GLUT2-mediated glucose uptake and availability are required for embryonic brain development in zebrafish

Glucose transporter 2 (GLUT2; gene name SLC2A2) has a key role in the regulation of glucose dynamics in organs central to metabolism. Although GLUT2 has been studied in the context of its participation in peripheral and central glucose sensing, its role in the brain is not well understood. To decipher the role of GLUT2 in brain development, we knocked down slc2a2 (glut2), the functional ortholog of human GLUT2, in zebrafish. Abrogation of glut2 led to defective brain organogenesis, reduced glucose uptake and increased programmed cell death in the brain. Coinciding with the observed localization of glut2 expression in the zebrafish hindbrain, glut2 deficiency affected the development of neural progenitor cells expressing the proneural genes atoh1b and ptf1a but not those expressing neurod. Specificity of the morphant phenotype was demonstrated by the restoration of brain organogenesis, whole-embryo glucose uptake, brain apoptosis, and expression of proneural markers in rescue experiments. These results indicate that glut2 has an essential role during brain development by facilitating the uptake and availability of glucose and support the involvement of glut2 in brain glucose sensing.

Expression cloning of a human polysialyltransferase that forms the polysialylated neural cell adhesion molecule present in embryonic brain.

Polysialic acid is a developmentally regulated posttranslational modification of the neural cell adhesion molecule (N-CAM). It has been suggested that this large anionic carbohydrate modulates the adhesive property of N-CAM, but the precise function of polysialic acid is not known. Here we describe the isolation and functional expression of a cDNA encoding a human polysialyltransferase. For this expression cloning, COS-1 cells were cotransfected with a human fetal brain cDNA library and a cDNA encoding human N-CAM. Transfected COS-1 cells were stained with a monoclonal antibody specific for polysialic acid and enriched by fluorescence-activated cell sorting. Sibling selection of recovered plasmids resulted in a cDNA clone that directs the expression of polysialic acid on the cell surface. The deduced amino acid sequence indicates that the polysialyltransferase shares a common sequence motif with other sialyltransferases cloned so far. The polysialyltransferase is, however, distinct by having two clusters of basic amino acids. The amount of the polysialyltransferase transcripts correlates well with the formation of polysialic acid in various human tissues, and is abundant in the fetal brain but not in the adult brain. Moreover, HeLa cells stably expressing polysialic acid and N-CAM promoted neurite outgrowth and sprouting. These results indicate that the cloned polysialyltransferase forms polysialylated, embryonic N-CAM, which is critical for plasticity of neural cells.

Vitamin D receptor expression in the embryonic rat brain

We are interested in determining whether low maternal vitamin D-3 affects brain development in utero. Whilst the vitamin D receptor (VDR) has been identified in embryonic rat brains, the timing and magnitude of its expression across the brain remains unclear. In this study we have quantitated VDR expression during development as well correlated the timing of its appearance with two vital developmental events, apoptosis and mitosis. Brains from embryonic rats (embryonic days 15-23) were examined. We show that the well-described increase in apoptotic cells and decrease in mitotic cells during development correlates with the appearance of the VDR in brain tissue. Given that vitamin D-3 regulates mitosis and apoptosis in non-neuronal tissue we speculate that the timing of VDR expression in embryonic brain may directly or indirectly mediate features of neuronal apoptosis and mitosis.

Selective neuronal toxicity of cocaine in embryonic mouse brain cocultures.

Cocaine exposure in utero causes severe alterations in the development of the central nervous system. To study the basis of these teratogenic effects in vitro, we have used cocultures of neurons and glial cells from mouse embryonic brain. Cocaine selectively affected embryonic neuronal cells, causing first a dramatic reduction of both number and length of neurites and then extensive neuronal death. Scanning electron microscopy demonstrated a shift from a multipolar neuronal pattern towards bi- and unipolarity prior to the rounding up and eventual disappearance of the neurons. Selective toxicity of cocaine on neurons was paralleled by a concomitant decrease of the culture content in microtubule-associated protein 2 (MAP2), a neuronal marker measured by solid-phase immunoassay. These effects on neurons were reversible when cocaine was removed from the culture medium. In contrast, cocaine did not affect astroglial cells and their glial fibrillary acidic protein (GFAP) content. Thus, in embryonic neuronal-glial cell cocultures, cocaine induces major neurite perturbations followed by neuronal death without affecting the survival of glial cells. Provided similar neuronal alterations are produced in the developing human brain, they could account for the qualitative or quantitative defects in neuronal pathways that cause a major handicap in brain function following in utero exposure to cocaine.

