Search results for "melanogaster"

showing 10 items of 452 documents

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.)
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A critical role for Cyclin E in cell fate determination in the central nervous system of Drosophila melanogaster

2004

We have examined the process by which cell diversity is generated in neuroblast (NB) lineages in the central nervous system of Drosophila melanogaster. Thoracic NB6-4 (NB6-4t) generates both neurons and glial cells, whereas NB6-4a generates only glial cells in abdominal segments. This is attributed to an asymmetric first division of NB6-4t, localizing prospero (pros) and glial cell missing (gcm) only to the glial precursor cell, and a symmetric division of NB6-4a, where both daughter cells express pros and gcm. Here we show that the NB6-4t lineage represents the ground state, which does not require the input of any homeotic gene, whereas the NB6-4a lineage is specified by the homeotic genes…

Central Nervous SystemCyclin ELineage (genetic)Cell divisionDown-RegulationNerve Tissue ProteinsCell fate determinationNeuroblastCyclin EAnimalsDrosophila ProteinsCell LineageHomeodomain ProteinsNeuronsbiologyStem CellsNeuropeptidesGenes HomeoboxGene Expression Regulation DevelopmentalNuclear ProteinsCell DifferentiationCell BiologyCell cyclebiology.organism_classificationGanglia InvertebrateCell biologyDNA-Binding ProteinsDrosophila melanogasterTrans-ActivatorsDrosophila melanogasterHomeotic geneNeurogliaTranscription FactorsNature Cell Biology
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Comm Sorts Robo to Control Axon Guidance at the Drosophila Midline

2002

AbstractAxon growth across the Drosophila midline requires Comm to downregulate Robo, the receptor for the midline repellent Slit. We show here that comm is required in neurons, not in midline cells as previously thought, and that it is expressed specifically and transiently in commissural neurons. Comm acts as a sorting receptor for Robo, diverting it from the synthetic to the late endocytic pathway. A conserved cytoplasmic LPSY motif is required for endosomal sorting of Comm in vitro and for Comm to downregulate Robo and promote midline crossing in vivo. Axon traffic at the CNS midline is thus controlled by the intracellular trafficking of the Robo guidance receptor, which in turn depends…

Central Nervous SystemEmbryo NonmammalianEndosomeGrowth ConesMolecular Sequence DataEndocytic cycleDown-RegulationNerve Tissue ProteinsReceptors Cell SurfaceCell CommunicationEndosomesBiologyModels BiologicalFunctional LateralityGeneral Biochemistry Genetics and Molecular BiologySequence Homology Nucleic AcidEctodermmedicineAnimalsDrosophila ProteinsReceptors ImmunologicAxonTransport VesiclesReceptorSequence Homology Amino AcidBiochemistry Genetics and Molecular Biology(all)Stem CellsCell MembraneGraft SurvivalGene Expression Regulation DevelopmentalMembrane ProteinsCell DifferentiationAnatomyCommissureSlitProtein Structure TertiaryCell biologyProtein TransportDrosophila melanogastermedicine.anatomical_structureCOS CellsRoundaboutAxon guidanceStem Cell TransplantationCell
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Compartmentalization of Central Neurons inDrosophila: A New Strategy of Mosaic Analysis Reveals Localization of Presynaptic Sites to Specific Segment…

2002

Synaptogenesis in the CNS has received far less attention than the development of neuromuscular synapses, although only central synapses allow the study of neuronal postsynaptic mechanisms and display a greater variety of structural and functional features. This neglect is attributable mainly to the enormous complexity of the CNS, which makes the visualization of individual synapses on defined neuronal processes very difficult. We overcome this obstacle and demonstrate by confocal microscopy the specific arrangement of output synapses on individual neurites. These studies are performed via genetic mosaic strategies in the CNS of the fruitfly Drosophila melanogaster. First, we use targeted e…

Central Nervous SystemEmbryo NonmammalianNeuropilNeuriteCell TransplantationTransport pathwaysPresynaptic TerminalsSynaptogenesisGene ExpressionNerve Tissue ProteinsBiologylaw.inventionGenes ReporterInterneuronsConfocal microscopylawPostsynaptic potentialNeuritesAnimalsCell LineageARTICLENeuronsTransplantation ChimeraMosaicismGeneral NeuroscienceGene targetingbiology.organism_classificationCell CompartmentationTransplantationDrosophila melanogasterGene TargetingMutationSynapsesDrosophila melanogasterNeuroscienceThe Journal of Neuroscience
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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
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Tenectin, a novel extracellular matrix protein expressed during Drosophila melanogaster embryonic development

2006

1567-133X (Print) Journal Article Research Support, Non-U.S. Gov't; During Drosophila embryonic development, various morphogenetic processes require the remodeling of the extracellular matrix. In a previous study, we have identified and characterized a cDNA encoding a novel putative extracellular matrix protein named tenebrin, in the beetle Tenebrio molitor. Here, we examine the expression of the Drosophila ortholog, referred to as Tenectin (Tnc), during embryonic development. Tnc is expressed in the majority of tissues of neuroectodermic origin such as hindgut, foregut, tracheal system, anal plate, and CNS. In the CNS, the Tnc transcript is restricted to a few cells, whereas the protein is…

