2023
Use of Ecto-Tagged Integrins to Monitor Integrin Exocytosis and Endocytosis
Huet-Calderwood C, Rivera-Molina F, Toomre D, Calderwood D. Use of Ecto-Tagged Integrins to Monitor Integrin Exocytosis and Endocytosis. Methods In Molecular Biology 2023, 2608: 17-38. PMID: 36653699, PMCID: PMC9999384, DOI: 10.1007/978-1-0716-2887-4_2.ChaptersConceptsΒ1 integrinTotal internal reflection fluorescence microscopyNormal cell adhesionIntegrin adhesion receptorsReflection fluorescence microscopyAdhesion receptorsCell adhesionEndocytosisFluorescence microscopyExocytosisIntegrinsCellsHaloTagPHluorinIntracellular labelingEctoPhotobleachingTagsReceptorsChaseFluorescentAdhesionLabelingMigration
2022
Fibroblasts secrete fibronectin under lamellipodia in a microtubule- and myosin II–dependent fashion
Huet-Calderwood C, Rivera-Molina F, Toomre D, Calderwood D. Fibroblasts secrete fibronectin under lamellipodia in a microtubule- and myosin II–dependent fashion. Journal Of Cell Biology 2022, 222: e202204100. PMID: 36416725, PMCID: PMC9699186, DOI: 10.1083/jcb.202204100.Peer-Reviewed Original ResearchConceptsFN secretionFocal adhesion dynamicsExtracellular matrixFocal adhesion formationSites of exocytosisLive-cell microscopyIntegrin-independent mannerCytoskeletal dynamicsFocal adhesionsAdhesion dynamicsRegulatory componentsMyosin IIIntact microtubulesCell polarizationCell adhesionIntegrin receptorsFN depositionLamellipodiaMicrotubulesFibronectinAdhesion formationNew adhesion formationFibroblastsII-dependent fashionCells
2020
Signalling through cerebral cavernous malformation protein networks
Su VL, Calderwood DA. Signalling through cerebral cavernous malformation protein networks. Open Biology 2020, 10: 200263. PMID: 33234067, PMCID: PMC7729028, DOI: 10.1098/rsob.200263.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBiomarkersCarrier ProteinsDisease ManagementDisease SusceptibilityGenetic Predisposition to DiseaseHemangioma, Cavernous, Central Nervous SystemHumansIntracellular SpaceMutationProtein BindingProtein Interaction Domains and MotifsProtein Interaction MappingProtein Interaction MapsProtein TransportSignal TransductionConceptsCCM proteinsCerebral cavernous malformationsCell junctionalMEKK3-MEK5Protein complexesAdaptor proteinProtein functionSubcellular localizationCytoskeletal reorganizationComplex proteinsProtein networkRhoA-ROCKMolecular basisProtein activityGene expressionFunction mutationsCell adhesionCell contractilityProteinPathwayLeaky blood vesselsCurrent knowledgeDisease pathologyCdc42Recent advancesChapter 22: Structural and signaling functions of integrins
Kadry YA, Calderwood DA. Chapter 22: Structural and signaling functions of integrins. Biochimica Et Biophysica Acta (BBA) - Biomembranes 2020, 1862: 183206. PMID: 31991120, PMCID: PMC7063833, DOI: 10.1016/j.bbamem.2020.183206.Peer-Reviewed Original ResearchConceptsFunction of integrinsAbility of integrinsTransmembrane adhesion receptorsNon-redundant functionsDifferent integrin heterodimersExtracellular matrix proteinsComplex structural rearrangementsDiverse downstreamCytoskeletal complexMetazoan lifeExtracellular environmentΒ-subunitAdhesion receptorsIntegrin heterodimersIntegrin familyMatrix proteinsCell adhesionIntegrinsStructural rearrangementsHeterodimersRecent advancesSubunitsSignalingProteinFunction
2019
The subcellular localization of type I p21-activated kinases is controlled by the disordered variable region and polybasic sequences
