2024
microRNA-33 controls hunger signaling in hypothalamic AgRP neurons
Price N, Fernández-Tussy P, Varela L, Cardelo M, Shanabrough M, Aryal B, de Cabo R, Suárez Y, Horvath T, Fernández-Hernando C. microRNA-33 controls hunger signaling in hypothalamic AgRP neurons. Nature Communications 2024, 15: 2131. PMID: 38459068, PMCID: PMC10923783, DOI: 10.1038/s41467-024-46427-0.Peer-Reviewed Original ResearchConceptsAgRP neuronsFeeding behaviorFatty acid metabolismNon-coding RNAsMitochondrial biogenesisRegulatory pathwaysTarget genesHypothalamic AgRP neuronsExcessive nutrient intakeCentral regulatorBioenergetic processesAcid metabolismActivation of AgRP neuronsModulate feeding behaviorCentral regulation of feeding behaviorRegulation of feeding behaviorMiR-33Hunger signalsMicroRNA-33Metabolic diseasesAlternative therapeutic approachLoss of miR-33Mouse modelMetabolic dysfunctionRegulation
2021
Loss of hepatic miR-33 improves metabolic homeostasis and liver function without altering body weight or atherosclerosis
Price NL, Zhang X, Fernández-Tussy P, Singh AK, Burnap SA, Rotllan N, Goedeke L, Sun J, Canfrán-Duque A, Aryal B, Mayr M, Suárez Y, Fernández-Hernando C. Loss of hepatic miR-33 improves metabolic homeostasis and liver function without altering body weight or atherosclerosis. Proceedings Of The National Academy Of Sciences Of The United States Of America 2021, 118: e2006478118. PMID: 33495342, PMCID: PMC7865172, DOI: 10.1073/pnas.2006478118.Peer-Reviewed Original ResearchConceptsMiR-33 deficiencyHDL-C levelsMiR-33Body weightAtherosclerotic plaque sizeAtherosclerotic plaque burdenDevelopment of fibrosisCholesterol transport capacityCholesterol transporter ABCA1High-density lipoprotein biogenesisSREBP2 transcription factorKnockout mouse modelConditional knockout mouse modelPlaque burdenCardiometabolic diseasesChow dietLiver functionMetabolic dysfunctionHDL metabolismHyperlipidemic conditionsMouse modelGlucose homeostasisCholesterol effluxLipid metabolismObesity
2019
Genetic deficiency or pharmacological inhibition of miR-33 protects from kidney fibrosis
Price NL, Miguel V, Ding W, Singh AK, Malik S, Rotllan N, Moshnikova A, Toczek J, Zeiss C, Sadeghi MM, Arias N, Baldán Á, Andreev OA, Rodríguez-Puyol D, Bahal R, Reshetnyak YK, Suárez Y, Fernández-Hernando C, Lamas S. Genetic deficiency or pharmacological inhibition of miR-33 protects from kidney fibrosis. JCI Insight 2019, 4 PMID: 31613798, PMCID: PMC6948871, DOI: 10.1172/jci.insight.131102.Peer-Reviewed Original ResearchConceptsFatty acid oxidationChronic kidney diseaseKidney diseaseDisease progressionMiR-33Bone marrow transplantExtent of fibrosisDevelopment of fibrosisAttractive therapeutic targetExpression of factorsNucleic acid inhibitorsMarrow transplantKidney fibrosisFibrotic kidneysMouse modelTherapeutic targetLipid metabolismPharmacological inhibitionFibrosisLipid accumulationDiseaseGenetic deficiencyProgressionKidneyAcid oxidationCaveolin-1 Regulates Atherogenesis by Attenuating Low-Density Lipoprotein Transcytosis and Vascular Inflammation Independently of Endothelial Nitric Oxide Synthase Activation
Ramírez CM, Zhang X, Bandyopadhyay C, Rotllan N, Sugiyama MG, Aryal B, Liu X, He S, Kraehling JR, Ulrich V, Lin CS, Velazquez H, Lasunción MA, Li G, Suárez Y, Tellides G, Swirski FK, Lee WL, Schwartz MA, Sessa WC, Fernández-Hernando C. Caveolin-1 Regulates Atherogenesis by Attenuating Low-Density Lipoprotein Transcytosis and Vascular Inflammation Independently of Endothelial Nitric Oxide Synthase Activation. Circulation 2019, 140: 225-239. PMID: 31154825, PMCID: PMC6778687, DOI: 10.1161/circulationaha.118.038571.Peer-Reviewed Original ResearchConceptsEndothelial nitric oxide synthaseDiet-induced atherosclerosisNO productionVascular inflammationENOS activationEndothelial nitric oxide synthase activationNitric oxide synthase activationAthero-protective functionsLipid metabolic factorsEndothelial cell inflammationNitric oxide synthaseWild-type miceMice Lacking ExpressionProduction of NOExtracellular matrix remodelingInflammatory primingHyperlipidemic miceInflammatory pathwaysAortic archCell inflammationOxide synthaseMetabolic factorsMouse modelAtherosclerosisInflammationSpecific Disruption of Abca1 Targeting Largely Mimics the Effects of miR-33 Knockout on Macrophage Cholesterol Efflux and Atherosclerotic Plaque Development
