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NEURONE MIGRATION

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N-CAM (nerve cell adhesion molecule) stains all neurones in all layers - non ... Staining remains until migration complete and synapses formed - then lost. ... – PowerPoint PPT presentation

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Title: NEURONE MIGRATION


1
  • NEURONE MIGRATION
  • Neurones born distant from final location must
    migrate
  • Migration lays down the layers of the laminated
    (layered) cortex
  • earliest to migrate laid down first
  • later generated neurones pass by earlier ones.
  • Ones nearest cortical surface are the last to
    have migrated.
  • Single cells migrate variable long distances - up
    to mms.
  • 3 types of migration - gliophilic neurophilic
    biphilic
  • Gliophilic - migrate along pre-fromed fibres
  • eg. radial glial fibres - bundles of elongated
    radial glia span entire thickness of cortex
    several mm
  • successive generations of neurones migrate
    OUTWARDS along same glial track to end up in
    appropriate laminar position.
    (handout Fig 1)
  • Radial glia are transient cells - once migration
    is complete, either degenerate or become
    astrocytes.

2
  • Neurophilic (Handout Fig 2)
  • some migrating neurones ignore glia and adhere
    preferentially to nearby axons. Neurones migrate
    along brain stem surface to pons - bypass radial
    glial fibres on the way, ignore them
  • Biphilic
  • Combined -- gliophilic and neurophilic
    properties
  • eg cerebellar granule cells migrate INWARDS from
    proliferative zone in external granule layer,
    just below pial surface membrane - establishes
    anatomy of cerebellum
  • (see Figs. 3 4).
  • Final division of Granule cells - in molecular
    layer - then
  • become bipolar by extending horizontal processes
    along parallel fibres of a previous granule cells
  • occurs parallel to pial surface and at right
    angles to Purkinje cell dendrites (this is the
    neurophilic part)
  • Next cell becomes tripolar
  • attaches a vertical process to the shaft of a
    Bergmann glial fibre (radial glial equivalent in
    cerebellum - not attached to both pia and
    ventricle surfaces - cell body in Purkinje layer
    is called Golgi epithelial cell) this is the
    gliophilic part.
  • Once vertical process of sufficient length
    nucleus migrates through its own process - entire
    cell body passes through interwoven mesh of
    processes in molecular layer.
  • Again many successive generations follow same
    glial fibre.

3
  • Granule cell migration creates the cellular and
    synaptic architecture of the cerebellum
  • because the horizontal and vertical segments of
    the cell are left behind after nuclear migration
    and become the parallel fibres and vertical shaft
    of the T-shaped granule cell axon This makes
    synapses with Purkinje dendrites.
  • Again anatomy reflects developmental timescale
  • the depth of parallel fibres in molecular layer
    reflects the time of differentiation.
  • Deepest - first granule cells to migrate
  • closest to pial surface - most recent
  • 2 issues
  • 1. How does the cell surface segregate the
    molecules that drive neurophilic movements of 2of
    the 3 neurites and gliophilic movements of 1of
    the 3 neurites?
  • 2. What drives the inward migration of the
    nucleus?
  • Specific cell adhesion molecules (glycoproteins)
    promote specific cell-cell attachments.
  • N-CAM (nerve cell adhesion molecule) stains all
    neurones in all layers - non specific so no
    guidance role.
  • BUT isoform NCAM - PSA (poly sialic acid) is
    distributed differentially.

4
  • Not present in proliferative zone - does stain
    both cell bodies and leading process of migrating
    neurones also stains Bergmann glial radial fibre.
    Staining remains until migration complete and
    synapses formed - then lost.
  • Antibodies to NCAM-PSA block granule cell
    migration
  • Other CAMs involved also.
  • Antibodies to Ng-CAM to cytotactin - inhibit
    migration - at different time points
  • slice cultures
  • anti NgCAM inhibits migration out of external
    granule layer - early on in process
  • d 0-1.5 effective d 1.5-3 NOT effective
  • ab cytotactin - inhibition effective later on
  • d 0-1.5 poor inhibition d 1.5 - 3 good
    inhibition.
  • So conclude
  • Early migration/contact with/binding to Bergmann
    glia requires Ng-CAM
  • later migration through molecular layer requires
    cytotactin.

5
  • Migration fails in some mutations
  • weaver mice - cerebellar granule neurones fail
    to migrate, and die in ectopic sites.
  • Is this a problem with the neuron or with glial
    cells?
  • Co-culture normal / weaver tissues in
    combinations
  • Normal neurones migrate on normal and weaver
    glia
  • weaver neurones do NOT migrate on either - fail
    to attach defective neuronal adhesion.
  • Migration also fails due to some environmental
    factors
  • In development of the cerebral cortex, groups
    of 90 cells coupled to each other by gap
    junctions in proliferative (ventricular) zone.
  • Cells from same proliferative area use same
    radial glial guide to enter cortex
  • creates developmental (ontogenetic) column of
    neurones
  • ventricular zone is a pre-parceled, mosaic map
    of proliferative units - fate map of future
    cortex (Fig.5)
  • Columnar arrangements in cortex leads to groups
    of cortical cells expressing specific marker
    molecules because of their clonal origins and
    because they used the same glial guides and were
    previously coupled by gap junctions.

6
  • 2 basic types of cortical malformations when
    migration fails
  • 1. lissencephalic
  • smooth cortex normal thickness but reduced area
  • number of ontogenetic columns is greatly reduced,
    but there are a normal number of neurones in each
  • This is due to early defects when proliferating
    units are forming in the ventricular zone - in
    humans damage during first 7 weeks of gestation
    can wipe out many proliferative units
  • 2. polymicrogyria
  • cortex is convoluted but much thinner and of
    normal area
  • numbers of ontogenetic columns are normal but
    much reduced number of neurones in each
  • Defects arise after the normal number of
    proliferative units are formed - in humans post 7
    weeks of gestation
  • This is due to defective neuron migration -
    leading to reduced numbers of neurones in each
    ontogenetic column.

7
  • Radiation of humans embryos leads to brain
    malformations
  • These are a direct result of neuronal
    proliferation / migration defects.
  • Many born with small heads and mentally retarded
    -
  • examples where exposed foetally at 2 months
    gestation and lived for 16 yr - then post mortem
  • small thin brain, much of superficial layers
    missing - migration had been compromised.
  • but also large areas where ectopic neurones have
    survived in the wrong places - in sub cortical
    areas close to ventricles (proliferative areas).
  • These have never migrated, but survived in
    ectopic sites and made incorrect synapses.
  • Experimental model - irradiation of rats
  • also results in survival of ectopic neurones
  • remarkably some from ventricular proliferative
    zones still project down spinal cord
  • these would have been part of cortico-spinal
    projections still make spinal projection - but
    not from cortex, from subcortical ventricular
    area.
  • Never migrated correctly, but some are capable of
    doing axonal elongation and projection correctly.
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