2024
Insulin Resistance in Type 2 Diabetes
Roden M, Petersen K, Shulman G. Insulin Resistance in Type 2 Diabetes. 2024, 238-249. DOI: 10.1002/9781119697473.ch17.Peer-Reviewed Original Research
2023
FRI032 Cellular Insights Into Metabolically Healthy And Unhealthy Obesity
Petersen M, Smith G, Yu J, Barve R, Yoshino J, Shulman G, Klein S. FRI032 Cellular Insights Into Metabolically Healthy And Unhealthy Obesity. Journal Of The Endocrine Society 2023, 7: bvad114.043. PMCID: PMC10555440, DOI: 10.1210/jendso/bvad114.043.Peer-Reviewed Original ResearchAbdominal subcutaneous adipose tissueWhole-body insulin sensitivityInsulin sensitivityMUO groupMuscle ceramide contentCeramide contentAdipose tissueGreater whole-body insulin sensitivityPlasma C-peptide concentrationC-peptide concentrationsAdverse metabolic effectsSubcutaneous adipose tissueExpression of genesSkeletal muscle expressionMitochondrial content/functionHealthy obesityMitochondrial structure/functionSkeletal muscle diacylglycerolUnhealthy obesityExtracellular matrix remodelingExcess adiposityMHL groupMetabolic effectsMuscle diacylglycerolInsulin actionMAD2-Dependent Insulin Receptor Endocytosis Regulates Metabolic Homeostasis.
Park J, Hall C, Hubbard B, LaMoia T, Gaspar R, Nasiri A, Li F, Zhang H, Kim J, Haeusler R, Accili D, Shulman G, Yu H, Choi E. MAD2-Dependent Insulin Receptor Endocytosis Regulates Metabolic Homeostasis. Diabetes 2023, 72: 1781-1794. PMID: 37725942, PMCID: PMC10658066, DOI: 10.2337/db23-0314.Peer-Reviewed Original ResearchConceptsIR endocytosisInsulin receptor endocytosisCell division regulatorsInsulin receptorProlongs insulin actionReceptor endocytosisTranscriptomic profilesInsulin stimulationEndocytosisMetabolic homeostasisCell surfaceGenetic ablationMetabolic functionsInsulin actionP31cometMad2BubR1DisruptionSignalingRegulatorHomeostasisAdipose tissueInteractionHepatic fat accumulationMetabolism1569-P: Lysophosphatidic Acid Mediates Inflammation in Liver and White Adipose Tissue in a Rat Model of 1-acyl-sn-glycerol-3-phosphate Acyltransferase 2 Deficiency
SAKUMA I, GASPAR R, LUUKKONEN P, KAHN M, MURRAY S, SAMUEL V, PETERSEN K, SHULMAN G. 1569-P: Lysophosphatidic Acid Mediates Inflammation in Liver and White Adipose Tissue in a Rat Model of 1-acyl-sn-glycerol-3-phosphate Acyltransferase 2 Deficiency. Diabetes 2023, 72 DOI: 10.2337/db23-1569-p.Peer-Reviewed Original ResearchWhite adipose tissueControlled-release mitochondrial protonophoreCongenital generalized lipodystrophyAGPAT2 deficiencyHepatic inflammationASO treatmentAdipose tissueLysophosphatidic acidAdult male SD ratsAntisense oligonucleotideMale SD ratsNovel therapeutic targetNovo NordiskCRMP treatmentFortress BiotechWAT inflammationDohme Corp.SD ratsRat modelAGPAT2 geneGeneralized lipodystrophyInflammationTherapeutic targetIonis PharmaceuticalsDeficient animals192-OR: Lipid-Induced Insulin Resistance in Brown Adipose Tissue Is Mediated by the sn-1,2 DAG-PKCe-IRKT1150 Phosphorylation Pathway
GASPAR R, HUBBARD B, SAKUMA I, LAMOIA T, ZHANG D, SHULMAN G. 192-OR: Lipid-Induced Insulin Resistance in Brown Adipose Tissue Is Mediated by the sn-1,2 DAG-PKCe-IRKT1150 Phosphorylation Pathway. Diabetes 2023, 72 DOI: 10.2337/db23-192-or.Peer-Reviewed Original ResearchO-linked N-acetylglucosamine modification is essential for physiological adipose expansion induced by high-fat feeding
