Featured Publications
Thyroid hormone inhibits lung fibrosis in mice by improving epithelial mitochondrial function
Yu G, Tzouvelekis A, Wang R, Herazo-Maya JD, Ibarra GH, Srivastava A, de Castro JPW, DeIuliis G, Ahangari F, Woolard T, Aurelien N, Arrojo e Drigo R, Gan Y, Graham M, Liu X, Homer RJ, Scanlan TS, Mannam P, Lee PJ, Herzog EL, Bianco AC, Kaminski N. Thyroid hormone inhibits lung fibrosis in mice by improving epithelial mitochondrial function. Nature Medicine 2017, 24: 39-49. PMID: 29200204, PMCID: PMC5760280, DOI: 10.1038/nm.4447.Peer-Reviewed Original ResearchmicroRNA-33 deficiency in macrophages enhances autophagy, improves mitochondrial homeostasis, and protects against lung fibrosis
Ahangari F, Price N, Malik S, Chioccioli M, Bärnthaler T, Adams T, Kim J, Pradeep S, Ding S, Cosme C, Rose K, McDonough J, Aurelien N, Ibarra G, Omote N, Schupp J, DeIuliis G, Nunez J, Sharma L, Ryu C, Dela Cruz C, Liu X, Prasse A, Rosas I, Bahal R, Fernandez-Hernando C, Kaminski N. microRNA-33 deficiency in macrophages enhances autophagy, improves mitochondrial homeostasis, and protects against lung fibrosis. JCI Insight 2023, 8: e158100. PMID: 36626225, PMCID: PMC9977502, DOI: 10.1172/jci.insight.158100.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAutophagyBleomycinHomeostasisHumansIdiopathic Pulmonary FibrosisMacrophagesMiceMicroRNAsMitochondriaConceptsIdiopathic pulmonary fibrosisPulmonary fibrosisMiR-33MiR-33 levelsSpecific genetic ablationBronchoalveolar lavage cellsNovel therapeutic approachesMitochondrial homeostasisFatty acid metabolismMacrophages protectsBleomycin injuryLavage cellsLung fibrosisHealthy controlsInflammatory responseTherapeutic approachesImmunometabolic responsesCholesterol effluxFibrosisFatal diseasePharmacological inhibitionSterol regulatory element-binding protein (SREBP) genesGenetic ablationMacrophagesEx vivo mouse
2023
Thyroid hormone modulates hyperoxic neonatal lung injury and mitochondrial function
Vamesu B, Nicola T, Li R, Hazra S, Matalon S, Kaminski N, Ambalavanan N, Kandasamy J. Thyroid hormone modulates hyperoxic neonatal lung injury and mitochondrial function. JCI Insight 2023, 8: e160697. PMID: 36917181, PMCID: PMC10243814, DOI: 10.1172/jci.insight.160697.Peer-Reviewed Original ResearchConceptsUmbilical cord-derived mesenchymal stem cellsNeonatal lung injuryMild bronchopulmonary dysplasiaSevere bronchopulmonary dysplasiaBronchopulmonary dysplasiaLung injuryELBW infantsThyroid hormonesLung homogenatesMitochondrial dysfunctionTotal T4Newborn miceLow birth weight infantsMitochondrial functionNeonatal hyperoxic lung injuryPeroxisome proliferator-activated receptor γ coactivator 1αProliferator-activated receptor γ coactivator 1αHyperoxic lung injuryReceptor γ coactivator 1αLow total T4Murine lung fibroblastsΓ coactivator 1αNeonatal hypothyroxinemiaWeight infantsPulmonary fibrosis
2021
PINK1 mediates the protective effects of thyroid hormone T3 in hyperoxia-induced lung injury
Zhang Y, Yu G, Kaminski N, Lee P. PINK1 mediates the protective effects of thyroid hormone T3 in hyperoxia-induced lung injury. American Journal Of Physiology - Lung Cellular And Molecular Physiology 2021, 320: l1118-l1125. PMID: 33851544, PMCID: PMC8285622, DOI: 10.1152/ajplung.00598.2020.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsHyperoxiaInflammationLungLung InjuryMice, KnockoutMitochondriaProtein KinasesTriiodothyronineConceptsLung injuryWT miceThyroid hormonesBronchoalveolar lavageHyperoxia exposureBAL total cell countT3 pretreatmentAdult wild-type miceAdministration of PTULung cellular infiltratesAcute lung injuryWild-type miceNovel protective roleRespiratory failureCellular infiltrateThyroid hormone T3Total cell countHistological changesProtective effectPotential therapyProtective roleCell countCytoprotective effectsMitochondrial injuryHyperoxia
2020
