2017
Human induced pluripotent stem cells for modelling neurodevelopmental disorders
Ardhanareeswaran K, Mariani J, Coppola G, Abyzov A, Vaccarino FM. Human induced pluripotent stem cells for modelling neurodevelopmental disorders. Nature Reviews Neurology 2017, 13: 265-278. PMID: 28418023, PMCID: PMC5782822, DOI: 10.1038/nrneurol.2017.45.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsEmbryonic stem cellsNeurodevelopmental disordersPluripotent stem cellsBrain developmentStem cellsAbnormal brain developmentBrain cell typesDopaminergic neuronsCortical neuronsUnique genetic signatureEarly developmentKey PointsHumanHiPSC modelsSomatic cellsDisordersGenetic signaturesGenetic studiesAltered trajectoryCell typesAdult cellsNeuronsUnknown facetsCellsDrug discoveryHiPSCs
2012
Modeling human cortical development in vitro using induced pluripotent stem cells
Mariani J, Simonini MV, Palejev D, Tomasini L, Coppola G, Szekely AM, Horvath TL, Vaccarino FM. Modeling human cortical development in vitro using induced pluripotent stem cells. Proceedings Of The National Academy Of Sciences Of The United States Of America 2012, 109: 12770-12775. PMID: 22761314, PMCID: PMC3411972, DOI: 10.1073/pnas.1202944109.Peer-Reviewed Original ResearchConceptsHuman brain developmentHuman induced pluripotent stem cellsLayer-specific cortical neuronsBrain developmentHuman cerebral cortexHuman cortical developmentStem cellsPluripotent stem cellsCerebral cortexCortical neuronsCortical developmentCNS regionsRadial gliaCortical wallDorsal telencephalonEmbryonic telencephalonGene expression profilesInduced pluripotent stem cellsIntermediate progenitorsTelencephalic developmentTelencephalonExpression profilesTranscriptional programsCellsGliaLearning and Memory Depend on Fibroblast Growth Factor Receptor 2 Functioning in Hippocampus
Stevens HE, Jiang GY, Schwartz ML, Vaccarino FM. Learning and Memory Depend on Fibroblast Growth Factor Receptor 2 Functioning in Hippocampus. Biological Psychiatry 2012, 71: 1090-1098. PMID: 22541947, PMCID: PMC3371339, DOI: 10.1016/j.biopsych.2012.03.013.Peer-Reviewed Original ResearchConceptsFGF receptor 2Fibroblast growth factorDentate gyrusReceptor 2Embryonic knockoutWater maze probe trialGrowth factor receptor 2Reference memoryFactor receptor 2Spatial reference memoryNeural stem cellsFibroblast growth factor receptor 2Immature neuronsCortical neuronsHippocampal volumeInducible knockout miceParvalbumin interneuronsShort-term learningGranule cellsKnockout miceSeparate cellular componentsHippocampusLong-term reference memoryAdult spatial memoryGrowth factor
2010
Fgfr2 Is Required for the Development of the Medial Prefrontal Cortex and Its Connections with Limbic Circuits
Stevens HE, Smith KM, Maragnoli ME, Fagel D, Borok E, Shanabrough M, Horvath TL, Vaccarino FM. Fgfr2 Is Required for the Development of the Medial Prefrontal Cortex and Its Connections with Limbic Circuits. Journal Of Neuroscience 2010, 30: 5590-5602. PMID: 20410112, PMCID: PMC2868832, DOI: 10.1523/jneurosci.5837-09.2010.Peer-Reviewed Original ResearchConceptsMedial prefrontal cortexCerebral cortexFibroblast growth factor receptorCKO miceExcitatory neuronsPrefrontal cortexCortical neuron developmentEntire cerebral cortexRadial glial cellsSpecific fibroblast growth factor receptorsGrowth factor receptorGABAergic neuronsLimbic circuitsCortical neuronsGlial cellsSubcortical stationsBed nucleusCortical developmentLimbic systemStria terminalisSynaptic terminalsSecondary decreaseNeuronal precursorsVentricular zoneNeuron development
