Search results for "Neural"

showing 10 items of 2783 documents

AAV vector-mediated overexpression of CB1 cannabinoid receptor in pyramidal neurons of the hippocampus protects against seizure-induced excitoxicity.

2010

The CB1 cannabinoid receptor is the most abundant G-protein coupled receptor in the brain and a key regulator of neuronal excitability. There is strong evidence that CB1 receptor on glutamatergic hippocampal neurons is beneficial to alleviate epileptiform seizures in mouse and man. Therefore, we hypothesized that experimentally increased CB1 gene dosage in principal neurons would have therapeutic effects in kainic acid (KA)-induced hippocampal pathogenesis. Here, we show that virus-mediated conditional overexpression of CB1 receptor in pyramidal and mossy cells of the hippocampus is neuroprotective and moderates convulsions in the acute KA seizure model in mice. We introduce a recombinant a…

Central Nervous SystemCannabinoid receptormedicine.medical_treatmentHippocampuslcsh:MedicineHippocampal formationHippocampuschemistry.chemical_compoundMiceReceptor Cannabinoid CB1Neurobiology of Disease and RegenerationTransgeneslcsh:ScienceNeuronsRecombination GeneticMultidisciplinaryBehavior AnimalNeuromodulationmusculoskeletal neural and ocular physiologyfood and beveragesNeurochemistryGenomicsGene TherapyDependovirusEndocannabinoid systemCell biologyFunctional GenomicsNeurologyHomeostatic MechanismsMedicinelipids (amino acids peptides and proteins)Viral VectorsNeurochemicalsGenetic EngineeringResearch ArticleBiotechnologyKainic acidGenetic VectorsGreen Fluorescent ProteinsNeurophysiologyBiologyMicrobiologyVector BiologyGlutamatergicGenomic MedicineSeizuresmedicineGeneticsAnimalsBiologyEpilepsyIntegrasesDentate gyruslcsh:RMolecular biologyMice Inbred C57BLchemistryGene Expression Regulationnervous systemGenetics of DiseaseSynapseslcsh:QCannabinoidGene FunctionMolecular NeuroscienceAnimal GeneticsTransgenicsNeuroscienceEndocannabinoidsPLoS ONE
researchProduct

Cyclin E acts under the control of Hox-genes as a cell fate determinant in the developing central nervous system.

2005

The mechanisms controlling the generation of cell diversity in the central nervous system belong to the major unsolved problems in developmental biology. The fly Drosophila melanogaster is a suitable model system to examine these mechanisms at the level of individually identifiable cells. Recently, we have provided evidence that CyclinE--largely independent of its role in cell proliferation--plays a critical role in the specification of neural stem cells (neuroblasts). CycE specifies neuronal fate within neuroblast lineages by acting upstream of glial factors (prospero and glial cell missing), whereby levels of CycE are controlled by homeotic genes, the master control genes regulating segme…

Central Nervous SystemCell fate determinationBiologyModels BiologicalNeuroblastCyclin EAnimalsHumansCell LineageHox geneMolecular BiologyGeneticsNeuronsStem CellsGenes HomeoboxGene Expression Regulation DevelopmentalCell Biologybiology.organism_classificationNeural stem cellCell biologyDrosophila melanogasterStem cellDrosophila melanogasterHomeotic geneDevelopmental biologyDevelopmental BiologyCell cycle (Georgetown, Tex.)
researchProduct

Generation of cell diversity and segmental pattern in the embryonic central nervous system of Drosophila.

2005

Development of the central nervous system (CNS) involves the transformation of a two-dimensional epithelial sheet of uniform ectodermal cells, the neuroectoderm, into a highly complex three-dimensional structure consisting of a huge variety of different neural cell types. Characteristic numbers of each cell type become arranged in reproducible spatial patterns, which is a prerequisite for the establishment of specific functional contacts. The fruitfly Drosophila is a suitable model to approach the mechanisms controlling the generation of cell diversity and pattern in the developing CNS, as it allows linking of gene function to individually identifiable cells. This review addresses aspects o…

Central Nervous SystemCell typeanimal structuresNeuroectodermCellCentral nervous systemAnatomyBiologyEmbryonic stem cellModels BiologicalNeural stem cellCell biologymedicine.anatomical_structureNeuroblastmedicineAnimalsDrosophilaNeural cellDevelopmental BiologyBody PatterningDevelopmental dynamics : an official publication of the American Association of Anatomists
researchProduct

Spatio-temporal pattern of cells expressing the clock genes period and timeless and the lineages of period expressing neurons in the embryonic CNS of…

