0000000000543793

AUTHOR

Elaine Cabrales

showing 2 related works from this author

Bi- and uniciliated ependymal cells define continuous floor-plate-derived tanycytic territories

2017

Multiciliated ependymal (E1) cells line the brain ventricles and are essential for brain homeostasis. We previously identified in the lateral ventricles a rare ependymal subpopulation (E2) with only two cilia and unique basal bodies. Here we show that E2 cells form a distinct biciliated epithelium extending along the ventral third into the fourth ventricle. In the third ventricle floor, apical profiles with only primary cilia define an additional uniciliated (E3) epithelium. E2 and E3 cells' ultrastructure, marker expression and basal processes indicate that they correspond to subtypes of tanycytes. Using sonic hedgehog lineage tracing, we show that the third and fourth ventricle E2 and E3 …

Male0301 basic medicineEpendymal CellScienceEpendymoglial CellsGene ExpressionGeneral Physics and AstronomyMice TransgenicS100 Calcium Binding Protein beta SubunitFourth ventricleArticleGeneral Biochemistry Genetics and Molecular BiologyNestinMice03 medical and health sciencesLateral ventriclesEpendymaGlial Fibrillary Acidic ProteinmedicineAnimalsHumansVimentinCell LineageHedgehog ProteinsCiliaSonic hedgehogAgedBrain VentricleFloor plateBrain MappingMultidisciplinaryThird ventriclebiologyQCD24 AntigenCell DifferentiationGeneral ChemistryAnatomyMiddle Aged030104 developmental biologymedicine.anatomical_structureCell Trackingbiology.proteinFemaleNerve NetEpendymaBiomarkersNature Communications
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Perineuronal Net Formation and the Critical Period for Neuronal Maturation in the Hypothalamic Arcuate Nucleus

2019

In leptin-deficient ob/ob mice, obesity and diabetes are associated with abnormal development of neurocircuits in the hypothalamic arcuate nucleus (ARC)1, a critical brain area for energy and glucose homoeostasis2,3. Because this developmental defect can be remedied by systemic leptin administration, but only if given before postnatal day 28, a critical period for leptin-dependent development of ARC neurocircuits has been proposed4. In other brain areas, critical-period closure coincides with the appearance of perineuronal nets (PNNs), extracellular matrix specializations that restrict the plasticity of neurons that they enmesh5. Here we report that in humans and rodents, subsets of neurons…

LeptinEndocrinology Diabetes and MetabolismPeriod (gene)BiologyArticleMiceArcuate nucleusPhysiology (medical)Internal MedicineAnimalsarcuate nucleusglucose homeostasisObesityNeuronsArc (protein)LeptinPerineuronal netArcuate Nucleus of Hypothalamusenergy 33 balanceCell Biologycritical periodMice Inbred C57BLnervous systemMedian eminenceNeuron maturationGABAergicNerve Netperineuronal netNeuroscienceneural plasticity
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