Your search keyword '"Neuron Migration"' showing total 2 results

1. Molecules and mechanisms that regulate multipolar migration in the intermediate zone.

Author

Cooper, Jonathan A.

Subjects

NEURONS, AXONS, CENTROSOMES, CELL anatomy, KARYOKINESIS

Abstract

Most neurons migrate with an elongated, "bipolar" morphology, extending a long leading process that explores the environment. However, when immature projection neurons enter the intermediate zone (IZ) of the neocortex they become "multipolar". Multipolar cells extend and retract cytoplasmic processes in different directions and move erratically--sideways, up and down. Multipolar cells extend axons while they are in the lower half of the IZ. Remarkably, the cells then resume radial migration: they reorient their centrosome and Golgi apparatus towards the pia, transform back to bipolar morphology, and commence locomotion along radial glia (RG) fibers. This reorientation implies the existence of directional signals in the IZ that are ignored during the multipolar stage but sensed after axonogenesis. In vivo genetic manipulation has implicated a variety of candidate directional signals, cell surface receptors, and signaling pathways, that may be involved in polarizing multipolar cells and stabilizing a pia-directed leading process for radial migration. Other signals are implicated in starting multipolar migration and triggering axon outgrowth. Here we review the molecules and mechanisms that regulate multipolar migration, and also discuss how multipolar migration affects the orderly arrangement of neurons in layers and columns in the developing neocortex. [ABSTRACT FROM AUTHOR]

Published

2014

2. Molecules and mechanisms that regulate multipolar migration in the intermediate zone

Author

Jonathan A. Cooper

Subjects

axonogenesis, Review Article, Axonogenesis, lcsh:RC321-571, neuron migration, 03 medical and health sciences, Cellular and Molecular Neuroscience, symbols.namesake, cortical lamination, 0302 clinical medicine, Semaphorin, medicine, Ephrin, Neuropilins, Reelin, cdc42 GTP-Binding Protein, 10. No inequality, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, 030304 developmental biology, 0303 health sciences, Neocortex, biology, mini-columns, Phospholipase C gamma, rap1 GTP-Binding Proteins, radial migration, multipolar migration, Golgi apparatus, neuron locomotion, neocortex development, medicine.anatomical_structure, Cdc42 GTP-Binding Protein, nervous system, Centrosome, Connexin 43, symbols, biology.protein, Biophysics, biological phenomena, cell phenomena, and immunity, Ephrins, Neuroscience, 030217 neurology & neurosurgery

Abstract

Most neurons migrate with an elongated, “bipolar” morphology, extending a long leading process that explores the environment. However, when immature projection neurons enter the intermediate zone of the neocortex they become “multipolar”. Multipolar cells extend and retract cytoplasmic processes in different directions and move erratically - sideways, up and down. Multipolar cells extend axons while they are in the lower half of the intermediate zone. Remarkably, the cells then resume radial migration: they reorient their centrosome and Golgi apparatus towards the pia, transform back to bipolar morphology, and commence locomotion along radial glia fibers. This reorientation implies the existence of directional signals in the intermediate zone that are ignored during the multipolar stage but sensed after axonogenesis. In vivo genetic manipulation has implicated a variety of candidate directional signals, cell surface receptors, and signaling pathways, that may be involved in polarizing multipolar cells and stabilizing a pia-directed leading process for radial migration. Other signals are implicated in starting multipolar migration and triggering axon outgrowth. Here we review the molecules and mechanisms that regulate multipolar migration, and also discuss how multipolar migration affects the orderly arrangement of neurons in layers and columns in the developing neocortex.

Published

2014