2010

The initial steps towards the generation of cell diversity in the central nervous system of the fruitfly Drosophila melanogaster take place during early phases of embryonic development when a stereotypic population of neural progenitor cells (neuroblasts and midline precursors) is formed in a precise spatial and temporal pattern, and subsequently expresses a particular sequence of genes. The clarification of the positional, temporal and molecular features of the individual progenitor cells in the nerve cord and brain as well as of their specific types of neuronal and/or glial progeny cells forms an essential basis to understand the mechanisms controlling their development. The present study…

Central Nervous SystemEmbryo NonmammalianTimelessPeriod (gene)PopulationModels BiologicalAnimals Genetically ModifiedNeuroblastCell MovementGeneticsAnimalsDrosophila ProteinsCell LineageeducationMolecular BiologyBody PatterningGeneticsNeuronseducation.field_of_studyLife Cycle StagesbiologyGene Expression Regulation DevelopmentalPeriod Circadian Proteinsbiology.organism_classificationNeural stem cellCell biologyClone CellsCLOCKDrosophila melanogasterLarvaDrosophila melanogasterNeural developmentDevelopmental BiologyGene expression patterns : GEP
researchProduct

Impact of Ultrabithorax alternative splicing on Drosophila embryonic nervous system development.

2015

Hox genes control divergent segment identities along the anteroposterior body axis of bilateral animals by regulating a large number of processes in a cell context-specific manner. How Hox proteins achieve this functional diversity is a long-standing question in developmental biology. In this study we investigate the role of alternative splicing in functional specificity of the Drosophila Hox gene Ultrabithorax (Ubx). We focus specifically on the embryonic central nervous system (CNS) and provide a description of temporal expression patterns of three major Ubx isoforms during development of this tissue. These analyses imply distinct functions for individual isoforms in different stages of n…

Central Nervous SystemEmbryologyanimal structuresNeurogenesisGenes InsectBiologyCell fate determinationNeuroblastAnimalsDrosophila ProteinsProtein IsoformsHox geneUltrabithoraxGeneticsHomeodomain ProteinsAlternative splicingGenes HomeoboxGene Expression Regulation DevelopmentalCell biologyAlternative Splicingembryonic structuresRNA splicingDrosophilaNeural developmentDrosophila ProteinDevelopmental BiologyTranscription FactorsMechanisms of development
researchProduct

Multiple roles forHoxgenes in segment-specific shaping of CNS lineages

2008

In this article we highlight some of the recently accumulating evidence showing that Hox genes are involved at different steps during the development of neural cell lineages to control segmental patterning of the CNS. In addition to their well-known early role in establishing segmental identities, Hox genes act on neural stem cells and their progeny at various stages during embryonic and postembryonic development to control proliferation, cell fate and/or apoptosis in a segment-specific manner. This leads to differential shaping of serially homologous lineages and thus to structural diversification of segmental CNS units (neuromeres) in adaptation to their specific functional tasks in proce…

Central Nervous SystemGeneticsCellular differentiationGenes HomeoboxApoptosisCell DifferentiationBiologyCell fate determinationNeuromerebiology.organism_classificationEmbryonic stem cellNeural stem cellCell biologyDrosophila melanogasterInsect ScienceAnimalsDrosophila melanogasterHox geneNeural cellCell ProliferationFly
researchProduct

Polysialic acid is required for dopamine D2 receptor-mediated plasticity involving inhibitory circuits of the rat medial prefrontal cortex.

2011

Decreased expression of dopamine D2 receptors (D2R), dysfunction of inhibitory neurotransmission and impairments in the structure and connectivity of neurons in the medial prefrontal cortex (mPFC) are involved in the pathogenesis of schizophrenia and major depression, but the relationship between these changes remains unclear. The polysialylated form of the neural cell adhesion molecule (PSA-NCAM), a plasticity-related molecule, may serve as a link. This molecule is expressed in cortical interneurons and dopamine, via D2R, modulates its expression in parallel to that of proteins related to synapses and inhibitory neurotransmission, suggesting that D2R-targeted antipsychotics/antidepressants…

Central Nervous SystemMaleAnatomy and Physiologylcsh:MedicineRats Sprague-DawleyNeural PathwaysMolecular Cell BiologyNeurobiology of Disease and Regenerationlcsh:SciencePsychiatryMicroscopy ConfocalNeuronal PlasticityMultidisciplinaryNeuronal MorphologybiologyGlutamate Decarboxylasemusculoskeletal neural and ocular physiologyNeurotransmittersAnatomyImmunohistochemistryMental Healthmedicine.anatomical_structureNeurologyDopamine AgonistsMedicineNcamResearch Articlemedicine.drugNeural NetworksInterneuronSynaptophysinNeurophysiologyPrefrontal CortexNeuropsychiatric DisordersNeural Cell Adhesion Molecule L1NeurotransmissionNeurological SystemNeuropharmacologyDopamineDopamine receptor D2NeuroplasticityCell AdhesionNeuropilmedicineAnimalsBiologyMood DisordersReceptors Dopamine D2lcsh:RRatsNeuroanatomynervous systemCellular NeuroscienceSynapsesSchizophreniaSialic Acidsbiology.proteinNeural cell adhesion moleculelcsh:QNeuroscienceParvalbuminNeurosciencePLoS ONE
researchProduct

