2024
Endothelial γ-protocadherins inhibit KLF2 and KLF4 to promote atherosclerosis
Joshi D, Coon B, Chakraborty R, Deng H, Yang Z, Babar M, Fernandez-Tussy P, Meredith E, Attanasio J, Joshi N, Traylor J, Orr A, Fernandez-Hernando C, Libreros S, Schwartz M. Endothelial γ-protocadherins inhibit KLF2 and KLF4 to promote atherosclerosis. Nature Cardiovascular Research 2024, 3: 1035-1048. PMID: 39232138, PMCID: PMC11399086, DOI: 10.1038/s44161-024-00522-z.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAtherosclerosisCadherin Related ProteinsCadherinsDisease Models, AnimalEndothelial CellsHuman Umbilical Vein Endothelial CellsHumansKruppel-Like Factor 4Kruppel-Like Transcription FactorsMaleMiceMice, Inbred C57BLMice, KnockoutPlaque, AtheroscleroticReceptors, NotchSignal TransductionConceptsAtherosclerotic cardiovascular diseaseIntracellular domainNotch intracellular domainTranscription factor KLF2Mechanisms of vascular inflammationAnti-inflammatory programVascular endothelial cellsHost defenseCleavage resultsAntibody blockadeGenetic deletionVascular inflammationViral infectionImmune systemEndothelial cellsCardiovascular diseasePromote atherosclerosisBlood flowKLF2KLF4Suppressive signalsEndotheliumMechanistic studies
2022
mTOR inhibition prevents angiotensin II–induced aortic rupture and pseudoaneurysm but promotes dissection in Apoe-deficient mice
He C, Jiang B, Wang M, Ren P, Murtada SI, Caulk AW, Li G, Qin L, Assi R, Lovoulos CJ, Schwartz MA, Humphrey JD, Tellides G. mTOR inhibition prevents angiotensin II–induced aortic rupture and pseudoaneurysm but promotes dissection in Apoe-deficient mice. JCI Insight 2022, 7: e155815. PMID: 35132962, PMCID: PMC8855820, DOI: 10.1172/jci.insight.155815.Peer-Reviewed Original ResearchConceptsApoE-deficient miceAngiotensin IIVascular wall cellsAortic tearAortic ruptureMTOR inhibitionSmooth muscle cell hypertrophyMatricellular proteinWall cellsSuprarenal abdominal aortaMuscle cell hypertrophyExtracellular matrix accumulationInhibition of mTORRole of mTORSubadventitial hematomaFree ruptureAortic dissectionAortic diseaseAortic aneurysmSignificant dissectionAbdominal aortaHemorrhagic lesionsExtensive dissectionMetalloproteinase expressionCell hypertrophy
2021
Activation of Smad2/3 signaling by low fluid shear stress mediates artery inward remodeling
Deng H, Min E, Baeyens N, Coon BG, Hu R, Zhuang ZW, Chen M, Huang B, Afolabi T, Zarkada G, Acheampong A, McEntee K, Eichmann A, Liu F, Su B, Simons M, Schwartz MA. Activation of Smad2/3 signaling by low fluid shear stress mediates artery inward remodeling. Proceedings Of The National Academy Of Sciences Of The United States Of America 2021, 118: e2105339118. PMID: 34504019, PMCID: PMC8449390, DOI: 10.1073/pnas.2105339118.Peer-Reviewed Original ResearchConceptsLow fluid shear stressFluid shear stressNuclear translocationSmad linker regionTransmembrane protein Neuropilin-1Target gene expressionCyclin-dependent kinasesBone morphogenetic proteinEC-specific deletionSmad2/3 nuclear translocationNuclear localizationHigh fluid shear stressLinker regionMorphogenetic proteinsGene expressionRegulatory mechanismsActivation of Smad2/3Receptor ALK5Smad2/3 phosphorylationTranslocationCell sensingEndothelial cell (EC) sensingPhosphorylationALK5Smad2/3Developmental origins of mechanical homeostasis in the aorta
