2023
Lysophosphatidic acid triggers inflammation in the liver and white adipose tissue in rat models of 1-acyl-sn-glycerol-3-phosphate acyltransferase 2 deficiency and overnutrition
Sakuma I, Gaspar R, Luukkonen P, Kahn M, Zhang D, Zhang X, Murray S, Golla J, Vatner D, Samuel V, Petersen K, Shulman G. Lysophosphatidic acid triggers inflammation in the liver and white adipose tissue in rat models of 1-acyl-sn-glycerol-3-phosphate acyltransferase 2 deficiency and overnutrition. Proceedings Of The National Academy Of Sciences Of The United States Of America 2023, 120: e2312666120. PMID: 38127985, PMCID: PMC10756285, DOI: 10.1073/pnas.2312666120.Peer-Reviewed Original ResearchHepatocyte CYR61 polarizes profibrotic macrophages to orchestrate NASH fibrosis
Mooring M, Yeung G, Luukkonen P, Liu S, Akbar M, Zhang G, Balogun O, Yu X, Mo R, Nejak-Bowen K, Poyurovsky M, Booth C, Konnikova L, Shulman G, Yimlamai D. Hepatocyte CYR61 polarizes profibrotic macrophages to orchestrate NASH fibrosis. Science Translational Medicine 2023, 15: eade3157. PMID: 37756381, PMCID: PMC10874639, DOI: 10.1126/scitranslmed.ade3157.Peer-Reviewed Original ResearchConceptsNonalcoholic steatohepatitisLiver inflammationNonalcoholic fatty liver diseaseProgression of NASHCysteine-rich angiogenic inducer 61Fatty liver diseaseLiver-specific knockout miceImproved glucose toleranceType 2 diabetesGlucose toleranceLiver diseaseNASH progressionProfibrotic macrophagesProinflammatory propertiesReduced fibrosisCardiovascular diseaseProfibrotic phenotypeFibrotic developmentKnockout miceNF-κBMetabolic diseasesNASH dietPDGFB expressionFibrosisProfibrotic programMAD2-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 accumulationMetabolismO-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 fibrosisInhibition of HSD17B13 protects against liver fibrosis by inhibition of pyrimidine catabolism in nonalcoholic steatohepatitis
Luukkonen P, Sakuma I, Gaspar R, Mooring M, Nasiri A, Kahn M, Zhang X, Zhang D, Sammalkorpi H, Penttilä A, Orho-Melander M, Arola J, Juuti A, Zhang X, Yimlamai D, Yki-Järvinen H, Petersen K, Shulman G. Inhibition of HSD17B13 protects against liver fibrosis by inhibition of pyrimidine catabolism in nonalcoholic steatohepatitis. Proceedings Of The National Academy Of Sciences Of The United States Of America 2023, 120: e2217543120. PMID: 36669104, PMCID: PMC9942818, DOI: 10.1073/pnas.2217543120.Peer-Reviewed Original ResearchConceptsNonalcoholic fatty liver diseaseLiver fibrosisLiver diseaseCommon chronic liver diseaseChronic liver diseaseFatty liver diseaseRisk of fibrosisDistinct mouse modelsPyrimidine catabolismNonalcoholic steatohepatitisMouse modelTherapeutic targetFibrosisDihydropyrimidine dehydrogenaseHuman liverA variantCommon variantsMetabolomics approachDiseaseMiceInhibitionCatabolismKnockdownSteatohepatitisGimeracil
2022
Q-Flux: A method to assess hepatic mitochondrial succinate dehydrogenase, methylmalonyl-CoA mutase, and glutaminase fluxes in vivo
Hubbard B, LaMoia T, Goedeke L, Gaspar R, Galsgaard K, Kahn M, Mason G, Shulman G. Q-Flux: A method to assess hepatic mitochondrial succinate dehydrogenase, methylmalonyl-CoA mutase, and glutaminase fluxes in vivo. Cell Metabolism 2022, 35: 212-226.e4. PMID: 36516861, PMCID: PMC9887731, DOI: 10.1016/j.cmet.2022.11.011.Peer-Reviewed Original ResearchDistinct subcellular localisation of intramyocellular lipids and reduced PKCε/PKCθ activity preserve muscle insulin sensitivity in exercise-trained mice