2009
Fgfr1 Is Required for Cortical Regeneration and Repair after Perinatal Hypoxia
Fagel DM, Ganat Y, Cheng E, Silbereis J, Ohkubo Y, Ment LR, Vaccarino FM. Fgfr1 Is Required for Cortical Regeneration and Repair after Perinatal Hypoxia. Journal Of Neuroscience 2009, 29: 1202-1211. PMID: 19176828, PMCID: PMC2768410, DOI: 10.1523/jneurosci.4516-08.2009.Peer-Reviewed Original ResearchMeSH KeywordsAge FactorsAnalysis of VarianceAnimalsAnimals, NewbornBromodeoxyuridineCell ProliferationCerebral CortexCreatinineDNA-Binding ProteinsGlial Fibrillary Acidic ProteinHypoxiaMiceMice, Inbred C57BLMice, TransgenicNerve RegenerationNeurogenesisNeuronsOlfactory BulbParvalbuminsPhosphopyruvate HydrataseReceptor, Fibroblast Growth Factor, Type 1T-Box Domain ProteinsConceptsWild-type miceCortical neuronsOlfactory bulbSubventricular zoneChronic postnatal hypoxiaNeonatal hypoxic injuryPersistent behavioral deficitsExcitatory cortical neuronsSVZ cell proliferationCell proliferationPostnatal day 3Receptor 1 geneNormoxic miceOB neurogenesisReactive neurogenesisPerinatal hypoxiaPostnatal hypoxiaNeuronal recoveryFibroblast growth factor receptor 1 (FGFR1) geneHypoxic miceChronic hypoxiaGABAergic interneuronsHypoxic injuryResidual deficitsCortical regeneration
2006
Cortical neurogenesis enhanced by chronic perinatal hypoxia
Fagel DM, Ganat Y, Silbereis J, Ebbitt T, Stewart W, Zhang H, Ment LR, Vaccarino FM. Cortical neurogenesis enhanced by chronic perinatal hypoxia. Experimental Neurology 2006, 199: 77-91. PMID: 15916762, DOI: 10.1016/j.expneurol.2005.04.006.Peer-Reviewed Original ResearchConceptsChronic perinatal hypoxiaCerebral cortexPerinatal hypoxiaCortical neurogenesisCessation of hypoxiaInfant mouse brainSubcortical white matterLower cortical layersMature mammalian brainPostnatal day 3Forebrain subventricular zoneBrdU-positive cellsCortical neuron numberAstroglial cell proliferationNormoxic miceNeonatal injuryNeuronal lossBrain weightCortical neuronsNew neuronsCortical volumeNeuronal markersSubventricular zoneJuvenile micePutative neuroblasts
2000
Basic Fibroblast Growth Factor (Fgf2) Is Necessary for Cell Proliferation and Neurogenesis in the Developing Cerebral Cortex
Raballo R, Rhee J, Lyn-Cook R, Leckman J, Schwartz M, Vaccarino F. Basic Fibroblast Growth Factor (Fgf2) Is Necessary for Cell Proliferation and Neurogenesis in the Developing Cerebral Cortex. Journal Of Neuroscience 2000, 20: 5012-5023. PMID: 10864959, PMCID: PMC6772267, DOI: 10.1523/jneurosci.20-13-05012.2000.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsApoptosisCell DivisionCerebral CortexChoroid PlexusEmbryonic and Fetal DevelopmentFibroblast Growth Factor 2Gene Expression Regulation, DevelopmentalGerm-Line MutationGestational AgeMiceMice, KnockoutProsencephalonReceptor Protein-Tyrosine KinasesReceptor, Fibroblast Growth Factor, Type 1Receptors, Fibroblast Growth FactorTelencephalonConceptsFgf2 knockout micePseudostratified ventricular epitheliumKnockout miceCerebral cortexCortical neuronsFrontal cerebral cortexDeep cortical layersBasic fibroblast growth factorEnd of neurogenesisCortical neuron numberNeuronal progenitor cellsNull mutant miceBasic fibroblast growth factor (bFGF) geneFibroblast growth factorDegree of apoptosisLarge neuronsBasal gangliaCortical layersFgf2 knockoutGrowth factor geneMutant miceVentricular epitheliumGermline mutationsNeuron numberNeurogenesis