SOURCE, FATE AND FUNCTION OF EARLY GLIAL CELLS EXPRESSING NKX2.1 IN MOUSE EMBRYONIC BRAINS

The brain tissue is made of neuronal and glial cells generated in the germinal layer bordering the ventricles. These cells divide, differentiate and migrate following specific pathways. The specification of GABAergic interneurons and glutamatergic neurons has been broadly studied but little is known about the origin, the fate and the function of early glial cells in the embryonic telencephalon. It has been commonly accepted since long that the glial cells and more particularly the astrocytes were generated after neurogenesis from the dorsal telencephalon. However, our work shows that, unlike what was previously thought, numerous glial cells (astroglia and polydendrocytes) are generated during neurogenesis in the early embryonic stages from E14.5 to E16.5, and originate from the ventral Nkx2.1-expressing precursors instead. NK2 homeobox 1 (Nkx2.1) is a member of the NK2 family of homeodomaincontaining transcription factors. The specification of the MGE precursors requires the expression of the Nkx2.1 homeobox gene. Moreover, Nkx2.1 is previously known to regulate the specification of GABAergic interneurons and early oligodendrocytes in the ventral telencephalon. Here, in my thesis work, I have discovered that, in addition, Nkx2.1 also regulates astroglia and polydendrocytes differentiation. The use of Nkx2.1 antibody and Nkx2.1 riboprobe have revealed the presence of numerous Nkx2.1-positive cells that express astroglial markers (like GLAST and GFAP) in the entire embryonic brain. Thus, to selectively fate map MGE-derived GABAergic interneurons and glia, we crossed Nkx2.1-Cre mice, Glast-Cre ERT+/- inducible mice and NG2-Cre mice with the Cre reporter Rosa26-lox-STOP-lox-YFP (Rosa26-YFP) mice. The precise origin of Nkx2.1-positive astroglia has been directly ascertained by combining glial immunostaining and focal electroporation of the pCAG-GS-EGFP plasmids into the subpallial domains of organotypic slices, as well as, by using in vitro neurosphere experiments and in utero electroporation of the pCAG-GS-tomato plasmid into the ventral pallium of E14.5 Nkx2.1-Cre+/Rosa-YFP+/- embryos. We have, thus, confirmed that the three germinal regions of the ventral telencephalon i.e. the MGE, the AEP/POA and the triangular septal nucleus are able to generate early astroglial cells. Moreover, immunohistochemistry for several astroglial cells and polydendrocyte markers, both in the Nkx2.1-/- and control embryos and in the neurospheres, has revealed a severe loss of both glial cell types in the Nkx2.1 mutants. We found that the loss of glia corresponded to a decrease of Nkx2.1-derived precursor division capacity and glial differentiation. There was a drastic decrease of BrdU+ dividing cells labeled for Nkx2.1 in the MGE*, the POA* and the septal nucleus* of Nkx2.1 mutants. In addition, we noticed that while some remaining Nkx2.1+ precursors still succeeded to give rise to post-mitotic neurons in vitro and in vivo in the Nkx2.1-/-, they completely lost the capacity to differentiate in astrocytes. Altogether, these observations indicate for the first time that the transcription factor Nkx2.1 regulates the proliferation and differentiation of precursors in three subpallial domains that generate early embryonic astroglia and polydendrocytes. Furthermore, in order to investigate the potential function of these early Nkx2.1- derived glia, we have performed multiple immunohistochemical stainings on Nkx2.1-/- and wild-type animals, and Nkx2.1-Cre mice that were crossed to Rosa-DTA+/- mice in which the highly toxic diphtheria toxin aided to selectively deplete a majority of the Nkx2.1-derived cells. Interestingly, in these two mutants, we observed a drastic and significant loss of GFAP+, GLAST+, NG2+ and S100ß+ astroglial cells at the telencephalic midline and in the medial cortical areas. This cells loss could be directly correlated with severe axonal guidance defects observed in the corpus callosum (CC), the hippocampal commissure (HIC), the fornix (F) and the anterior commissure (AC). Axonal guidance is a key step allowing neurons to form specific connections and to become