Radial glial cell‐specific ablation in the adult Zebrafish brain

The zebrafish brain can continue to produce new neurons in widespread neurogenic brain regions throughout life. In contrast, neurogenesis in the adult mammalian brain is restricted to the subventricular zone (SVZ) and dentate gyrus (DG). In neurogenic regions in the adult brain, radial glial cells (RGCs) are considered to function as neural stem cells (NSCs). We generated a Tg(gfap:Gal4FF) transgenic zebrafish line, which enabled us to express specific genes in RGCs. To study the function of RGCs in neurogenesis in the adult zebrafish brain, we also generated a Tg(gfap: Gal4FF; UAS:nfsB‐mcherry) transgenic zebrafish line, which allowed us to induce cell death exclusively within RGCs upon addition of metronidazole (Mtz) to the media. RGCs expressing nitroreductase were specifically ablated by the Mtz treatment, decreasing the number of proliferative RGCs. Using the Tg(gfap:Gal4FF; UAS:nfsB‐mcherry) transgenic zebrafish line, we found that RGCs were specifically ablated in the adult zebrafish telencephalon. The Tg(gfap:Gal4FF) line could be useful to study the function of RGCs. genesis 53:431–439, 2015. © 2015 Wiley Periodicals, Inc.     

Mapping neurogenesis onset in the optic tectum of Xenopus laevis

Neural progenitor cells have a central role in the development and evolution of the vertebrate brain. During early brain development, neural progenitors first expand their numbers through repeated proliferative divisions and then begin to exhibit neurogenic divisions. The transparent and experimentally accessible optic tectum of Xenopus laevis is an excellent model system for the study of the cell biology of neurogenesis, but the precise spatial and temporal relationship between proliferative and neurogenic progenitors has not been explored in this system. Here we construct a spatial map of proliferative and neurogenic divisions through lineage tracing of individual progenitors and their progeny. We find a clear spatial separation of proliferative and neurogenic progenitors along the anterior‐posterior axis of the optic tectum, with proliferative progenitors located more posteriorly and neurogenic progenitors located more anteriorly. Since individual progenitors are repositioned toward more anterior locations as they mature, this spatial separation likely reflects an increasing restriction in the proliferative potential of individual progenitors. We then examined whether the transition from proliferative to neurogenic behavior correlates with cellular properties that have previously been implicated in regulating neurogenesis onset. Our data reveal that the transition from proliferation to neurogenesis is associated with a small change in cleavage plane orientation and a more pronounced change in cell cycle kinetics in a manner reminiscent of observations from mammalian systems. Our findings highlight the potential to use the optic tectum of Xenopus laevis as an accessible system for the study of the cell biology of neurogenesis. © 2016 Wiley Periodicals, Inc. Develop Neurobiol 76: 1328–1341, 2016     

β2 and γ3 laminins are critical cortical basement membrane components: Ablation of Lamb2 and Lamc3 genes disrupts cortical lamination and produces dysplasia

Cortical development is dependent on the timely production and migration of neurons from neurogenic sites to their mature positions. Mutations in several receptors for extracellular matrix (ECM) molecules and their downstream signaling cascades produce dysplasia in brain. Although mutation of a critical binding site in the gene that encodes the ECM molecule laminin γ1 (Lamc1) disrupts cortical lamination, the ECM ligand(s) for many ECM receptors have not been demonstrated directly in the cortex. Several isoforms of the heterotrimeric laminins, all containing the β2 and γ3 chain, have been isolated from the brain, suggesting they are important for CNS function. Here, we report that mice homozygous null for the laminin β2 and γ3 chains exhibit cortical laminar disorganization. Mice lacking both of these laminin chains exhibit hallmarks of human cobblestone lissencephaly (type II, nonclassical): they demonstrate severe laminar disruption; midline fusion; perturbation of Cajal‐Retzius cell distribution; altered radial glial cell morphology; and ectopic germinal zones. Surprisingly, heterozygous mice also exhibit laminar disruption of cortical neurons, albeit with lesser severity. In compound null mice, the pial basement membrane is fractured, and the distribution of a key laminin receptor, dystroglycan, is altered. These data suggest that β2 and γ3‐containing laminins play an important dose‐dependent role in development of the cortical pial basement membrane, which serves as an attachment site for Cajal‐Retzius and radial glial cells, thereby guiding neural development. © 2012 Wiley Periodicals, Inc. Develop Neurobiol, 2013     

