grant

Off-The-Shelf Dual Targeted NK Cells For NHL

Organization UNIVERSITY OF MINNESOTALocation MINNEAPOLIS, UNITED STATESPosted 1 Jul 2005Deadline 31 Mar 2027
NIHUS FederalResearch GrantFY2025ATAC sequencingATAC-seqATACseqAb-dependent cellular cytotoxicityAbnormal Assessment of MetabolismAdoptive TransferAffinityAllogenicAntigen TargetingAntigensAssay for Transposase-Accessible Chromatin using sequencingAutograftAutologousAutologous TransplantationAutotransplantB lymphomaB-Cell LymphomasBindingBp35C2B8 Monoclonal AntibodyCAR NKCAR T cellsCAR modified T cellsCAR-TCAR-TsCD16CD16BCD19CD19 geneCD20CD34CD34 geneCRISPRCRISPR/Cas systemCancer TreatmentCell BodyCell Death InductionCell FunctionCell LineCell PhysiologyCell ProcessCell surfaceCellLineCellsCellular FunctionCellular Metabolic ProcessCellular PhysiologyCellular ProcessChIP SequencingChIP-seqChIPseqClinicalClinical TrialsClipClone CellsClustered Regularly Interspaced Short Palindromic RepeatsCollaborationsCytotoxic cellDataDevelopmentDoseDose LimitingEngineeringEngraftmentEnzyme GeneEnzymesExhibitsFCGR3BFCGR3B geneFDA approvedFailureFc Receptor III-1Fc gamma IIIb receptorFc-Gamma RIII-BetaFc-Gamma RIIIBFcRIIIBFundingFutureGene DeletionGene ModifiedGenesGenetic EngineeringGenetic Engineering BiotechnologyGenetic Engineering Molecular BiologyGerminoblastic SarcomaGerminoblastomaGoalsHPCA1Half-LifeHeterogeneityIL-15IL15IL15 ProteinIgG Fc Receptor IIIBImmuneImmunesIn complete remissionIndividualInfusionInfusion proceduresInkInterleukin-15Interleukin-15 PrecursorIntermediary MetabolismInvestigationK lymphocyteKnock-outKnockoutLeu-16Low Affinity IgG Fc Receptor IIIBLow Affinity Immunoglobulin Gamma Fc Region Receptor III-BLymphomaMGC9721MS4A1MS4A1 geneMS4A2MabTheraMaintenance TherapyMalignantMalignant - descriptorMalignant LymphomaMalignant Neoplasm TherapyMalignant Neoplasm TreatmentMediatingMembraneMetabolicMetabolic ProcessesMetabolic StudiesMetabolismMetabolism StudiesMinnesotaModificationMolecular InteractionNK CellsNK cell immune therapyNK cell immunotherapyNK cell therapyNK cell treatmentNK cell-based immune therapyNK cell-based immunotherapyNK cell-based therapyNK cell-based treatmentNK cellular immunotherapyNK cellular therapyNK immunotherapyNK therapyNK treatmentNatural IncreasesNatural Killer Cell ImmunotherapyNatural Killer CellsNon-Hodgkin's LymphomaNonhodgkins LymphomaOralOxidative Stress InductionPDX modelPatient derived xenograftPatientsPhase I StudyPhenotypePreclinical dataPreventative strategyPrevention strategyPreventive strategyProcessProductionRNA SeqRNA sequencingRNAseqReceptor ProteinRecombinant DNA TechnologyRelapseReportingResistanceReticulolymphosarcomaRituxanRoleSiteSpecificityStrains Cell LinesSubcellular ProcessT cells for CART-CellsT-LymphocyteTestingTherapeuticToxic effectToxicitiesTranslationsTransplantationUniversitiesVariantVariationWorkanti-cancer therapyantibody dependent cell mediated cytotoxicityantibody dependent cytotoxicityantibody mediated cellular cytotoxicityantibody-dependent cell cytotoxicityantibody-dependent cellular cytotoxicityantibody-mediated cytotoxicityassay for transposase accessible chromatin followed by sequencingassay for transposase accessible chromatin seqassay for transposase accessible chromatin sequencingassay for transposase-accessible chromatin with sequencingautologous graftautotransplantationcancer therapycancer-directed therapycell metabolismcell transductioncellular metabaolismcellular transductionchimeric antigen T cell receptorchimeric antigen receptorchimeric antigen receptor (CAR) T cellschimeric antigen receptor Tchimeric antigen receptor T cellschimeric antigen receptor engineered natural killer cellchimeric antigen receptor fusion protein T-cellschimeric antigen receptor modified T cellschimeric antigen receptor natural killer cellschromatin immunoprecipitation coupled with sequencingchromatin immunoprecipitation followed by sequencingchromatin immunoprecipitation with sequencingchromatin immunoprecipitation-seqchromatin immunoprecipitation-sequencingcomplete responsecultured cell linecytokinecytokine release syndromecytokine stormdevelopmentaldifferentiation of pluripotent stem cellsdisease riskdisorder riskengineered NK cellengineered natural killer cellexperiencegastrointestinalgene deletion mutationgene modificationgenetically engineeredgenetically modifiedhigh riskiPSiPSCiPSCsimmunogenimprovedin vivoinduced pluripotent cellinduced pluripotent stem cellinducible pluripotent cellinducible pluripotent stem cellinfusionsinhibitormanufacturing processmanufacturing runmembrane structuremetabolic abnormality assessmentmetabolic fitnessmetabolic profilenatural killer cell based immune therapynatural killer cell based immunotherapynatural killer cell therapynatural killer cell treatmentnatural killer cell-based therapynatural killer cells expressing chimeric antigen receptorsnatural killer cells with chimeric antigen receptorsnatural killer cellular therapynatural killer therapynon-Hodgkins diseaseoverexpressoverexpressionpatient derived xenograft modelphase 1 studypluripotent stem cell differentiationpost-transplantpost-transplantationposttransplantposttransplantationpre-clinicalpre-clinical trialpreclinicalpreclinical findingspreclinical informationpreclinical trialpreventprevent relapsepreventingproduction runprogenitorprogramsreceptorrelapse preventionresistantresponserituximabsafety studyscale upsmall moleculesocial rolesynergismtargeted drug therapytargeted drug treatmentstargeted therapeutictargeted therapeutic agentstargeted therapytargeted treatmentthymus derived lymphocytetranscriptome sequencingtranscriptomic sequencingtransduced cellstransgene expressiontranslationtransplant
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Full Description