organized in a functional network. The contribution of guidepost cells inside the CC and the AC in mediating the growth of commissural axons have until now been attributed to specialized midline guidepost astroglia. Previous published results in our group have unravelled that, during embryonic development, the CC is populated in addition to astroglia by numerous glutamatergic and GABAergic guidepost neurons that are essential for the correct midline crossing of callosal axons. Therefore, the relative contribution of individual neuronal or glial populations towards the guidance of commissural axons remains largely to be investigated to understand guidance mechanisms further. Thus, we crossed Nkx2.1-Cre mice with NSE-DTA+/- mice that express the diphtheria toxin only in neurons and allowed us to selectively deplete Nkx2.1-derived GABAergic neurons. Interestingly, in the Nkx2.1-/- mice, the CC midline was totally disorganized and the callosal axons partly lost their orientation, whereas in the Nkx2.1Cre+/Rosa-DTA+/- and the Nkx2.1Cre+/NSE-DTA+/- mice, the axonal organization of the CC was not affected. In the three types of mice, hippocampal axons of the fornix were not properly fasciculated and formed disoriented bundles through the septum. Additionally, the AC formation was completely absent in Nkx2.1-/- mice and the AC was divided into two/three separate paths in the Nkx2.1Cre+/Rosa-DTA+/- mice that project in wrong territories. On the other hand, the AC didn't form or was reduced to a relatively narrower tract in the Nkx2.1Cre+/NSE-DTA+/- mice as compared to wild-type AC. These results clearly indicate that midline Nkx2.1-derived cells play a major role in commissural axons pathfinding and that both Nkx2.1-derived guidepost neurons and glia are necessary elements for the correct development of these commissures. Furthermore, during our investigations on Nkx2.1-/- and Nkx2.1Cre+/Rosa-DTA+/- mice, we noticed similar and severe defects in the erythrocytes distribution and the blood vessels network morphology in the embryonic brain of both mutants. As the Cre-mediated recombination was never observed to occur in the blood vessels of Nkx2.1-Cre mice, we inferred that the vessels defects observed were due to the loss of Nkx2.1-derived cells and not to the cells autonomous effects of Nkx2.1 in regulating endothelial cell precursors. Thereafter, the respective contribution of individual Nkx2.1-regulated neuronal or glial populations in the blood vessels network building were studied with the use of transgenic mice strains. Indeed, the use of Nkx2.1Cre+/NSE-DTA+/- mice indicated that the Nkx2.1-derived neurons were not implicated in this process. Finally, to discriminate between the two Nkx2.1-derived glial cell populations, the GLAST+ astroglia and the NG2+ polydendrocytes, an NG2-Cre mouse strain crossed to the Rosa-DTA+/- mice was used. In that mutant, the blood vessel network and the erythrocytes distribution were similarly affected as observed in Nkx2.1Cre+/Rosa-DTA+/- animals. Therefore, this result indicates that most probably, the NG2+ polydendrocytes are involved in helping to build the vessels network in the brain. Taken altogether, these observations show that during brain development, Nkx2.1- derived embryonic glial cells act as guidepost cells on the guidance of axons as well as forming vessels. Both Nkx2.1-regulated guidepost GABAergic neurons and glia collaborate to guide growing commissural axons, while polydendrocytes are implicated in regulating brain angiogenesis. - Le tissu cérébral est composé de cellules neuronales et gliales générées dans les couches germinales qui bordent les ventricules. Ces cellules se divisent, se différencient et migrent selon des voies particulières. La spécification des interneurones GABAergiques et des neurones glutamatergiques a été largement étudiée, par contre, l'origine, le destin et la fonction des cellules gliales précoces du télencéphale embryonnaire restent peu élucidées. Depuis longtemps, il était communément accepté que les cellules gliales, et plus particulièrement les astrocytes, sont générés après la neurogénèse à partir du télencéphale dorsal. Toutefois, notre travail montre que de nombreuses