2017
Rapamycin treatment dose‐dependently improves the cystic kidney in a new ADPKD mouse model via the mTORC1 and cell‐cycle‐associated CDK1/cyclin axis
Li A, Fan S, Xu Y, Meng J, Shen X, Mao J, Zhang L, Zhang X, Moeckel G, Wu D, Wu G, Liang C. Rapamycin treatment dose‐dependently improves the cystic kidney in a new ADPKD mouse model via the mTORC1 and cell‐cycle‐associated CDK1/cyclin axis. Journal Of Cellular And Molecular Medicine 2017, 21: 1619-1635. PMID: 28244683, PMCID: PMC5543471, DOI: 10.1111/jcmm.13091.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntibiotics, AntineoplasticCDC2 Protein KinaseCell CycleCyclinsDose-Response Relationship, DrugFemaleFounder EffectGene Expression RegulationHumansIntegrasesKidneyMaleMiceMice, TransgenicMicrofilament ProteinsPolycystic Kidney, Autosomal DominantPromoter Regions, GeneticSignal TransductionSirolimusTOR Serine-Threonine KinasesTRPP Cation ChannelsConceptsAutosomal dominant polycystic kidney diseaseEnd-stage renal diseaseMouse modelCyclin-dependent kinase 1Kidney/body weight ratioPreclinical trialsVivo preclinical resultsBody weight ratioCre transgenic miceHigh-dose rapamycinStandardized animal modelHuman autosomal dominant polycystic kidney diseaseRapamycin (mTOR) inhibitor rapamycinDominant polycystic kidney diseaseMonths of ageOrthologous mouse modelConditional knockout miceDose-dependent mannerPolycystic kidney diseaseAberrant epithelial cell proliferationEpithelial cell proliferationNew molecular targetsADPKD therapyRenal functionADPKD mouse model
2009
Distinct Roles for Basal and Induced COX-2 in Podocyte Injury
Cheng H, Fan X, Guan Y, Moeckel GW, Zent R, Harris RC. Distinct Roles for Basal and Induced COX-2 in Podocyte Injury. Journal Of The American Society Of Nephrology 2009, 20: 1953-1962. PMID: 19643929, PMCID: PMC2736764, DOI: 10.1681/asn.2009010039.Peer-Reviewed Original ResearchMeSH KeywordsAlbuminuriaAnimalsAntibiotics, AntineoplasticApoptosisCell AdhesionCell Line, TransformedCell SurvivalCyclooxygenase 2DinoprostoneDoxorubicinGlomerulonephritisMaleMiceMice, Inbred StrainsMice, TransgenicPodocytesPuromycinReceptors, Prostaglandin EReceptors, ThromboxaneRNA, MessengerThromboxanesConceptsCyclooxygenase-2Thromboxane receptorCOX-2 knockout miceSelective deletionCOX-2 deletionInduced COX-2Receptor subtype 4COX-2 metabolitesFoot process effacementGlomerular injuryPodocyte injuryProstanoid receptorsAttenuated albuminuriaWild-type podocytesSubtype 4Transgenic miceProcess effacementTP antagonistPodocyte survivalInjuryMore prostaglandinsGenetic deletionMicePodocytesGreater expression
2004
Lack of Integrin α1β1 Leads to Severe Glomerulosclerosis after Glomerular Injury
Chen X, Moeckel G, Morrow JD, Cosgrove D, Harris RC, Fogo AB, Zent R, Pozzi A. Lack of Integrin α1β1 Leads to Severe Glomerulosclerosis after Glomerular Injury. American Journal Of Pathology 2004, 165: 617-630. PMID: 15277235, PMCID: PMC1618576, DOI: 10.1016/s0002-9440(10)63326-3.Peer-Reviewed Original ResearchConceptsSevere glomerulosclerosisGlomerular injuryIntegrin alpha1-null miceSeverity of fibrosisCollagen IV accumulationWild-type miceHost genetic susceptibilityMetabolism of collagenReactive oxygen species productionFibrotic lesionsIntegrin alpha1beta1Oxygen species productionAdriamycin treatmentMesangial cellsMatrix accumulationGenetic susceptibilityInjuryGlomerulosclerosisFibrosisCell proliferationROS productionSpecies productionROS synthesisIntegrin α1β1Mice