory Tract DiseasesRespiratory TractsRespiratory tract structureRoleSamter's triadSignal TransductionSignal Transduction SystemsSignalingStromal CellsSubcellular ProcessSystemTestingTherapeuticTissue BasophilsTissuesTranscriptionTryptaseTumorigenicityadulthoodairflow limitationairflow obstructionairway limitationairway obstructionaspirin-exacerbated respiratory diseaseaspirin-induced asthmabiological signal transductionchronic rhinosinusitischymase-1chymotrypsin-like proteasecyclo-oxygenase Icyclooxygenase 1cytokinedevelopmentaldisease onsetdisorder onsetdrivingdrug/agentethicalgp130 Transducer Chainhealth care expenditurehost responseimmune system responseimmunopathologyimmunoresponsein vivointerferon beta 2leukemialung tryptasemast cellmast cell hyperplasiamast cell proteasemast cell protease 1mast cell protease Imast cell protease IImast cell proteinase-1mast cell tryptasemastocytemastocytosismedical expenditurenovelobstructed airflowobstructed airwaypathophysiologypathwaypolyposisprogramsprostaglandin H synthase-1recruitrespiratoryrespiratory airway obstructionskeletal muscle proteaseskin tryptasesocial rolestem cellstherapeutic targetthree dimensional
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Full Description

Abstract/Summary
This Project focuses on the mechanisms responsible for mast cell (MC) hyperplasia, heterogeneity, and
activation that are characteristic of chronic rhinosinusitis with nasal polyposis (CRSwNP), especially in aspirin
exacerbated respiratory disease (AERD). Studies in the current iteration of this AADCRC suggest that
canonical mast cell subtypes expressing tryptase and chymase (MCTC) or tryptase alone (MCT) emerge from a
novel CD117hiCD38hi transitional MC population that is enriched for markers of proliferation and activation.
New data suggest that fibroblast-derived factors drive the emergence of this proliferating MC population from
circulating MC progenitors (MCp), and that stromal cells conspire with cytokines (particularly IL-4Rα-active
cytokines and IL-33) to drive different MC effector functions in correspondingly different anatomic
compartments of the sinonasal mucosa. An unsupervised network analysis combined with functional studies in
a novel 3-dimensional culture system reveals a likely feed-forward system between MC-derived LIF and
fibroblast-derived IL-6 that may promote MC expansion and activation, and is greatly facilitated by IL-4Rα
signaling at both MCs and fibroblasts. This Project combines hypothesis-testing and unbiased approaches to
understand the developmental origins of MCs, the functional control of MC expansion and activation in T2I,
and the mechanisms by which MCs in turn influence stromal cell function in this context. The long-term overall
goals are to precisely identify the cell-intrinsic and -extrinsic factors most responsible for driving MC
hyperplasia and influencing their effector function in respiratory T2I, to understand the local consequences of
MC hyperplasia in tissue function, and to identify potential therapeutic targets. Aim 1 will map the molecular
transitions between circulating MCp and their putative tissue descendants and determine the developmental
origins of proliferation-enriched transitional MCs. Aim 2 will identify the mechanisms by which fibroblasts and
EpCs facilitate the development of subepithelial MCTC and transitional MCs and potentiate their activation in
the setting of T2I. Aim 3 will determine the role of stromal cell-amplified MC-derived mediators, including LIF,
in driving MC-stromal cell interactions in T2I. The project is integral to the overall goals of the AADCRC, and
involves substantial interactions with the other two Projects.

Grant Number: 5U19AI095219-15
NIH Institute/Center: NIH
Principal Investigator: Joshua Boyce

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