Murtada S, Kawamura Y, Li G, Schwartz MA, Tellides G, Humphrey JD. Developmental origins of mechanical homeostasis in the aorta. Developmental Dynamics 2021, 250: 629-639. PMID: 33341996, PMCID: PMC8089041, DOI: 10.1002/dvdy.283.Peer-Reviewed Original ResearchMeSH KeywordsAdaptation, BiologicalAnimalsAorta, ThoracicHomeostasisMaleMice, Inbred C57BLStress, MechanicalConceptsPostnatal days P2Intramural cellsSmooth muscle contractilityLate prenatal periodBlood pressureDays P2Muscle contractilityAortic structureMurine aortaPrenatal periodEndothelial cellsAortaPathological conditionsAortic developmentDeposition of matrixDevelopmental originsMatrix depositionHomeostasisHomeostatic stateCellsIntramural stressPressure-induced mechanical stressFlow-induced shear stressMechanical loadingContractility
2019
Caveolin-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 modelAtherosclerosisInflammationMicroRNA-dependent regulation of biomechanical genes establishes tissue stiffness homeostasis
Moro A, Driscoll TP, Boraas LC, Armero W, Kasper DM, Baeyens N, Jouy C, Mallikarjun V, Swift J, Ahn SJ, Lee D, Zhang J, Gu M, Gerstein M, Schwartz M, Nicoli S. MicroRNA-dependent regulation of biomechanical genes establishes tissue stiffness homeostasis. Nature Cell Biology 2019, 21: 348-358. PMID: 30742093, PMCID: PMC6528464, DOI: 10.1038/s41556-019-0272-y.Peer-Reviewed Original ResearchConceptsArgonaute 2MicroRNA-dependent regulationMechanical homeostasisMicroRNA recognition elementsExtracellular matrix proteinsZebrafish finsMicroRNA familiesTarget mRNAsVertebrate tissuesHyper-contractile phenotypesRegulatory pathwaysUntranslated regionRecognition elementMatrix proteinsComprehensive identificationCaM mRNAConnective tissue growth factorExtracellular matrix depositionHomeostasisTissue growth factorMRNAFibroblast cellsMicroRNAsGrowth factorSoft substratesARHGAP18: A Flow‐Responsive Gene That Regulates Endothelial Cell Alignment and Protects Against Atherosclerosis
Lay AJ, Coleman PR, Formaz‐Preston A, Ting KK, Roediger B, Weninger W, Schwartz MA, Vadas MA, Gamble JR. ARHGAP18: A Flow‐Responsive Gene That Regulates Endothelial Cell Alignment and Protects Against Atherosclerosis. Journal Of The American Heart Association 2019, 8: e010057. PMID: 30630384, PMCID: PMC6497359, DOI: 10.1161/jaha.118.010057.Peer-Reviewed Original ResearchConceptsApolipoprotein EHigh-fat diet-induced modelIntercellular adhesion molecule-1Endothelial nitric oxide synthaseHigh-fat dietDevelopment of atherosclerosisNitric oxide synthaseDiet-induced modelAdhesion molecule-1Double mutant miceAortic diseaseAtherosclerosis developmentInflammatory phenotypeOxide synthaseMolecule-1AtherosclerosisEarly onsetProtective genesMiceFlow-responsive genesAtheroprotective regionsEndothelial cell alignmentAdaptive responseAnalysis of ECEC ability
2018
Inhibiting Integrin α5 Cytoplasmic Domain Signaling Reduces Atherosclerosis and Promotes Arteriogenesis
Budatha M, Zhang J, Zhuang ZW, Yun S, Dahlman JE, Anderson DG, Schwartz MA. Inhibiting Integrin α5 Cytoplasmic Domain Signaling Reduces Atherosclerosis and Promotes Arteriogenesis. Journal Of The American Heart Association 2018, 7: e007501. PMID: 29382667, PMCID: PMC5850249, DOI: 10.1161/jaha.117.007501.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAortaAortic DiseasesAtherosclerosisCyclic Nucleotide Phosphodiesterases, Type 4Disease Models, AnimalExtracellular MatrixFibronectinsFibrosisGenetic Predisposition to DiseaseHindlimbInflammation MediatorsIntegrin alpha2Integrin alpha5IschemiaLeukocytesMaleMatrix MetalloproteinasesMice, Inbred C57BLMice, Knockout, ApoEMuscle, SkeletalNeovascularization, PhysiologicNF-kappa BPhenotypePlaque, AtheroscleroticSignal TransductionVascular RemodelingConceptsEndothelial inflammatory activationAtherosclerotic plaque sizeInflammatory activationPlaque stabilityVascular remodelingEndothelial NF-κB activationSmooth muscle cell contentPlaque sizeFemoral artery ligationMuscle cell contentTreatment of atherosclerosisInflammatory gene expressionPotential therapeutic targetFibrous cap thicknessNF-κB activationSmaller atherosclerotic plaquesArtery ligationAortic rootHindlimb ischemiaCompensatory remodelingAtherosclerotic plaquesTherapeutic targetLeukocyte contentMetalloproteinase expressionEndothelial basement membrane