Sun X, Su VL, Calderwood DA. The subcellular localization of type I p21-activated kinases is controlled by the disordered variable region and polybasic sequences. Journal Of Biological Chemistry 2019, 294: 14319-14332. PMID: 31391252, PMCID: PMC6768646, DOI: 10.1074/jbc.ra119.007692.Peer-Reviewed Original ResearchConceptsCell-cell contactCell-cell junctionsPolybasic sequenceP21-activated kinaseSmall GTPases RacVariable regionsCell-cell boundariesPAK regulationDomain organizationCdc42 bindingAdhesion dynamicsCRIB domainGTPases RacSubcellular localizationTruncation mutantsKinase domainKinase effectorsCellular signalsExtensive similaritySequence regionsPAK1Cell adhesionCdc42PAKKinase
2015
PAK6 targets to cell–cell adhesions through its N-terminus in a Cdc42-dependent manner to drive epithelial colony escape
Morse EM, Sun X, Olberding JR, Ha BH, Boggon TJ, Calderwood DA. PAK6 targets to cell–cell adhesions through its N-terminus in a Cdc42-dependent manner to drive epithelial colony escape. Journal Of Cell Science 2015, 129: 380-393. PMID: 26598554, PMCID: PMC4732285, DOI: 10.1242/jcs.177493.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAntigens, CDCadherinsCdc42 GTP-Binding ProteinCell AdhesionCell Line, TumorEpithelial CellsHEK293 CellsHumansIntercellular JunctionsMolecular Sequence DataP21-Activated KinasesProtein BindingProtein Interaction Domains and MotifsProtein Sorting SignalsProtein TransportConceptsCell-cell adhesionN-terminusCdc42/Rac interactive binding (CRIB) domainSerine/threonine kinaseP21-activated kinase (PAK) familyCdc42-dependent mannerPolybasic regionThreonine kinaseCdc42 knockdownKinase familyBinding domainsKinase activityImportant regulatorCell adhesionPAK6Broader rolePAKAdhesionTargetingCdc42PAK1KinaseKnockdownRegulatorMutations
2014
Differences in binding to the ILK complex determines kindlin isoform adhesion localization and integrin activation
Huet-Calderwood C, Brahme NN, Kumar N, Stiegler AL, Raghavan S, Boggon TJ, Calderwood DA. Differences in binding to the ILK complex determines kindlin isoform adhesion localization and integrin activation. Journal Of Cell Science 2014, 127: 4308-4321. PMID: 25086068, PMCID: PMC4179494, DOI: 10.1242/jcs.155879.Peer-Reviewed Original ResearchConceptsIntegrin activationKindlin-2Kindlin-3Focal adhesion proteinsFunctional differencesIntegrin-linked kinaseILK complexAdhesion proteinsF2 subdomainMolecular basisIsoform specificityComplex bindsKindlinFA targetingActivation defectsCell adhesionActivationFALocalizesKinaseGFPSignalingILKIsoformsProteinCerebral cavernous malformation proteins at a glance
Draheim KM, Fisher OS, Boggon TJ, Calderwood DA. Cerebral cavernous malformation proteins at a glance. Journal Of Cell Science 2014, 127: 701-707. PMID: 24481819, PMCID: PMC3924200, DOI: 10.1242/jcs.138388.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsApoptosis Regulatory ProteinsCapillary PermeabilityCarrier ProteinsCentral Nervous System NeoplasmsHemangioma, Cavernous, Central Nervous SystemHumansKRIT1 ProteinMembrane ProteinsMicrotubule-Associated ProteinsNeoplasm ProteinsProto-Oncogene ProteinsRho GTP-Binding ProteinsSignal TransductionConceptsAdaptor proteinCerebral Cavernous Malformation ProteinsMulti-domain adaptor proteinBasic cellular processesProtein-protein interactionsCerebral cavernous malformationsAccompanying posterGlance articleCCM proteinsCellular processesProtein functionCellular phenotypesTrimeric complexFunction mutationsCell adhesionCell scienceProteinLeaky blood vesselsFocal neurological defectsCurrent understandingNeurological defectsCytoskeletalGenesPDCD10KRIT1