Nakamoto A, Ohashi N, Sugawara L, Morino K, Ida S, Perry R, Sakuma I, Yanagimachi T, Fujita Y, Ugi S, Kume S, Shulman G, Maegawa H. O-linked N-acetylglucosamine modification is essential for physiological adipose expansion induced by high-fat feeding. AJP Endocrinology And Metabolism 2023, 325: e46-e61. PMID: 37224467, PMCID: PMC10292976, DOI: 10.1152/ajpendo.00263.2022.Peer-Reviewed Original ResearchConceptsFKO miceAdipose tissueBody weight gainPrimary cultured adipocytesAdipose expansionFree fatty acidsInflammatory genesWeight gainFree fatty acid effluxCultured adipocytesDiet-induced obesityHigh-fat dietHigh-fat feedingLess body weightDe novo lipogenesisAdipose tissue physiologyDe novo lipogenesis genesFatty acid effluxWeeks of ageAdipose inflammationGlucose intoleranceRAW 264.7 macrophagesControl miceFatty acidsSevere fibrosis
2022
Brown adipose TRX2 deficiency activates mtDNA-NLRP3 to impair thermogenesis and protect against diet-induced insulin resistance
Huang Y, Zhou JH, Zhang H, Canfrán-Duque A, Singh AK, Perry RJ, Shulman G, Fernandez-Hernando C, Min W. Brown adipose TRX2 deficiency activates mtDNA-NLRP3 to impair thermogenesis and protect against diet-induced insulin resistance. Journal Of Clinical Investigation 2022, 132 PMID: 35202005, PMCID: PMC9057632, DOI: 10.1172/jci148852.Peer-Reviewed Original ResearchConceptsBrown adipose tissueBAT inflammationInsulin resistanceMitochondrial reactive oxygen speciesReactive oxygen speciesAberrant innate immune responsesDiet-induced insulin resistanceSystematic metabolismDiet-induced obesityNLRP3 inflammasome pathwayWhole-body energy metabolismCGAS/STINGInnate immune responseFatty acid oxidationExcessive mitochondrial reactive oxygen speciesMetabolic benefitsImmune responseInflammasome pathwayAdipose tissueInflammationInhibition reversesLipid uptakeLipid metabolismThioredoxin 2Adaptive thermogenesis
2021
IL-27 signalling promotes adipocyte thermogenesis and energy expenditure
Wang Q, Li D, Cao G, Shi Q, Zhu J, Zhang M, Cheng H, Wen Q, Xu H, Zhu L, Zhang H, Perry RJ, Spadaro O, Yang Y, He S, Chen Y, Wang B, Li G, Liu Z, Yang C, Wu X, Zhou L, Zhou Q, Ju Z, Lu H, Xin Y, Yang X, Wang C, Liu Y, Shulman GI, Dixit VD, Lu L, Yang H, Flavell RA, Yin Z. IL-27 signalling promotes adipocyte thermogenesis and energy expenditure. Nature 2021, 600: 314-318. PMID: 34819664, DOI: 10.1038/s41586-021-04127-5.Peer-Reviewed Original ResearchMeSH KeywordsAdipocytesAnimalsBariatric SurgeryDisease Models, AnimalEnergy MetabolismFemaleHumansInsulin ResistanceInterleukin-27MaleMiceObesityP38 Mitogen-Activated Protein KinasesPeroxisome Proliferator-Activated Receptor Gamma Coactivator 1-alphaReceptors, InterleukinSignal TransductionThermogenesisUncoupling Protein 1ConceptsIL-27Beige adipose tissueAdipose tissueSerum IL-27Diet-induced obesityBariatric surgeryMetabolic morbidityImmunological factorsInsulin resistanceObesity showTherapeutic administrationMetabolic disordersMouse modelObesityPromising targetEnergy expenditureSignaling promotesThermogenesisBody temperatureMetabolic programsImportant roleTissueCritical roleImmunotherapyMorbidityCIDEA expression in SAT from adolescent girls with obesity and unfavorable patterns of abdominal fat distribution
Tarabra E, Nouws J, Vash‐Margita A, Hellerstein M, Shabanova V, McCollum S, Pierpont B, Zhao D, Shulman GI, Caprio S. CIDEA expression in SAT from adolescent girls with obesity and unfavorable patterns of abdominal fat distribution. Obesity 2021, 29: 2068-2080. PMID: 34672413, PMCID: PMC8612981, DOI: 10.1002/oby.23295.Peer-Reviewed Original ResearchConceptsAbdominal fat distributionVisceral adipose tissueCIDEA expressionFat distributionProtein levelsAbdominal SATAdolescent girlsHigher visceral adipose tissueSubcutaneous adipose tissue biopsiesAdipose tissue biopsiesReverse transcription-polymerase chain reactionTranscription-polymerase chain reactionMagnetic resonance imagingWeight gain effectsExpression of CIDEAAdipocyte dysfunctionSAT biopsiesAdipose lipidsInsulin resistanceAdipocyte hypertrophySmall adipocytesAdipose tissueTissue biopsiesUnfavorable patternsStrong inverse correlationAn update on brown adipose tissue biology: a discussion of recent findings
