grant

Uncovering immune network principles driving humoral immunity in inflammatory conditions

Organization ROCKEFELLER UNIVERSITYLocation NEW YORK, UNITED STATESPosted 1 Aug 2025Deadline 31 Jul 2027
NIHUS FederalResearch GrantFY2025Ab responseAffinityAntibodiesAntibody AffinityAntibody FormationAntibody ProductionAntibody RepertoireAntigensAppearanceAutomobile DrivingB blood cellsB cellB cellsB-CellsB-LymphocytesB-cellBiotinBody TissuesBp50CD154CD4 CellsCD4 Positive T LymphocytesCD4 T cellsCD4 helper T cellCD4 lymphocyteCD4+ T-LymphocyteCD4-Positive LymphocytesCD40CD40LCD40LGCDW40Cancer InductionCancer PatientCancersCell BodyCell CommunicationCell Communication and SignalingCell ComponentsCell InteractionCell SignalingCell StructureCell to Cell Communication and SignalingCell-Cell SignalingCell-to-Cell InteractionCellsCellular StructuresChronicClinicalClone CellsCollaborationsComplexDevelopmentEctopic lymphoid organEctopic lymphoid structureEnvironmentEnzyme GeneEnzymesExperimental DesignsFlow CytofluorometriesFlow CytofluorometryFlow CytometryFlow MicrofluorimetryFlow MicrofluorometryGeneticGerminal CenterHelper CellsHelper T-CellsHelper T-LymphocytesHelper-Inducer T-CellsHelper-Inducer T-LymphocyteHumoral ImmunitiesImmuneImmune mediated therapyImmune responseImmunesImmunochemical ImmunologicImmunologicImmunologicalImmunologicallyImmunologically Directed TherapyImmunologicsImmunotherapyInducer CellsInducer T-LymphocytesInfectionInflammationInflammatoryInfluenza AInfluenza A virusInfluenza Viruses Type AInfluenzavirus AIntracellular Communication and SignalingLabelLaboratoriesLicensingLinkLiteratureLungLung AdenocarcinomaLung Respiratory SystemLymph Node Reticuloendothelial SystemLymph node properLymphatic nodesLymphoidLymphoid CellMGC9013Malignant NeoplasmsMalignant TumorMalignant Tumor of the LungMalignant neoplasm of lungMediatingMediatorMethodsMiceMice MammalsModelingMurineMusOrganOrthomyxovirus Type AOutputPathologyPathway interactionsPatient outcomePatient-Centered OutcomesPatient-Focused OutcomesPeptidesPhaseProcessPropertyPublishingPulmonary CancerPulmonary malignant NeoplasmReactionResearchSeriesShapesSignal TransductionSignal Transduction SystemsSignalingSpecificityStructure of germinal center of lymph nodeT-CellsT-LymphocyteT4 CellsT4 LymphocytesTNFRSF5TNFRSF5 geneTNFSF5TNFSF5 geneTRAP GeneTechnologyTertiary lymphoid structureTissuesTumor ImmunityTumor Necrosis Factor Receptor Superfamily Member 5 GeneType A InfluenzaViral CancerViral DiseasesViral Gene ProductsViral Gene ProteinsViral ProteinsViral Respiratory Tract InfectionVirusVirus DiseasesVitamin HWorkanti-tumor effectanti-tumor immunityantibody biosynthesisantibody-based immunityantigen antibody affinityantitumor effectantitumor immunitybiological signal transductioncancer immunitycancer immunologycancer typecarcinogenesiscoenzyme Rdevelopmentaldrivingexperienceflow cytophotometryhost responseimmune system responseimmune therapeutic approachimmune therapeutic interventionsimmune therapeutic regimensimmune therapeutic strategyimmune therapyimmune-based therapiesimmune-based treatmentsimmuno therapyimmunogenimmunoglobulin biosynthesisimmunoresponseimprovedin vivoin vivo Modelinsightintercellular communicationinterestlung cancerlymph glandlymph nodeslymphnodesmalignancymouse modelmulti-photon imagingmultiphoton excitation microscopymultiphoton imagingmultiphoton microscopymurine modelneoplasm immunologyneoplasm/cancernoveloperationoperationsp50pathogenpathwaypatient oriented outcomespreventpreventingprogramsresponseresponse to therapyresponse to treatmentscRNA sequencingscRNA-seqsingle cell RNA-seqsingle cell RNAseqsingle cell expression profilingsingle cell transcriptomic profilingsingle-cell RNA sequencingsortasesrtA gene producttertiary lymphoid organtherapeutic responsetherapy responsethymus derived lymphocytetreatment responsetreatment responsivenesstumortumor immunologyviral infectionviral respiratory infectionvirus infectionvirus proteinvirus-induced disease
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Full Description

PROJECT SUMMARY/ABSTRACT
B cells participate in germinal center (GC) reactions to generate high-affinity antibodies, which represent a crucial
line of protection from viruses and other pathogens. To date, the mechanism by which the highest-affinity B cell
clones are selected remains elusive. Vital to the development of these high-affinity clones are T follicular helper
(Tfh) cells, which stimulate B cells to undergo GC selection through an interaction known as T cell help. While
our understanding of T cell help dynamics in single-antigen GCs has significantly increased over the last few
years, less is understood about the distribution of Tfh cell help in inflammatory conditions such as viral infections
or cancer. Importantly, GC-like clusters referred to as tertiary lymphoid structures (TLSs) have been a subject of
recent interest, as chronic respiratory viral infections and many cancers and are accompanied by TLS formation.
Notably, the occurrence of TLSs in cancer patients correlates – with some exceptions - with increased
responsiveness to immunotherapy. However, most studies are limited to describing the appearance of TLS and
how their formation is correlated with patient outcome, rather than providing mechanistic details about their anti-
tumoral effects.
The F99 phase of this proposal is focused on determining how T cell help varies and is distributed among
different viral protein-specific B cell clones co-residing in GCs and TLSs using intercellular labeling and in vivo
infection models. Having established novel methods to study immune networks in lymph nodes and virus-
induced TLSs in lungs of Influenza A virus infected mice, I am characterizing the properties and directionality in
which T cell help is provided to B cells of varying antigen-specificities and investigating how competition for T
cell help shapes the antibody repertoire against Influenza A virus.
For the K00 phase of this proposal, I plan to leverage my experiences using mechanistic mouse models of B-
and T-cell collaboration with my prior work studying cancer immunology to elucidate the dynamics of TLS
contribution to humoral immunity in vivo, with a focus on lung adenocarcinoma models. By characterizing the
contacts between immune cells taking place in cancer-induced TLSs, I hope to uncover the pathways in tumor-
bearing mice that generate beneficial TLSs. Applying my expertise with intercellular labeling approaches and
tissue multi-photon microscopy, I aim to identify if and how the immune cell interaction landscape changes in the
context of immunotherapy. These insights could then be used to develop ways to reprogram inert TLSs, or
produce new TLSs, that are capable of tumor control.

Grant Number: 1F99CA305580-01
NIH Institute/Center: NIH
Principal Investigator: Jana Bilanovic

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