2019
Synaptic Connectivity and Cortical Maturation Are Promoted by the ω-3 Fatty Acid Docosahexaenoic Acid
Carbone BE, Abouleish M, Watters KE, Vogel S, Ribic A, Schroeder OH, Bader BM, Biederer T. Synaptic Connectivity and Cortical Maturation Are Promoted by the ω-3 Fatty Acid Docosahexaenoic Acid. Cerebral Cortex 2019, 30: 226-240. PMID: 31034037, DOI: 10.1093/cercor/bhz083.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCells, CulturedDendritesDocosahexaenoic AcidsMice, Inbred C57BLNeural PathwaysNeuronsSynapsesVisual AcuityVisual CortexConceptsVisual acuityDietary DHASynaptic connectivityFatty Acid Docosahexaenoic AcidVivo electrophysiological recordingsSize of synapsesEarly neuronal differentiationDose-dependent mannerFatty acid DHACortical maturationYoung miceAwake miceDendritic arborsCultured neuronsDHA's roleVisual cortexFunctional maturationPostsynaptic specializationsElectrophysiological recordingsCortical processingBrain developmentDocosahexaenoic acidAcid DHAPostnatal stagesNeuronal differentiationSynapse-Selective Control of Cortical Maturation and Plasticity by Parvalbumin-Autonomous Action of SynCAM 1
Ribic A, Crair MC, Biederer T. Synapse-Selective Control of Cortical Maturation and Plasticity by Parvalbumin-Autonomous Action of SynCAM 1. Cell Reports 2019, 26: 381-393.e6. PMID: 30625321, PMCID: PMC6345548, DOI: 10.1016/j.celrep.2018.12.069.Peer-Reviewed Original ResearchConceptsCortical plasticityCell adhesion molecule-1Critical periodJuvenile-like plasticityAdhesion molecule-1Primary visual cortexVisual critical periodThalamocortical inputsCortical maturationCircuit maturationV1 plasticityParvalbumin interneuronsFeedforward inhibitionSynaptic cell adhesion molecule 1Cell-autonomous mechanismsBrief lossCortical responsesSynaptic lociMolecule-1Visual cortexSynaptic factorsInterneuronsSpecific knockdownAdulthoodEyes
2015
Topographic Mapping of the Synaptic Cleft into Adhesive Nanodomains
de Arce K, Schrod N, Metzbower SWR, Allgeyer E, Kong G, Tang AH, Krupp AJ, Stein V, Liu X, Bewersdorf J, Blanpied TA, Lucić V, Biederer T. Topographic Mapping of the Synaptic Cleft into Adhesive Nanodomains. Neuron 2015, 88: 1165-1172. PMID: 26687224, PMCID: PMC4687029, DOI: 10.1016/j.neuron.2015.11.011.Peer-Reviewed Original ResearchConceptsSynaptic cell adhesion molecule 1Trans-synaptic complexesEphB2 receptor tyrosine kinaseReceptor tyrosine kinasesCryo-ETSynaptic cleftCryoelectron tomographyTyrosine kinaseMolecular insightsSynCAM 1Macromolecular organizationImmunoglobulin proteinCell adhesion molecule-1Immunoelectron microscopyAdhesion molecule-1Super-resolution imagingPostsynaptic densityDistinct density profilesDepression paradigmExcitatory synapsesPostsynaptic areaMolecule-1Cleft edgesSynapsesCleft
2014
Activity-Dependent Regulation of Dendritic Complexity by Semaphorin 3A through Farp1
Cheadle L, Biederer T. Activity-Dependent Regulation of Dendritic Complexity by Semaphorin 3A through Farp1. Journal Of Neuroscience 2014, 34: 7999-8009. PMID: 24899721, PMCID: PMC4044256, DOI: 10.1523/jneurosci.3950-13.2014.Peer-Reviewed Original ResearchConceptsDendritic complexityTotal dendritic branch lengthActivity-dependent regulationDendritic shaftsDendritic arborizationDendritic arborsHippocampal neuronsSynaptic inputsNeuronal activityRat neuronsSemaphorin 3ANeuronal structuresSema3ADendrite differentiationNeuronsRac1 activatorDendritic morphologyComplex neuronal structuresPlexinA1Soluble cuesSignaling proteinsArborizationFARP1Coreceptor
2011
Lateral assembly of the immunoglobulin protein SynCAM 1 controls its adhesive function and instructs synapse formation
Fogel AI, Stagi M, Perez de Arce K, Biederer T. Lateral assembly of the immunoglobulin protein SynCAM 1 controls its adhesive function and instructs synapse formation. The EMBO Journal 2011, 30: 4728-4738. PMID: 21926970, PMCID: PMC3243608, DOI: 10.1038/emboj.2011.336.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell AdhesionCell Adhesion Molecule-1Cell Adhesion MoleculesCell Adhesion Molecules, NeuronalCell DifferentiationCells, CulturedChlorocebus aethiopsCoculture TechniquesCOS CellsFluorescence Resonance Energy TransferHEK293 CellsHippocampusHumansImmunoglobulinsImmunohistochemistryMiceNeuritesProtein Structure, QuaternarySynapsesConceptsSynCAM 1Specialized adhesion sitesSynapse formationTrans-synaptic interactionsSynaptic cleftCI assemblyProtein complexesSynaptic cell adhesion molecule SynCAM 1Adhesion sitesSynaptogenic activityAdhesive functionSynapse developmentStructural organizationNovel insightsSynapse inductionLateral assemblyAdhesive capacityAdhesion moleculesSynaptic morphologyAdhesive mechanismsOligomerizationAssemblyAxo-dendritic contactsCleftLater stages
2007
SynCAMs Organize Synapses through Heterophilic Adhesion
Fogel AI, Akins MR, Krupp AJ, Stagi M, Stein V, Biederer T. SynCAMs Organize Synapses through Heterophilic Adhesion. Journal Of Neuroscience 2007, 27: 12516-12530. PMID: 18003830, PMCID: PMC6673342, DOI: 10.1523/jneurosci.2739-07.2007.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell AdhesionCell Adhesion MoleculesCell Adhesion Molecules, NeuronalCell DifferentiationCell LineCells, CulturedCoculture TechniquesHippocampusHumansImmunoglobulinsMacromolecular SubstancesMiceNeural PathwaysPresynaptic TerminalsProtein IsoformsRatsRats, Sprague-DawleySynapsesSynaptic MembranesSynaptic TransmissionTumor Suppressor ProteinsConceptsAdhesion complexesDivergent expression profilesImmunoglobulin superfamily memberHeterophilic complexesProtein familyPosttranslational modificationsHeterophilic adhesionSuperfamily membersCell adhesion moleculeSynapse organizationExpression profilesSynapse developmentSynCAM 1Cell junctionsActive presynaptic terminalsPostsynaptic sideMolecular compositionAdhesion moleculesAdhesive patternsProteinSynaptic cleftPresynaptic terminalsComplexesExcitatory neurotransmissionFunctional synapses