Evolution of ASPM coding variation in apes and associations with brain structure in chimpanzees

Studying genetic mechanisms underlying primate brain morphology can provide insight into the evolution of human brain structure and cognition. In humans, loss‐of‐function mutations in the gene coding for ASPM (Abnormal Spindle Microtubule Assembly) have been associated with primary microcephaly, which is defined by a significantly reduced brain volume, intellectual disability and delayed development. However, less is known about the effects of common ASPM variation in humans and other primates. In this study, we characterized the degree of coding variation at ASPM in a large sample of chimpanzees (N = 241), and examined potential associations between genotype and various measures of brain morphology. We identified and genotyped five non‐synonymous polymorphisms in exons 3 (V588G), 18 (Q2772K, K2796E, C2811Y) and 27 (I3427V). Using T1‐weighted magnetic resonance imaging of brains, we measured total brain volume, cerebral gray and white matter volume, cerebral ventricular volume, and cortical surface area in the same chimpanzees. We found a potential association between ASPM V588G genotype and cerebral ventricular volume but not with the other measures. Additionally, we found that chimpanzee, bonobo, and human lineages each independently show a signature of accelerated ASPM protein evolution. Overall, our results suggest the potential effects of ASPM variation on cerebral cortical development, and emphasize the need for further functional studies. These results are the first evidence suggesting ASPM variation might play a role in shaping natural variation in brain structure in nonhuman primates.     

A heterozygous mutation in tubulin,beta 2B ( Tubb2b ) causes cognitive deficits and hippocampal disorganization

Development of the mammalian forebrain requires a significant contribution from tubulin proteins to physically facilitate both the large number of mitoses in the neurogenic brain (in the form of mitotic spindles) as well as support cellular scaffolds to guide radial migration (radial glial neuroblasts). Recent studies have identified a number of mutations in human tubulin genes affecting the forebrain, including TUBB2B . We previously identified a mouse mutation in Tubb2b and we show here that mice heterozygous for this missense mutation in Tubb2b have significant cognitive defects in spatial learning and memory. We further showed reduced hippocampal long‐term potentiation consistent with these defects. In addition to the behavioural and physiological deficits, we show here abnormal hippocampal morphology. Taken together, these phenotypes suggest that heterozygous mutations in tubulin genes result in cognitive deficits not previously appreciated. This has implications for design and interpretation of genetic testing for humans with intellectual disability disorders.     

Asymmetric inheritance of radial glial fibers by cortical neurons

Recent studies demonstrated the neuronogenic role of radial glial cells (RGCs) in the rodent. To reveal the fate of radial glial processes, we intensively monitored divisions of RGCs in DiI-labeled slices from the embryonic day 14 mouse cortex. During RGC division, each pia-connected fiber becomes thin but is neither lost nor divided; it is inherited asymmetrically by one daughter cell. In divisions that produce a neuron and a progenitor, the neuron inherits the pial fiber, also grows a thick ventricular process for several hours, and is therefore indistinguishable from the progenitor RGC. The ventricular process in the radial glial-like neuron ("radial neuron") then collapses, leading to ascent of the neuron by using the "recycled" radial fiber.     

