grant

Regulation of B cell signaling in autoimmunity by TRAF3

Organization UNIVERSITY OF IOWALocation IOWA CITY, UNITED STATESPosted 1 Aug 2021Deadline 31 Jul 2026
NIHUS FederalResearch GrantFY2024Adaptor ProteinAdaptor Protein GeneAdaptor Signaling ProteinAdaptor Signaling Protein GeneAddressAffectAgeAgingAmericanAntibody-Producing CellsAppearanceAtrophic ArthritisAutoantibodiesAutoimmuneAutoimmune DiseasesAutoimmune StatusAutoimmunityB blood cellsB cellB cell receptorB cellsB lymphomaB-Cell ActivationB-Cell Antigen ReceptorB-Cell DevelopmentB-Cell LymphomasB-CellsB-LymphocytesB-cellBlood CellsBlood leukocyteBody TissuesBp50CD40CD40 Receptor-Associated Factor 1CD40bp ProteinCDW40CRAF1 ProteinCancersCell BodyCell Communication and SignalingCell CompartmentationCell CompartmentationsCell FunctionCell LineCell PhysiologyCell ProcessCell SignalingCell SurvivalCell ViabilityCellLineCellsCellular FunctionCellular PhysiologyCellular ProcessChronicComplexDataDevelopmentDiseaseDisorderDisseminated SclerosisEventFutureGeneticGerminoblastic SarcomaGerminoblastomaGoalsHematopoietic Cell TumorHematopoietic MalignanciesHematopoietic NeoplasmsHematopoietic Neoplasms including LymphomasHematopoietic TumorHematopoietic and Lymphoid Cell NeoplasmHematopoietic and Lymphoid NeoplasmsHumanImmunoglobulin-Producing CellsImmunologic ReceptorsImmunological ReceptorsImmunosuppressionImmunosuppression EffectImmunosuppressive EffectIn VitroIndividualInflammationInflammatoryInterruptionIntracellular Communication and SignalingKinasesKnowledgeLAP-1 ProteinLeadLeukocytesLeukocytes Reticuloendothelial SystemLifeLupus Erythematosus DisseminatusLymphomaLymphomagenesisMGC9013Malignant CellMalignant Hematopoietic NeoplasmMalignant LymphomaMalignant NeoplasmsMalignant TumorMarrow leukocyteMediatingMiceMice MammalsModelingModern ManMolecularMultiple SclerosisMurineMusNational Institutes of HealthOutcome StudyPKD proteinPathogenesisPathogenicityPathogenicity FactorsPathway interactionsPb elementPeripheral Blood CellPhenotypePhosphatasesPhosphohydrolasesPhosphomonoesterasesPhosphoric Monoester HydrolasesPhosphotransferase GenePhosphotransferasesPost-Translational Modification Protein/Amino Acid BiochemistryPost-Translational ModificationsPost-Translational Protein ModificationPost-Translational Protein ProcessingPosttranslational ModificationsPosttranslational Protein ProcessingProcessProtein ModificationProteinsReceptor ProteinReceptor SignalingRegulationReportingReticulolymphosarcomaRheumatoid ArthritisRiskSLESicca SyndromeSignal PathwaySignal TransductionSignal Transduction SystemsSignalingSjogren's SyndromeSjogrensSjögren SyndromeStrains Cell LinesSubcellular ProcessSystemic Lupus ErythematosusSystemic Lupus ErythematousSystemic Lupus ErythmatosusTLR proteinTNF receptor-associated factor 3TNFRSF5TNFRSF5 geneTRAF-3TRAF3TissuesToll-Like Receptor Family GeneToll-like receptorsTransphosphorylasesTumor Necrosis Factor Receptor Superfamily Member 5 GeneUnited States National Institutes of HealthVirulence FactorsWhite Blood CellsWhite CellWorkactivated B cellsadapter proteinadult youthaged animalaged animalsagesalleviate symptomameliorating symptomanimal old ageautoimmune antibodyautoimmune conditionautoimmune disorderautoimmune reactivityautoimmunity diseaseautoreactive B cellautoreactive antibodyautoreactivitybiological signal transductionblood cancercancer cellcancer of bloodcancer of the bloodcell typechronic inflammatory diseasecultured cell linedecrease symptomdevelopmentaldisseminated lupus erythematosuseffective therapyeffective treatmentelderly animalfewer symptomsheavy metal Pbheavy metal leadimmune receptorimmune suppressionimmune suppressive activityimmune suppressive functionimmunosuppressive activityimmunosuppressive functionimmunosuppressive responsein vivoinnate immune functioninsular sclerosismalignancymouse modelmurine modelneoplasm/cancerold animalsp50pathwaypre-clinicalpreclinicalpreventpreventingprotein kinase Dreceptorreceptor bindingreceptor boundreceptor-mediated signalingreduce symptomsrelieves symptomsrestraintrheumatic arthritisself reactive B cellself reactive antibodystress disordersymptom alleviationsymptom reductionsymptom reliefsystemic lupus erythematosistargeted drug therapytargeted drug treatmentstargeted therapeutictargeted therapeutic agentstargeted therapytargeted treatmentwhite blood cellwhite blood corpusclexerodermosteosisyoung adultyoung adulthood
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Full Description

The National Institutes of Health reports that > 23 million (~5-8%) of Americans suffer from chronic
inflammatory conditions, many of which involve the pathogenic functions of autoreactive B lymphocytes and
the autoantibodies they produce. Chronic inflammatory conditions also predispose to the subsequent
development of malignancies, such as B cell lymphoma, in the affected cells and tissues. There is thus a
critical window of opportunity in which alleviation of autoimmunity and chronic inflammation can also reduce
future risk of malignancies. However, many of the current treatments for B cell-mediated autoimmunity globally
deplete B cells, which can alleviate symptoms but result in immunosuppression. There is thus an ongoing
need for development and refinement of therapies that target the pathogenic function of autoreactive B cells.
The adapter protein TNF Receptor Associated Factor 3 (TRAF3) acts in a cell-type-specific manner to
suppress B cell signaling pathways contributing to both autoimmunity and malignancy, and loss of TRAF3
protein in B cells by inflammation-induced degradation creates chronic B cell TRAF3 deficiency. This
deficiency in turn predisposes to abnormally enhanced B cell survival and function, leading to autoimmunity in
young adults in a preclinical mouse model, and development of B cell lymphoma in these mice as they age.
This highlights a critical need to define how TRAF3 regulates B cell functions, the long-term goal of this work.
The objective of this project is to address the knowledge gap of how TRAF3 regulates signals via the B cell
antigen receptor (BCR) and the innate Toll-like Receptors (TLR) that are involved in autoimmunity, via the
following Specific Aims: (1) Identify the molecular mechanisms by which TRAF3 restrains BCR signaling and
BCR contributions to autoimmunity. (2) Define how TRAF3 inhibits B cell signals and functions of innate
immune Toll-like receptors (TLRs). (3) Determine how inhibition of TRAF3-regulated BCR and TLR signaling
pathways impacts development of autoimmunity in B cell-specific TRAF3-deficient mice (B-Traf3-/-). The
expected outcome of these studies is a detailed knowledge of how a deficiency in TRAF3, which is associated
with both aging and chronic B cell activation, contributes to B cell-mediated autoimmunity. This knowledge will
be valuable in selection and development of pathway-targeted therapies for autoimmune conditions.

Grant Number: 5R01AI162656-04
NIH Institute/Center: NIH
Principal Investigator: GAIL BISHOP

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