2017
Shear-induced Notch-Cx37-p27 axis arrests endothelial cell cycle to enable arterial specification
Fang JS, Coon BG, Gillis N, Chen Z, Qiu J, Chittenden TW, Burt JM, Schwartz MA, Hirschi KK. Shear-induced Notch-Cx37-p27 axis arrests endothelial cell cycle to enable arterial specification. Nature Communications 2017, 8: 2149. PMID: 29247167, PMCID: PMC5732288, DOI: 10.1038/s41467-017-01742-7.Peer-Reviewed Original ResearchConceptsEndothelial cell cycle arrestArterial gene expressionCell cycle arrestArterial specificationGene expressionCycle arrestArterial-venous specificationCell cycle inhibitor CDKN1BEndothelial cell cycleCell cycle inhibitionEmbryonic developmentBlood vessel formationP27 axisFunctional vascular networkCell cycleGrowth controlSpecialized phenotypeFluid shear stressCycle inhibitionVessel formationGrowth inhibitionTissue repairMechanochemical pathwayEndothelial cellsVascular regeneration
2016
Syndecan 4 controls lymphatic vasculature remodeling during mouse embryonic development
Wang Y, Baeyens N, Corti F, Tanaka K, Fang JS, Zhang J, Jin Y, Coon B, Hirschi KK, Schwartz MA, Simons M. Syndecan 4 controls lymphatic vasculature remodeling during mouse embryonic development. Development 2016, 143: 4441-4451. PMID: 27789626, PMCID: PMC5201046, DOI: 10.1242/dev.140129.Peer-Reviewed Original ResearchConceptsLymphatic endothelial cellsPlanar cell polarity protein Vangl2Lymphatic vessel remodelingMouse embryonic developmentHuman lymphatic endothelial cellsVangl2 overexpressionVangl2 expressionEmbryonic developmentValve morphogenesisEndothelial cellsVasculature developmentSyndecan-4Lymphatic vasculatureFluid shear stressSDC4Double knockout miceMice resultsHigh expressionVessel remodelingLymphatic vesselsExpressionVangl2RemodelingCellsMorphogenesis
2015
KLF4 is a key determinant in the development and progression of cerebral cavernous malformations
Cuttano R, Rudini N, Bravi L, Corada M, Giampietro C, Papa E, Morini MF, Maddaluno L, Baeyens N, Adams RH, Jain MK, Owens GK, Schwartz M, Lampugnani MG, Dejana E. KLF4 is a key determinant in the development and progression of cerebral cavernous malformations. EMBO Molecular Medicine 2015, 8: 6-24. PMID: 26612856, PMCID: PMC4718159, DOI: 10.15252/emmm.201505433.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBone Morphogenetic Protein 6Cell ProliferationDisease Models, AnimalDisease ProgressionEndothelial CellsHEK293 CellsHemangioma, Cavernous, Central Nervous SystemHumansKRIT1 ProteinKruppel-Like Factor 4Kruppel-Like Transcription FactorsMiceMice, Inbred C57BLMice, KnockoutMicrotubule-Associated ProteinsMitogen-Activated Protein Kinase 7MutationProto-Oncogene ProteinsRNA InterferenceSignal TransductionSmad1 ProteinTransforming Growth Factor betaConceptsKruppel-like factor 4Cerebral cavernous malformationsEndothelial cellsCavernous malformationsFamilial cerebral cavernous malformationsCentral nervous systemDouble knockout miceGrowth factor-beta/bone morphogenetic protein signalingCerebral hemorrhageMouse mortalityPharmacological treatmentCurrent therapiesVascular malformationsKnockout miceTherapeutic targetNervous systemMesenchymal transitionKLF4 transcriptional activityMalformationsCCM3 genesFactor 4Function mutationsEndMTMorphogenetic protein signalingBone morphogenetic protein (BMP) signalingIntramembrane binding of VE-cadherin to VEGFR2 and VEGFR3 assembles the endothelial mechanosensory complex
