In the brains of adult mammals long-distance cell migration of neuronal precursors is known to occur in the rostral migratory stream, involving chains of cells sliding into astrocytic glial tubes. By combining immunocytochemistry for polysialylated neural cell adhesion molecule (PSA-NCAM), neuronal and glial antigens, endogenous and exogenously administered cell-proliferation markers, and light and electron microscopy 3D reconstructions, we show that chains of newly generated neuroblasts exist both inside and outside the subventricular zone of adult rabbits. Two groups of chains were detectable within the mature brain parenchyma: anterior chains, into the anterior forceps of the corpus callosum, and posterior chains, close to the external capsule. Parenchymal chains were not associated with any special glial structures, thus coming widely in contact with the mature nervous tissue, including unmyelinated͞myelinated fibers, astrocytes, neurons, and oligodendrocytes. These chains of cells, unlike those in the subventricular zone, do not display cell proliferation, but they contain BrdUrd administered several weeks before. Telencephalic areas, such as the putamen, amygdala, claustrum, and cortex, adjacent to the chains harbor numerous PSA-NCAM-positive cells. The counting of newly generated cells in these areas shows small differences in comparison with others, and a few cells double-labeled for BrdUrd͞PSA-NCAM (after 1-month survival) and for BrdUrd͞NeuN (after 2 months) were detectable. These results demonstrate the occurrence of glial-independent chains of migrating neuroblasts, which directly contact the mature brain parenchyma of adult mammals. These chains could provide a possible link between the adult germinative layers and a very low-rate͞long-term process of cell addition in the telencephalon. C rucial morphogenetic processes, such as cell proliferation and migration, commonly occur during developmental͞ early postnatal periods, but they are highly restricted in the adult brain. In mammals, adult neurogenesis has been fully demonstrated to occur in two allocortical (three-layered) regions: the hippocampus (1) and the olfactory bulb (2). At present, the only well characterized example of long-distance cell migration in the adult mammalian brain is the rostral migratory stream (RMS), allowing the displacement of cell precursors from the forebrain subventricular zone (SVZ) to the olfactory bulb (2). This unique type of migration consists of tangentially oriented ''chains'' of cells expressing the polysialylated form of the neural cell adhesion molecule (PSA-NCAM; refs. 3 and 4) and sliding into a meshwork of astrocytic ''glial tubes'' (5, 6). Recent studies carried out in primates, in addition to the RMS (7, 8), reported the existence of newly generated neurons in several telencephalic areas, including the neocortex and the amygdala (9-11). Although a stream of proliferating cells was observed between the lateral ventricle and the amygdala (11), and some elongated cells were detected in the white matter benea...
Adult neurogenesis in mammals is restricted to some brain regions, in contrast with other vertebrates in which the genesis of new neurons is more widespread in different areas of the nervous system. In the mammalian cerebellum, neurogenesis is thought to be limited to the early postnatal period, coinciding with end of the granule cell genesis and disappearance of the external granule cell layer (EGL). We recently showed that in the rabbit cerebellum the EGL is replaced by a proliferative layer called ‘subpial layer’ (SPL) which persists beyond puberty on the cerebellar surface. Here we investigated what happens in the cerebellar cortex of peripuberal rabbits by using endogenous and exogenously-administered cell proliferation antigens in association with a cohort of typical markers for neurogenesis. We show that cortical cell progenitors extensively continue to be generated herein. Surprisingly, this neurogenic process continues to a lesser extent in the adult, even in the absence of a proliferative SPL. We describe two populations of newly generated cells, involving neuronal cells and multipolar, glia-like cells. The genesis of neuronal precursors is restricted to the molecular layer, giving rise to cells immunoreactive for GABA, and for the transcription factor Pax2, a marker for GABAergic cerebellar interneuronal precursors of neuroepithelial origin that ascend through the white matter during early postnatal development. The multipolar cells are Map5+, contain Olig2 and Sox2 transcription factors, and are detectable in all cerebellar layers. Some dividing Sox2+ cells are Bergmann glia cells. All the cortical newly generated cells are independent from the SPL and from granule cell genesis, the latter ending before puberty. This study reveals that adult cerebellar neurogenesis can exist in some mammals. Since rabbits have a longer lifespan than rodents, the protracted neurogenesis within its cerebellar parenchyma could be a suitable model for studying adult nervous tissue permissiveness in mammals.