Gaspar R, Lyu K, Hubbard B, Leitner B, Luukkonen P, Hirabara S, Sakuma I, Nasiri A, Zhang D, Kahn M, Cline G, Pauli J, Perry R, Petersen K, Shulman G. Distinct subcellular localisation of intramyocellular lipids and reduced PKCε/PKCθ activity preserve muscle insulin sensitivity in exercise-trained mice. Diabetologia 2022, 66: 567-578. PMID: 36456864, PMCID: PMC11194860, DOI: 10.1007/s00125-022-05838-8.Peer-Reviewed Original ResearchConceptsProtein kinase CsSubcellular compartmentsDistinct subcellular localisationMuscle insulin sensitivityMultiple subcellular compartmentsInsulin receptor kinaseNovel protein kinase CsActivation of PKCεSubcellular localisationPKCθ translocationReceptor kinasePlasma membraneSubcellular distributionTriacylglycerol contentCrucial pathwaysIntramuscular triacylglycerol contentRC miceDiacylglycerolConclusions/interpretationThese resultsPKCεPM compartmentPhosphorylationMuscle triacylglycerol contentSkeletal muscleRecent findingsDeletion of Jazf1 gene causes early growth retardation and insulin resistance in mice
Lee H, Jang H, Li H, Samuel V, Dudek K, Osipovich A, Magnuson M, Sklar J, Shulman G. Deletion of Jazf1 gene causes early growth retardation and insulin resistance in mice. Proceedings Of The National Academy Of Sciences Of The United States Of America 2022, 119: e2213628119. PMID: 36442127, PMCID: PMC9894197, DOI: 10.1073/pnas.2213628119.Peer-Reviewed Original ResearchConceptsKO miceEarly growth retardationInsulin resistanceFat massGrowth retardationAge-matched wild-type miceHepatic nuclear factor 4 alphaGH-IGF-1 axisHigh-fat diet feedingKO liversHyperinsulinemic-euglycemic clamp techniquePlasma growth hormone concentrationInsulin-like growth factor-1Type 2 diabetesGrowth hormone concentrationsIGF-1 expressionWild-type miceLean body massMuscle insulin resistanceGrowth factor-1Nuclear factor 4 alphaInsulin sensitivityDiet feedingPlasma concentrationsHormone concentrationsOverexpression of UCP3 decreases mitochondrial efficiency in mouse skeletal muscle in vivo
Codella R, Alves TC, Befroy DE, Choi CS, Luzi L, Rothman DL, Kibbey RG, Shulman GI. Overexpression of UCP3 decreases mitochondrial efficiency in mouse skeletal muscle in vivo. FEBS Letters 2022, 597: 309-319. PMID: 36114012, DOI: 10.1002/1873-3468.14494.Peer-Reviewed Original ResearchConceptsOverexpression of UCP3ATP synthesisMitochondrial oxidationMitochondrial transmembrane proteinInner mitochondrial membraneSkeletal muscleMitochondrial oxidative phosphorylationMitochondrial oxidative metabolismMuscle-specific overexpressionMouse skeletal muscleTransmembrane proteinMitochondrial membraneProton leakPrecise functionOxidative phosphorylationMitochondrial efficiencyUCP3 expressionMitochondrial inefficiencyOverexpressionProtein 3UCP3Oxidative metabolismVivoMagnetic resonance spectroscopyPhosphorylationBrown 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 thermogenesisMetformin, phenformin, and galegine inhibit complex IV activity and reduce glycerol-derived gluconeogenesis
LaMoia TE, Butrico GM, Kalpage HA, Goedeke L, Hubbard BT, Vatner DF, Gaspar RC, Zhang XM, Cline GW, Nakahara K, Woo S, Shimada A, Hüttemann M, Shulman GI. Metformin, phenformin, and galegine inhibit complex IV activity and reduce glycerol-derived gluconeogenesis. Proceedings Of The National Academy Of Sciences Of The United States Of America 2022, 119: e2122287119. PMID: 35238637, PMCID: PMC8916010, DOI: 10.1073/pnas.2122287119.Peer-Reviewed Original ResearchConceptsGlucose-lowering effectPlasma glucose concentrationComplex I activityHepatic gluconeogenesisType 2 diabetes mellitusGlucose concentrationGlycerol-3-phosphate dehydrogenase activityI activityDiabetes mellitusSelective inhibitionMetforminInhibitionRelevant concentrationsGluconeogenesisPhenforminVivoMost studiesDehydrogenase activityGalegineMellitusBioactive lipids and metabolic syndrome—a symposium report
DeVito LM, Dennis EA, Kahn BB, Shulman GI, Witztum JL, Sadhu S, Nickels J, Spite M, Smyth S, Spiegel S. Bioactive lipids and metabolic syndrome—a symposium report. Annals Of The New York Academy Of Sciences 2022, 1511: 87-106. PMID: 35218041, PMCID: PMC9219555, DOI: 10.1111/nyas.14752.Peer-Reviewed Original ResearchConceptsBioactive lipidsMetabolic syndromeCardiometabolic conditionsCardiovascular diseaseAnimal modelsDietary lipidsLipid metabolismMetabolic homeostasisMultitude of functionsLipidomic approachLipid pathwaysContinued investigationSyndromeMolecular functionsSymposium reportGenetic studiesLipidsPathwayInflammationGreater understandingDiseaseLiverMacrophagesLipogenesisDyrk1b promotes hepatic lipogenesis by bypassing canonical insulin signaling and directly activating mTORC2 in mice