Coon BG, Baeyens N, Han J, Budatha M, Ross TD, Fang JS, Yun S, Thomas JL, Schwartz MA. Intramembrane binding of VE-cadherin to VEGFR2 and VEGFR3 assembles the endothelial mechanosensory complex. Journal Of Cell Biology 2015, 208: 975-986. PMID: 25800053, PMCID: PMC4384728, DOI: 10.1083/jcb.201408103.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigens, CDCadherinsCell MovementCells, CulturedEndothelium, VascularHEK293 CellsHuman Umbilical Vein Endothelial CellsHumansMechanotransduction, CellularMiceMice, Inbred C57BLNeovascularization, PhysiologicPlaque, AtheroscleroticPlatelet Endothelial Cell Adhesion Molecule-1Protein Structure, TertiaryRNA InterferenceRNA, Small InterferingStress, MechanicalStress, PhysiologicalVascular Endothelial Growth Factor Receptor-2Vascular Endothelial Growth Factor Receptor-3ZO-1 controls endothelial adherens junctions, cell–cell tension, angiogenesis, and barrier formation
Tornavaca O, Chia M, Dufton N, Almagro LO, Conway DE, Randi AM, Schwartz MA, Matter K, Balda MS. ZO-1 controls endothelial adherens junctions, cell–cell tension, angiogenesis, and barrier formation. Journal Of Cell Biology 2015, 208: 821-838. PMID: 25753039, PMCID: PMC4362456, DOI: 10.1083/jcb.201404140.Peer-Reviewed Original ResearchMeSH KeywordsActomyosinAdherens JunctionsAnimalsAntigens, CDCadherinsCapillary PermeabilityCell Adhesion MoleculesCell MovementCells, CulturedClaudin-5Cytoskeletal ProteinsCytoskeletonEndothelial CellsHumansMechanotransduction, CellularMice, Inbred C57BLMyosinsNeovascularization, PhysiologicProtein TransportReceptors, Cell SurfaceTight JunctionsZonula Occludens-1 ProteinConceptsCell-cell tensionAdherens junctionsActive myosin IIZO-1VE-cadherinBarrier formationEndothelial adherens junctionsJunctional recruitmentPrimary endothelial cellsCadherin complexActomyosin organizationCentral regulatorStress fibersInhibition of ROCKMyosin IIProtein ZO-1Tight junction protein ZO-1Cell migrationIntercellular junctionsP114RhoGEFMechanotransducersTight junctionsEndothelial junctionsEndothelial cellsTight junction disruption
2014
Syndecan 4 is required for endothelial alignment in flow and atheroprotective signaling
Baeyens N, Mulligan-Kehoe MJ, Corti F, Simon DD, Ross TD, Rhodes JM, Wang TZ, Mejean CO, Simons M, Humphrey J, Schwartz MA. Syndecan 4 is required for endothelial alignment in flow and atheroprotective signaling. Proceedings Of The National Academy Of Sciences Of The United States Of America 2014, 111: 17308-17313. PMID: 25404299, PMCID: PMC4260558, DOI: 10.1073/pnas.1413725111.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAtherosclerosisBlotting, WesternCells, CulturedEndothelial CellsFemaleHuman Umbilical Vein Endothelial CellsHumansKruppel-Like Factor 4Kruppel-Like Transcription FactorsMaleMice, Inbred C57BLMice, KnockoutMicroscopy, ConfocalNF-kappa BReverse Transcriptase Polymerase Chain ReactionRNA InterferenceSignal TransductionStress, MechanicalSyndecan-4Vascular Endothelial Growth Factor Receptor-2ConceptsHuman umbilical vein endothelial cellsNF-κBProinflammatory NF-κBAtherosclerotic plaque burdenKruppel-like factor 2Umbilical vein endothelial cellsVEGF receptor 2Appearance of plaquesVein endothelial cellsHypercholesterolemic micePlaque burdenAntiinflammatory pathwayThoracic aortaReceptor 2Endothelial cellsEndothelial alignmentFlow correlatesCausal roleAtherosclerosisFactor 2MiceCyclic stretchLocalization correlatesActivationSyndecan-4Chemokine-coupled β2 integrin–induced macrophage Rac2–Myosin IIA interaction regulates VEGF-A mRNA stability and arteriogenesis