Gaspar RC, Pauli JR, Shulman GI, Muñoz VR. An update on brown adipose tissue biology: a discussion of recent findings. AJP Endocrinology And Metabolism 2021, 320: e488-e495. PMID: 33459179, PMCID: PMC7988785, DOI: 10.1152/ajpendo.00310.2020.Peer-Reviewed Original ResearchConceptsBrown adipose tissueBAT thermogenesisBrown adipose tissue biologyEnergy expenditureBrown-like cellsWhole-body glucoseAdipose tissue biologyBAT metabolismAdrenergic drugsAdipose tissuePotential treatmentThermogenic activityWhite adipocytesBody glucoseFat metabolismEndocrine mechanismsBeneficial roleSecretory moleculesActivity capacityTissue biologyThermogenesisRecent findingsRecent studiesAdditional focusMetabolism
2020
Mitophagy-mediated adipose inflammation contributes to type 2 diabetes with hepatic insulin resistance
He F, Huang Y, Song Z, Zhou HJ, Zhang H, Perry RJ, Shulman GI, Min W. Mitophagy-mediated adipose inflammation contributes to type 2 diabetes with hepatic insulin resistance. Journal Of Experimental Medicine 2020, 218: e20201416. PMID: 33315085, PMCID: PMC7927432, DOI: 10.1084/jem.20201416.Peer-Reviewed Original ResearchMeSH KeywordsAdipocytesAdipose TissueAnimalsDiabetes Mellitus, Type 2Diet, High-FatEnergy MetabolismFatty LiverGene DeletionGene TargetingGluconeogenesisHomeostasisHumansHyperglycemiaInflammationInsulin ResistanceLipogenesisLiverMaleMice, Inbred C57BLMice, KnockoutMitochondriaMitophagyNF-kappa BOxidative StressPhenotypeReactive Oxygen SpeciesSequestosome-1 ProteinSignal TransductionThioredoxinsConceptsHepatic insulin resistanceWhite adipose tissueInsulin resistanceAdipose inflammationType 2 diabetes mellitusLipid metabolic disordersNF-κB inhibitorAdipose-specific deletionWhole-body energy homeostasisAltered fatty acid metabolismFatty acid metabolismT2DM progressionT2DM patientsDiabetes mellitusReactive oxygen species pathwayHepatic steatosisMetabolic disordersNF-κBP62/SQSTM1Adipose tissueHuman adipocytesEnergy homeostasisExcessive mitophagyOxygen species pathwayInflammationMechanisms by which adiponectin reverses high fat diet-induced insulin resistance in mice
Li X, Zhang D, Vatner DF, Goedeke L, Hirabara SM, Zhang Y, Perry RJ, Shulman GI. Mechanisms by which adiponectin reverses high fat diet-induced insulin resistance in mice. Proceedings Of The National Academy Of Sciences Of The United States Of America 2020, 117: 32584-32593. PMID: 33293421, PMCID: PMC7768680, DOI: 10.1073/pnas.1922169117.Peer-Reviewed Original ResearchConceptsEpididymal white adipose tissueInsulin resistanceAdiponectin treatmentAdipose tissueHigh-fat diet-induced insulin resistanceType 2 diabetes mellitusWhole-body insulin resistanceDiet-induced insulin resistanceSkeletal muscleEctopic lipid storageReverses insulin resistanceInsulin-mediated suppressionMuscle fatty acid oxidationEndogenous glucose productionMuscle insulin resistanceWhite adipose tissueLipoprotein lipase activityMuscle fat oxidationPKCε translocationInsulin-stimulated glucose uptakeFatty acid oxidationTAG uptakeDiabetes mellitusMuscle sensitivityAkt serine phosphorylationThe omentum of obese girls harbors small adipocytes and browning transcripts
