grant

Determining the Intrinsic and Environmental Signal Contributing to Early T1D Progression

Organization WEILL MEDICAL COLL OF CORNELL UNIVLocation NEW YORK, UNITED STATESPosted 15 Sept 2020Deadline 30 Jun 2026
NIHUS FederalResearch GrantFY2023(TNF)-αActive OxygenAnti-InflammatoriesAnti-Inflammatory AgentsAnti-inflammatoryAntiinflammatoriesAntiinflammatory AgentsAutoantibodiesAutoimmune ResponsesAutoregulationB9 endocrine pancreasBeta CellBeta Proprotein Interleukin 1BiologicalBiological FunctionBiological ProcessBiologyBiopsyBody TissuesBrittle Diabetes MellitusCachectinCell BodyCell Communication and SignalingCell DeathCell SignalingCell SurvivalCell ViabilityCellsCellular biologyCessation of lifeChromatinDeathDevelopmentDiabetes MellitusDiseaseDisease ProgressionDisorderDysfunctionEndocrine PancreasEnvironmentExposure toFunctional disorderGWA studyGWASGene variantGenesGeneticGenetic AlterationGenetic ChangeGenetic DiversityGenetic VariationGenetic defectGenetic studyGoalsHomeostasisHumanHyperglycemiaIDDMIL-1 betaIL-1 βIL-1-bIL-1βIL1-BetaIL1-βIL1B ProteinIL1F2IL1βImmuneImmunesIndividualInflammationInflammatoryInflammatory ResponseInnate Immune ResponseInsulin CellInsulin Secreting CellInsulin-Dependent Diabetes MellitusInterleukin 1betaInterleukin-1 betaInterleukin-1βIntracellular Communication and SignalingIslands of LangerhansIslet CellIslets of LangerhansJuvenile-Onset Diabetes MellitusKetosis-Prone Diabetes MellitusKnowledgeLaboratoriesMacrophageMacrophage-Derived TNFMapsModelingModern ManMolecularMolecular GeneticsMonocyte-Derived TNFMultiomic DataMutationNesidioblastsNetwork AnalysisOxygen RadicalsPancreasPancreaticPancreatic IsletsPancreatic beta CellPancreatic β-CellPars endocrina pancreatisPathway AnalysisPatientsPhysiological HomeostasisPhysiopathologyPlayPopulationPopulation DecreasesPreinterleukin 1 BetaPro-OxidantsReactive Oxygen SpeciesRegulatory ElementResolutionRoleSamplingSignal TransductionSignal Transduction SystemsSignalingSingle Base PolymorphismSingle Nucleotide PolymorphismStructure of beta Cell of isletSudden-Onset Diabetes MellitusT1 DMT1 diabetesT1DT1DMTNFTNF ATNF AlphaTNF geneTNF-αTNFATNFαTissuesTumor Necrosis FactorTumor Necrosis Factor-alphaType 1 Diabetes MellitusType 1 diabetesType I Diabetes MellitusValidationVirusadaptive immune responseallele variantallelic variantantiinflammatoryautoimmune antibodyautoreactive antibodybeta cell developmentbiologicbiological signal transductioncell biologycell typecytokinedevelopmentaldiabetesdrug developmentendocrine pancreas developmentenvironmental changeexperimentexperimental researchexperimental studyexperimentsfunctional genomicsgenetic variantgenome mutationgenome wide associationgenome wide association scangenome wide association studiesgenome wide association studygenomewide association scangenomewide association studiesgenomewide association studygenomic variantglobal gene expressionglobal transcription profilehuman pluripotent stem cellhyperglycemicinsulin dependent diabetesinsulin dependent type 1insulitisisletislet developmentislet progenitorjuvenile diabetesjuvenile diabetes mellitusketosis prone diabetesknockout genemultiomicsmultiple omic datamultiple omicsnecrocytosisnetwork modelsnew drug treatmentsnew drugsnew pharmacological therapeuticnew therapeuticsnew therapynext generation therapeuticsnovel drug treatmentsnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel therapeuticsnovel therapypancreas beta cellpancreas β cellpancreatic b-cellpathogenpathophysiologyprecision medicineprecision-based medicineprogression biomarkerprogression markerresolutionsresponsescRNA-seqself reactive antibodysingle cell RNA-seqsingle cell RNAseqsingle cell expression profilingsingle cell transcriptomic profilingsingle nucleotide variantsingle-cell RNA sequencingsocial rolestem cell based modelstem cell biologystem cell derived modelstem cell modeltraittranscriptometype I diabetestype one diabetesvalidationswhole genome association analysiswhole genome association studieswhole genome association studyβ-cellβ-cellsβCell
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Full Description

Abstract.
Type 1 diabetes (T1D) is caused by autoimmune response induced pancreatic β cell destruction. Both intrinsic
(beta cell) and environmental (immune cell) signals play critical roles in pancreatic β cell dysfunction and death.
Understanding the intrinsic and environmental network signature dynamics will facilitate dissecting the molecular
mechanisms controlling T1D progression. Here, we build an interdisciplinary team with the expertise of diabetes
computational and functional genomics, stem cell biology, and islet biology to systematically explore the intrinsic
and environmental changes during T1D progression. In the preliminary studies, we performed single cell
transcriptome (scRNA-seq) and chromatin (scATAC-seq) profiling of healthy, autoantibody positive (both non-
hyperglycemia and hyperglycemia) patient islet samples, as well as a laboratory model that mimics T1D islet
cell-specific signatures using human islets exposed to either cytokines or virus. In addition, we have created a
platform to use isogenic human pluripotent stem cells (hPSCs)-derived pancreatic beta cells and macrophage-
like cells to explore the biological function of diabetes associated genes or single nucleotide polymorphisms.
Here, we will combine our expertise of diabetes computational and functional genomics and stem cell biology to
systematically investigate the role of key intrinsic and environmental signal dynamics in T1D progression and
establish the mechanistic network controlling pancreatic beta cell dysfunction. To achieve these goals, we
propose three specific aims:
Aim 1: Determine the cell-specific intrinsic and environmental signatures during T1D progression.
Aim 2: Decode the cell-specific genetic regulatory network controlling T1D progression.
Aim 3: Validate cells, genes, genetic variants, and intrinsic and environment signatures in T1D progression using
an isogenic hPSC-based platform and primary T1D islets.
Our key deliverables include: 1) a single-cell resolution multi-omic (scRNA-seq, scATAC-seq) map of healthy,
T1D and cytokine- or CVB4 treated human islets; 2) the cell/context-specific molecular genetic (e/caQTL)
network and hub signature of intrinsic and environmental signals in human pancreatic islets; 3) Isogenic hPSC-
derived beta and immune cells with T1D-associated (hub) gene knockouts to validate individual or multiple genes.
These results will be foundational for development of novel drugs and precision disease progression markers.

Grant Number: 5U01DK127777-04
NIH Institute/Center: NIH
Principal Investigator: Shuibing Chen

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