cellules gliales sont générées à partir de précurseurs ventraux qui expriment le gène Nkx2.1, entre E14.5 et E16.5, c'est-à dire,à des stades embryonnaires très précoces. Le gène NK2 homéobox 1 (Nkx2.1) appartient à une famille de facteurs de transcription appelée NK2. Il s'agit de protéines qui contiennent un homéo-domaine. La spécification des précurseurs de la MGE requiert l'expression du gène homéobox Nkx2.1. De plus, la fonction du gène Nkx2.1 dans la régulation de la spécification des interneurones GABAergiques et des oligodendrocytes dans le télencéphale ventral était déjà connue. Au cours de mon travail de thèse, j'ai également mis en évidence que, Nkx2.1 régule aussi les étapes de prolifération et de différenciation de divers sous-types de cellules gliales soit de type astrocytes ou bien polydendrocytes. L'utilisation d'un anticorps contre la protéine Nkx2.1 ainsi qu'une sonde à ribonucléotides contre l'ARN messager du gène Nkx2.1 ont révélé la présence de nombreuses cellules positives pour Nkx2.1 qui exprimaient des marqueurs astrocytaires (comme GLAST et GFAP) dans le télencéphale embryonnaire. Afin de déterminer de manière sélective le sort des interneurones GABAergiques, des polydendrocytes et des astrocytes dérivés de la MGE, nous avons croisé soit des souris Nkx2.1-Cre, des souris Glast-Cre ERT+/- inductibles ou bien des souris NG2-Cre avec des souris Rosa26-lox-STOP-lox-YFP (Rosa26-YFP) Cre rapportrices. L'origine précise des astroglies positives pour Nkx2.1 a été directement établie en combinant une coloration immunologique pour les glies et une électroporation focale d'un plasmide pCAG-GS-EGFP dans les domaines subpalliaux de tranches organotypiques, puis également, par des cultures de neurosphères in vitro et des expériences d'électroporation in utero d'un plasmide pCAG-GS-tomato dans le pallium ventral d'embryons Nkx2.1-Cre+/Rosa- YFP+/- au stade E14.5. Nous avons donc confirmé que les trois régions germinales du télencéphale ventral, c'est-à-dire, la MGE, l'AEP/POA et le noyau triangulaire septal sont capables de générer des cellules astrogliales. D'autre part, l'immunohistochimie pour plusieurs marqueurs d'astrocytes ou de polydendrocytes, dans les embryons Nkx2.1-/- et contrôles ainsi que dans les neurosphères, a révélé une sévère perte de ces deux types gliaux chez les mutants. Nous avons trouvé que la perte de glies correspondait à une diminution de la capacité de division des précurseurs dérivés de Nkx2.1, ainsi que l'incapacité de ces précurseurs de se différencier en cellules gliales. Nous avons en effet observé une diminution importante des cellules BrdU+ en division exprimant Nkx2.1dans la MGE*, la POA* et le noyau septal* des mutants pour Nkx2.1. D'autre part, nous avons pu mettre en évidence aussi bien in vitro, qu'in vivo, que certains précurseurs Nkx2.1+ chez le mutant gardent la capacité à se différencier en neurones tandis qu'ils perdent celle de se différencier en cellules gliales. Prises dans leur ensemble, ces observations indiquent pour la première fois que le facteur de transcription Nkx2.1 régule les étapes de prolifération et de différentiation des précurseurs des trois domaines subpalliaux qui génèrent les astroglies et polydendrocytes embryonnaires précoces. Par la suite, dans le but de comprendre la fonction potentielle de ces glies précoces, nous avons procédé à de multiples colorations immunohistochimiques sur des animaux Nkx2.1-/- et sauvages, ainsi que sur des souris Nkx2.1-Cre croisées à des souris Rosa-DTA+/- dans lesquelles la toxine diphthérique hautement toxique a permis de supprimer sélectivement la majorité des cellules dérivées de Nkx2.1. De manière intéressante, nous avons observé dans ces deux mutants, une perte drastique et significative de cellules astrogliales GFAP+, GLAST+ et polydendrocytaires NG2+ et S100ß+ dans le télencéphale, à la midline et dans les aires corticales médianes. Ces pertes ont pu être directement corrélées avec des défauts de guidage axonal observés dans le corps calleux (CC), la commissure hippocampique (HIC), le fornix (F) et la commissure antérieure (AC). Le guidage axonal est une étape clé permettant aux neurones de former des connections spécifiques et de