Search results for "Neuroblast"

showing 10 items of 348 documents

Differential regulation of apoptosis-associated genes by estrogen receptor alpha in human neuroblastoma cells

2012

Purpose: The neuroendocrinology of female sex hormones is of great interest for a variety of neuropsychiatric disorders. In fact, estrogens and estrogen receptors (ERs) exert neuromodulatory and neuroprotective functions. Here we investigated potential targets of the ER subtype alpha that may mediate neuroprotection and focused on direct modulators and downstream executors of apoptosis. Methods: We employed subclones of human neuroblastoma cells (SK-N-MC) stably transfected with one of the ER subtypes, ERalpha or ERbeta. Differences between the cell lines regarding the mRNA expression levels were examined by qPCR, changes on protein levels were examined by Western Blot and immunocytochemist…

Cell SurvivalEstrogen receptorApoptosisCaspase 3BiologyNeuroprotectionRats Sprague-DawleyNeuroblastomaDevelopmental NeuroscienceCell Line TumorAnimalsEstrogen Receptor betaHumansGene silencingAdaptor Proteins Signal TransducingNeuronsCaspase 3Estrogen Receptor alphaTransfectionMolecular biologyRatsUp-RegulationDNA-Binding ProteinsProto-Oncogene Proteins c-bcl-2NeurologyCell cultureApoptosisCancer researchNeurology (clinical)Apoptosis Regulatory ProteinsEstrogen receptor alphahormones hormone substitutes and hormone antagonistsTranscription FactorsRestorative Neurology and Neuroscience
researchProduct

Cell Culture Characterization of Prooxidative Chain-Transfer Agents as Novel Cytostatic Drugs

2021

Prooxidative therapy is a well-established concept in infectiology and parasitology, in which prooxidative drugs like artemisinin and metronidazole play a pivotal clinical role. Theoretical considerations and earlier studies have indicated that prooxidative therapy might also represent a promising strategy in oncology. Here, we have investigated a novel class of prooxidative drugs, namely chain-transfer agents, as cytostatic agents in a series of human tumor cell lines in vitro. We have found that different chain-transfer agents of the lipophilic thiol class (like dodecane-1-thiol) elicited half-maximal effective concentrations in the low micromolar range in SY5Y cells (human neuroblastoma)…

Cell Survivallipophilic thiolCellular differentiationPharmaceutical ScienceOrganic chemistryfree radical chain reactionAntineoplastic AgentschemotherapyAntioxidantsArticleAnalytical Chemistryradical propagationHeLaQD241-441Coordination ComplexesNeuroblastomaDrug DiscoverymedicineTumor Cells CulturedHumansDoxorubicinSulfhydryl CompoundsPhysical and Theoretical ChemistryCytotoxicityoxidative cell deathCell Proliferationprooxidative drugbiologyChemistryHEK 293 cellslipid peroxidationbiology.organism_classificationmedicine.diseaseCytostatic Agentschain-transfer agentIn vitroChemistry (miscellaneous)Cell cultureCancer researchMolecular MedicineNitrogen OxidesDrug Screening Assays Antitumormedicine.drugrate-limiting stepMolecules
researchProduct

The Embryonic Central Nervous System Lineages ofDrosophila melanogaster

1996

In Drosophila, central nervous system (CNS) formation starts with the delamination from the neuroectoderm of about 30 neuroblasts (NBs) per hemisegment. They give rise to approximately 350 neurons and 30 glial cells during embryonic development. Understanding the mechanisms leading to cell fate specification and differentiation in the CNS requires the identification of the NB lineages. The embryonic lineages derived from 17 NBs of the ventral part of the neuroectoderm have previously been described (Bossing et al., 1996). Here we present 13 lineages derived from the dorsal part of the neuroectoderm and we assign 12 of them to identified NBs. Together, the 13 lineages comprise approximately …

Cell divisionNeuroectodermLineage (evolution)food and beveragesAnatomyCell BiologyBiologyCell fate determinationEmbryonic stem cellCell biologynervous systemNeuroblastVentral nerve cordembryonic structuresGanglion mother cellMolecular BiologyDevelopmental BiologyDevelopmental Biology
researchProduct

Subtle Changes in Clonal Dynamics Underlie the Age-Related Decline in Neurogenesis

2017

SUMMARYNeural stem cells in the adult murine brain have only a limited capacity to self-renew, and the number of neurons they generate drastically declines with age. How cellular dynamics sustain neurogenesis and how alterations with age may result in this decline, are both unresolved issues. Therefore, we clonally traced neural stem cell lineages using confetti reporters in young and middle-aged adult mice. To understand underlying mechanisms, we derived mathematical population models of adult neurogenesis that explain the observed clonal cell type abundances. Models fitting the data best consistently show self renewal of transit amplifying progenitors and rapid neuroblast cell cycle exit.…

Cell typeNeuroblastCellular differentiationNeurogenesisStem cell theory of agingStem cellBiologyProgenitor cellNeuroscienceNeural stem cell
researchProduct

Timing of identity: spatiotemporal regulation of hunchback in neuroblast lineages of Drosophila by Seven-up and Prospero.

2006

Neural stem cells often generate different cell types in a fixed birth order as a result of temporal specification of the progenitors. In Drosophila, the first temporal identity of most neural stem cells(neuroblasts) in the embryonic ventral nerve cord is specified by the transient expression of the transcription factor Hunchback. When reaching the next temporal identity, this expression is switched off in the neuroblasts by seven up (svp) in a mitosis-dependent manner, but is maintained in their progeny (ganglion mother cells). We show that svpmRNA is already expressed in the neuroblasts before this division. After mitosis, Svp protein accumulates in both cells, but the downregulation of h…

Cell typeReceptors Steroidanimal structuresTranscription GeneticMitosisNerve Tissue ProteinsNeuroblastAnimalsDrosophila ProteinsCell LineageProgenitor cellMolecular BiologyMitosisGeneticsNeuronsbiologyStem CellsfungiGene Expression Regulation DevelopmentalNuclear ProteinsProsperobiology.organism_classificationEmbryonic stem cellNeural stem cellCell biologyDNA-Binding ProteinsDrosophila melanogasterGanglion mother cellDevelopmental BiologyTranscription FactorsDevelopment (Cambridge, England)
researchProduct

The ladybird homeobox genes are essential for the specification of a subpopulation of neural cells

2004

AbstractIn Drosophila, neurons and glial cells are produced by neural precursor cells called neuroblasts (NBs), which can be individually identified. Each NB generates a characteristic cell lineage specified by a precise spatiotemporal control of gene expression within the NB and its progeny. Here we show that the homeobox genes ladybird early and ladybird late are expressed in subsets of cells deriving from neuroblasts NB 5-3 and NB 5-6 and are essential for their correct development. Our analysis revealed that ladybird in Drosophila, like their vertebrate orthologous Lbx1 genes, play an important role in cell fate specification processes. Among those cells that express ladybird are NB 5-6…

Cellular differentiationApoptosisAnimals Genetically ModifiedNeuroblastPrecursor cellGlial cellsmedicineHomeoboxAnimalsDrosophila ProteinsCell LineageMolecular BiologyBody PatterningGeneticsHomeodomain ProteinsNeuronsbiologyGene Expression Regulation DevelopmentalCell DifferentiationCell Biologybiology.organism_classificationLadybirdCell biologymedicine.anatomical_structureDrosophila melanogasternervous systemVentral nerve cordIdentity specificationHomeoboxNeurogliaDrosophilaDrosophila melanogasterCNSNeurogliaDrosophila ProteinTranscription FactorsDevelopmental BiologyDevelopmental Biology
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

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
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