2018
Genetic Ablation of miR-33 Increases Food Intake, Enhances Adipose Tissue Expansion, and Promotes Obesity and Insulin Resistance
Price NL, Singh AK, Rotllan N, Goedeke L, Wing A, Canfrán-Duque A, Diaz-Ruiz A, Araldi E, Baldán Á, Camporez JP, Suárez Y, Rodeheffer MS, Shulman GI, de Cabo R, Fernández-Hernando C. Genetic Ablation of miR-33 Increases Food Intake, Enhances Adipose Tissue Expansion, and Promotes Obesity and Insulin Resistance. Cell Reports 2018, 22: 2133-2145. PMID: 29466739, PMCID: PMC5860817, DOI: 10.1016/j.celrep.2018.01.074.Peer-Reviewed Original ResearchMeSH KeywordsAdipose TissueAdiposityAnimalsCholesterol, HDLCholesterol, LDLEatingEnzyme ActivationGene DeletionGene Expression RegulationGenetic Predisposition to DiseaseGerm CellsInflammation MediatorsInsulin ResistanceLipid MetabolismLiverMice, Inbred C57BLMicroRNAsModels, BiologicalObesityProtein Kinase C-epsilonSterol Regulatory Element Binding Protein 1ConceptsMiR-33Insulin resistanceFood intakeIncreases food intakeAdipose tissue expansionKey metabolic tissuesWild-type animalsPromotes obesityImpaired lipolysisPair feedingCardiovascular diseaseMetabolic dysfunctionTherapeutic modulationAdipose tissueLipid uptakeMiRNA-based therapiesMetabolic tissuesGenetic ablationTissue expansionMiceObesityTherapyDeleterious effectsDiseasePrevious reports
2016
ANGPTL4 deficiency in haematopoietic cells promotes monocyte expansion and atherosclerosis progression
Aryal B, Rotllan N, Araldi E, Ramírez CM, He S, Chousterman BG, Fenn AM, Wanschel A, Madrigal-Matute J, Warrier N, Martín-Ventura JL, Swirski FK, Suárez Y, Fernández-Hernando C. ANGPTL4 deficiency in haematopoietic cells promotes monocyte expansion and atherosclerosis progression. Nature Communications 2016, 7: 12313. PMID: 27460411, PMCID: PMC4974469, DOI: 10.1038/ncomms12313.Peer-Reviewed Original ResearchMeSH KeywordsAngiopoietin-Like Protein 4AnimalsApoptosisAtherosclerosisBone Marrow TransplantationCell ProliferationCell SurvivalDisease ProgressionFoam CellsHematopoietic Stem CellsHumansInflammationLeukocytosisMacrophagesMaleMiceMice, Inbred C57BLModels, BiologicalMonocytesMyeloid Progenitor CellsPlaque, AtheroscleroticConceptsFoam cell formationMyeloid progenitor cell expansionANGPTL4 deficiencyCell formationMacrophage gene expressionLipid raft contentMyeloid progenitor populationsProgenitor cell expansionUpregulated genesProgenitor populationsGene expressionHaematopoietic cellsCell surfaceMacrophage apoptosisCell expansionCells resultsProtein 4Lipid accumulationCD36 expressionLike protein 4ExpressionProfound effectMacrophagesGenesLarger atherosclerotic plaques
2012
MicroRNAs regulating lipid metabolism in atherogenesis
Rayner K, Fernandez-Hernando C, Moore K. MicroRNAs regulating lipid metabolism in atherogenesis. Thrombosis And Haemostasis 2012, 107: 642-647. PMID: 22274626, PMCID: PMC3618663, DOI: 10.1160/th11-10-0694.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAtherosclerosisATP Binding Cassette Transporter 1ATP-Binding Cassette TransportersCholesterolDisease Models, AnimalFatty AcidsGene Expression RegulationHumansLipid MetabolismLipoproteins, HDLLipoproteins, VLDLLiverMiceMicroRNAsModels, BiologicalSterol Regulatory Element Binding Protein 1Sterol Regulatory Element Binding Protein 2TriglyceridesConceptsSmall non-coding RNAsImportant post-transcriptional regulatorsCellular sterol levelsPost-transcriptional regulatorsNon-coding RNAsVariety of genesSterol response elementFatty acid homeostasisIntronic microRNAsLipid metabolismFatty acid synthesisHost genesTranscription factorsProtein geneCholesterol exportMetabolic programsKey regulatorFatty acid oxidationResponse elementHigh-density lipoproteinMicroRNAsRelated metabolic diseasesGenesABCA1 pathwayAcid homeostasis