Par-complex proteins promote proliferative progenitor divisions in the developing mouse cerebral cortex

The size of brain regions depends on the balance between proliferation and differentiation. During development of the mouse cerebral cortex, ventricular zone (VZ) progenitors, neuroepithelial and radial glial cells, enlarge the progenitor pool by proliferative divisions, while basal progenitors located in the subventricular zone (SVZ) mostly divide in a differentiative mode generating two neurons. These differences correlate to the existence of an apico-basal polarity in VZ, but not SVZ, progenitors. Only VZ progenitors possess an apical membrane domain at which proteins of the Par complex are strongly enriched. We describe a prominent decrease in the amount of Par-complex proteins at the apical surface during cortical development and examine the role of these proteins by gain- and loss-of-function experiments. Par3 (Pard3) loss-of-function led to premature cell cycle exit, reflected in reduced clone size in vitro and the restriction of the progeny to the lower cortical layers in vivo. By contrast, Par3 or Par6 (Pard6alpha) overexpression promoted the generation of Pax6+ self-renewing progenitors in vitro and in vivo and increased the clonal progeny of single progenitors in vitro. Time-lapse video microscopy revealed that a change in the mode of cell division, rather than an alteration of the cell cycle length, causes the Par-complex-mediated increase in progenitors. Taken together, our data demonstrate a key role for the apically located Par-complex proteins in promoting self-renewing progenitor cell divisions at the expense of neurogenic differentiation in the developing cerebral cortex.     

Adult neurogenesis in the crayfish brain: Proliferation,migration, and possible origin of precursor cells

The birth of new neurons and their incorporation into functional circuits in the adult brain is a characteristic of many vertebrate and invertebrate organisms, including decapod crustaceans. Precursor cells maintaining life‐long proliferation in the brains of crayfish (Procambarus clarkii, Cherax destructor) and clawed lobsters (Homarus americanus) reside within a specialized niche on the ventral surface of the brain; their daughters migrate to two proliferation zones along a stream formed by processes of the niche precursors. Here they divide again, finally producing interneurons in the olfactory pathway. The present studies in P. clarkii explore (1) differential proliferative activity among the niche precursor cells with growth and aging, (2) morphological characteristics of cells in the niche and migratory streams, and (3) aspects of the cell cycle in this lineage. Morphologically symmetrical divisions of neuronal precursor cells were observed in the niche near where the migratory streams emerge, as well as in the streams and proliferation zones. The nuclei of migrating cells elongate and undergo shape changes consistent with nucleokinetic movement. LIS1, a highly conserved dynein‐binding protein, is expressed in cells in the migratory stream and neurogenic niche, implicating this protein in the translocation of crustacean brain neuronal precursor cells. Symmetrical divisions of the niche precursors and migration of both daughters raised the question of how the niche precursor pool is replenished. We present here preliminary evidence for an association between vascular cells and the niche precursors, which may relate to the life‐long growth and maintenance of the crustacean neurogenic niche. © 2009 Wiley Periodicals, Inc. Develop Neurobiol, 2009     

CoupTFI Interacts with Retinoic Acid Signaling during Cortical Development

We examined the role of the orphan nuclear hormone receptor CoupTFI in mediating cortical development downstream of meningeal retinoic acid signaling. CoupTFI is a regulator of cortical development known to collaborate with retinoic acid (RA) signaling in other systems. To examine the interaction of CoupTFI and cortical RA signaling we utilized Foxc1-mutant mice in which defects in meningeal development lead to alterations in cortical development due to a reduction of RA signaling. By analyzing CoupTFI^−/−;Foxc1^H/L double mutant mice we provide evidence that CoupTFI is required for RA rescue of the ventricular zone and the neurogenic phenotypes in Foxc1-mutants. We also found that overexpression of CoupTFI in Foxc1-mutants is sufficient to rescue the Foxc1-mutant cortical phenotype in part. These results suggest that CoupTFI collaborates with RA signaling to regulate both cortical ventricular zone progenitor cell behavior and cortical neurogenesis.     