Bhat N, Narayanan A, Fathzadeh M, Kahn M, Zhang D, Goedeke L, Neogi A, Cardone RL, Kibbey RG, Fernandez-Hernando C, Ginsberg HN, Jain D, Shulman G, Mani A. Dyrk1b promotes hepatic lipogenesis by bypassing canonical insulin signaling and directly activating mTORC2 in mice. Journal Of Clinical Investigation 2022, 132: e153724. PMID: 34855620, PMCID: PMC8803348, DOI: 10.1172/jci153724.Peer-Reviewed Original ResearchConceptsDe novo lipogenesisNonalcoholic steatohepatitisInsulin resistanceHepatic lipogenesisElevated de novo lipogenesisNonalcoholic fatty liver diseaseFatty liver diseaseLiver of patientsHepatic glycogen storageHigh-sucrose dietHepatic insulin resistanceFatty acid uptakeMetabolic syndromeLiver diseaseHepatic steatosisTriacylglycerol secretionNovo lipogenesisHepatic insulinTherapeutic targetImpaired activationAcid uptakeGlycogen storageMouse liverLiverLipogenesisSex‐ and strain‐specific effects of mitochondrial uncoupling on age‐related metabolic diseases in high‐fat diet‐fed mice
Goedeke L, Murt KN, Di Francesco A, Camporez JP, Nasiri AR, Wang Y, Zhang X, Cline GW, de Cabo R, Shulman GI. Sex‐ and strain‐specific effects of mitochondrial uncoupling on age‐related metabolic diseases in high‐fat diet‐fed mice. Aging Cell 2022, 21: e13539. PMID: 35088525, PMCID: PMC8844126, DOI: 10.1111/acel.13539.Peer-Reviewed Original ResearchConceptsControlled-release mitochondrial protonophoreAge-related metabolic diseasesHepatocellular carcinomaMetabolic diseasesHigh-fat diet-fed miceProtein kinase C epsilon activationDiet-induced obese miceWhole-body energy expenditureC57BL/6J male miceDiet-fed miceHigh-fat dietHepatic lipid peroxidationHepatic lipid contentMitochondrial uncouplingHepatic insulin resistanceHigh therapeutic indexHepatic mitochondrial biogenesisStrain-specific effectsSex-specific mannerCRMP treatmentHFD feedingUnwanted side effectsObese miceInsulin resistanceChronic ingestion
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 roleImmunotherapyMorbidityMMAB promotes negative feedback control of cholesterol homeostasis
Goedeke L, Canfrán-Duque A, Rotllan N, Chaube B, Thompson BM, Lee RG, Cline GW, McDonald JG, Shulman GI, Lasunción MA, Suárez Y, Fernández-Hernando C. MMAB promotes negative feedback control of cholesterol homeostasis. Nature Communications 2021, 12: 6448. PMID: 34750386, PMCID: PMC8575900, DOI: 10.1038/s41467-021-26787-7.Peer-Reviewed Original ResearchMeSH KeywordsAlkyl and Aryl TransferasesAnimalsCell Line, TumorCholesterolCholesterol, LDLFeedback, PhysiologicalGene Expression ProfilingHeLa CellsHep G2 CellsHomeostasisHumansHydroxymethylglutaryl CoA ReductasesLiverMice, Inbred C57BLMice, KnockoutPromoter Regions, GeneticReceptors, LDLRNA InterferenceSterol Regulatory Element Binding Protein 2ConceptsCholesterol biosynthesisCholesterol homeostasisMouse hepatic cell lineIntegrative genomic strategyIntricate regulatory networkMaster transcriptional regulatorCellular cholesterol levelsHMGCR activityLDL-cholesterol uptakeCholesterol levelsHuman hepatic cellsSterol contentGenomic strategiesTranscriptional regulatorsRegulatory networksIntracellular cholesterol levelsGene expressionUnexpected roleHepatic cell linesBiosynthesisMMABIntracellular levelsCell linesHomeostasisExpression of SREBP2Isthmin-1 is an adipokine that promotes glucose uptake and improves glucose tolerance and hepatic steatosis
