grant

Project-003

Organization UNIVERSITY OF CALIFORNIA, SAN FRANCISCOLocation SAN FRANCISCO, UNITED STATESPosted 17 Feb 2022Deadline 31 Jan 2027
NIHUS FederalResearch GrantFY2026APRF proteinAblationAcute-Phase Response FactorAffectAldaraAllogenicAnimalsAutoimmune DiseasesAutoimmune StatusAutoimmunityAutomobile DrivingB-Cell Differentiation Factor GeneB-Cell Stimulatory Factor 2 GeneBSF-2 GeneBSF2 GeneBeta-2 Gene InterferonBiologyBlood Precursor CellCRISPRCRISPR approachCRISPR based approachCRISPR editing screenCRISPR methodCRISPR methodologyCRISPR screenCRISPR techniqueCRISPR technologyCRISPR toolsCRISPR-CAS-9CRISPR-based methodCRISPR-based screenCRISPR-based techniqueCRISPR-based technologyCRISPR-based toolCRISPR/CAS approachCRISPR/Cas methodCRISPR/Cas systemCRISPR/Cas technologyCRISPR/Cas9CRISPR/Cas9 screenCRISPR/Cas9 technologyCas nuclease technologyCausalityCell BodyCell CommunicationCell Communication and SignalingCell Culture SystemCell Culture TechniquesCell DifferentiationCell Differentiation processCell FunctionCell InteractionCell PhysiologyCell ProcessCell SignalingCell SurvivalCell TherapyCell ViabilityCell modelCell-to-Cell InteractionCellsCellular FunctionCellular PhysiologyCellular ProcessCellular modelChemosensitizationChemosensitization/PotentiationClustered Regularly Interspaced Short Palindromic RepeatsClustered Regularly Interspaced Short Palindromic Repeats approachClustered Regularly Interspaced Short Palindromic Repeats methodClustered Regularly Interspaced Short Palindromic Repeats methodologyClustered Regularly Interspaced Short Palindromic Repeats techniqueClustered Regularly Interspaced Short Palindromic Repeats technologyComplexCoupledCritical PathsCritical PathwaysDNA SequenceDNA TherapyDNA mutationDevelopmentDifferentiation in cell cultureDiseaseDisorderElectroporationEpistatic GeneEtiologyExonsFamilyFutureGene TargetingGene TranscriptionGene Transfer ClinicalGenesGeneticGenetic ChangeGenetic InterventionGenetic ScreeningGenetic TranscriptionGenetic defectGenetic mutationGenomeGenome engineeringGenomic approachGenomicsGerm-Line MutationGrantGuide RNAHSC transplantationHSF GeneHematopoietic Progenitor CellsHematopoietic Stem Cell TransplantHematopoietic Stem Cell TransplantationHematopoietic stem cellsHepatocyte Stimulatory Factor GeneHereditary MutationHeterozygoteHumanHuman GeneticsHybridoma Growth Factor GeneIFNB2 GeneIL-6 GeneIL6IL6 geneIL6-response factorImiquimodImmuneImmune ToleranceImmune responseImmune systemImmunesImmunochemical ImmunologicImmunologicImmunologic ModelImmunologic ToleranceImmunologicalImmunological ModelsImmunologicallyImmunologicsIn VitroIn vitro cell differentiationInflammationInflammatoryInterleukin 6 (Interferon, Beta 2) GeneInterleukin-6 GeneIntracellular Communication and SignalingInvestigationKnock-outKnockoutLIF-response factorLibrariesLymphoproliferative DisordersMapsMediatingMethodsMiceMice MammalsModelingModern ManModernizationMolecularMurineMusMutationOrganP01 MechanismP01 ProgramPathogenesisPathogenicityPathologyPathway interactionsPatientsPeripheralPhenotypePhysiologicPhysiologicalPositionPositioning AttributePotentiationProgram Project GrantProgram Research Project GrantsRNA ExpressionRegulatory T-LymphocyteResearch Program ProjectsRibonucleoproteinsSamplingScientistSignal Transducer and Activator of Transcription 3Signal TransductionSignal Transduction SystemsSignalingSiteSkinSourceStat3 proteinSubcellular ProcessSurvey InstrumentSurveysSyndromeSystemT cell responseT-CellsT-LymphocyteTechnologyTestingTherapy Clinical TrialsTimeTranscriptionTregValidationVariantVariationWorkautoimmune conditionautoimmune disorderautoimmunity diseasebiological signal transductionblood cell progenitorblood progenitorblood stem cellblood stem cell transplantationblood-forming stem cellcausationcell based interventioncell culturecell culturescell mediated interventioncell mediated therapiescell typecell-based therapeuticcell-based therapycellular differentiationcellular therapeuticcellular therapyclustered regularly interspaced short palindromic repeats screencurative interventioncurative therapeuticcurative therapycurative treatmentscytokinedesigndesigningdevelopmentaldifferentiation in culturedifferentiation in vitrodiscover genesdisease causationdrivingdrug developmentearly onsetelectroporative deliveryentire genomeexperimentexperimental researchexperimental studyexperimentsfull genomefunctional genomicsfunctional improvementgRNAgain of functiongene correctedgene correctiongene discoverygene electrotransfergene interactiongene repair therapygene therapygene-based therapygenetic approachgenetic strategygenetic therapygenome editinggenome mutationgenome scalegenome wide screengenome-widegenomewidegenomic correctiongenomic editinggenomic effortgenomic strategygenomic therapygerm-line defectgermline varianthematopoietic cell transplantationhematopoietic cellular transplantationhematopoietic progenitorhematopoietic progenitor cell transplantationhematopoietic stem progenitor cellhemopoietic progenitorhemopoietic stem cellheterozygosityhost responseimmune system responseimmune system toleranceimmune unresponsivenessimmunological paralysisimmunoresponseimprove functionimprovedimproved functional outcomesin vitro cellular differentiationin vivoinhibitorinsightlymphoproliferative diseasemouse modelmurine modelmutation correctionnew drug treatmentsnew drugsnew pharmacological therapeuticnew therapeuticsnew therapynext generation therapeuticsnovelnovel drug treatmentsnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel therapeuticsnovel therapypathwaypre-clinicalpreclinicalpreservationprogramsregulatory T-cellssynergismtherapeutic targetthymus derived lymphocytevalidationswhole genome
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Full Description