MTOR controls genesis and autophagy of GABAergic interneurons during brain development

Interneuron progenitors in the ganglionic eminence of the ventral telencephalon generate most cortical interneurons during brain development. However, the regulatory mechanism of interneuron progenitors remains poorly understood. Here, we show that MTOR (mechanistic target of rapamycin [serine/threonine kinase]) regulates proliferation and macroautophagy/autophagy of interneuron progenitors in the developing ventral telencephalon. To investigate the role of MTOR in interneuron progenitors, we conditionally deleted the Mtor gene in mouse interneuron progenitors and their progeny by using Tg(mI56i-cre,EGFP)1Kc/Dlx5/6-Cre-IRES-EGFP and Nkx2–1-Cre drivers. We found that Mtor deletion markedly reduced the number of interneurons in the cerebral cortex. However, relative positioning of cortical interneurons was normal, suggesting that disruption of progenitor self-renewal caused the decreased number of cortical interneurons in the Mtor-deleted brain. Indeed, Mtor-deleted interneuron progenitors showed abnormal proliferation and cell cycle progression. Additionally, we detected a significant activation of autophagy in Mtor-deleted brain. Our findings suggest that MTOR plays a critical role in the regulation of cortical interneuron number and autophagy in the developing brain.     

FGF signaling gradient maintains symmetrical proliferative divisions of midbrain neuronal progenitors

For the correct development of the central nervous system, the balance between self-renewing and differentiating divisions of the neuronal progenitors must be tightly regulated. To maintain their self-renewing identity, the progenitors need to retain both apical and basal interfaces. However, the identities of fate-determining signals which cells receive via these connections, and the exact mechanism of their action, are poorly understood. The conditional inactivation of Fibroblast growth factor (FGF) receptors 1 and 2 in the embryonic mouse midbrain–hindbrain area results in premature neuronal differentiation. Here, we aim to elucidate the connection between FGF signaling and neuronal progenitor maintenance. Our results reveal that the loss of FGF signaling leads to downregulation of Hes1 and upregulation of Ngn2, Dll1, and p57 in the ventricular zone (VZ) cells, and that this increased neurogenesis occurs cell-autonomously. Yet the cell cycle progression, apico-basal-polarity, cell–cell connections, and the positioning of mitotic spindle in the mutant VZ appear unaltered. Interestingly, FGF8-protein is highly concentrated in the basal lamina. Thus, FGFs may act through basal processes of neuronal progenitors to maintain their progenitor status. Indeed, midbrain neuronal progenitors deprived in vitro of FGFs switched from symmetrical proliferative towards symmetrical neurogenic divisions. We suggest that FGF signaling in the midbrain VZ is cell-autonomously required for the maintenance of symmetrical proliferative divisions via Hes1-mediated repression of neurogenic genes.     

Adult neurogenesis in the short-lived teleost Nothobranchius furzeri: localization of neurogenic niches, molecular characterization and effects of aging

We studied adult neurogenesis in the short‐lived annual fish Nothobranchius furzeri and quantified the effects of aging on the mitotic activity of the neuronal progenitors and the expression of glial fibrillary acid protein (GFAP) in the radial glia. The distribution of neurogenic niches is substantially similar to that of zebrafish and adult stem cells generate neurons, which persist in the adult brain. As opposed to zebrafish, however, the N. furzeri genome contains a doublecortin (DCX) gene. Doublecortin is transiently expressed by newly generated neurons in the telencephalon and optic tectum (OT). We also analyzed the expression of the microRNA miR‐9 and miR‐124 and found that they have complementary expression domains: miR‐9 is expressed in the neurogenic niches of the telencephalon and the radial glia of the OT, while miR‐124 is expressed in differentiated neurons. The main finding of this paper is the demonstration of an age‐dependent decay in adult neurogenesis. Using unbiased stereological estimates of cell numbers, we detected an almost fivefold decrease in the number of mitotically active cells in the OT between young and old age. This reduced mitotic activity is paralleled by a reduction in DCX labeling. Finally, we detected a dramatic up‐regulation of GFAP in the radial glia of the aged brain. This up‐regulation is not paralleled by a similar up‐regulation of S100B and Musashi‐1, two other markers of the radial glia. In summary, the brain of N. furzeri replicates two typical hallmarks of mammalian aging: gliosis and reduced adult neurogenesis.     