Jiang Z, Zhao M, Voilquin L, Jung Y, Aikio MA, Sahai T, Dou FY, Roche AM, Carcamo-Orive I, Knowles JW, Wabitsch M, Appel EA, Maikawa CL, Camporez JP, Shulman GI, Tsai L, Rosen ED, Gardner CD, Spiegelman BM, Svensson KJ. Isthmin-1 is an adipokine that promotes glucose uptake and improves glucose tolerance and hepatic steatosis. Cell Metabolism 2021, 33: 1836-1852.e11. PMID: 34348115, PMCID: PMC8429235, DOI: 10.1016/j.cmet.2021.07.010.Peer-Reviewed Original ResearchConceptsFatty liver diseaseAdipose glucose uptakeGlucose toleranceLiver diseaseHepatic steatosisGlucose uptakeDiet-induced obese miceImpaired glucose toleranceInsulin-like growth factor receptorType 2 diabetesHepatic lipid synthesisIsthmin 1Growth factor receptorObese miceInsulin sensitivityTherapeutic dosingMouse modelGlucoregulatory functionGlucose regulationUnmet needTherapeutic potentialDiabetesLipid accumulationPI3K-AktFactor receptorDeletion of the diabetes candidate gene Slc16a13 in mice attenuates diet-induced ectopic lipid accumulation and insulin resistance
Schumann T, König J, von Loeffelholz C, Vatner DF, Zhang D, Perry RJ, Bernier M, Chami J, Henke C, Kurzbach A, El-Agroudy NN, Willmes DM, Pesta D, de Cabo R, O´Sullivan J, Simon E, Shulman GI, Hamilton BS, Birkenfeld AL. Deletion of the diabetes candidate gene Slc16a13 in mice attenuates diet-induced ectopic lipid accumulation and insulin resistance. Communications Biology 2021, 4: 826. PMID: 34211098, PMCID: PMC8249653, DOI: 10.1038/s42003-021-02279-8.Peer-Reviewed Original ResearchMeSH KeywordsAMP-Activated Protein KinasesAnimalsDiabetes Mellitus, Type 2Diet, High-FatGene ExpressionGenetic Predisposition to DiseaseHumansInsulin ResistanceLipid MetabolismLiverMice, Inbred C57BLMice, KnockoutMitochondriaMonocarboxylic Acid TransportersNon-alcoholic Fatty Liver DiseaseObesityOxygen ConsumptionConceptsMitochondrial respirationGenome-wide association studiesNovel susceptibility genesLipid accumulationPlasma membraneAMPK activationAssociation studiesPhysiological functionsEctopic lipid accumulationReduced hepatic lipid accumulationSusceptibility genesLactate transporterMonocarboxylate transportersPotential targetGenesTransportersDeletionLipid contentHepatic lipid accumulationPotential importanceKnockout miceRespirationHepatic insulin sensitivityMCT13AccumulationValidation of a Gas Chromatography-Mass Spectrometry Method for the Measurement of the Redox State Metabolic Ratios Lactate/Pyruvate and β-Hydroxybutyrate/Acetoacetate in Biological Samples
Wijngaard R, Perramón M, Parra-Robert M, Hidalgo S, Butrico G, Morales-Ruiz M, Zeng M, Casals E, Jiménez W, Fernández-Varo G, Shulman GI, Cline GW, Casals G. Validation of a Gas Chromatography-Mass Spectrometry Method for the Measurement of the Redox State Metabolic Ratios Lactate/Pyruvate and β-Hydroxybutyrate/Acetoacetate in Biological Samples. International Journal Of Molecular Sciences 2021, 22: 4752. PMID: 33946157, PMCID: PMC8125771, DOI: 10.3390/ijms22094752.Peer-Reviewed Original ResearchInsulin-stimulated endoproteolytic TUG cleavage links energy expenditure with glucose uptake
Habtemichael EN, Li DT, Camporez JP, Westergaard XO, Sales CI, Liu X, López-Giráldez F, DeVries SG, Li H, Ruiz DM, Wang KY, Sayal BS, González Zapata S, Dann P, Brown SN, Hirabara S, Vatner DF, Goedeke L, Philbrick W, Shulman GI, Bogan JS. Insulin-stimulated endoproteolytic TUG cleavage links energy expenditure with glucose uptake. Nature Metabolism 2021, 3: 378-393. PMID: 33686286, PMCID: PMC7990718, DOI: 10.1038/s42255-021-00359-x.Peer-Reviewed Original ResearchConceptsTUG cleavageGlucose uptakeProtein degradation pathwaysGLUT4 glucose transportersCoactivator PGC-1αC-terminal cleavage productInsulin-stimulated glucose uptakeAte1 arginyltransferaseGene expressionPhysiological relevanceWhole-body energy expenditureGlucose transporterPeroxisome proliferator-activated receptorCell surfacePGC-1αProtein 1Proliferator-activated receptorDegradation pathwayEffect of insulinCleavage pathwayAdipose cellsCleavage productsPathwayCleavageEnergy expenditure