Morrison AR, Yarovinsky TO, Young BD, Moraes F, Ross TD, Ceneri N, Zhang J, Zhuang ZW, Sinusas AJ, Pardi R, Schwartz MA, Simons M, Bender JR. Chemokine-coupled β2 integrin–induced macrophage Rac2–Myosin IIA interaction regulates VEGF-A mRNA stability and arteriogenesis. Journal Of Experimental Medicine 2014, 211: 1957-1968. PMID: 25180062, PMCID: PMC4172219, DOI: 10.1084/jem.20132130.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsArteriesCD18 AntigensDNA PrimersFlow CytometryHumansMiceMice, Inbred C57BLMonocytesNeovascularization, PhysiologicNonmuscle Myosin Type IIARac GTP-Binding ProteinsReal-Time Polymerase Chain ReactionReceptors, CCR2RNA StabilityVascular Endothelial Growth Factor AX-Ray MicrotomographyConceptsMyosin IIASignal transduction eventsHuR translocationRapid nuclearTransduction eventsProteomic analysisProtein HuR.Induction of arteriogenesisMRNA stabilityMRNA stabilizationNovel roleCytosolic translocationMyosin-9ICAM-1 adhesionReceptor engagementDevelopmental vasculogenesisCellular effectorsMolecular triggersTranslocationHeavy chainGrowth factorMyeloid cellsVascular endothelial growth factorKey molecular triggerCCL2 stimulation
2012
The role of p21-activated kinase in the initiation of atherosclerosis
Jhaveri K, Debnath P, Chernoff J, Sanders J, Schwartz M. The role of p21-activated kinase in the initiation of atherosclerosis. BMC Cardiovascular Disorders 2012, 12: 55. PMID: 22824149, PMCID: PMC3489605, DOI: 10.1186/1471-2261-12-55.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAorta, ThoracicAortic DiseasesAtherosclerosisBiomechanical PhenomenaCells, CulturedDisease Models, AnimalEndothelial CellsFibronectinsGalectin 3ImmunohistochemistryInflammation MediatorsIntercellular Adhesion Molecule-1MaleMiceMice, Inbred C57BLMice, KnockoutP21-Activated KinasesRegional Blood FlowTranscription Factor RelBVascular Cell Adhesion Molecule-1ConceptsLesser curvatureNF-κB subunitsInflammatory activationEndothelial cellsAtherosclerosis-prone sitesPro-inflammatory functionsInflammatory marker expressionNormal chow dietArch of aortaInitiation of atherosclerosisInflammatory markersOverall inflammationChow dietInflammatory pathwaysYoung miceAtherosclerosis-susceptible regionsConclusionThese dataICAM-1VCAM-1NF-κBRelA NF-κB subunitMarker expressionLow levelsFibronectin depositionInflammation
2010
Atheroprone Hemodynamics Regulate Fibronectin Deposition to Create Positive Feedback That Sustains Endothelial Inflammation
Feaver RE, Gelfand BD, Wang C, Schwartz MA, Blackman BR. Atheroprone Hemodynamics Regulate Fibronectin Deposition to Create Positive Feedback That Sustains Endothelial Inflammation. Circulation Research 2010, 106: 1703-1711. PMID: 20378855, PMCID: PMC2891748, DOI: 10.1161/circresaha.109.216283.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAortic DiseasesApolipoproteins EAtherosclerosisCells, CulturedDisease Models, AnimalEndothelium, VascularFeedback, PhysiologicalFibronectinsHemodynamicsHumansInflammationMechanotransduction, CellularMiceMice, Inbred C57BLMice, KnockoutNF-kappa BPlatelet Endothelial Cell Adhesion Molecule-1Pulsatile FlowRegional Blood FlowRNA InterferenceStress, MechanicalTime FactorsTransfectionUp-RegulationConceptsFN depositionAtheroprone flowPECAM-1FN expressionTranscription factor NF-kappaB.Platelet endothelial cell adhesion moleculeNF-kappaB activationNF-kappaB activityAtheroprone hemodynamicsHuman endothelial cellsEndothelial inflammationProinflammatory phenotypeAortic archInduction of fibronectinCarotid arteryCell adhesion moleculeExogenous fibronectinInflammatory signalingFN accumulationNF-kappaBSustained increaseNF-kappaB.Nuclear factorTransient increaseEndothelial cellsMatrix-Specific Protein Kinase A Signaling Regulates p21-Activated Kinase Activation by Flow in Endothelial Cells