Central Nervous SystemEmbryo Nonmammaliananimal structuresEmbryonic DevelopmentIn situ hybridizationModels BiologicalExtracellular matrixModelsComplementary DNAGeneticsDrosophila ProteinsAnimalsDevelopmentalMolecular BiologyRegulation of gene expressionExtracellular Matrix ProteinsDrosophila Proteins/*metabolismNonmammalianbiologyExtracellular Matrix Proteins/*metabolismEmbryogenesisGene Expression Regulation DevelopmentalHindgutForegutGastrulabiology.organism_classificationmusculoskeletal systemBiologicalMolecular biologyTracheaCentral Nervous System/embryology/metabolismDrosophila melanogasterGene Expression RegulationEmbryoGastrula/metabolismembryonic structuresDrosophila melanogaster/*embryology/*metabolismDrosophila melanogasterTrachea/cytology/embryology/metabolismDevelopmental Biology
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Abdominal-A mediated repression of Cyclin E expression during cell-fate specification in the Drosophila central nervous system

2009

Homeotic/Hox genes are known to specify a given developmental pathway by regulating the expression of downstream effector genes. During embryonic CNS development of Drosophila, the Hox protein Abdominal-A (AbdA) is required for the specification of the abdominal NB6-4 lineage. It does so by down regulating the expression of the cell cycle regulator gene Dcyclin E (CycE). CycE is normally expressed in the thoracic NB6-4 lineage to give rise to mixed lineage of neurons and glia, while only glial cells are produced from the abdominal NB6-4 lineage due to the repression of CycE by AbdA. Here we investigate how AbdA represses the expression of CycE to define the abdominal fate of a single NB6-4 …

Central Nervous SystemEmbryologyTranscription GeneticRegulatorCell fate determinationBiologyAnimals Genetically ModifiedCyclin EAnimalsCell LineageTransgenesEnhancerHox genePsychological repressionIn Situ HybridizationRegulator geneHomeodomain ProteinsNeuronsGene Expression Regulation DevelopmentalCell DifferentiationCell cycleMolecular biologyCell biologyDrosophila melanogasterHomeotic geneNeurogliaDevelopmental BiologyMechanisms of Development
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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
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Mutations in spalt cause a severe but reversible neurodegenerative phenotype in the embryonic central nervous system ofDrosophila melanogaster

2002

The gene spalt is expressed in the embryonic central nervous system of Drosophila melanogaster but its function in this tissue is still unknown. To investigate this question, we used a combination of techniques to analyse spalt mutant embryos. Electron microscopy showed that in the absence of Spalt, the central nervous system cells are separated by enlarged extracellular spaces populated by membranous material at 60% of embryonic development. Surprisingly, the central nervous system from slightly older embryos (80% of development) exhibited almost wild-type morphology. An extensive survey by laser confocal microscopy revealed that thespalt mutant central nervous system has abnormal levels o…

Central Nervous SystemHeterozygoteTime FactorsFasciclin 2Cellular differentiationCentral nervous systemLigandsCell AdhesionImage Processing Computer-AssistedIn Situ Nick-End LabelingmedicineAnimalsDrosophila ProteinsCell LineageCell adhesionMolecular BiologyCells CulturedCytoskeletonHomeodomain ProteinsNeuronsMicroscopy ConfocalMicroscopy VideobiologyCell adhesion moleculeCell DifferentiationAnatomyCadherinsbiology.organism_classificationImmunohistochemistryPhenotypeCell biologyTransplantationMicroscopy ElectronDrosophila melanogasterPhenotypemedicine.anatomical_structureMutationDrosophila melanogasterTranscription FactorsDevelopmental BiologyDevelopment
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A glial amino-acid transporter controls synapse strength and courtship in Drosophila

2008

1097-6256 (Print) Journal Article Research Support, N.I.H., Extramural Research Support, Non-U.S. Gov't; Mate choice is an evolutionarily critical decision that requires the detection of multiple sex-specific signals followed by central integration of these signals to direct appropriate behavior. The mechanisms controlling mate choice remain poorly understood. Here, we show that the glial amino-acid transporter genderblind controls whether Drosophila melanogaster males will attempt to mate with other males. Genderblind (gb) mutant males showed no alteration in heterosexual courtship or copulation, but were attracted to normally unappealing male species-specific chemosensory cues. As a resul…

Central Nervous SystemMaleNervous systemAmino Acid Transport System y+media_common.quotation_subjectNeuroscience(all)Glutamic AcidArticleAnimals Genetically ModifiedCourtshipSynapseGlutamatergicmedicineAnimalsDrosophila ProteinsRNA Small Interferingmedia_commonBehavior AnimalbiologyGeneral NeuroscienceCourtshipHomosexualitybiology.organism_classificationmedicine.anatomical_structureMate choiceMutationSynapsesGenderblindDrosophilaFemaleGlutamatergic synapseDrosophila melanogaster/dk/atira/pure/subjectarea/asjc/2800NeurogliaNeuroscience
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