Tarabra E, Nouws J, Vash-Margita A, Nadzam GS, Goldberg-Gell R, Van Name M, Pierpont B, Knight J, Shulman GI, Caprio S. The omentum of obese girls harbors small adipocytes and browning transcripts. JCI Insight 2020, 5 PMID: 32125283, PMCID: PMC7213797, DOI: 10.1172/jci.insight.135448.Peer-Reviewed Original ResearchConceptsSubcutaneous adipose tissueSAT depotsSleeve gastrectomySevere obesityInsulin resistanceInsulin sensitivitySmall adipocytesAdipose tissueAbdominal subcutaneous adipose tissueWeight lossType 2 diabetesOmental adipose tissueSubgroup of subjectsTranscriptomic profilesSAT biopsiesAdipocyte sizeObese girlsCardiovascular diseaseLeptin mediates postprandial increases in body temperature through hypothalamus–adrenal medulla–adipose tissue crosstalk
Perry RJ, Lyu K, Rabin-Court A, Dong J, Li X, Yang Y, Qing H, Wang A, Yang X, Shulman GI. Leptin mediates postprandial increases in body temperature through hypothalamus–adrenal medulla–adipose tissue crosstalk. Journal Of Clinical Investigation 2020, 130: 2001-2016. PMID: 32149734, PMCID: PMC7108915, DOI: 10.1172/jci134699.Peer-Reviewed Original ResearchConceptsBrown adipose tissueLeptin concentrationsBody temperatureAdrenomedullary catecholamine secretionPlasma leptin concentrationsAdipose tissue lipolysisFasting-induced reductionFeeding-induced increaseMeal ingestionPlasma catecholaminesPostprandial increaseCatecholamine secretionObese ratsTissue lipolysisLean ratsAdrenergic activationAdipose tissueTissue crosstalkWeight gainIntragastric infusionRatsLeptinBolusLipolysisFatty acidsMitochondrial Dysfunction, Insulin Resistance, and Potential Genetic Implications
Sangwung P, Petersen KF, Shulman GI, Knowles JW. Mitochondrial Dysfunction, Insulin Resistance, and Potential Genetic Implications. Endocrinology 2020, 161: bqaa017. PMID: 32060542, PMCID: PMC7341556, DOI: 10.1210/endocr/bqaa017.Peer-Reviewed Original ResearchConceptsInsulin resistanceWhole-body insulin resistanceMitochondrial functionEctopic lipid depositionBody insulin resistanceType 2 diabetesWhite adipose tissuePrediabetic individualsVivo metabolic studiesInsulin-responsive tissuesLipid depositionAdipose tissueType 2Skeletal muscleMitochondrial dysfunctionPotential mechanismsMetabolic studiesHuman genetic studiesTissueEnvironmental determinantsMitochondrial malfunctionCellular energy balanceRecent insightsCritical roleDiabetesRegulation of adipose tissue inflammation by interleukin 6
Han MS, White A, Perry RJ, Camporez JP, Hidalgo J, Shulman GI, Davis RJ. Regulation of adipose tissue inflammation by interleukin 6. Proceedings Of The National Academy Of Sciences Of The United States Of America 2020, 117: 2751-2760. PMID: 31980524, PMCID: PMC7022151, DOI: 10.1073/pnas.1920004117.Peer-Reviewed Original ResearchConceptsInterleukin-6Adipose tissue inflammationLow-grade inflammationIndividual cell typesMacrophage infiltrationInflammatory cytokinesTissue inflammationGlucose disposalImmune cellsIL6 productionMouse modelChronic stateAdipose tissueMyeloid cellsTissue infiltrationReceptor αConditional expressionCell typesOxidative metabolismOpposite actionsPhysiological regulationEnergy expenditureCanonical modeInflammationSpecific cells
2019
The integrative biology of type 2 diabetes
Roden M, Shulman GI. The integrative biology of type 2 diabetes. Nature 2019, 576: 51-60. PMID: 31802013, DOI: 10.1038/s41586-019-1797-8.Peer-Reviewed Original ResearchConceptsType 2 diabetesInsulin resistanceFrequent metabolic disorderWhite adipose tissueRelevant animal modelsCommon underlying abnormalityAdequate substrate supplyInflammatory pathwaysUnderlying abnormalityMetabolic disordersAnimal modelsAdipose tissueEnergy intakeHepatic gluconeogenesisDiabetesObesityAbnormalitiesTissue communicationRecent studiesEnergy imbalanceDysfunctionPathwayInsulinIntakeBrain
2016