Funk SD, Yurdagul A, Green JM, Jhaveri KA, Schwartz MA, Orr AW. Matrix-Specific Protein Kinase A Signaling Regulates p21-Activated Kinase Activation by Flow in Endothelial Cells. Circulation Research 2010, 106: 1394-1403. PMID: 20224042, PMCID: PMC2862370, DOI: 10.1161/circresaha.109.210286.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAnti-Inflammatory AgentsBasement MembraneCattleCdc42 GTP-Binding ProteinCells, CulturedCyclic AMP-Dependent Protein KinasesEndothelial CellsEnzyme ActivationEnzyme ActivatorsHumansIloprostInflammationInflammation MediatorsInjections, IntraperitonealIntegrinsMaleMechanotransduction, CellularMiceMice, Inbred C57BLNF-kappa BP21-Activated KinasesPhosphorylationProtein Kinase InhibitorsPulsatile FlowRac GTP-Binding ProteinsRegional Blood FlowStress, MechanicalTime FactorsTransfectionConceptsInflammatory gene expressionNF-kappaB activationInflammatory signalingEndothelial cellsProstacyclin analogue iloprostBasement membrane proteinsBlood flow patternsPKA-dependent inhibitionInflammatory pathwaysAnalogue iloprostGene expressionKappaB activationNF-kappaB.Subendothelial extracellular matrixNuclear factorPAK activationBasement membrane
2009
The Subendothelial Extracellular Matrix Modulates JNK Activation by Flow
Hahn C, Orr AW, Sanders JM, Jhaveri KA, Schwartz MA. The Subendothelial Extracellular Matrix Modulates JNK Activation by Flow. Circulation Research 2009, 104: 995-1003. PMID: 19286608, PMCID: PMC2702158, DOI: 10.1161/circresaha.108.186486.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsApolipoproteins EAtherosclerosisBasement MembraneCattleCell Culture TechniquesCells, CulturedCollagenDisease Models, AnimalEndothelial CellsEnzyme ActivationExtracellular MatrixFibronectinsHemorheologyInflammationIntegrinsJNK Mitogen-Activated Protein KinasesMiceMice, Inbred C57BLMice, KnockoutMitogen-Activated Protein Kinase KinasesOscillometryP21-Activated KinasesPhosphorylationRegional Blood FlowStress, Mechanical
2008
Endothelial Cell PECAM-1 Promotes Atherosclerotic Lesions in Areas of Disturbed Flow in ApoE-Deficient Mice
Harry BL, Sanders JM, Feaver RE, Lansey M, Deem TL, Zarbock A, Bruce AC, Pryor AW, Gelfand BD, Blackman BR, Schwartz MA, Ley K. Endothelial Cell PECAM-1 Promotes Atherosclerotic Lesions in Areas of Disturbed Flow in ApoE-Deficient Mice. Arteriosclerosis Thrombosis And Vascular Biology 2008, 28: 2003-2008. PMID: 18688018, PMCID: PMC2651147, DOI: 10.1161/atvbaha.108.164707.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAorta, AbdominalAorta, ThoracicApolipoproteins EAtherosclerosisBone Marrow CellsBone Marrow TransplantationCells, CulturedDietary FatsDisease Models, AnimalDisease ProgressionEndothelial CellsHumansMacrophagesMiceMice, Inbred C57BLMice, KnockoutNF-kappa BPlatelet Endothelial Cell Adhesion Molecule-1Regional Blood FlowRNA InterferenceRNA, Small InterferingStress, MechanicalVascular Cell Adhesion Molecule-1ConceptsEndothelial PECAM-1PECAM-1Aortic archAbdominal aortaNF-kappaBVascular cell adhesion molecule-1 expressionCell adhesion molecule-1 expressionAdhesion molecule-1 expressionCell adhesion molecule-1ApoE-deficient miceAtherosclerotic lesion sizeBone marrow transplantationAtherosclerotic lesion formationMolecule-1 expressionVCAM-1 expressionAdhesion molecule-1Endothelial cell adhesion molecule-1NF-kappaB activityNuclear NF-kappaBDisturbed flowMarrow transplantationMacrophage infiltrationLesser curvatureWestern dietDeficient mice