2014
Erratum: CORRIGENDUM: Regeneration of Aplysia Bag Cell Neurons is Synergistically Enhanced by Substrate-Bound Hemolymph Proteins and Laminin
Hyland C, Dufresne E, Forscher P. Erratum: CORRIGENDUM: Regeneration of Aplysia Bag Cell Neurons is Synergistically Enhanced by Substrate-Bound Hemolymph Proteins and Laminin. Scientific Reports 2014, 4: 5582. PMCID: PMC4087918, DOI: 10.1038/srep05582.Peer-Reviewed Original ResearchBag cell neuronsHemolymph proteinsRespiratory protein hemocyaninAplysia bag cell neuronsProtein complexesFurther molecular characterizationAddition of hemolymphHigh molecular weight proteinsCell neuronsMolecular weight proteinsMolecular characterizationCellular targetsExtracellular matrixProteinNervous system repairNovel synergistic effectWeight proteinsLaminin substrateHumoral proteinsLamininPossible cooperationActive factorsMigration rateEndogenous factorsPotential relevanceRegeneration of Aplysia Bag Cell Neurons is Synergistically Enhanced by Substrate-Bound Hemolymph Proteins and Laminin
Hyland C, Dufresne ER, Forscher P. Regeneration of Aplysia Bag Cell Neurons is Synergistically Enhanced by Substrate-Bound Hemolymph Proteins and Laminin. Scientific Reports 2014, 4: 4617. PMID: 24722588, PMCID: PMC3983596, DOI: 10.1038/srep04617.Peer-Reviewed Original ResearchConceptsBag cell neuronsHemolymph proteinsRespiratory protein hemocyaninAplysia bag cell neuronsProtein complexesFurther molecular characterizationAddition of hemolymphHigh molecular weight proteinsCell neuronsMolecular weight proteinsMolecular characterizationCellular targetsExtracellular matrixProteinNervous system repairNovel synergistic effectWeight proteinsLaminin substrateHumoral proteinsLamininPossible cooperationActive factorsMigration rateEndogenous factorsPotential relevance
2000
Substrate–cytoskeletal coupling as a mechanism for the regulation of growth cone motility and guidance
Suter D, Forscher P. Substrate–cytoskeletal coupling as a mechanism for the regulation of growth cone motility and guidance. Developmental Neurobiology 2000, 44: 97-113. PMID: 10934315, DOI: 10.1002/1097-4695(200008)44:2<97::aid-neu2>3.0.co;2-u.Peer-Reviewed Original ResearchConceptsGrowth cone motilityCone motilityGuidance cuesGrowth conesDifferent guidance cuesDynamic cytoskeletonCell adhesion moleculeSignal transducerAxon guidanceMolecular componentsCytoskeletonMotile structuresMotility deviceAppropriate target cellsDifferent functionsRespective receptorsAdhesion moleculesProteinAxonal growthMotilityGrowth cone movementTarget cellsNeuronal processesRecent evidenceCone movement
1999
A diffusion barrier maintains distribution of membrane proteins in polarized neurons
Winckler B, Forscher P, Mellman I. A diffusion barrier maintains distribution of membrane proteins in polarized neurons. Nature 1999, 397: 698-701. PMID: 10067893, DOI: 10.1038/17806.Peer-Reviewed Original ResearchMeSH KeywordsActinsAnimalsAxonsBiological TransportCell CompartmentationCell MembraneCell PolarityCells, CulturedCytoskeletonDiffusionDimethyl SulfoxideLeukocyte L1 Antigen ComplexMembrane GlycoproteinsMembrane ProteinsMicrospheresNeural Cell Adhesion MoleculesNeuronsRatsReceptors, AMPAThy-1 AntigensConceptsMembrane proteinsDiffusion barrierObvious physical barriersPlasma membrane domainsLateral mobilityOptical tweezersCell-cell contactMembrane domainsPresumptive domainPolarized neuronsPlasma membraneCytoskeletal componentsPolarized distributionF-actinDiffusion of proteinsDistinct domainsBasolateral surfaceMembrane markersProteinSpecialized domainsInitial segmentTight junctionsAsymmetric distributionPhysical barrierTweezers
1998
An emerging link between cytoskeletal dynamics and cell adhesion molecules in growth cone guidance
Suter D, Forscher P. An emerging link between cytoskeletal dynamics and cell adhesion molecules in growth cone guidance. Current Opinion In Neurobiology 1998, 8: 106-116. PMID: 9568398, DOI: 10.1016/s0959-4388(98)80014-7.Peer-Reviewed Original ResearchConceptsGrowth cone guidanceCell adhesion moleculeCell surface receptorsAdhesion moleculesCytoskeletal dynamicsCytoskeletal networkCytoskeletal proteinsExtracellular substratesSurface receptorsConcerted actionMolecular motorsNeuronal growthImportant mechanismRecent studiesModulation of couplingProtein
1989
Calcium and polyphosphoinositide control of cytoskeletal dynamics
Forscher P. Calcium and polyphosphoinositide control of cytoskeletal dynamics. Trends In Neurosciences 1989, 12: 468-474. PMID: 2479150, DOI: 10.1016/0166-2236(89)90098-2.Peer-Reviewed Original ResearchConceptsMajor actin-binding proteinActin-binding proteinsNeuronal cell typesCytoskeletal dynamicsCytoskeletal plasticityCytoskeletal proteinsRegulatory proteinsActin polymerizationNeuronal motilityActin filamentsMembrane interactionsCell typesNeuronal cytoskeletonProteinReceptor-mediated changesPolyphosphoinositide turnoverSynaptic functionDynamic alterationsMechanochemical propertiesAxonal growthPhosphoinositide turnoverCell structureRecent evidenceTurnoverIntracellular calcium