grant

Potentiating Checkpoint Blockade by Cross-Priming Tumor-Reactive T cells with In Situ Vaccination

Organization ICAHN SCHOOL OF MEDICINE AT MOUNT SINAILocation NEW YORK, UNITED STATESPosted 1 Dec 2024Deadline 30 Nov 2026
NIHUS FederalResearch GrantFY2026AddressAgonistAnimal ModelAnimal Models and Related StudiesAntigen PresentationAntigen TargetingAntigensAu antigenAustralia AntigenB blood cellsB cellB cellsB-CellsB-LymphocytesB-cellCD8 CellCD8 T cellsCD8 lymphocyteCD8+ T cellCD8+ T-LymphocyteCD8-Positive LymphocytesCD8-Positive T-LymphocytesCRISPRCRISPR/Cas systemCRM-197CRM197Cancer TreatmentCell LineCellLineClinicalClinical ResearchClinical StudyClinical TrialsClustered Regularly Interspaced Short Palindromic RepeatsCombination VaccinesCombined Modality TherapyCombined VaccinesCross PresentationCross-PrimingCryofixationCryopreservationCytometryDNA mutationDataDendritic CellsDistantEngerix-BExclusionFLT 3 LigandFLT3 ligandFLT3LFLT3LGFLT3LG geneFMS-Related Tyrosine Kinase 3 Ligand GeneFMS-Related Tyrosine Kinase-3 LigandFundingFutureGenesGenetic ChangeGenetic defectGenetic mutationGerminoblastic SarcomaGerminoblastomaGoalsHBsAgHepatitis B Surface AntigensHodgkin DiseaseHodgkin DisorderHodgkin lymphomaHodgkin'sHodgkin's LymphomaHodgkin's diseaseHodgkins lymphomaImmune EvasionImmune MonitoringImmune TargetingImmune mediated therapyImmune responseImmune systemImmunologic MonitoringImmunological MonitoringImmunologically Directed TherapyImmunologyImmunomonitoringImmunotherapyIn SituKeytrudaLymphomaLymphoma cellMalignantMalignant - descriptorMalignant LymphogranulomaMalignant LymphomaMalignant Neoplasm TherapyMalignant Neoplasm TreatmentMalignant Tumor of the LungMalignant neoplasm of lungMiceMice MammalsMinorityMonitorMultimodal TherapyMultimodal TreatmentMurineMusMutateMutationOncologyOncology CancerOutcomePD-1 antibodyPD-1 antibody therapyPD-1 blockadePD-1 therapyPD1 antibodyPD1 antibody therapyPD1 based treatmentPD1 blockadePatient MonitoringPatientsPhenotypePositionPositioning AttributePre-Clinical ModelPreclinical ModelsPreclinical dataPrevenarPrevnarProxyPulmonary CancerPulmonary malignant NeoplasmRadiation therapyRadiotherapeuticsRadiotherapyResearch ResourcesResourcesReticulolymphosarcomaSTK1-ligandSafetySamplingScienceSeminalSiteSomatic MutationStrains Cell LinesT cell responseT-CellsT-LymphocyteT8 CellsT8 LymphocytesTLR proteinTM-MKRTestingTherapeuticToll-Like Receptor Family GeneToll-like receptorsTranslatingTumor AntigensTumor MarkersTumor PromotionTumor-Associated AntigenVeiled CellsVisualizationWorkaPD-1aPD-1 therapyaPD-1 treatmentaPD1aPD1 therapyaPD1 treatmentanti 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-cancer therapyanti-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 immune responseantiPD-1antigen-specific T cellsbiomarker validationcancer antigenscancer therapycancer typecancer-directed therapycheck point blockadecheckpoint blockadeclinical remissioncold preservationcold storagecombination therapycombined modality treatmentcombined treatmentcross reacting material 197cultured cell linedifferentiation factorsearly clinical trialearly phase clinical trialearly phase trialflk2 ligandflk2-flt3 ligandflt3 ligand proteingenome mutationhost responseimmune check point blockadeimmune checkpoint blockadeimmune evasiveimmune system responseimmune therapeutic approachimmune therapeutic interventionsimmune therapeutic regimensimmune therapeutic strategyimmune therapyimmune-based therapiesimmune-based treatmentsimmuno therapyimmunogenimmunogenicimmunoresponseimprovedin situ vaccinationin situ vaccinelung cancermarker validationmodel of animalmorphogenic factorsmorphogensmouse modelmulti-modal therapymulti-modal treatmentmurine modelneo-antigenneo-epitopesneoantigensneoepitopesnovelpatient subclasspatient subclusterpatient subgroupspatient subpopulationspatient subsetspatient subtypespembrolizumabpre-clinicalpreclinicalpreclinical findingspreclinical informationprogrammed cell death protein 1 therapyprogramsradiation treatmentrational designrecruitresponseresponse biomarkerresponse markerssomatic variantstem cell tyrosine kinase 1 ligandthymus derived lymphocytetreatment with radiationtumortumor biomarkertumor specific biomarkertumor-specific antigenvaccination studyvaccination trialvaccine studyvaccine trialαPD-1αPD1
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Full Description

