Dye coupling and connexin expression by cortical radial glia in the early postnatal subventricular zone.

In this study, we have analyzed the specific contribution of the cortical radial glia (RG) for gap junctional communication (GJC) within the postnatal subventricular zone (SVZ). To specifically target RG as source of dye-coupling in situ, we have developed a new technique that involves direct cell loading through the processes that reach the pial surface, with a mix of gap junction permeant (Lucifer yellow, LY) and nonpermeant (rhodamine-conjugated dextran 3 KDa, RD) fluorochromes, the latter used as a marker for direct loaded cells. Tissue sections were analyzed for identification of directly loaded (LY+RD+) and coupled cells (LY+RD-) in the SVZ. Directly loaded cells were restricted to the region underlying the pial loading surface area. Coupled cells were distributed in a bistratified manner, along the outer dorsal surface of the SVZ and aligning the ventricle, leaving the SVZ core relatively free. Blocking GJC prior to pial loading greatly reduced dye coupling. Phenotypic analysis indicated that coupling by RG excludes neuroblasts and is mostly restricted to cells of glial lineage. Notwithstanding, no corresponding restriction to specific cell phenotype was found for two connexin isotypes, Cx43 and Cx45, in the postnatal SVZ. The extensive homocellular cell coupling by RG suggests an important role in the regulation of neurogenesis and functional compartmentalization of the postnatal SVZ.

Generation of glutamatergic neurons from postnatal and adult subventricular zone with pyramidal-like morphology.

The mammalian subventricular zone (SVZ) contains progenitors derived from cerebral cortex radial glia cells, which give rise to glutamatergic pyramidal neurons during embryogenesis. However, during postnatal life, SVZ generates neurons that migrate and differentiate into olfactory bulb γ-aminobutyric acid (GABA)ergic interneurons. In this work, we tested if SVZ cells are able to produce glutamatergic neurons if confronted with the embryonic cortical ventricular zone environment. Different from typical SVZ chain migration, cells from P9-P11 SVZ explants migrate into embryonic cortical slices individually, many of which radially oriented. An average of 82.5% of green fluorescent protein-positive cells were immunolabeled for neuronal marker class III ß-tubulin. Invading cells differentiate into multiple morphologies, including a pyramidal-like morphotype. A subset of these cells are GABAergic; however, about 28% of SVZ-derived cells are immunoreactive for glutamate. Adult SVZ explants also give rise to glutamatergic neurons in these conditions. Taken together, our results indicate that SVZ can be a source of glutamatergic cortical neurons when submitted to proper environmental cues.

Gap junctions are involved in cell migration in the early postnatal subventricular zone.

The massive migration of neuroblasts and young neurons through the anterior extension of the postnatal subventricular zone (SVZ), known as the rostral migratory stream (RMS) is still poorly understood on its molecular basis. In this work, we investigated the involvement of gap junctional communication (GJC) in the robust centrifugal migration from SVZ/RMS explants obtained from early postnatal (P4) rats. Cells were dye-coupled in homocellular and heterocellular pairings and expressed at least two connexins, Cx 43 and 45. Treatment with the uncoupler agent carbenoxolone (CBX, 10-100 microM) reversibly reduced outgrowth from SVZ explants, while its inactive analog, glycyrhizinic acid (GZA), had no effect. Consistent with a direct effect on cell migration, time-lapse video microscopy show that different pharmacological uncouplers cause an abrupt and reversible arrest of cell movement in explants. Our results indicate that GJC is positively involved in the migration of neuroblasts within the SVZ/RMS.

Initial stages of radial glia astrocytic transformation in the early postnatal anterior subventricular zone.

In the early postnatal subventricular zone (SVZ), two seemingly unrelated events occur simultaneously: a massive tangential migration of neuroblasts towards the olfactory bulb, known as the rostral migratory stream (RMS), and the outward movement of radial glia (RG) undergoing astrocytic transformation. Because of the orthogonal arrangement between these two sets of cells, little, if any, relevance has been ascribed for their possible interactions. By depositing DiI at the pial surface we have studied RG transformation within the SVZ/RMS, from birth up to the end of the first postnatal week. While still within the SVZ/RMS, RG morphology changed from simple bipolar to highly complex branched profiles, attaining their highest degree of complexity at the interface of the SVZ with the overlying white matter. At this interface cell bodies of radial glia accumulate and their processes run tangentially, surrounding the SVZ/RMS. Processes of RG surrounding the SVZ/RMS could also be observed by immunostaining for vimentin, GFAP, and nestin. In contrast, in the white matter all DiI-labeled RG presented a simple bipolar profile. These results indicate that the outward radial migration of the transforming RG does not occur uniformly. Instead, the different morphologies and cell densities that RG assume when they cross the SVZ/RMS and overlying white matter imply different migratory behaviors. Finally, our data suggest that RG provide a cellular scaffold to the early postnatal SVZ/RMS, much in the same way as astrocytes in the adult RMS.