Retrograde signaling by a mtDNA-encoded non-coding RNA preserves mitochondrial bioenergetics
Blumental-Perry A, Jobava R, Bederman I, Degar A, Kenche H, Guan B, Pandit K, Perry N, Molyneaux N, Wu J, Prendergas E, Ye Z, Zhang J, Nelson C, Ahangari F, Krokowski D, Guttentag S, Linden P, Townsend D, Miron A, Kang M, Kaminski N, Perry Y, Hatzoglou M. Retrograde signaling by a mtDNA-encoded non-coding RNA preserves mitochondrial bioenergetics. Communications Biology 2020, 3: 626. PMID: 33127975, PMCID: PMC7603330, DOI: 10.1038/s42003-020-01322-4.Peer-Reviewed Original ResearchConceptsMitochondrial genomeNuclear-encoded genesCell type-specific mannerNon-coding RNASteady-state transcriptionMitochondrial energy metabolismControl regionPositive regulationMitochondrial bioenergeticsMitochondria stressMitochondrial functionSpecific mannerAlveolar epithelial type II cellsEnergy metabolismType II cellsEpithelial type II cellsGenomePhysiological stressRNAII cellsCellsMouse lungTranscriptionGenesMitochondria
2015
Mesenchymal stem cells use extracellular vesicles to outsource mitophagy and shuttle microRNAs
Phinney DG, Di Giuseppe M, Njah J, Sala E, Shiva S, St Croix CM, Stolz DB, Watkins SC, Di YP, Leikauf GD, Kolls J, Riches DW, Deiuliis G, Kaminski N, Boregowda SV, McKenna DH, Ortiz LA. Mesenchymal stem cells use extracellular vesicles to outsource mitophagy and shuttle microRNAs. Nature Communications 2015, 6: 8472. PMID: 26442449, PMCID: PMC4598952, DOI: 10.1038/ncomms9472.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsArrestinsBlotting, WesternCell-Derived MicroparticlesExosomesExtracellular VesiclesFlow CytometryHumansMacrophagesMesenchymal Stem CellsMiceMicroRNAsMicroscopy, ElectronMitochondriaMitophagyMyeloid Differentiation Factor 88Oxidative StressReceptors, ImmunologicSignal TransductionSilicosisToll-Like Receptor 4Toll-Like Receptor 9Toll-Like ReceptorsConceptsMesenchymal stem cellsStem cellsDomain-containing protein 1Stem cell nicheHealthy mitochondrial functionHaematopoietic stem cellsCell nichePlasma membraneToll-like receptor signalingIntracellular oxidative stressMitochondrial functionExtracellular vesiclesMicro RNAsReceptor signalingProtein 1MitophagyMSC survivalMitochondriaOxidative stressMacrophage functionVesiclesCellsRecent studiesMacrophage activationMacrophages
2014
The Mitochondrial Cardiolipin Remodeling Enzyme Lysocardiolipin Acyltransferase Is a Novel Target in Pulmonary Fibrosis
Huang LS, Mathew B, Li H, Zhao Y, Ma SF, Noth I, Reddy SP, Harijith A, Usatyuk PV, Berdyshev EV, Kaminski N, Zhou T, Zhang W, Zhang Y, Rehman J, Kotha SR, Gurney TO, Parinandi NL, Lussier YA, Garcia JG, Natarajan V. The Mitochondrial Cardiolipin Remodeling Enzyme Lysocardiolipin Acyltransferase Is a Novel Target in Pulmonary Fibrosis. American Journal Of Respiratory And Critical Care Medicine 2014, 189: 1402-1415. PMID: 24779708, PMCID: PMC4098083, DOI: 10.1164/rccm.201310-1917oc.Peer-Reviewed Original ResearchMeSH Keywords1-Acylglycerol-3-Phosphate O-AcyltransferaseAcyltransferasesAnimalsBiomarkersCardiolipinsCohort StudiesDisease Models, AnimalHumansIdiopathic Pulmonary FibrosisIn Situ HybridizationLeukocytes, MononuclearMiceMitochondriaPredictive Value of TestsPulmonary FibrosisRNA, MessengerSensitivity and SpecificitySeverity of Illness IndexConceptsPeripheral blood mononuclear cellsIdiopathic pulmonary fibrosisPulmonary fibrosisMurine modelAlveolar epithelial cellsOverall survivalReactive oxygen species generationLysocardiolipin acyltransferaseOxygen species generationCarbon monoxide diffusion capacityRadiation-induced pulmonary fibrosisPulmonary function outcomesEpithelial cellsBlood mononuclear cellsPreclinical murine modelsNovel therapeutic approachesSpecies generationBleomycin challengeLung inflammationLung protectionPulmonary functionFunction outcomesLung fibrosisMononuclear cellsFibrotic lungs