s'organiser dans un réseau fonctionnel. La contribution des cellules « guidepost » dans le CC et dans la AC comme médiateurs de la croissance des axones commissuraux à jusqu'à aujourd'hui été attribuée spécifiquement à des astroglies « guidepost » de la midline. Des résultats publiés précédemment dans notre groupe, ont permis de montrer que, pendant le développement embryonnaire, le CC est peuplé en plus de la glie par de nombreux neurones « guidepost » glutamatergiques et GABAergiques qui sont essentiels pour le croisement correct des axones callosaux à la midline. Ainsi, la contribution relative des populations individuelles neuronales ou gliales pour le guidage des axones commissuraux demande à être approfondie afin de mieux comprendre les mécanismes de guidage. A ces fins, nous avons croisé des souris Nkx2.1-Cre avec des souris NSE-DTA+/- qui expriment la toxine diphthérique uniquement dans les neurones et ainsi, nous avons pu sélectivement supprimer les neurones dérivés de domaines Nkx2.1+. Dans les souris Nkx2.1-/-,nous avons découvert que le CC était désorganisé avec des axones callosaux perdant partiellement leur orientation, alors que dans les souris Nkx2.1Cre+/Rosa-DTA+/- et Nkx2.1Cre+/NSE-DTA+/-, l'organisation axonale n'était pas affectée. De plus, les faisceaux hippocampiques du fornix étaient défasciculés dans les trois types de mutants. Par ailleurs, la formation de la commissure antérieure (AC) était complètement absente dans les souris Nkx2.1-/- d'une part, et d'autre part, celle-ci était divisée en deux à trois voies séparées dans les souris Nkx2.1Cre+/Rosa-DTA+/-. Finalement, la AC était soit absente, soit réduite de manière ne former plus qu'un faisceau relativement plus étroit dans les souris Nkx2.1Cre+/NSE-DTA+/- en comparaison avec la AC sauvage. Ces derniers résultats indiquent clairement que les cellules dérivées de Nkx2.1 à la midline, jouent un rôle majeur dans le guidage des axones commissuraux et que, autant les neurones, que les astrocytes « guidepost » dérivés de Nkx2.1, sont des éléments nécessaires au développement correct de ces commissures. En outre, lors de nos investigations sur les souris Nkx2.1-/- et Nkx2.1Cre+/Rosa-DTA+/-, nous avons remarqués des défauts sévères et similaires dans la distribution des erythrocytes et dans la morphologie du réseau de vaisseaux sanguins dans le cerveau embryonnaire des deux mutants précités. Puisque nous n'avons jamais observé de recombinaison de la Cre recombinase dans les vaisseaux sanguins des souris Nkx2.1Cre, nous en avons déduit que les défauts de vaisseaux observés étaient dus à la perte de cellules dérivées de Nkx2.1. Il existerait donc en plus de la fonction cellulaire autonome de Nkx2.1 reconnue pour régulée directement la spécification des cellules endothéliales, une fonction indirecte de Nkx2.1. Afin de déterminer la contribution respective des populations individuelles neuronales ou gliales régulées par Nkx2.1 dans la construction du réseau de vaisseaux sanguins, nous avons utilisé diverses lignées de souris transgéniques. L'utilisation de souris Nkx2.1Cre+/NSE-DTA+/- a indiqué que les neurones dérivés de Nkx2.1 n'étaient pas impliqués dans ce processus. Finalement, afin de discriminer entre les deux populations de cellules gliales dérivées de Nkx2.1, les astroglies et les polydendrocytes, nous avons croisé une lignée de souris NG2-Cre avec des souris Rosa-DTA+/-. Dans ce dernier mutant, le réseau de vaisseaux sanguins du cortex ainsi que la distribution des erythrocytes étaient affectés de la même manière que dans le cortex des souris Nkx2.1Cre+/Rosa-DTA+/-. Par conséquent, ce résultat indique que très probablement, les polydendrocytes NG2+ sont impliqués dans la mise en place du réseau de vaisseaux dans le cerveau. Prises dans leur ensemble, ces observations montrent que durant le développement embryonnaire du cerveau, des sous-populations de glies régulées par Nkx2.1 jouent un rôle de cellules « guidepost » dans le guidage des axones, ainsi que des vaisseaux. Les polydendrocytes sont impliquées dans la régulation de l'angiogenèse tandis que, autant les neurones GABAergiques que les astrocytes collaborent dans le guidage des axones commissuraux en croissance.