PROJECT SUMMARY
Checkpoint blockade therapy of cancer has had tremendous impact, but still only a subset of patients
respond. One possible explanation is that some tumor types do not have a sufficient number of somatic mutations
to produce tumor-associated-antigens (TAA) that can be targeted by the immune system, specifically CD8 T
cells. Recent data from our group and others suggest an alternative explanation: there are sufficient TAA, but
also suboptimal cross-presentation of these antigens by suitably activated dendritic cells.
We have proposed that this central problem can be addressed using a novel in situ vaccine approach which
uses 1) Flt3L to recruit DC, 2) radiotherapy to load Flt3L-mobilized DC with TAA, and 3) Toll-like Receptor agonist
(TLRa) to activate TAA-loaded DC for cross-presentation. We carried out an early phase trial testing this
approach and observed partial and complete systemic tumor regressions at distant (untreated) tumors, improving
months after therapy, and even specific elimination of malignant B cells with sparing of healthy B cells,
suggesting a systemic anti-tumor immune response. However, whether this approach actually addressed this
problem of insufficient TAA cross-presentation, and whether this could potentiate subsequent checkpoint
blockade therapy is unknown.
In this proposal, we will investigate the mechanism of the in situ
blockade therapy in a mouse model we have developed and in banked, unidentified samples from two clinical
trials of in situ vaccine alone or with anti-PD1 antibody therapy. First, we will assess clinical samples from the
nearly completed in situ vaccine trial to assess whether the appropriate subsets of DC were recruited and
whether this results in the induction of TAA-specific CD8 T cell responses. Next, we will use several unique
resources in the mouse model, including a novel GFP-
collaborators, a panel of CRISPR gene-edited GFP-expressing lymphoma cell lines, and a mass cytometry
(CyTOF) panel to perform deep profiling of tumor-specific T cells in each therapeutic setting. Finally, we will
assess samples from our newly developed clinical trial (funded by CRI) combining the in situ vaccine with anti-
PD1 antibody therapy to assess whether cross-presentation of both TAA and two surrogate antigens introduced
alongside the ISV (HBsAg and CRM-197) actually occurs and correlates with clinical benefit.
We are well positioned to perform the proposed studies, having generated a large set of preliminary data
indicating not only therapeutic opportunity but also our ability to perform high level immune monitoring of samples
from our patients treated on these novel and promising clinical studies. The proposed studies are important
because they will deepen our understanding of anti-tumor T cell mechanisms and address an urgent and unmet
clinical need for our patients with advanced stage lymphoma, and potentially in the future, for many cancer types.

Grant Number: 5R37CA246239-07
NIH Institute/Center: NIH
Principal Investigator: Joshua Brody

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