grant

Deciphering age-dependent beige adipocyte failure

Organization CORNELL UNIVERSITYLocation ITHACA, UNITED STATESPosted 15 Mar 2022Deadline 31 Jan 2027
NIHUS FederalResearch GrantFY2026AblationAdipocytesAdipose CellAdipose tissueAdrenergic AgentsAdrenergic DrugsAdrenergicsAdult-Onset Diabetes MellitusAgeAgingAgreementAutomobile DrivingAutoregulationBiochemicalBiogenesisBlood GlucoseBlood SugarBlood VesselsBody TissuesBody fatCD140b AntigensCardiovascular DiseasesCell AgingCell BodyCell CommunicationCell Communication and SignalingCell InteractionCell SenescenceCell SignalingCell-to-Cell InteractionCellsCellular AgingCellular SenescenceCessation of lifeClinicalCommunicationConsumptionD-GlucoseDeathDeteriorationDevelopmentDextroseDysfunctionFailureFat CellsFat progenitor cellFat stem cellFatsFatty TissueFatty acid glycerol estersFosteringFree Fatty AcidsFunctional disorderGene TranscriptionGenerationsGeneticGenetic ModelsGenetic TranscriptionGlucoseGoalsHealthHelper CellsHelper T-CellsHelper T-LymphocytesHelper-Inducer T-CellsHelper-Inducer T-LymphocyteHomeostasisHumanImmuneImmunesImmunochemical ImmunologicImmunologicImmunologicalImmunologicallyImmunologicsIncidenceIncrease lifespanInducer CellsInducer T-LymphocytesInterleukinsIntermediary MetabolismIntracellular Communication and SignalingKetosis-Resistant Diabetes MellitusLength of LifeLineage TracingLinkLipocytesLongevityLymphoid CellMammaliaMammalsMature LipocyteMature fat cellMaturity-Onset Diabetes MellitusMetabolicMetabolic DiseasesMetabolic DisorderMetabolic ProcessesMetabolic dysfunctionMetabolismMethodsMiceMice MammalsModelingModern ManMolecularMurineMusNIDDMNon-Insulin Dependent DiabetesNon-Insulin-Dependent Diabetes MellitusNonesterified Fatty AcidsNoninsulin Dependent DiabetesNoninsulin Dependent Diabetes MellitusObesityObesity EpidemicOlder PopulationOrigin of LifeOutputPDGF Receptor βPDGF beta ReceptorPDGF β ReceptorPDGFR betaPDGFR-βPathway interactionsPhenotypePhysiologicPhysiologicalPhysiological HomeostasisPhysiopathologyPlatelet-Derived Growth Factor Receptor Beta PolypeptidePlatelet-Derived Growth Factor Receptor βPlatelet-Derived Growth Factor beta ReceptorPopulationProgenitor CellsRNA ExpressionRampRejuvenationReplicative SenescenceResearchRoleSignal TransductionSignal Transduction SystemsSignalingSignaling MoleculeSlow-Onset Diabetes MellitusSourceStable Diabetes MellitusT2 DMT2DT2DMTestingTherapeuticThesaurismosisTissuesTranscriptionType 2 Diabetes MellitusType 2 diabetesType 2 diabeticType II Diabetes MellitusType II diabetesType II diabeticUpregulationadipocyte developmentadipocyte differentiationadipocyte progenitorsadipocyte stem celladipocyte-derived stem celladiposeadipose derived stem celladipose progenitoradipose stem celladipose tissue derived stem celladipose tissue stem cellsadiposityadult onset diabetesadult youthage associatedage associated alterationsage associated changesage associated declineage correlatedage correlated alterationsage correlated changesage dependentage dependent alterationsage dependent changesage dependent declineage induced alterationsage induced changesage linkedage relatedage related alterationsage related changesage related declineage reversalage specificage specific alterationsage specific changesagedaged miceaged mouseagesaging associated alterationsaging associated changesaging correlated alterationsaging correlated changesaging dependent alterationsaging dependent changesaging induced alterationsaging induced changesaging preventionaging processaging related alterationsaging related changesaging reversalaging specific alterationsaging specific changesalleviate age relatedalleviate agingalterations with ageameliorating aginganti aginganti geronicantiagingbiological signal transductionboost longevitycardiovascular disordercell lineage analysiscell lineage mappingcell lineage tracingcell lineage trackingcellular lineage mappingcellular lineage trackingchanges with ageclinical efficacycold temperaturecombatcorpulencecounter age relatedcounter agingcounteract age relatedcounteract agingdecline with agedesensitizationdevelopmentaldrivingelderly miceelongating the lifespanenhance healthspanenhance longevityextend healthspanextend life spanextend lifespanextend longevityextending healthy lifespanfat derived stem cellfoster longevityhealthspan extensionimprove healthspanimprove lifespanimprove longevityimprovedincrease healthspanjuvenile animalketosis resistant diabeteslifespan extensionlow temperaturematurity onset diabetesmetabolic fitnessmetabolism disordermouse modelmurine modelnew drug treatmentsnew drugsnew pharmacological therapeuticnew therapeuticsnew therapynext generation therapeuticsnovelnovel drug treatmentsnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel therapeuticsnovel therapyobese patientsold miceolder groupsolder individualsolder personpathophysiologypathwaypatients with obesitypharmacologicprematureprematuritypreservationpreventprevent age relatedprevent agingpreventingprogenitor agingprogenitor cell agingprogenitor cell functionprogenitor functionprolong healthspanprolong lifespanprolong longevitypromote healthspanpromote lifespanpromote longevityrecruitreplicative agingresponsereverse agereverse agingreverse aging effectsreversible agingsenescencesenescentsocial rolestem and progenitor cell functionstem and progenitor functionstem cell agingstem cell functionstem cellssupport longevitysuppress agingthermal stressthermo stresstranscriptomicstype 2 DMtype II DMtype two diabetesvascularwhite adipose tissueyellow adipose tissueyoung adultyoung adult ageyoung adulthoodyoung animal
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Full Description