Limiting relapse is the biggest challenge following autologous transplantation for non-Hodgkin’s lymphoma.
Antigen-directed CAR T cell products and other targeted therapies may be changing the field, yet for high-risk
lymphomas, new and safer approaches are needed. We will study the safety and efficacy of antigen-directed,
off-the-shelf, induced pluripotent stem cell (iPSC)-derived NK cells engineered for dual-antigen targeting. We
have optimized the differentiation of iPSC-derived CD34+ cells to highly potent NK cells, scaled production at the
University of Minnesota, and can now produce hundreds of doses in a manufacturing run with a clonal iPSC
transduced with a high-affinity, non-cleavable CD16 (called hnCD16). In late 2019, we initiated clinical trials
testing this engineered iPSC product (designated FT516). The overarching hypothesis for this project is that
dual targeting of NK cells with a CAR and through hnCD16 will protect against relapse after auto-transplant for
lymphoma and that future gene edits to alter metabolism will enhance adoptive transfer. This hypothesis fits with
the themes of this Program, and Project 2 will inform the Program on the development of off-the-shelf NK cells,
NK CAR, and the role of membrane IL-15, as well as pre-clinically on whether manipulating metabolism will
enhance NK cell therapy. These investigations are supported by the following Specific Aims. Aim 1 will test dual
targeting of NK cells to CD19 and CD20 using two mechanisms of action, ADCC and an NK CAR, to prevent
relapse after autologous transplantation for lymphoma. We will test a triple gene-modified iPSC-derived NK cell
product (FT596) transduced with hnCD16, an NK cell-optimized CD19 CAR, and membrane bound 15/IL-15Ra
fusions. FT596 will be combined with rituximab as maintenance therapy to limit relapse after autologous HCT.
This trial is FDA-approved and will first establish an MTD at day +30 after engraftment and then, if single dosing
is safe, move to day +7 before engraftment with the goal of 3 doses in the first hundred days to prevent relapse.
Aim 2 will test enhancement of NK cell metabolic fitness by ARID5B overexpression and CD38 knockout. Our
preliminary data shows both adaptive NK cells and CD38 knockout iPSC-derived NK cells resist oxidative stress-
induced cell death. ARID5B overexpression, naturally increased in adaptive NK cells, mediates similar effects.
We will generate new iPSC lines to build on FT596 with transgenic expression of ARID5B or a CRISPR knockout
of CD38. These clones will be evaluated to probe the mechanisms on how they drive NK cell metabolism and
augment function. Aim 3 will test whether manipulating ARID5B and CD38 will drive metabolic fitness and
enhance FT596 persistence and function in vivo. These pre-clinical trials will inform future clinical trial
modifications—all to promote enhanced anti-lymphoma activity by extending transferred NK cell persistence and
potency. These metabolic and potency findings will directly inform Project 1 to improve cell targeting and
metabolism, Project 3 for cell persistence, and all 3 Projects to define the advantages of autonomous
presentation of IL-15.

Grant Number: 5P01CA111412-20
NIH Institute/Center: NIH
Principal Investigator: VERONIKA BACHANOVA

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