Price NL, Rotllan N, Zhang X, Canfrán-Duque A, Nottoli T, Suarez Y, Fernández-Hernando C. Specific Disruption of Abca1 Targeting Largely Mimics the Effects of miR-33 Knockout on Macrophage Cholesterol Efflux and Atherosclerotic Plaque Development. Circulation Research 2019, 124: 874-880. PMID: 30707082, PMCID: PMC6417928, DOI: 10.1161/circresaha.118.314415.Peer-Reviewed Original ResearchConceptsMacrophage cholesterol effluxAtherosclerotic plaque formationCholesterol effluxMiR-33Proatherogenic effectsABCA1 expressionBone marrowDeficient animalsPlaque formationMiR-33-deficient miceHigh-fat diet feedingHepatic ABCA1 expressionAtherosclerotic plaque burdenFat diet feedingDevelopment of obesityNovel mouse modelAtherosclerotic plaque developmentFoam cell formationPlaque burdenDeficient miceDiet feedingMetabolic dysfunctionSpecific disruptionMouse modelKnockout mice
2018
Brown adipose tissue derived ANGPTL4 controls glucose and lipid metabolism and regulates thermogenesis
Singh AK, Aryal B, Chaube B, Rotllan N, Varela L, Horvath TL, Suárez Y, Fernández-Hernando C. Brown adipose tissue derived ANGPTL4 controls glucose and lipid metabolism and regulates thermogenesis. Molecular Metabolism 2018, 11: 59-69. PMID: 29627378, PMCID: PMC6001401, DOI: 10.1016/j.molmet.2018.03.011.Peer-Reviewed Original ResearchConceptsBrown adipose tissueAdipose tissueAbsence of ANGPTL4Lipoprotein metabolismLPL activityShort-term HFD feedingTriglyceride-rich lipoprotein catabolismLipoprotein lipaseRole of ANGPTL4Novel mouse modelAcute cold exposureGlucose toleranceHFD feedingFatty acidsLipoprotein catabolismWhole body lipidGlucose homeostasisMouse modelGlucose metabolismTAG clearanceBAT resultsLipid metabolismANGPTL4Cold exposureFA oxidation
2016
Chronic miR‐29 antagonism promotes favorable plaque remodeling in atherosclerotic mice
Ulrich V, Rotllan N, Araldi E, Luciano A, Skroblin P, Abonnenc M, Perrotta P, Yin X, Bauer A, Leslie KL, Zhang P, Aryal B, Montgomery RL, Thum T, Martin K, Suarez Y, Mayr M, Fernandez-Hernando C, Sessa WC. Chronic miR‐29 antagonism promotes favorable plaque remodeling in atherosclerotic mice. EMBO Molecular Medicine 2016, 8: 643-653. PMID: 27137489, PMCID: PMC4888854, DOI: 10.15252/emmm.201506031.Peer-Reviewed Original ResearchConceptsPlaque morphologyReduced lesion sizeAcute myocardial infarctionAtherosclerotic mouse modelVulnerable atherosclerotic lesionsFibrous cap thicknessPlaque extracellular matrixChronic administrationExtracellular matrixAtherosclerotic miceMyocardial infarctionPlaque remodelingSolid organsAbnormal remodelingMouse modelAtherosclerotic lesionsAtherosclerotic plaquesBlood chemistryLesion sizeMiR-29Necrotic zoneLesionsPlaquesCap thicknessMiR-29 target genesSREBP-1c/MicroRNA 33b Genomic Loci Control Adipocyte Differentiation
Price NL, Holtrup B, Kwei SL, Wabitsch M, Rodeheffer M, Bianchini L, Suárez Y, Fernández-Hernando C. SREBP-1c/MicroRNA 33b Genomic Loci Control Adipocyte Differentiation. Molecular And Cellular Biology 2016, 36: 1180-1193. PMID: 26830228, PMCID: PMC4800797, DOI: 10.1128/mcb.00745-15.Peer-Reviewed Original ResearchConceptsWhite adipose tissueCyclin-dependent kinase 6MiR-33bSREBP-1Adipocyte differentiationReceptor-γ target genesPeroxisome proliferator-activated receptor-γ target genesDevelopment of obesityStandard mouse modelSterol regulatory element-binding protein 2Lipid droplet formationLipid droplet accumulationIntronic microRNAsHost genesTarget genesMouse modelKinase 6Adipose tissueMetabolic diseasesNovel roleImportant regulatorHuman preadipocytesDroplet accumulationVivo assessmentProtein 2