Radial glial cell development and transformation are disturbed in reeler forebrain

Radial glia are among the earliest cell types to differentiate in the developing mammalian forebrain. Glial fibers span the early cortical wall, forming a dense scaffold; this persists throughout corticogenesis, providing a cellular substrate which supports and directs the migration of young neurons. Although the mechanisms regulating radial glial cell development are poorly understood, a secreted cortical radial glial differentiation signal was recently identified in the embryonic mouse forebrain. This signal is abundant at the time radial glia function to support neuronal migration, and down-regulated perinatally, when radial glia are known to undergo transformation into astrocytes. Therefore, it seems that this signal functions as a radial glial maintenance factor, the availability of which regulates the phenotype of cortical astroglia. Here the differentiation signal is further characterized as RF60, a protein with a molecular weight of approximately 60 kD. In addition, the neurologic mutant mouse reeler provides a genetic model for analysis of RF60 function. Radial glia in reeler cortex are shown to be poorly differentiated and the radial scaffold is shown to be maintained for a shorter time than normal. Furthermore, although astroglial cells from normal cortex are induced to elaborate a radial phenotype by RF60, reeler astroglia show an impaired differentiation response to this. These findings suggest that an intrinsic defect in glial differentiation contributes to the phenotype of abnormal cortical lamination seen in reeler mouse, and indicate that RF60 may play a critical role in normal cortical patterning. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 459–472, 1997     

Efficient Cargo Delivery into Adult Brain Tissue Using Short Cell-Penetrating Peptides

Zebrafish brains can regenerate lost neurons upon neurogenic activity of the radial glial progenitor cells (RGCs) that reside at the ventricular region. Understanding the molecular events underlying this ability is of great interest for translational studies of regenerative medicine. Therefore, functional analyses of gene function in RGCs and neurons are essential. Using cerebroventricular microinjection (CVMI), RGCs can be targeted efficiently but the penetration capacity of the injected molecules reduces dramatically in deeper parts of the brain tissue, such as the parenchymal regions that contain the neurons. In this report, we tested the penetration efficiency of five known cell-penetrating peptides (CPPs) and identified two– polyR and Trans – that efficiently penetrate the brain tissue without overt toxicity in a dose-dependent manner as determined by TUNEL staining and L-Plastin immunohistochemistry. We also found that polyR peptide can help carry plasmid DNA several cell diameters into the brain tissue after a series of coupling reactions using DBCO-PEG4-maleimide-based Michael’s addition and azide-mediated copper-free click reaction. Combined with the advantages of CVMI, such as rapidness, reproducibility, and ability to be used in adult animals, CPPs improve the applicability of the CVMI technique to deeper parts of the central nervous system tissues.     

Supersize me—new insights into cortical expansion and gyration of the mammalian brain

