Bagirathy Nadarajah

Two modes of radial migration in early development of the cerebral cortex.

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.

Modes of neuronal migration in the developing cerebral cortex

The conventional scheme of cortical formation shows that postmitotic neurons migrate away from the germinal ventricular zone to their positions in the developing cortex, guided by the processes of radial glial cells. However, recent studies indicate that different neuronal types adopt distinct modes of migration in the developing cortex. Here, we review evidence for two modes of radial movement: somal translocation, which is adopted by the early-generated neurons; and glia-guided locomotion, which is used predominantly by pyramidal cells. Cortical interneurons, which originate in the ventral telencephalon, use a third mode of migration. They migrate tangentially into the cortex, then seek the ventricular zone before moving radially to take up their positions in the cortical anlage.

Ventricle-directed migration in the developing cerebral cortex

It is believed that postmitotic neurons migrate away from their sites of origin in the germinal zones to populate distant targets. Contrary to this notion, we found, using time-lapse imaging of brain slices, populations of neurons positioned at various levels of the developing neocortex that migrate towards the cortical ventricular zone. After a pause in this proliferative zone, they migrate radially in the direction of the pial surface to take up positions in the cortical plate. Immunohistochemical analysis together with tracer labeling in brain slices showed that cells showing ventricle-directed migration in the developing cortex are GABAergic interneurons originating in the ganglionic eminence in the ventral telencephalon. We speculate that combinations of chemoattractant and chemorepellent molecules are involved in this ventricle-directed migration and that interneurons may seek the cortical ventricular zone to receive layer information.

Layering defect in p35 deficiency is linked to improper neuronal-glial interaction in radial migration

Several genes essential for neocortical layering have been identified in recent years, but their precise roles in this process remain to be elucidated. Mice deficient in p35—an activator of cyclin-dependent kinase 5 (Cdk5)—are characterized by a neocortex that has inverted layering. To decipher the physiological mechanisms that underlie this defect, we compared time-lapse recordings between p35−/− and wild-type cortical slices. In the p35−/− neocortex, the classic modes of radial migration—somal translocation and locomotion—were largely replaced by a distinct mode of migration: branched migration. Branched migration is cell-autonomous, associated with impaired neuronal-glial interaction and rare in neurons of scrambler mice, which are deficient in Dab1. Hence, our findings suggest that inside-out layering requires distinct functions of Reelin and p35/Cdk5 signaling, with the latter being important for proper glia-guided migration.

Radial Glial Cells: Are They Really Glia?

During the development of the cerebral cortex, radial glia serve as a scaffold to support and direct neurons during their migration. This view is now changing in the light of emerging evidence showing that these cells have a much more dynamic and diverse role. A recent series of studies has provided strong support for their role as precursor cells in the ventricular zone that generate cortical neurons and glia, in addition to providing migration guidance.

Stromal-derived factor 1 signalling regulates radial and tangential migration in the developing cerebral cortex

Stromal-derived factor 1 (SDF-1), a known chemoattractant, and its receptor CXCR4 are widely expressed in the developing and adult cerebral cortex. Recent studies have highlighted potential roles for SDF-1 during early cortical development. In view of the current findings, our histological analysis has revealed a distinct pattern of SDF-1 expression in the developing cerebral cortex at a time when cell proliferation and migration are at peak. To determine the role of chemokine signalling during early cortical development, embryonic rat brain slices were exposed to a medium containing secreted SDF-1 to perturb the endogenous levels of chemokine. Alternatively, brain slices were treated with 40 µM of T140 or AMD3100, known antagonists of CXCR4. Using these experimental approaches, we demonstrate that chemokine signalling is imperative for the maintenance of the early cortical plate. In addition, we provide evidence that both neurogenesis and radial migration are concomitantly regulated by this signalling system. Conversely, interneurons, although not dependent on SDF-1 signalling to transgress the telencephalic boundary, require the chemokine to maintain their tangential migration. Collectively, our results demonstrate that SDF-1 with its distinct pattern of expression is essential and uniquely positioned to regulate key developmental events that underlie the formation of the cerebral cortex.

Radial glia and somal translocation of radial neurons in the developing cerebral cortex.

A series of recent studies have demonstrated that radial glia are neural precursors in the developing cerebral cortex. These studies have further implied that these cells are the sole precursor constituents of the dorsal forebrain ventricular zone that generate the projection neurons of the cortex. In view of these new findings, this review discusses radial neurons, a progeny of cortical neurons that are generated by radial glia and adopt somal translocation as the mode of migration. GLIA 43:33–36, 2003.

The origin and migration of cortical neurons.

Publisher Summary The chapter discusses the origin and migration of cortical neurons. Sources of neurons destined for the cerebral cortex are discovered in the ganglionic eminence, the primordium of the basal ganglia in the ventral telencephalon lateral ventricle tend to migrate to the striatum, pallidum and neocortex, while lateral ganglionic eminence (LGE) cells migrate prodominantly into the striatum and olfactory bulb. Neurons of the ganglionic eminence destined for the developing cerebral cortex express the L&I homeobox gene Lhx6. The molecular mechanisms that guide the migration of interneurons from the ganglionic eminence, around the corticostriatal notch and into the neocortex are unknown. A number of factors have been shown to stimulate motogenic activity in neural and non-neural tissue. One of these molecules, hepatocyte growth factor/scatter factor (HGFISF) and its receptor MET have recently been shown to be important in the migration of cortical interneurons. Disruption of the normal expression of HGFiSF appears to result in undirected scattering of cells from the ganglionic eminence and in a significant reduction of interneurons in the cortex at the time of birth.

A novel method of labeling and characterizing migrating neurons in the developing central nervous system.

Neuronal migration, a discrete event in the developing nervous system, is currently being intensively investigated using a variety of anatomical and molecular approaches. Using 4-chloromethyl benzoyl amino tetramethyl rhodamine (CMTMR) coated particles, we describe here a novel and efficient method of tracer labeling to investigate cell migration in embryonic and postnatal brain. Further, we demonstrate that application of CMTMR facilitates the labeling of a large number of migrating cells and enables the characterization of their phenotypes with immunohistochemical and in situ hybridization techniques. We also illustrate that CMTMR labeling is ideally suited for time-lapse imaging of the behavior and dynamics of migrating cells.

Stromal derived factor-1 exerts differential regulation on distinct cortical cell populations in vitro

BackgroundStromal derived factor (SDF-1), an alpha chemokine, is a widely known chemoattractant in the immune system. A growing body of evidence now suggests multiple regulatory roles for SDF-1 in the developing nervous system.ResultsTo investigate the role of SDF-1 signaling in the growth and differentiation of cortical cells, we performed numerous in vitro experiments, including gene chip and quantitative RT-PCR analysis. Using SDF-1 medium and AMD3100, a receptor antagonist, we demonstrate that the chemokine signaling regulates key events during early cortical development. First, SDF-1 signaling maintains cortical progenitors in proliferation, possibly through a mechanism involving connexin 43 mediated intercellular coupling. Second, SDF-1 signaling upregulates the differentiation of cortical GABAergic neurons, independent of sonic signaling pathway. Third, SDF-1 enables the elongation and branching of axons of cortical glutamatergic neurons. Finally, cortical cultures derived from CXCR4-/- mutants show a close parallel to AMD3100 treatment with reduced cell proliferation and differentiation of GABAergic neurons.ConclusionResults from this study show that SDF-1 regulates distinct cortical cell populations in vitro.