Project Summary/Abstract Signal transducer and activator of transcription 3 (STAT3) gain of function (GOF) germline mutations are a monogenic cause of a syndrome of early-onset multiorgan autoimmune and lymphoproliferative disease for which the only current definitive cure is an allogeneic hematopoietic stem cell transplant. Despite the clear genetic understanding of this syndrome, mechanistic cellular and molecular understanding of this syndrome remains obscure, particularly with regards to the STAT3 GOF effects on T cells, the cell type thought to be responsible for much of the autoimmunity seen in STAT3 GOF patients. This proposal is part of a Program Project Grant that seeks to gain mechanistic insight into the immunological etiology of this disease incorporating human patient samples, mechanistic mouse studies, T cell culture experiments, and functional genomics approaches. This specific Project within the Program Grant seeks to leverage functional genomics approaches powered by CRISPR-Cas9 technology to understand how STAT3 GOF variants affect T cell function.

CRISPR- Cas9 genome engineering technology is driving a revolution in modern biology. Scientists now possess unprecedented capabilities to test the cellular functions of human genetic sequences and correct mutations that cause disease directly in primary mouse and human cells. Of relevance to this Project proposal, our lab has pioneered methods and systems to conduct targeted and genome-wide knockout screens in primary T cells from mice and humans. Further, we have developed an efficient method for orthogonal validations using Cas9:single- guide RNA ribonucleoprotein (Cas9 RNP) electroporation coupled with multiplexed flow cytometric phenotyping.

These advances now position us to use functional genomics approaches in mouse and human T cells to reveal novel pathways that control abnormal T cell function in STAT3 GOF syndrome, prioritize novel targets in further studies for drug development, and improve the design of genetically reprogrammed cell-based therapies. Specifically, Project 3 seeks to implement unbiased CRISPR functional genetic approaches in mouse T cells modeling STAT3 GOF mutations to identify critical gene targets that modulate STAT3-mediated inflammation (Aim 1a, 1b). Further, we seek to leverage the information from these screens to improve function in human patient T cells (Aim 1c). Finally, Project 3 seeks to use cutting-edge non-viral CRISPR based methods to correct STAT3 GOF mutations in actual patient T cells, as well as to develop a preclinical approach to replace selected STAT3 exons in primary human hematopoietic stem progenitor cells (HSPCs) (Aim 2).

Taken together, these studies will form the basis for a framework to understand how STAT3 GOF variants alter T cell function to drive inflammatory disease as well as open multiple avenues towards immune cell CRISPR gene targeting to treat autoimmunity.

Grant Number: 5P01AI155393-05
NIH Institute/Center: NIH
Principal Investigator: Mark Anderson

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