PROJECT SUMMARY:
Cold temperature (<15°C) exposure stimulates perivascular beige adipocyte progenitor cells (bAPCs) to
generate beige adipocytes. Beige adipocytes act as cellular furnaces to burn blood glucose and free fatty acids
to generate heat. Recent studies have shown the metabolic benefits of beige adipocytes, suggesting potential
clinical efficacy for obese patients and type 2 diabetics. However, the potential to form cold-induced beige
adipocytes declines with age, creating a pivotal challenge to the therapeutic promise for older individuals, many
of whom constitute the obesity epidemic. Our studies begin to unravel how aging suppresses beige adipogenic
potential and identifies new ways to rejuvenate beige fat cell biogenesis to restore metabolic fitness in aged
mammals. Our previous studies have linked cellular senescence, a state of cellular arrest, of bAPCs to the age-
associated decline in beige adipose tissue. In an attempt to find additional mechanisms blocking beige fat
biogenesis in aged mammals, we found that the expression and signaling of platelet derived growth factor
receptor beta (Pdgfrβ) is increased in aged bAPCs. Moreover, ablation of Pdgfrβ within the beige adipose lineage
restored beige adipocyte generation and improved metabolic health in aged (not young) mice. Despite beige fat
formation in aged Pdgfrβ-deficient mice, lineage-tracing studies revealed that auxiliary source(s) generated
beige adipocytes. In agreement, senescence tests demonstrated that Pdgfrβ neither promoted nor reversed
cellular senescence. Instead, we found that Pdgfrβ signaling prevents group 2 innate lymphoid cell (ILC2)
recruitment and activation within iWAT depots. Mechanistically, we identified that Pdgfrβ elicits signals via Stat1
to suppress the ILC2-inducer, interleukin-33 (IL-33), to control WAT ILC2 activity. Finally, we identify sympathetic
tone as a significant regulator of age-induced Pdgfrβ expression. Our aims will elucidate the physiological and
cellular role of Pdgfrβ in regulating beige fat biogenesis under aging and obese conditions. We will elucidate the
Pdgfrβ-Stat1 signaling mechanism in bAPCs to control ILC2 recruitment via IL-33. We uncover how sympathetic
output regulates Pdgfrβ expression to drive the age-dependent beige adipogenic failure. These findings will
implicate Pdgfrβ signaling as a central node in the bAPC aging process. Importantly, this application will identify
factors that reverse age-dependent beige adipogenic failure with a direct clinical utility to combat excess body
fat and metabolic dysfunction to extend lifespan and restore health.

Grant Number: 5R01DK132264-05
NIH Institute/Center: NIH
Principal Investigator: Daniel Berry

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