Persistent neurogenic sites, harboring neurogenic progenitor cells, which give rise to neuronal precursors throughout life, occur in different mammals, including humans. The telencephalic subventricular zone (SVZ) is the most active adult neurogenic site. Despite remarkable knowledge of its anatomical and cellular composition in rodents, detailed arrangement of SVZ in other mammals is poorly understood, yet comparative studies suggest that differences might exist. Here, by analyzing the cellular composition/arrangement in the SVZ of postnatal, young, and adult rabbits, we found a remarkably heterogeneous distribution of its chain and glia compartments. Starting from postnatal stages, this heterogeneity leads to a distinction between a ventricular SVZ and an abventricular SVZ, whereby the former contains small chains and isolated neuroblasts and the latter is characterized by large chains and a loose astrocytic meshwork. In addition to analysis of the SVZ proper, attention has been focused on its extensions, called parenchymal chains. Anterior parenchymal chains are compact chains surrounded by axon bundles and frequently establish direct contact with blood vessels. Posterior parenchymal chains are less compact, being squeezed between gray and white matter. In the shift from neonatal to adult rabbit SVZ, chains occur very early, both in the SVZ and within the brain parenchyma. Comparison of these results with the pattern in rodents reveals different types of chains, displaying a variety of relationships with glia or other substrates in vivo, an issue that might be important in understanding differences in the adaptation of persistent germinative layers to different mammalian brain anatomies.
Protracted neurogenesis occurs at different postnatal stages in different brain locations, whereby leading to site-specific adult neurogenesis in some cases. No spontaneous genesis of neurons occurs in the cerebellum after the postnatal genesis of granule cells from the external germinal layer (EGL), a transitory actively proliferating zone which is thought to be exhausted before puberty. Here, we show the protracted genesis of newly generated neuronal precursors in the cerebellar cortex of young rabbits, persisting beyond puberty. Neuroblasts generated within an actively proliferating subpial layer thus extending the postnatal EGL are arranged to form thousands of tangential chains reminiscent of those responsible for cell migration in the forebrain subventricular zone. These subpial chains cover the whole cerebellar surface from the 2nd to the 5th month of life, then disappearing after puberty. In addition, we describe the appearance of similar groups of cells at the end of granule cell genesis in the mouse cerebellum, here limited to the short period of EGL exhaustion (4-5 days). These results show common features do exist in the postnatal reorganization of secondary germinal layers of brain and cerebellum at specific stages, parallel to differences in the slowing down of cerebellar neurogenesis among mammalian species.
Steroid hormones are important players to regulate adult neurogenesis in the dentate gyrus of hippocampus, but their involvement in the regulation of the same phenomenon in the subventricular zone (SVZ) of the lateral ventricles is not completely understood. Here, in male rats, we tested the existence of activational effects of Testosterone (T) on cell proliferation in the adult SVZ. To this aim, three groups of male rats: castrated, castrated and treated with T, and controls were treated with BrdU and killed after 24 hours. The density of BrdU labeled cells was significantly lower in castrated animals in comparison to the other two groups, thus supporting a direct correlation between SVZ proliferation and levels of circulating T. To clarify whether this effect is purely androgen-dependent, or mediated by the T metabolites, estradiol (E 2 ) and dihydrotestosterone (DHT), we evaluated SVZ proliferation in castrated males treated with E 2 , DHT and E 2 +DHT, in comparison to T-and vehicle-treated animals, and sham-operated controls. The stereological analysis demonstrated that E 2 and T, but not DHT, increase proliferation in the SVZ of adult male rats. Quantitative evaluation of cells expressing the endogenous marker of cell proliferation PHH3, or the marker of highly dividing SVZ progenitors Mash1, indicated the effect of T/E 2 is mostly restricted to SVZ proliferating progenitors. The same experimental protocol was repeated on ovariectomized female rats treated with E 2 or T. In this case, no statistically significant difference was found among groups. Overall, our results clearly show that the gonadal hormones T and E 2 represent important mediators of cell proliferation in the adult SVZ. Moreover, we show that such effect is restricted to males, supporting adult neurogenesis in rats is a process differentially modulated in the two sexes.
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