Insulin Resistance in Type 2 Diabetes
Roden M, Petersen K, Shulman G. Insulin Resistance in Type 2 Diabetes. 2016, 174-186. DOI: 10.1002/9781118924853.ch13.Peer-Reviewed Original ResearchType 2 diabetesNon-alcoholic fatty liver diseaseInsulin resistanceInflammatory pathwaysAdipose tissueHepatic mitochondrial oxidative capacityLipid-mediated insulin resistanceFatty liver diseaseImpaired glucose toleranceDiabetes-related complicationsEctopic lipid accumulationΒ-cell dysfunctionFatty acid availabilityAction of insulinMitochondrial oxidative capacityAtherogenic dyslipidemiaMultiple deleterious effectsGlucose toleranceLiver diseaseCarbohydrate ingestionEctopic storagePostprandial hyperglycemiaSystemic abnormalitiesInhibits lipolysisFree fatty acids
2015
A Role of the Inflammasome in the Low Storage Capacity of the Abdominal Subcutaneous Adipose Tissue in Obese Adolescents
Kursawe R, Dixit VD, Scherer PE, Santoro N, Narayan D, Gordillo R, Giannini C, Lopez X, Pierpont B, Nouws J, Shulman GI, Caprio S. A Role of the Inflammasome in the Low Storage Capacity of the Abdominal Subcutaneous Adipose Tissue in Obese Adolescents. Diabetes 2015, 65: 610-618. PMID: 26718495, PMCID: PMC4764142, DOI: 10.2337/db15-1478.Peer-Reviewed Original ResearchMeSH KeywordsAbdomenAcetyl-CoA CarboxylaseAdipogenesisAdiponectinAdolescentCarrier ProteinsCaspase 1ChildDown-RegulationFatty Acid Synthase, Type IFemaleGene Expression ProfilingGlucose Transporter Type 4HumansInflammasomesInsulin ResistanceInterleukin-1betaIntra-Abdominal FatLeptinLipogenesisLipoprotein LipaseMacrophagesMagnetic Resonance ImagingMaleNLR Family, Pyrin Domain-Containing 3 ProteinObesityPPAR gammaSirtuin 1Sterol Regulatory Element Binding Protein 1Subcutaneous FatToll-Like Receptor 4ConceptsVisceral adipose tissueObese adolescentsInsulin resistanceTissue inflammationNLRP3 inflammasomeAdipose tissueInnate immune cell sensorsAbdominal subcutaneous adipose tissueAbdominal adipose depotsAbdominal fat partitioningAdipogenesis/lipogenesisAdipose tissue inflammationProinflammatory cytokines interleukinInfiltration of macrophagesExpression of CASP1Subcutaneous adipose tissueInflammation markersSAT biopsiesIL-18Macrophage infiltrationVisceral fatCytokines interleukinSAT ratioInsulin sensitivityAdipose depots
2001
Glucose toxicity and the development of diabetes in mice with muscle-specific inactivation of GLUT4
Kim J, Zisman A, Fillmore J, Peroni O, Kotani K, Perret P, Zong H, Dong J, Kahn C, Kahn B, Shulman G. Glucose toxicity and the development of diabetes in mice with muscle-specific inactivation of GLUT4. Journal Of Clinical Investigation 2001, 108: 153-160. PMID: 11435467, PMCID: PMC353719, DOI: 10.1172/jci10294.Peer-Reviewed Original ResearchMeSH KeywordsAdipose TissueAge of OnsetAnimalsDepression, ChemicalDiabetes Mellitus, Type 2Disease Models, AnimalGlucoseGlucose Transporter Type 4HyperglycemiaInsulinInsulin Infusion SystemsInsulin ResistanceKidney TubulesLiverMaleMiceMice, KnockoutMonosaccharide Transport ProteinsMuscle ProteinsMuscle, SkeletalPhlorhizinPrediabetic StateProtein TransportConceptsDevelopment of diabetesMuscle glucose uptakeKO miceHepatic glucose productionInsulin-stimulated glucose uptakeGlucose toxicityMuscle-specific inactivationGlucose uptakeAdipose tissueInsulin-stimulated muscle glucose uptakeGlucose productionWhole-body glucose uptakeSkeletal muscle glucose uptakeAdipose tissue glucose uptakeSuppress hepatic glucose productionTissue glucose uptakeHyperinsulinemic-euglycemic clampMuscle glucose transportInsulin resistanceTransgenic miceDiabetes phenotypeInsulin actionPhloridzin treatmentInsulin's abilityDiabetes