1999
Changes in cerebral cortex size are governed by fibroblast growth factor during embryogenesis
Vaccarino F, Schwartz M, Raballo R, Nilsen J, Rhee J, Zhou M, Doetschman T, Coffin J, Wyland J, Hung Y. Changes in cerebral cortex size are governed by fibroblast growth factor during embryogenesis. Nature Neuroscience 1999, 2: 246-253. PMID: 10195217, DOI: 10.1038/6350.Peer-Reviewed Original ResearchConceptsPseudostratified ventricular epitheliumFibroblast growth factor-2Number of gliaAdult cerebral cortexEnd of neurogenesisCerebral cortex sizeFibroblast growth factorGrowth factor 2Cerebral cortexCerebral ventricleSingle microinjectionCortical neuronsBrdU studiesCortical progenitorsVentricular epitheliumCortex sizeGrowth factorRat embryosFGF2 geneEarly neurogenesisFGF receptorsFactor 2GliaNeurogenesisCell cycle length
1988
Subsets of GABAergic neurons in dissociated cell cultures of neonatal rat cerebral cortex show co-localization with specific modulator peptides.
Alho H, Ferrarese C, Vicini S, Vaccarino F. Subsets of GABAergic neurons in dissociated cell cultures of neonatal rat cerebral cortex show co-localization with specific modulator peptides. Brain Research 1988, 467: 193-204. PMID: 3378169, DOI: 10.1016/0165-3806(88)90023-5.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAnimals, NewbornCarrier ProteinsCells, CulturedCerebral CortexDiazepam Binding InhibitorElectrophysiologyGABA Plasma Membrane Transport ProteinsGamma-Aminobutyric AcidGlutamate DecarboxylaseMembrane ProteinsMembrane Transport ProteinsNerve Tissue ProteinsNeuronsNeuropeptidesOrganic Anion TransportersPeptide FragmentsRatsConceptsGlutamic acid decarboxylaseNeuropeptide YGABAergic propertiesCerebral cortexGAD immunoreactivityGABA-modulinNeonatal cortical neuronsPrimary culturesInhibitory synaptic currentsDouble-labeling studiesBenzodiazepine recognition sitesGABA receptor modulatorsUseful experimental modelDays of cultureNeuroregulatory peptideGABAergic neuronsGABAergic neurotransmissionSpontaneous excitatoryNeonatal ratsCortical neuronsReceptor modulatorsLower incidenceTyrosine hydroxylaseSynaptic currentsCultured neurons
1987
Subcellular Location and Neuronal Release of Diazepam Binding Inhibitor
Ferrarese C, Vaccarino F, Alho H, Mellstrom B, Costa E, Guidotti A. Subcellular Location and Neuronal Release of Diazepam Binding Inhibitor. Journal Of Neurochemistry 1987, 48: 1093-1102. PMID: 3819722, DOI: 10.1111/j.1471-4159.1987.tb05632.x.Peer-Reviewed Original ResearchConceptsDBI-like immunoreactivitySlices of hypothalamusCerebral cortical neuronsGamma-aminobutyric acid receptorsRat brain neuronsDiazepam binding inhibitorAllosteric modulatory sitesVeratridine depolarizationNeuronal releaseCerebral cortexMicroM tetrodotoxinSlices of liverPeripheral organsCNS neuronsCortical neuronsBinding of benzodiazepinesCortical astrocytesBrain neuronsNeuromodulatory substancesRat brainSynaptosomal lysatesModulatory siteMet5-enkephalinAcid receptorsNeurons