Four distinct phases of basket/stellate cell migration after entering their final destination (the molecular layer) in the developing cerebellum.

In the adult cerebellum, basket/stellate cells are scattered throughout the ML, but little is known about the process underlying the cell dispersion. To determine the allocation of stellate/basket cells within the ML, we examined their migration in the early postnatal mouse cerebellum. We found that after entering the ML, basket/stellate cells sequentially exhibit four distinct phases of migration. First, the cells migrated radially from the bottom to the top while exhibiting saltatory movement with a single leading process (Phase I). Second, the cells turned at the top and migrated tangentially in a rostro-caudal direction, with an occasional reversal of the direction of migration (Phase II). Third, the cells turned and migrated radially within the ML at a significantly reduced speed while repeatedly extending and withdrawing the leading processes (Phase III). Fourth, the cells turned at the middle and migrated tangentially at their slowest speed, while extending several dendrite-like processes after having completely withdrawn the leading process (Phase IV). Finally, the cells stopped and completed their migration. These results suggest that the dispersion of basket/stellate cells in the ML is controlled by the orchestrated activity of external guidance cues, cell-cell contact and intrinsic programs in a position- and time-dependent manner.

Autonomous turning of cerebellar granule cells in vitro by intrinsic programs.

External guidance cues play a role in controlling neuronal cell turning in the developing brain, but little is known about whether intrinsic programs are also involved in controlling the turning. In this study, we examined whether granule cells undergo autonomous changes in the direction of migration in the microexplant cultures of the early postnatal mouse cerebellum. We found that granule cells exhibit spontaneous and periodical turning without cell-cell contact and in the absence of external guidance cues. The frequency of turning was increased by stimulating the Ca(2+) influx and the internal Ca(2+) release, or inhibiting the cAMP signaling pathway, while the frequency was reduced by inhibiting the Ca(2+) influx. Granule cell turning in vitro was classified into four distinct modes, which were characterized by the morphological changes in the leading process and the trailing process, such as bifurcating, turning, withdrawing, and changing the polarity. The occurrence of the 1st and 2nd modes of turning was differentially affected by altering the Ca(2+) and cAMP signaling pathways. Collectively, the results demonstrate that intrinsic programs regulate the autonomous turning of cerebellar granule cells in vitro. Furthermore, the results suggest that extrinsic signals play a role as essential modulators of intrinsic programs.

Cerebellar granule cell migration and the effects of alcohol.

In the developing brain the majority of neurons migrate from their birthplace to their final destination. This active movement is essential for the formation of cortical layers and nuclei. The impairment of migration does not affect the viability of neurons but often results in abnormal differentiation. The proper migration of neurons requires the orchestrated activities of multiple cellular and molecular events, such as pathway selection, the activation of specific receptors and channels, and the assembly and disassembly of cytoskeletal components. The migration of neurons is very vulnerable to exposure to environmental toxins, such as alcohol. In this article, we will focus on recent developments in the migration of cerebellar granule cells. First, we will describe when, where and how granule cells migrate through different cortical layers to reach their final destination. Second, we will present how internal programs control the sequential changes in granule cell migration. Third, we will review the roles of external guidance cues and transmembrane signals in granule cell migration. Finally, we will reveal mechanisms by which alcohol exposure impairs granule cell migration.

How does alcohol impair neuronal migration?

Maternal alcohol consumption during pregnancy can cause serious birth defects, of which fetal alcohol syndrome (FAS) is the most devastating. Recognized by characteristic craniofacial abnormalities and growth deficiency, this condition produces severe alcohol-induced damage in the developing brain. FAS children experience ataxia; deficits in intellectual functioning; and difficulties in learning, memory, problem solving, and attention. Multiple aspects of central nervous system development can be affected by alcohol exposure, but the most striking abnormalities are neuronal and glial migration. Little is known about cellular mechanisms by which alcohol affects the migration of immature neurons. Recently, it has been found that Ca(2+) signaling and cyclic nucleotide signaling are the central targets of the action of alcohol in neuronal cell migration. Most importantly, the aberrant migration of immature neurons caused by alcohol exposure is significantly ameliorated by controlling the activity of these second-messenger pathways. In this Mini-Review, we first describe how alcohol exposure impairs the migration of cerebellar granule cells and then discuss the signaling mechanisms involved.