2013
ASB2α, an E3 Ubiquitin Ligase Specificity Subunit, Regulates Cell Spreading and Triggers Proteasomal Degradation of Filamins by Targeting the Filamin Calponin Homology 1 Domain*
Razinia Z, Baldassarre M, Cantelli G, Calderwood DA. ASB2α, an E3 Ubiquitin Ligase Specificity Subunit, Regulates Cell Spreading and Triggers Proteasomal Degradation of Filamins by Targeting the Filamin Calponin Homology 1 Domain*. Journal Of Biological Chemistry 2013, 288: 32093-32105. PMID: 24052262, PMCID: PMC3814802, DOI: 10.1074/jbc.m113.496604.Peer-Reviewed Original ResearchConceptsHematopoietic cell differentiationSpecificity subunitProteasomal degradationF-actin-rich structuresE3 ubiquitin ligase complexCell differentiationNormal subcellular localizationHomology 1 domainLoss of filaminUbiquitin acceptor sitesActin-binding domainCross-linking proteinsActin-binding siteLigase complexActin cytoskeletonTransmembrane proteinSubcellular localizationΑ-actinin1Transient expressionASB2αDegradation of filaminMinimal fragmentLysine residuesFilaminCell adhesion
2011
Talin and Signaling Through Integrins
Bouaouina M, Harburger DS, Calderwood DA. Talin and Signaling Through Integrins. Methods In Molecular Biology 2011, 757: 325-347. PMID: 21909921, PMCID: PMC5642996, DOI: 10.1007/978-1-61779-166-6_20.Peer-Reviewed Original ResearchConceptsCytoplasmic tailIntegrin activationIntegrin β tailsAbility of integrinsIntegrin cytoplasmic tailsShort cytoplasmic tailIntegrin adhesion receptorsBinding of talinDominant-negative constructMulticellular animalsActin cytoskeletonΒ tailExtracellular ligandsTalin domainTalinCharacterization of interactionsIntracellular signalsAdhesion receptorsCell adhesionIntegrin receptorsCultured cellsExtracellular matrixNegative constructsIntegrin subunitsIntegrins
2008
The structural basis of integrin-linked kinase–PINCH interactions
Chiswell BP, Zhang R, Murphy JW, Boggon TJ, Calderwood DA. The structural basis of integrin-linked kinase–PINCH interactions. Proceedings Of The National Academy Of Sciences Of The United States Of America 2008, 105: 20677-20682. PMID: 19074270, PMCID: PMC2634877, DOI: 10.1073/pnas.0811415106.Peer-Reviewed Original ResearchConceptsIntegrin-linked kinaseLIM1 domainGrowth factor signalingAtomic resolution descriptionILK bindingAnkyrin repeatsILK-PINCHHeterotrimeric complexZinc fingerMolecular basisMutagenesis dataStructural basisCell adhesionPoint mutationsConformational flexibilityKey interactionsParvinConvergence pointLim1DomainAnkyrinKinaseComplexesRepeatsSignalingStructural Basis of the Migfilin-Filamin Interaction and Competition with Integrin β Tails*
Lad Y, Jiang P, Ruskamo S, Harburger DS, Ylänne J, Campbell ID, Calderwood DA. Structural Basis of the Migfilin-Filamin Interaction and Competition with Integrin β Tails*. Journal Of Biological Chemistry 2008, 283: 35154-35163. PMID: 18829455, PMCID: PMC2596399, DOI: 10.1074/jbc.m802592200.Peer-Reviewed Original ResearchConceptsCell-extracellular matrix adhesion sitesHuman filaminN-terminal actin-binding domainProtein-protein interaction studiesActin cross-linking protein filaminIntegrin β tailsMatrix adhesion sitesActin-binding domainIntegrin beta tailsN-terminal portionIntegrin-cytoskeleton linkagesImmunoglobulin-like domainsIntegrin tailsΒ tailAdaptor proteinMigfilinBeta tailsProtein filaminCommon binding siteMolecular basisStructural basisAdhesion sitesCell shapeFilaminCell adhesion
