Type I lissencephaly is a central nervous system (CNS) malformation characterized by mental retardation and epilepsy. These clinical features suggest a deficit in inhibitory neurons may, in part, underlie the pathogenesis of this disorder. Mutations in, or deletions of, LIS1 are the most commonly recognized genetic anomaly associated with type I lissencephaly. The pathogenesis of type I lissencephaly is believed to be a defect in radial neuronal migration, a process requiring LIS1. In contrast the inhibitory neurons migrate non-radially from the basal forebrain to the neocortex and hippocampus. Given that Lis1 is expressed in all neurons, we hypothesized that Lis1 also functions in non-radial migrating inhibitory neurons. To test this hypothesis we used a combination of in vivo and in vitro studies with Lis1 mutant mice and found non-radial cell migration is also affected. Our data indicate Lis1 is required for normal non-radial neural migration and that the Lis1 requirement is primarily cell autonomous, although a small cell non-autonomous effect could not be excluded. These data indicate inhibitory neuron migration is slowed but not absent, similar to that found for radial cell migration. We propose that the defect in non-radial cell migration is likely to contribute to the clinical phenotype observed in individuals with a LIS1 mutation.
In the developing brain, differentiation of neural precursors into neurons or glial cells occurs in response to neurotrophic factors acting on the cell surface. Intracellular signaling mechanisms that relay information to initiate differentiative responses of neural precursor cells are poorly understood. To investigate whether stimulation of the cAMP-dependent signaling pathway participates in differentiative responses of cells in the developing CNS, we performed experiments using both conditionally immortalized neural precursor cells (RC2.E10 cells) and primary cultures of cells from developing rat cortex. Initially, we determined that RC2.E10 cells retain phenotypic features of neural precursors after inactivation of the immortalizing oncogene, a temperature-sensitive mutant of the simian virus 40 large-T antigen (SV40T). We found that, once SV40T is inactivated, RC2.E10 cells cease to divide and die. However, RC2.E10 cells can proliferate in the presence of basic fibroblast growth factor.In addition, they express nestin, a marker of neural precursor cells. Both RC2.E10 cells and primary cortical precursor cells undergo astroglial differentiation in response to cAMP stimulation by treatment with 8-bromo-cAMP. In both cases, cAMPinduced astrocyte differentiation is characterized by morphological changes, stimulation of glial fibrillary acidic protein expression, downregulation of nestin expression, and decreased proliferation. No increases in the expression of neuronal or oligodendrocytic markers were observed. Our results support the notion that the developing CNS contains neural precursor cells with the capacity of undergoing astrocyte differentiation in response to increased intracellular cAMP concentrations.
Mammalian forebrain development requires extensive cell migration for cells to reach their appropriate location in the adult brain. Defects in this migration result in human malformations and neurologic deficits. Thus, understanding the mechanisms underlying normal cell migration during development is essential to understanding the pathogenesis of human malformations. Radial glia are known to support radial cell migration, while axons have been proposed as substrate for some non-radially migrating cells. Herein we have directly tested the hypothesis that axons can support non-radial cell migration. One population of cells known to migrate non-radially is the inhibitory interneurons that move from the ganglionic eminence to the cerebral cortex. We first show that early born GABAergic cells colocalize with TAG-1-positive (TAG-1+) axons, while later born cells colocalize with intermediate weight neurofilament-positive, TAG-1-negative (TAG-1-) processes, suggesting temporal differences in substrate specificities. We next developed an in vitro assay that allows us to observe cell migration on axons in culture. Using this assay we find that early born medial ganglionic eminence-derived interneurons migrate preferentially on TAG-1+ axons, while later born cells only migrate on neurofilament-positive/TAG-1- processes. These data provide the first direct evidence that ganglionic eminence cells migrate on axons and that there is an age-dependent substrate preference. Furthermore, the assay developed and characterized herein provides a robust method to further study the molecular substrates and guidance cues of axonophilic cell migration in neural development.
Cell migration is an integral process in neural development. Analyses of radial cell migration (RCM) have revealed three modes of migration and specific defects in migration in various mouse mutants. In contrast, the dynamics of non-radial cell migration (NRCM) are incompletely understood. To investigate the dynamics of NRCM, we utilized a slice culture assay coupled with time-lapse videomicroscopy. This analysis revealed that non-radially migrating cells have a complex pattern of extending and retracting one or multiple processes while the nucleus advances concurrently or independently. These data indicate that the process of interneuron migration is unique to that seen for any mode of RCM. Non-radially migrating neurons moved for an average of 0.85 microm/min and paused for approximately 14% of the time observed. Given the novel morphology of NRCM, we hypothesized that specific aspects of migration would be defective with mutations in known cell migration genes, as described for RCM. This was tested by examining the dynamics of migration in the Lis1 mutant mouse; a well-defined cell migration mutant with known defects in NRCM. In contrast to wild-type cells, the rate of nuclear movement was significantly reduced in Lis1+/- interneurons, whereas the rate of active leading edge movement was similar. Morphologically, the leading process was significantly longer and the number of branches reduced in Lis1+/- mice. Together, these data indicate that the NRCM defect in Lis1+/- mice affects specific cellular processes. These data provide insight into NRCM and practical methods for future studies on the role(s) of specific genes in interneuron migration.
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