Layer formation in the developing cerebral cortex requires the movement of neurons from their site of origin to their final laminar position. We demonstrate, using time-lapse imaging of acute cortical slices, that two distinct forms of cell movement, locomotion and somal translocation, are responsible for the radial migration of cortical neurons. These modes are distinguished by their dynamic properties and morphological features. Locomotion and translocation are not cell-type specific; although at early ages some cells may move by translocation only, locomoting cells also translocate once their leading process reaches the marginal zone. The existence of two modes of radial migration may account for the differential effects of certain genetic mutations on cortical development.
Detailed retinotopic maps of primary visual cortex (area 17) and the extrastriate visual regions surrounding it (areas 18a and 18b) have been constructed for the C57BL/6J mouse using standard electrophysiological mapping techniques. Primary visual cortex (area 17), as defined cytoarchitectonically, contains one complete representation of the contralateral visual field, termed V1, in which azimuth and elevation lines are approximately orthogonal. The upper visual field is represented caudally and the nasal field laterally. Binocular cells are encountered in the cortical representation of the nasal 30--40 degrees of the visual field, and there is an expanded representation of the nasal field. Extrastriate visual cortex of the mouse, like that of other mammals, contains multiple representations of the visual field. The cytoarchitectonic region of cortex lateral and rostral to area 17, termed area 18a, contains at least two such representations. The more medial of these, which by convention we have called V2, is a narrow strip surrounding V1 on its lateral and rostral aspects; the vertical meridian lies along a portion of its common border with V1. The visual field representation in V2 is not a mirror image of that in V1; the representation of the horizontal meridian forms the lateral border of V2, and the visual field representation is split so that adjacent points on either side of the horizontal meridian are represented in nonadjacent parts of V2. The other visual field representation within area 18a, which we have termed V3, is a small but apparently complete representation that lies lateral to V2. The visual field representations medial to area 17 correspond to cytoarchitectonic area 18b. Area 18b contains two representations of the temporal visual field that we have labeled Vm-r and Vm-c, and contains little or no representation of the most nasal aspect of the field.
The distinct axonal tracts of the mature nervous system are defined during development by sets of substrate-bound and diffusible molecular signals that promote or restrict axonal elongation. In the adult cerebral cortex, efferent and afferent axons are segregated within the white matter. To define the relationship of growing efferent and afferent axons in the developing murine cortex to chondroitin sulfate proteoglycans (CSPGs) in the pericellular and extracellular matrix, we used the fluorescent tracer Dil to determine axonal trajectories and immunolabeling to disclose the distribution of CSPGs. Axons of neurons in the preplate are the first to leave the cortex; they arise in the CSPG-rich preplate and extend obliquely across it to enter the CSPG-poor intermediate zone. Slightly later, axons of cortical plate neurons extend directly across the CSPG-rich subplate, and then turn abruptly to run in the upper intermediate zone. In contrast, once afferent axons from the thalamus reach the developing cortical wall, their intracortical trajectory is centered on the CSPG-rich subplate, above the path taken by efferent axons. Our findings demonstrate a molecular difference between the adjacent but distinct efferent and afferent pathways in developing neocortex. Early efferents cross the subplate and follow a pathway that contains very little CSPG, while afferents preferentially travel more superficially within the CSPG-rich subplate. Thus, CSPGs and associated extracellular matrix (ECM) components in the preplate/subplate do not form a barrier to axonal initiation or outgrowth in the neocortex as they may in other locations. Instead, their distribution suggests a role in defining discrete axonal pathways during early cortical development.
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