grant

Project 3: Determining biomarkers for responsiveness to immunotherapy targeting LAG3/PD1 in HNSCC

Organization UNIVERSITY OF PITTSBURGH AT PITTSBURGHLocation PITTSBURGH, UNITED STATESPosted 1 Jul 2004Deadline 31 Aug 2027
NIHUS FederalResearch GrantFY2025AbscissionActemraAfter CareAfter-TreatmentAftercareAreaAutoregulationB-Cell Differentiation Factor GeneB-Cell Stimulatory Factor 2 GeneBSF-2 GeneBSF2 GeneBeta-2 Gene InterferonBiological MarkersBiologyBiopsyBlood PlasmaBody TissuesCD8CD8 CellCD8 T cellsCD8 lymphocyteCD8+ T cellCD8+ T-LymphocyteCD8-Positive LymphocytesCD8-Positive T-LymphocytesCD8BCD8B1CD8B1 geneCancer ModelCancer PatientCancerModelCancersCell BodyCell FunctionCell PhysiologyCell ProcessCell surfaceCellsCellular FunctionCellular PhysiologyCellular ProcessClinical TrialsCombination immunotherapyCombined Modality TherapyDataDevelopmentDiseaseDisorderDysfunctionExcisionExhibitsExtirpationFunctional disorderGene TranscriptionGenetic TranscriptionHNSCCHSF GeneHead and Neck CancerHead and Neck CarcinomaHead and Neck Squamous Cell CarcinomaHepatocyte Stimulatory Factor GeneHomeostasisHybridoma Growth Factor GeneIFNB2 GeneIL-6 GeneIL6IL6 geneImmuneImmune DiseasesImmune DisordersImmune DysfunctionImmune System DiseasesImmune System DisorderImmune System DysfunctionImmune System and Related DisordersImmune mediated therapyImmune responseImmunesImmunologic DiseasesImmunological DiseasesImmunological DysfunctionImmunological System DysfunctionImmunologically Directed TherapyImmunotherapeutic agentImmunotherapyInduction TherapyInflammationInterleukin 6 (Interferon, Beta 2) GeneInterleukin-6 GeneInterpersonal CommunicationInvestigatorsLYT3LinkMalignant Head and Neck NeoplasmMalignant NeoplasmsMalignant TumorMediatingMetallopeptidasesMetalloproteasesMetalloproteinasesMetastatic/RecurrentMinorityMolecularMultimodal TherapyMultimodal TreatmentNEOADJNRP1NRP1 geneNeoadjuvantNeoadjuvant TherapyNeoadjuvant TreatmentNivolumabOpdivoOperative ProceduresOperative Surgical ProceduresPD 1PD-1PD-1 antibodyPD-1 antibody therapyPD-1 blockadePD-1 therapyPD1PD1 antibodyPD1 antibody therapyPD1 based treatmentPD1 blockadePathway interactionsPatient outcomePatient-Centered OutcomesPatient-Focused OutcomesPatientsPeripheralPersonal CommunicationPhenotypePhysiological HomeostasisPhysiopathologyPlasmaPlasma SerumProliferatingRNA ExpressionRandomizedReceptor ProteinRegulationRemovalResearch PersonnelResearchersResistanceReticuloendothelial System, Serum, PlasmaSCCHNSeriesSubcellular ProcessSurfaceSurgicalSurgical InterventionsSurgical ProcedureSurgical RemovalT Cell SpecificityT cell receptor repertoire sequencingT cell receptor sequencingT-Cell ActivationT-Cell Immunologic SpecificityT-Cell ProliferationT-CellsT-LymphocyteT8 CellsT8 LymphocytesTCR repertoire sequencingTCR sequencingTCR-seqTCRseqTeff cellTherapeutic Clinical TrialTissuesTranscriptionTumor ImmunityTumor TissueVEGF165RValidationaPD-1aPD-1 therapyaPD-1 treatmentaPD1aPD1 therapyaPD1 treatmentactivate T cellsanti programmed cell death 1anti-PD-1anti-PD-1 Abanti-PD-1 antibodiesanti-PD-1 blockadeanti-PD-1 monoclonal antibodiesanti-PD-1 therapyanti-PD-1 treatmentanti-PD1anti-PD1 Abanti-PD1 antibodiesanti-PD1 blockadeanti-PD1 monoclonal antibodiesanti-PD1 therapyanti-PD1 treatmentanti-programmed cell death 1 therapyanti-programmed cell death protein 1anti-programmed cell death protein 1 antibodiesanti-programmed cell death protein 1 therapyanti-programmed death-1 antibodyanti-tumor immunityantiPD-1antitumor immunityarmbio-markersbiologic markerbiomarkerbiomarker identificationcancer imagingcancer immunitycancer microenvironmentcohortcombination therapycombinatorialcombinatorial immunotherapycombined modality treatmentcombined treatmentcytokinedevelopmentaldual immunotherapyeffector T cellhead and neck squamous carcinomahead and neck squamous cell cancerhead/neck cancerhost responseidentification of biomarkersidentification of new biomarkersimmune drugsimmune resistanceimmune system responseimmune therapeutic approachimmune therapeutic interventionsimmune therapeutic regimensimmune therapeutic strategyimmune therapyimmune-based therapeuticsimmune-based therapiesimmune-based treatmentsimmune-resistantimmuno therapyimmunologic therapeuticsimmunoresistanceimmunoresponseimmunotherapeuticsimmunotherapy agentimmunotherapy trialsimprovedinduction therapiesinnovateinnovationinnovativeinsightinterestmalignancymalignant head and neck tumormarker identificationmouse modelmulti-modal therapymulti-modal treatmentmurine modelneoplasm/cancernoveloncologic imagingoncology imagingpathophysiologypathwaypatient oriented outcomespatient populationpatient responsepatient specific responseperipheral bloodpost treatmentpredict responsivenesspredicting responseprogrammed cell death 1programmed cell death protein 1programmed cell death protein 1 therapyprogrammed death 1programsrandomisationrandomizationrandomly assignedreceptorreceptor expressionresectionresistance mechanismresistantresistant mechanismresponseresponse biomarkerresponse markersresponsive patientscRNA sequencingscRNA-seqsingle cell RNA-seqsingle cell RNAseqsingle cell expression profilingsingle cell transcriptomic profilingsingle-cell RNA sequencingsle2spectral imagespectral imageryspectrographspectrum imagespectrum imagerystandard of caresurgerysynergismsystemic lupus erythematosus susceptibility 2targeted drug therapytargeted drug treatmentstargeted therapeutictargeted therapeutic agentstargeted therapytargeted treatmenttherapeutic targetthymus derived lymphocytetocilizumabtranscriptomicstumortumor imagingtumor microenvironmentvalidationsαPD-1αPD1
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Full Description