EMBO J 32 13, 1817–1828 doi:10.1038/emboj.2013.96; published online April262013During evolution, the mammalian brain massively expanded its size. However, the exact roles of distinct neural precursors, identified in the developing cortex during embryogenesis, for size expansion and surface folding (i.e., gyration) remain largely unknown. New findings by Nonaka-Kinoshita et al advance our understanding of embryonic neural precursor function by identifying cell type-selective functions for size expansion and folding, and challenge previously held concepts of mammalian brain development.Over the course of evolution, the mammalian brain massively expanded its size and complexity, which is believed to be responsible for an increase in cognitive functions and intellectual skills. The increase in brain size and number of cortical neurons is primarily due to an increased surface area by generating folds (gyrations) while the cortical thickness remained relatively constant (Lui et al, 2011). In the last decade, substantial progress has been made in identifying the cellular sources of cortex development. Using genetic lineage tracing of individual cell populations and time-lapse imaging of rodent and human slices of the embryonic cortex, radial glial cells (RGCs) were identified as the primary progenitors or neural stem cells (NSCs) in the developing cortex (Gotz and Huttner, 2005). Simplified, RG in the ventricular zone (VZ) line the ventricular surface and self-renew through symmetric divisions or give rise to basal progenitors (BPs; also called intermediate progenitors) in the subventricular zone (SVZ) that typically divide symmetrically and generate neurons. In contrast to the lissencephalic rodent brain, the developing cortex of gyrated mammals (e.g., humans and ferrets) contains a large number of basal radial glial (bRG) cells that reside in the outer subventricular zone (OSVZ), retain a cellular process that is connected to the pial surface and that are, in contrast to BPs, multipotent, meaning that they have the potency to generate diverse neural cell types (Fietz et al, 2010; Hansen et al, 2010; Reillo et al, 2011).Largely based on the anatomical differences between the developing cortex of lissencephalic and gyrencephalic brains, several hypotheses have been formulated aiming to explain the massive increase in size and induction of brain folding during mammalian evolution. One prominent hypothesis, called the radial unit hypothesis, suggests that the expansion of RGCs lining the ventricle leads to an increase of radial units that generate neurons and thus is responsible for the increase of surface area (Rakic, 1995). Others proposed that the increase in size and folding could be due to an increase in BP expansion in the SVZ compared to RGC numbers in the VZ, a hypothesis called the intermediate progenitor model (Kriegstein et al, 2006). These hypotheses were helpful to start explaining mammalian brain evolution, but testing the exact role of different neural precursors remained extremely challenging due to technical difficulties to selectively manipulating the proliferative activity of distinct precursor populations. Even though previous approaches were successful in enhancing brain size/neuron numbers in mouse models (e.g., by ectopically enhancing WNT signalling activity or manipulating the activity of the small RhoGTPase Cdc42 in neural precursors), these strategies had the drawback that the normal six-layered cortical topography was disrupted, making it difficult to draw definite conclusions (Chenn and Walsh, 2002; Cappello et al, 2006).In a collaborative work from the Calegari and Borrell laboratories, Nonaka-Kinoshita et al, 2013 now used an elegant approach to selectively enhance proliferation of distinct precursor populations in the mouse and ferret developing cortex. They used a previously described approach manipulating cell cycle length and subsequently proliferation by overexpressing the cell cycle regulators cdk4 and cyclinD1 that is sufficient to enhance neurogenesis without affecting cortical layering (a system called 4D) (Lange et al, 2009). For their mouse experiments, Nonaka-Kinoshita et al used a transgenic strategy to transiently overexpress 4D in nestin-expressing precursors using a tetracycline-controlled gene expression system (nestin^rtTA/tetbi^4D). With this approach, they selectively enhanced proliferation of BPs in the SVZ without affecting the number or proliferation of RGCs in the VZ (Nonaka-Kinoshita et al, 2013). Strikingly, targeted expansion of BPs induced a substantial increase in surface area but was not sufficient to induce cortical folding in the otherwise smooth mouse cortex, challenging the radial unit hypothesis and the intermediate progenitor model with regard to their predictions on the effects on size and/or gyration of the cortex upon expansion of the BP pool. Complementing their findings of BP expansion in the lissencephalic mouse brain, Nonaka-Kinoshita et al used retroviral vectors and electroporation of 4D expression constructs to target 4D expression to neural precursors in the developing ferret cortex that is gyrated under physiological conditions. In the ferret, 4D expression induced proliferation of multipotent bRG located in the OSVZ, as outlined above, a cell type that is found predominantly in gyrated cortices compared to lissencephalic brains. Notably, enhanced proliferation of bRG triggered the formation of novel cortical folds, suggesting that indeed the expansion of bRG may represent a key event during evolution to induce gyration and subsequent surface expansion of the mammalian brain (Borrell and Reillo, 2012; Nonaka-Kinoshita et al, 2013) (Figure 1). This now experimentally supported hypothesis is strongly reinforced by two recent publications: one from (Tuoc et al, 2013) who found that deletion of the chromatin remodelling protein BAF170 increases the BP pool and subsequently enhances brain size; and another one from the Götz laboratory where it was found that experimentally reduced expression levels of the DNA-associated protein Trnp1 substantially increased the expansion of bRG and BPs, inducing folding of the normally lissencephalic mouse brain (Stahl et al, 2013). Taken together, these studies suggest that bRG in the OSVZ play an important role in cortical folding by enhancing the generation of neurons and by providing a glial scaffold for newborn neurons to disperse more laterally and thus to form folds in the developing brain (Reillo et al, 2011).Open in a separate windowFigure 1How different neural precursors appear to regulate size expansion and folding during mammalian brain development. (A) Shown are the main cellular components of the cortex of the lissencephalic mouse brain during embryonic development with RGCs (blue) lining the lateral ventricles in the VZ that generate BPs (yellow) in the SVZ and provide a scaffold for migrating neurons (left; green). Note that the mouse developing brain contains only a few bRG in the OSVZ (red). Notably, expansion of BPs using the 4D strategy developed in the Calegari laboratory increases surface area of the murine cortex without inducing the folding of the smooth mouse brain surface (right panel). (B) In contrast to lissencephalic animals, the developing cortices of species with gyrated brains (e.g., humans and ferrets) contain a substantial number of bRG located in the OSVZ (left panel). 4D-based, virus-mediated expansion of bRG in the ferret cortex leads to the induction of additional folds in the ferret cortex, indicating that the proliferative activity of bRG is critically involved in the extent of folding in physiologically gyrated brains (right panel).Even though this new study challenges previously held concepts regarding size expansion and folding of the mammalian brain, future studies are required that even more selectively enhance the proliferation and expansion of distinct precursor subtypes with high temporal and spatial control. Thus, the combination of sophisticated genetic tools to enhance precursor activity with detailed molecular analyses (e.g., analysing gene expression in highly folded versus unfolded brain regions, an approach that already showed differential levels of Trnp1 expression; Stahl et al, 2013) and live-imaging studies in the developing mammalian cortex will further enhance the understanding how our brains developed during evolution.     