2007
Forces and Bond Dynamics in Cell Adhesion
Evans EA, Calderwood DA. Forces and Bond Dynamics in Cell Adhesion. Science 2007, 316: 1148-1153. PMID: 17525329, DOI: 10.1126/science.1137592.Peer-Reviewed Original ResearchConceptsSingle-molecule force spectroscopyCell adhesionDissociation of bondsMolecular cell biologyCell signaling processesBond dynamicsForce spectroscopySurface bondingCell biologySignaling processesAdhesion receptorsLarge moleculesCell biochemistryChemical processesMolecular interactionsExtracellular matrixBondsIntracellular sitesAdhesion bondsChemical circuitryCellsBiological cellsKey nodesAdhesionSpectroscopy
2006
Reconstructing and Deconstructing Agonist-Induced Activation of Integrin αIIbβ3
Han J, Lim CJ, Watanabe N, Soriani A, Ratnikov B, Calderwood DA, Puzon-McLaughlin W, Lafuente EM, Boussiotis VA, Shattil SJ, Ginsberg MH. Reconstructing and Deconstructing Agonist-Induced Activation of Integrin αIIbβ3. Current Biology 2006, 16: 1796-1806. PMID: 16979556, DOI: 10.1016/j.cub.2006.08.035.Peer-Reviewed Original ResearchConceptsIntegrin activationIntegrin affinityIntegrin beta cytoplasmic domainsIntegrin-associated complexesAgonist stimulationBeta cytoplasmic domainsIntegrin activation pathwaysProtein kinase CalphaExtracellular matrix assemblyBinding of talinSiRNA-mediated knockdownTumor cell metastasisRap effectorMulticellular animalsPhorbol myristate acetateSynthetic geneticsCytoplasmic domainRap1 GTPaseTransmembrane alphaActivation complexCytoskeletal proteinsTalinBeta subunitIntegrin αIIbβ3Cell adhesion
2003
Talin Binding to Integrin ß Tails: A Final Common Step in Integrin Activation
Tadokoro S, Shattil SJ, Eto K, Tai V, Liddington RC, de Pereda J, Ginsberg MH, Calderwood DA. Talin Binding to Integrin ß Tails: A Final Common Step in Integrin Activation. Science 2003, 302: 103-106. PMID: 14526080, DOI: 10.1126/science.1086652.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAmino Acid SubstitutionAnimalsAntibodies, MonoclonalCell LineFibronectinsHumansIntegrin beta ChainsIntegrin beta1Integrin beta3Molecular Sequence DataMutationPlatelet Glycoprotein GPIIb-IIIa ComplexProtein BindingProtein ConformationProtein Structure, TertiaryRecombinant ProteinsRNA, Small InterferingSignal TransductionTalinTransfectionConceptsIntegrin activationCytoplasmic tailIntegrin betaCytoskeletal protein talinIntegrin extracellular domainCellular signaling cascadesIntegrin beta tailsNormal cell adhesionBinding of talinProtein talinBeta tailsSignaling cascadesIntegrin affinityConformational rearrangementsExtracellular domainFinal common stepTalinCell adhesionExtracellular matrixCommon stepSpecific bindingActivationBindingTailAffinity
2000
Integrin cytoplasmic domain-binding proteins
Liu S, Calderwood D, Ginsberg M. Integrin cytoplasmic domain-binding proteins. Journal Of Cell Science 2000, 113: 3563-3571. PMID: 11017872, DOI: 10.1242/jcs.113.20.3563.Peer-Reviewed Original ResearchConceptsDomain-binding proteinCytoplasmic domainCellular proteinsIntegrin cytoplasmic domainActin-binding proteinsMore cellular proteinsCell surface receptorsGene regulationCellular functionsTransduce signalsSignal transductionBiological functionsGene expressionFunctional analysisCell adhesionLarge familySurface receptorsProteinCytoskeletonIntegrin chainsIntegrinsBiological responsesPivotal roleMechanical linkImportant role