grant

Elucidating Drug Interactomes for Cardiac Protection by SGLT2 Inhibitors

Organization STANFORD UNIVERSITYLocation STANFORD, UNITED STATESPosted 1 Aug 2025Deadline 31 May 2027
NIHUS FederalResearch GrantFY20253-D3-Dimensional3DAdvisory CommitteesAffectAgeAnimal ModelAnimal Models and Related StudiesAnimalsAutoregulationBindingBinding ProteinsBiogenesisBiologyBiomedical EngineeringCalciumCardiacCardiac Muscle CellsCardiac MyocytesCardiocyteCardiovascularCardiovascular Body SystemCardiovascular Organ SystemCardiovascular systemCell BodyCell LineCell modelCellLineCellsCellular modelChronic stressClinicalClinical EvaluationClinical TestingClinical TrialsCo-TransportersCommittee MembersCoupledD-GlucoseDataDextroseDiabetes MellitusDiseaseDisorderDobutamineDoseDrugsEndothelial CellsEnvironmentFibroblastsGene ExpressionGene Expression InhibitorGlucoseGlucose Binding ProteinGlucose Transport ProteinGlucose TransporterGoalsHealthHeartHeart HypertrophyHeart Muscle CellsHeart VascularHeart failureHeart myocyteHomeostasisHospital AdmissionHospitalizationHumanHypertrophyIntermediary MetabolismKidneyKidney Urinary SystemKnowledgeLC/MSLigand Binding ProteinLigand Binding Protein GeneMass Photometry/Spectrum AnalysisMass SpectrometryMass SpectroscopyMass SpectrumMass Spectrum AnalysesMass Spectrum AnalysisMedicationMentorsMetabolicMetabolic ProcessesMetabolismMethodologyMitochondriaMitochondrial DNAModalityModelingModern ManModernizationMolecularMolecular InteractionMorbidityMorbidity - disease rateMyocardial depressionMyocardial dysfunctionNADHNa elementNon-Polyadenylated RNAOrigin of LifeOxidation-ReductionOxygen ConsumptionPathologicPathway interactionsPatientsPeptidesPharmaceutical PreparationsPhenotypePhysiological HomeostasisPopulationPrecision HealthProtein BindingProteinsProteomeProteomicsRNARNA Gene ProductsRedoxResearchResearch TrainingRibonucleic AcidSarcomeresSodiumSolubilitySolventsStrains Cell LinesSurvey InstrumentSurveysSystems BiologyTask ForcesTechnologyTestingTissue EngineeringToxic effectToxicitiesTrainingUniversitiesValidationVariantVariationWorkabsorptionadvisory teamagesaorta constrictionbio-engineeredbio-engineersbioengineered tissuebioengineeringbiological engineeringbound proteincardiac dysfunctioncardiac failurecardiac hypertrophycardiac metabolismcardiac tissue engineeringcardiomyocytecardioprotectantcardioprotectioncardioprotectivecardiovascular riskcardiovascular risk factorcell dimensioncirculatory systemclinical testcultured cell linedesigndesigningdiabetesdisease modeldisorder modeldrug candidatedrug efficacydrug mechanismdrug/agentengineered heart tissueengineered tissuefascinategenetic inhibitorglycemic controlheart dysfunctionheart metabolismhiPSChuman iPShuman iPSChuman induced pluripotent cellhuman induced pluripotent stem cellshuman inducible pluripotent stem cellshuman inducible stem cellsiPSiPS biologyiPSCiPSC biologyiPSCsimprovedinduced human pluripotent stem cellsinduced pluripotent cellinduced pluripotent stem cellinduced pluripotent stem cell biologyinducible pluripotent cellinducible pluripotent stem cellinhibitorliquid chromatography mass spectrometrymetabolism measurementmetabolomicsmetabonomicsmitochondrialmitochondrial dysfunctionmitochondrial metabolismmodel of animalmortalitymouse modelmtDNAmultiomicsmultiple omicsmurine modeloxidation reduction reactionpanomicspathwaypharmacologicprecision medicineprecision-based medicinepressurepreventpreventingprogenitor cell modelprogenitor modelprogramsprotection pathwayprotective pathwayrenalresearch clinical testingresponsescRNA sequencingscRNA-seqscreeningscreeningssexsingle cell RNA-seqsingle cell RNAseqsingle cell expression profilingsingle cell transcriptomic profilingsingle-cell RNA sequencingsmall moleculestem and progenitor cell modelstem cell based modelstem cell derived modelstem cell modelstudy populationsymporterthree dimensionaltraining opportunitytranscriptomicsvalidations
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Full Description

PROJECT SUMMARY
First designed to treat diabetes, sodium-glucose cotransporter-2 inhibitors (SGLT2i) were used to prevent
glucose reabsorption in the kidney. Recent clinical trials of SGLT2i further demonstrated an unexpected and
substantial reduction in heart failure hospitalizations in patients with and without diabetes. Since SGLT2 is lowly
expressed in the heart, its off-target mechanisms present a fascinating opportunity to elucidate cardiac protective
targets beyond glycemic control. This K99/R00 application describes a five-year research training plan that
leverages (i) human induced pluripotent stem cell-derived cardiovascular cells, (ii) single-cell RNA
transcriptomics (scRNA-seq), (iii) metabolomics, (iv) large-scale drug-protein interaction determination, and (v)
cell and animal validation to elucidate cardiac-protective mechanisms in health and disease. Given the well-
established, off-target protective mechanisms of SGLT2i in the heart, the applicant, Dr. Arianne Caudal, will test
the hypothesis that SGLT2i promotes mitochondrial biogenesis and metabolic remodeling, maintaining energy
homeostasis in heart failure. In Aim 1 (K99), Dr. Caudal will use a “cell village” multi-omic population screening
platform to determine the transcriptomic and metabolomic response conferred by SGLT2i in cardiomyocytes
(iPSC-CMs), fibroblasts (iPSC-CFs), and endothelial cells (iPSC-ECs). In Aim 2 (K99), Dr. Caudal will determine
the direct protein binding partners of SGLT2i using a cutting-edge proteomics approach in three-dimensional
iPSC-derived engineered heart tissues (EHTs). In Aim 3 (R00), Dr. Caudal will validate mitochondrial pathways
using pharmacological induction of cardiac dysfunction in iPSC-CMs and a mouse model of pressure overload-
induced hypertrophy heart failure. Furthermore, these methodological pipelines provide a springboard of
applicability to a range of small molecules, metabolites, and peptides, creating a systems biology niche for Dr.
Caudal’s independent work. The proposed studies build upon PI Dr. Arianne Caudal’s well-suited prior training
in iPSC modeling, proteomics, and mitochondrial metabolism while providing new training opportunities in (i)
precision health, (ii) single-cell multi-omics, and (iii) animal modeling. Mentor Dr. Joseph Wu is a pioneer in
iPSCs and cardiovascular biology, and co-mentor Dr. Michael Snyder is a leading expert in single-cell multi-
omics and precision medicine. Collaborators and advisory committee members Drs. Zoltan Arany (cardiac
metabolism, heart failure), Devin Schweppe (protein interactions), Allis Chien (mass spectrometry), and Sarah
Heilshorn (tissue bioengineering) provide additional expertise and guidance. In summary, the well-tailored
research training plan, exceptional mentoring team, and outstanding environment at Stanford University are
anticipated to help propel Dr. Caudal toward her long-term goal of establishing an independent research program
at the intersection of cardiovascular metabolism and systems biology.

Grant Number: 1K99HL179400-01
NIH Institute/Center: NIH
Principal Investigator: Arianne Caudal

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