Clonal analysis by distinct viral vectors identifies bona fide neural stem cells in the adult zebrafish telencephalon and characterizes their division properties and fate

Neurogenesis is widespread in the zebrafish adult brain through the maintenance of active germinal niches. To characterize which progenitor properties correlate with this extensive neurogenic potential, we set up a method that allows progenitor cell transduction and tracing in the adult zebrafish brain using GFP-encoding retro- and lentiviruses. The telencephalic germinal zone of the zebrafish comprises quiescent radial glial progenitors and actively dividing neuroblasts. Making use of the power of clonal viral vector-based analysis, we demonstrate that these progenitors follow different division modes and fates: neuroblasts primarily undergo a limited amplification phase followed by symmetric neurogenic divisions; by contrast, radial glia are capable at the single cell level of both self-renewing and generating different cell types, and hence exhibit bona fide neural stem cell (NSC) properties in vivo. We also show that radial glial cells predominantly undergo symmetric gliogenic divisions, which amplify this NSC pool and may account for its long-lasting maintenance. We further demonstrate that blocking Notch signaling results in a significant increase in proliferating cells and in the numbers of clones, but does not affect clone composition, demonstrating that Notch primarily controls proliferation rather than cell fate. Finally, through long-term tracing, we illustrate the functional integration of newborn neurons in forebrain adult circuitries. These results characterize fundamental aspects of adult progenitor cells and neurogenesis, and open the way to using virus-based technologies for stable genetic manipulations and clonal analyses in the zebrafish adult brain.     

MYC proteins promote neuronal differentiation by controlling the mode of progenitor cell division

The role of MYC proteins in somatic stem and progenitor cells during development is poorly understood. We have taken advantage of a chick in vivo model to examine their role in progenitor cells of the developing neural tube. Our results show that depletion of endogenous MYC in radial glial precursors (RGPs) is incompatible with differentiation and conversely, that overexpression of MYC induces neurogenesis independently of premature or upregulated expression of proneural gene programs. Unexpectedly, the neurogenic function of MYC depends on the integrity of the polarized neural tissue, in contrast to the situation in dissociated RGPs where MYC is mitogenic. Within the polarized RGPs of the neural tube, MYC drives differentiation by inhibiting Notch signaling and by increasing neurogenic cell division, eventually resulting in a depletion of progenitor cells. These results reveal an unexpected role of MYC in the control of stemness versus differentiation of neural stem cells in vivo.