Search results for "neuromere"

showing 10 items of 20 documents

Segmental Organization of Cephalic Ganglia in Arthropods

2007

Cephalic ganglia in arthropods encompass neuromeres of the supraesophageal ganglion (i.e., the brain) and the subesophageal ganglion. Whereas neuromeres of the subesophageal ganglion are clearly distinguishable, the segmental pattern of the brain is derived and less well understood. In this article, we give an overview of the current state of a long-lasting debate on the segmental organization of the arthropod head and brain, discussing embryonic morphological and molecular data, with a main focus on insects. Embryonic expression data on key developmental genes such as engrailed, orthodenticle, and Hox genes will be summarized to compare the metameric organization of the head (sub- and supr…

Central nervous systemAnatomyBiologybiology.organism_classificationNeuromereengrailedGanglionmedicine.anatomical_structureHead segmentationSupraesophageal ganglionmedicineArthropodHox geneNeuroscience
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Expression of en and wg in the embryonic head and brain of Drosophila indicates a refolded band of seven segment remnants

1992

ABSTRACT Based on the expression pattern of the segment polarity genes engrailed and wingless during the embryonic development of the larval head, we found evidence that the head of Drosophila consists of remnants of seven segments (4 pregnathal and 3 gnathal) all of which contribute cells to neuromeres in the central nervous system. Until completion of germ band retraction, the four pregnathal segment remnants and their corresponding neuromeres become arranged in an S-shape. We discuss published evidence for seven head segments and morphogenetic movements during head formation in various insects (and crustaceans).

Metamerism (biology)biologyfungiEmbryogenesisGene ExpressionGenes InsectEmbryoAnatomyNeuromerebiology.organism_classificationengrailedSegment polarity geneCrustaceaDrosophilidaeHead segmentationMorphogenesisAnimalsDrosophilaHeadMolecular BiologyDevelopmental BiologyDevelopment
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Segment polarity and DV patterning gene expression reveals segmental organization of theDrosophilabrain

2003

The insect brain is traditionally subdivided into the trito-, deuto- and protocerebrum. However, both the neuromeric status and the course of the borders between these regions are unclear. The Drosophila embryonic brain develops from the procephalic neurogenic region of the ectoderm, which gives rise to a bilaterally symmetrical array of about 100 neuronal precursor cells, called neuroblasts. Based on a detailed description of the spatiotemporal development of the entire population of embryonic brain neuroblasts, we carried out a comprehensive analysis of the expression of segment polarity genes (engrailed, wingless, hedgehog, gooseberry distal,mirror) and DV patterning genes (muscle segmen…

Models Anatomicanimal structuresBiologyNeuroblastGenes ReporterEctodermMorphogenesisAnimalsDrosophila ProteinsCompartment (development)Molecular BiologyIn Situ HybridizationBody PatterningNeuroectodermfungiGenes HomeoboxBrainGene Expression Regulation DevelopmentalAnatomyNeuromereengrailedDrosophila melanogasterSegment polarity geneembryonic structuresHomeoboxNeuroscienceGanglion mother cellDevelopmental BiologyDevelopment
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Distribution, classification, and development ofDrosophila glial cells in the late embryonic and early larval ventral nerve cord.

1994

To facilitate the investigation of glial development inDrosophila, we present a detailed description of theDrosophila glial cells in the ventral nerve cord. A GAL4 enhancer-trap screen for glial-specific expression was performed. Using UAS-lacZ and UAS-kinesin-lacZ as reporter constructs, we describe the distribution and morphology of the identified glial cells in the fully differentiated ventral nerve cord of first-instar larvae just after hatching. The three-dimensional structure of the glial network was reconstructed using a computer. Using the strains with consistent GAL4 expression during late embryogenesis, we traced back the development of the identified cells to provide a glial map …

Nerve rootEmbryogenesisCentral nervous systemAnatomyBiologyNeuromereEmbryonic stem cellCell biologyNeuroepithelial cellmedicine.anatomical_structurenervous systemVentral nerve cordGeneticsmedicineDevelopmental biologyDevelopmental BiologyRoux's archives of developmental biology : the official organ of the EDBO
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A Systematic Nomenclature for theDrosophilaVentral Nervous System

2017

AbstractThe fruit fly,Drosophila melanogaster, is an established and powerful model system for neuroscience research with wide relevance in biology and medicine. Until recently, research on theDrosophilabrain was hindered by the lack of a complete and uniform nomenclature. Recognising this problem, the Insect Brain Name Working Group produced an authoritative hierarchical nomenclature system for the adult insect brain, usingDrosophila melanogasteras the reference framework, with other taxa considered to ensure greater consistency and expandability (Ito et al., 2014). Here, we extend this nomenclature system to the sub-gnathal regions of the adultDrosophilanervous system, thus providing a sy…

Nervous system0303 health sciencesbiologymedia_common.quotation_subjectfungiAdult insectAnatomyInsectbiology.organism_classificationNeuromere3. Good health03 medical and health sciences0302 clinical medicineTaxonmedicine.anatomical_structuremedicineDrosophila melanogasterDrosophila (subgenus)NeuroscienceNomenclature030217 neurology & neurosurgery030304 developmental biologymedia_common
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A Systematic Nomenclature for the <i>Drosophila</i> Ventral Nervous System

2020

The fruit fly, Drosophila melanogaster, is an established and powerful model system for neuroscience research with wide relevance in biology and medicine. Until recently, research on the Drosophila brain was hindered by the lack of a complete and uniform nomenclature. Recognising this problem, the Insect Brain Name Working Group produced an authoritative hierarchical nomenclature system for the adult insect brain, using Drosophila melanogaster as the reference framework, with other taxa considered to ensure greater consistency and expandability (Ito et al., 2014). Here, we extend this nomenclature system to the sub-gnathal regions of the adult Drosophila nervous system, thus providing a sys…

Nervous systemConnectomicsbiologyfungiNeuromerebiology.organism_classificationmedicine.anatomical_structureTaxonmedicineNeuropilNomenclatureDrosophilaNeuroscienceNeuroanatomySSRN Electronic Journal
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The columnar gene vnd is required for tritocerebral neuromere formation during embryonic brain development of Drosophila.

