The rostral migratory stream (RMS) is a specialized migratory route found in the brain of some animals along which neuronal precursors that originated in the subventricular zone (SVZ) of the brain migrate to reach the main olfactory bulb (OB). The importance of the RMS lies in its ability to refine and even change an animal's sensitivity to smells, which explains its importance and larger size in the rodent brain as compared to the human brain, as our olfactory sense is not as developed. This pathway has been studied in the rodent, rabbit, and both the squirrel monkey and rhesus monkey. When the neurons reach the OB they differentiate into GABAergic interneurons as they are integrated into either the granule cell layer or periglomerular layer.
Although it was originally believed that neurons could not regenerate in the adult brain, neurogenesis has been shown to occur in mammalian brains, including those of primates. However, neurogenesis is limited to the hippocampus and SVZ, and the RMS is one mechanism neurons use to relocate from these areas.
The RMS was named and discovered by J. Altman in 1969 using 3H-thymidine autoradiography in the rat brain. He traced the migration of labeled cells from the SVZ, which is situated throughout the lateral walls of the lateral ventricles, rostrally to the main olfactory bulb. He also quantitatively studied the effect of age on the size of the RMS. There is still some ongoing debate about the extent of the RMS and adult SVZ neurogenesis of new neurons in humans.
Vascular cells are known to play a prominent role in regulating proliferation of adult neural precursors. In the adult subgranular zone (SGZ), dense clusters of dividing cells were found to be anatomically close to the vasculature, especially capillaries. Contacts between adult SVZ neuronal precursors and blood vessels are unusually permeable and frequently devoid of astrocyte and pericyte interferences, suggesting that blood-derived cues are gaining direct access to adult neural precursors and their progeny.
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The goal of the course is to guide students through the essential aspects of molecular neuroscience and neurodegenerative diseases. The student will gain the ability to dissect the molecular basis of
Students will learn essentials of cell and developmental biology with an engineering mind set, with an emphasis on animal model systems and quantitative approaches.
La neurogenèse désigne l'ensemble du processus de formation d'un neurone fonctionnel du système nerveux à partir d'une cellule souche neurale. Elle a principalement lieu lors du développement neuronal du cerveau chez l'embryon et l'enfant (« neurogenèse primaire »). Certaines structures cérébrales des mammifères continuent cependant à produire des neurones chez l'individu adulte (). Issues du neuroectoderme, provenant lui-même de l'ectoderme, ces cellules migrent pendant la formation des structures du système nerveux central (tube neural puis vésicules cérébrales primitives : prosencéphale, mésencéphale et rhombencéphale).
Les cellules souches neurales sont des cellules souches - multipotentes et capables de s'auto-renouveler - dont le potentiel de différenciation est restreint aux types cellulaires neuraux, notamment : Neurone, Astrocyte et Oligodendrocyte. Durant l'embryogenèse, ces cellules souches neurales sont situées dans la zone ventriculaire du tube neural. Elles génèrent l'ensemble des types cellulaires nécessaires au système nerveux central (à l'exception de la microglie), par un processus appelé neurogenèse.
The subgranular zone (SGZ) is a brain region in the hippocampus where adult neurogenesis occurs. The other major site of adult neurogenesis is the subventricular zone (SVZ) in the brain. The subgranular zone is a narrow layer of cells located between the granule cell layer and hilus of the dentate gyrus. This layer is characterized by several types of cells, the most prominent type being neural stem cells (NSCs) in various stages of development.
Explore le développement du cerveau, de la neurulation à la neurogenèse adulte, en mettant l'accent sur l'influence des facteurs environnementaux et l'impact potentiel sur la mémoire et la récupération du cerveau.
Explore le neurodéveloppement chez les embryons humains, de la neurulation à la neurogenèse adulte, en soulignant l'influence des facteurs environnementaux et le lien avec la dépression.
Explore la spécification des précurseurs neuraux chez les invertébrés et les vertébrés, en se concentrant sur les amas neuronaux, les neuroblastes et les précurseurs neuronaux.
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