The evolutionary history and tissue mapping of GPR123: specific CNS expression pattern predominantly in thalamic nuclei and regions containing large …

2007

The Adhesion family of G protein-coupled receptors (GPCRs) includes 33 receptors and is the second largest GPCR family. Most of these proteins are still orphans and fairly little is known of their tissue distribution and evolutionary context. We report the evolutionary history of the Adhesion family protein GPR123 as well as mapping of GPR123 mRNA expression in mouse and rat using in situ hybridization and real-time PCR, respectively. GPR123 was found to be well conserved within the vertebrate lineage, especially within the transmembrane regions and in the distal part of the cytoplasmic tail, containing a potential PDZ binding domain. The real-time PCR data indicates that GPR123 is predomin…

Central Nervous SystemMaleModels MolecularNeuronal signal transductionPDZ domainGene ExpressionContext (language use)In situ hybridizationBiologyBiochemistryReceptors G-Protein-CoupledMiceCellular and Molecular NeuroscienceAnimalsHumansTissue DistributionRNA MessengerNeural Cell Adhesion MoleculesIn Situ HybridizationPhylogenyG protein-coupled receptorReverse Transcriptase Polymerase Chain ReactionPyramidal CellsSubiculumRatsCell biologySignal transductionSequence AlignmentNeuroscienceBinding domainJournal of Neurochemistry
researchProduct

Oligodendrogliogenic and neurogenic adult subependymal zone neural stem cells constitute distinct lineages and exhibit differential responsiveness to…

2012

The adult mouse subependymal zone (SEZ) harbours adult neural stem cells (aNSCs) that give rise to neuronal and oligodendroglial progeny. However it is not known whether the same aNSC can give rise to neuronal and oligodendroglial progeny or whether these distinct progenies constitute entirely separate lineages. Continuous live imaging and single-cell tracking of aNSCs and their progeny isolated from the mouse SEZ revealed that aNSCs exclusively generate oligodendroglia or neurons, but never both within a single lineage. Moreover, activation of canonical Wnt signalling selectively stimulated proliferation within the oligodendrogliogenic lineage, resulting in a massive increase in oligodendr…

Central Nervous SystemMaleReceptor Platelet-Derived Growth Factor alphaWnt signallingNerve Tissue ProteinsBiologyWnt3 ProteinMiceNeural Stem CellsLive cell imagingSubependymal zoneBasic Helix-Loop-Helix Transcription FactorsAnimalsCell LineageWnt Signaling PathwayCells CulturedProgenitorCell ProliferationCell CycleWnt signaling pathwayCell DifferentiationCell BiologyOligodendrocyte Transcription Factor 2Neural stem cellCell biologyMice Inbred C57BLOligodendrogliaFemaleCell DivisionNature cell biology
researchProduct

Neuroblast pattern and identity in the Drosophila tail region and role of doublesex in the survival of sex-specific precursors.

2013

The central nervous system is composed of segmental units (neuromeres), the size and complexity of which evolved in correspondence to their functional requirements. In Drosophila, neuromeres develop from populations of neural stem cells (neuroblasts) that delaminate from the early embryonic neuroectoderm in a stereotyped spatial and temporal pattern. Pattern units closely resemble the ground state and are rather invariant in thoracic (T1-T3) and anterior abdominal (A1-A7) segments of the embryonic ventral nerve cord. Here, we provide a comprehensive neuroblast map of the terminal abdominal neuromeres A8-A10, which exhibit a progressively derived character. Compared with thoracic and anterio…

Central Nervous SystemMaleanimal structuresDoublesexSerial homologyApoptosisBiologyNeuroblastNeural Stem CellsAbdomenImage Processing Computer-AssistedAnimalsDrosophila ProteinsCell LineageMolecular BiologyBody PatterningSex CharacteristicsMicroscopy ConfocalNeuroectodermAnatomyNeuromereImmunohistochemistryNeural stem cellCell biologyDNA-Binding ProteinsVentral nerve cordDrosophilaFemaleGanglion mother cellDevelopmental BiologyDevelopment (Cambridge, England)
researchProduct