PROJECT SUMMARY – PROJECT 3
Although great strides have been made with immunotherapy for head and neck squamous cell carcinoma
(HNSCC), there is a strong imperative to [i] gain a better understanding of the mechanism(s) of action for
current standard-of-care (SOC) immunotherapies (e.g. anti-PD1) and novel immunotherapeutic treatments in
clinical trials (e.g. anti-LAG3); [ii] determine biomarkers of responsiveness that could predict patient outcomes
to immunotherapy; and [iii] determine if there are mechanisms of resistance that can be overcome. Tumor-
specific inhibitory mechanisms, such as inhibitory receptors (IRs), represent major obstacles to effective anti-
tumor immunity, highlighting the importance of understanding their cell intrinsic and extrinsic mechanisms and
optimal combinations to improve immunotherapies. Although LAG3 is the third ‘checkpoint’ to be targeted with
>10 agents in clinical trials, we still know very little about how LAG3 blockade, alone or with anti-PD1, impacts
the immune response to HNSCC. Our over-arching hypothesis is that LAG3/PD1 dual blockade synergizes to
promote CD8+ T cell function in the tumor and peripheral blood (PBL) of HNSCC patients, and a LAG3-
dominant IR module in peripheral CD8+ T cells downregulates T cell function, and ultimately, patient response
to PD1-targeted therapy. We ask two major questions in this area. What is the mechanism of anti-PD1 (nivo)
and anti-LAG3 (rela) on the anti-tumor function of CD8+ T cells? We are accruing to a novel neoadjuvant
window trial which randomizes treatment-naïve locally advanced HNSCC patients to two arms relevant to this
Aim: [i] nivo monotherapy, or [ii] nivo plus rela, followed by surgery after initiation of treatment. We hypothesize
that T cell activation and proliferation pathways are differentially regulated by anti-PD1 vs. anti-LAG3 in CD8+ T
cells, and that unique synergistic molecular programs will be revealed by this immunotherapeutic combination
in treatment-naïve patients with HNSCC. Secondly, we ask whether cytokines drive a LAG3-dominant IR
module in peripheral, naive CD8+ T cells and does it predict responsiveness to immunotherapy? We recently
made a series of novel findings regarding IR expression in peripheral CD8+ T cells implying a novel
mechanism of immune resistance. We hypothesize that cytokine-driven systemic immune dysfunction and
subsequent resistance to anti-PD1 therapy is driven by a LAG3-dominant IR module, and that this dysfunction
can be ameliorated by anti-LAG3+PD1 blockade. This project will [i] define biomarkers of response and
resistance to nivo and nivo/rela, [ii] potentially identify a patient population that will optimally benefit from
LAG3-based therapies, and [iii] lead to the development novel combinatorial immunotherapy trials of increased
efficacy in HNSCC.

Grant Number: 5P50CA097190-19
NIH Institute/Center: NIH
Principal Investigator: Tullia Bruno

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