2006

International audience; In Drosophila, evolutionarily conserved transcription factors are required for the specification of neural lineages along the anteroposterior and dorsoventral axes, such as Hox genes for anteroposterior and columnar genes for dorsoventral patterning. In this report, we analyse the role of the columnar patterning gene ventral nervous system defective (vnd) in embryonic brain development. Expression of vnd is observed in specific subsets of cells in all brain neuromeres. Loss-of-function analysis focussed on the tritocerebrum shows that inactivation of vnd results in regionalized axonal patterning defects, which are comparable with the brain phenotype caused by mutatio…

Nervous systemMutantApoptosis0302 clinical medicineMESH: Gene Expression Regulation DevelopmentalDrosophila ProteinsMESH: AnimalsAxonHox geneMESH: MelatoninGenetics0303 health sciencesMESH: Pineal GlandBrainGene Expression Regulation DevelopmentalMESH: Transcription FactorsNeuromerePhenotypeBiological EvolutionCell biologymedicine.anatomical_structureDrosophila melanogasterPhenotypeMESH: Photic StimulationMESH: Body PatterningMESH: MutationMESH: Drosophila ProteinsBiologyMESH: PhenotypeMESH: Drosophila melanogaster03 medical and health sciencesMESH: BrainNeuroblastMESH: EvolutionMESH: Homeodomain ProteinsmedicineAnimalsMESH: Circadian RhythmMolecular Biology030304 developmental biologyBody PatterningHomeodomain ProteinsMESH: HumansMESH: ApoptosisEmbryogenesis[SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry Molecular Biology/Molecular biologyMESH: LightMutationMESH: SerotoninMESH: Seasons030217 neurology & neurosurgeryDevelopmental BiologyTranscription Factors
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Normal Function of the mushroom body defect Gene of Drosophila Is Required for the Regulation of the Number and Proliferation of Neuroblasts

1994

In the developing central nervous system of Drosophila, proliferation follows a reproducible and well-described spatial and temporal pattern. This pattern involves a defined number and distribution of neural stem cells (neuroblasts), as well as a precisely regulated time course of division of these neuroblasts. We show that mutations in the mushroom body defect (mud) gene interfere with the regulation of this pattern in a rather specific manner. In the abdominal neuromeres a subset of neuroblasts prolongs the period of proliferation. Additional daughter cells persist into the imago. Similar defects are expressed in the anterior ventral nerve cord and in the lateral central brain region. In …

Neuronsanimal structuresCell divisionStem CellsfungiBrainCell CountCell BiologyAnatomyBiologyNeuromereNeural stem cellCell biologynervous systemNeuroblastVentral nerve cordMutationMushroom bodiesAnimalsDrosophilaStem cellMolecular BiologyGanglion mother cellCell DivisionDevelopmental BiologyDevelopmental Biology
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Neuroblast formation and patterning during early brain development in Drosophila.

2004

The Drosophila embryo provides a useful model system to study the mechanisms that lead to pattern and cell diversity in the central nervous system (CNS). The Drosophila CNS, which encompasses the brain and the ventral nerve cord, develops from a bilaterally symmetrical neuroectoderm, which gives rise to neural stem cells, called neuroblasts. The structure of the embryonic ventral nerve cord is relatively simple, consisting of a sequence of repeated segmental units (neuromeres), and the mechanisms controlling the formation and specification of the neuroblasts that form these neuromeres are quite well understood. Owing to the much higher complexity and hidden segmental organization of the bra…

Neuronsanimal structuresNeuroectodermfungiCentral nervous systemBrainProneural genesCell DifferentiationAnatomyBiologyNeuromereGeneral Biochemistry Genetics and Molecular BiologyNeural stem cellmedicine.anatomical_structureNeuroblastVentral nerve cordVertebratesmedicineAnimalsDrosophilaGanglion mother cellNeuroscienceBody PatterningBioEssays : news and reviews in molecular, cellular and developmental biology
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Molecular markers for identified neuroblasts in the developing brain of Drosophila.

2003

The Drosophila brain develops from the procephalic neurogenic region of the ectoderm. About 100 neural precursor cells (neuroblasts) delaminate from this region on either side in a reproducible spatiotemporal pattern. We provide neuroblast maps from different stages of the early embryo (stages 9, 10 and 11, when the entire population of neuroblasts has formed), in which about 40 molecular markers representing the expression patterns of 34 different genes are linked to individual neuroblasts. In particular, we present a detailed description of the spatiotemporal patterns of expression in the procephalic neuroectoderm and in the neuroblast layer of the gap genes empty spiracles, hunchback, hu…

animal structuresFasciclin 2EctodermBiologyNeuroblastmedicineMorphogenesisAnimalsDrosophila ProteinsMolecular BiologyGap geneIn Situ HybridizationGeneticsHomeodomain ProteinsNeuronsNeuroectodermfungiGenes HomeoboxBrainGene Expression Regulation DevelopmentalNuclear ProteinsNeuromereCell biologyDNA-Binding Proteinsmedicine.anatomical_structureDrosophila melanogasternervous systemembryonic structuresTrans-ActivatorsHomeotic geneGanglion mother cellBiomarkersDevelopmental BiologyDevelopment (Cambridge, England)
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