2014
The fate of internalized α5 integrin is regulated by matrix-capable fibronectin
Hsia HC, Nair MR, Corbett SA. The fate of internalized α5 integrin is regulated by matrix-capable fibronectin. Journal Of Surgical Research 2014, 191: 268-279. PMID: 25062814, PMCID: PMC4160403, DOI: 10.1016/j.jss.2014.05.084.Peer-Reviewed Original ResearchConceptsFibronectin matrix assemblyΑ5 integrinFibronectin matrixMatrix assemblySpecific lysine residuesMouse embryo fibroblast cellsEmbryo fibroblast cellsExtracellular spaceIntegrin turnoverCytoplasmic tailTissue-remodeling processesAbsence of fibronectinInternalized receptorsLysine residuesReceptor turnoverIntegrinsTissue remodelingUbiquitinationProtein levelsChinese hamsterFibroblast cellsFibronectin dimersWound repairRapid degradationFate
2011
The Fiber Diameter of Synthetic Bioresorbable Extracellular Matrix Influences Human Fibroblast Morphology and Fibronectin Matrix Assembly
Hsia HC, Nair MR, Mintz RC, Corbett SA. The Fiber Diameter of Synthetic Bioresorbable Extracellular Matrix Influences Human Fibroblast Morphology and Fibronectin Matrix Assembly. Plastic & Reconstructive Surgery 2011, 127: 2312-2320. PMID: 21617465, PMCID: PMC3103705, DOI: 10.1097/prs.0b013e3182139fa4.Peer-Reviewed Original ResearchConceptsFibronectin matrix assemblyMatrix assemblyActin cytoskeletal morphologyFocal adhesion complexesFocal adhesion sizeActin stress fibersCell proliferationAdhesion complexesAdhesion sizeEnvironmental cuesStress fibersCellular responsesAbility of scaffoldsCytoskeletal morphologyScaffold fiber diameterHuman dermal fibroblastsFibril formationCell functionImmunofluorescent microscopyBiological responsesMicrofiber scaffoldsFibroblast morphologyDermal fibroblastsHigher cell proliferationCells
2006
Modulation of Cell–Fibronectin Matrix Interactions during Tissue Repair
Midwood KS, Mao Y, Hsia HC, Valenick LV, Schwarzbauer JE. Modulation of Cell–Fibronectin Matrix Interactions during Tissue Repair. Journal Of Investigative Dermatology Symposium Proceedings 2006, 11: 73-78. PMID: 17069013, DOI: 10.1038/sj.jidsymp.5650005.Peer-Reviewed Original ResearchConceptsFocal adhesion kinaseExtracellular matrixAlpha 4 beta 1Fibronectin matrixActin stress fibersECM protein tenascinAlpha v beta 3Cell surface receptorsFibrin-fibronectin matrixOrganization of fibronectinAlpha 5 beta 1 integrin receptorBeta 3 integrinActin cytoskeletonBeta 1 integrin receptorsEnvironmental signalsMotile phenotypeTransmembrane proteoglycansAdhesion kinaseRho GTPaseRho signalingWound provisional matrixBeta 1Stress fibersIntegrin functionMultiple intracellular
2005
Fibronectin fragmentation promotes α4β1 integrin-mediated contraction of a fibrin–fibronectin provisional matrix
Valenick LV, Hsia HC, Schwarzbauer JE. Fibronectin fragmentation promotes α4β1 integrin-mediated contraction of a fibrin–fibronectin provisional matrix. Experimental Cell Research 2005, 309: 48-55. PMID: 15992798, DOI: 10.1016/j.yexcr.2005.05.024.Peer-Reviewed Original Research
2004
Coregulation of Fibronectin Signaling and Matrix Contraction by Tenascin-C and Syndecan-4
Midwood KS, Valenick LV, Hsia HC, Schwarzbauer JE. Coregulation of Fibronectin Signaling and Matrix Contraction by Tenascin-C and Syndecan-4. Molecular Biology Of The Cell 2004, 15: 5670-5677. PMID: 15483051, PMCID: PMC532045, DOI: 10.1091/mbc.e04-08-0759.Peer-Reviewed Original ResearchConceptsSyndecan-4 functionsSyndecan-4Actin stress fiber formationFocal adhesion kinaseMatrix contractionStress fiber formationExtracellular matrix proteinsEfficient tissue repairEffects of tenascinProvisional matrixTissue repairHeparan sulfate proteoglycanAdhesion kinaseCell spreadingSignaling pathwaysMatrix proteinsFibronectin signalingThree-dimensional fibrinExtracellular matrixFiber formationSulfate proteoglycanCell interactionsFibroblast morphologyTenascinFibroblast response