Preparation, maintenance, and use of serum-free aggregating brain cell cultures.

Serum-free aggregating brain cell cultures are free-floating three-dimensional primary cell cultures able to reconstitute spontaneously a histotypic brain architecture to reproduce critical steps of brain development and to reach a high level of structural and functional maturity. This culture system offers, therefore, a unique model for neurotoxicity testing both during the development and at advanced cellular differentiation, and the high number of aggregates available combined with the excellent reproducibility of the cultures facilitates routine test procedures. This chapter presents a detailed description of the preparation, maintenance, and use of these cultures for neurotoxicity studies and a comparison of the developmental characteristics between cultures derived from the telencephalon and cultures derived from the whole brain. For culture preparation, mechanically dissociated embryonic brain tissue is used. The initial cell suspension, composed of neural stem cells, neural progenitor cells, immature postmitotic neurons, glioblasts, and microglial cells, is kept in a serum-free, chemically defined medium under continuous gyratory agitation. Spherical aggregates form spontaneously and are maintained in suspension culture for several weeks. Within the aggregates, the cells rearrange and mature, reproducing critical morphogenic events, such as migration, proliferation, differentiation, synaptogenesis, and myelination. For experimentation, replicate cultures are prepared by the randomization of aggregates from several original flasks. The high yield and reproducibility of the cultures enable multiparametric endpoint analyses, including "omics" approaches.

NG2 glia are required for vessel network formation during embryonic development.

The NG2(+) glia, also known as polydendrocytes or oligodendrocyte precursor cells, represent a new entity among glial cell populations in the central nervous system. However, the complete repertoire of their roles is not yet identified. The embryonic NG2(+) glia originate from the Nkx2.1(+) progenitors of the ventral telencephalon. Our analysis unravels that, beginning from E12.5 until E16.5, the NG2(+) glia populate the entire dorsal telencephalon. Interestingly, their appearance temporally coincides with the establishment of blood vessel network in the embryonic brain. NG2(+) glia are closely apposed to developing cerebral vessels by being either positioned at the sprouting tip cells or tethered along the vessel walls. Absence of NG2(+) glia drastically affects the vascular development leading to severe reduction of ramifications and connections by E18.5. By revealing a novel and fundamental role for NG2(+) glia, our study brings new perspectives to mechanisms underlying proper vessels network formation in embryonic brains.

Distribution of microglial cells in the cerebral hemispheres of embryonic and neonatal chicks

The distribution, morphology and morphometry of microglial cells in the chick cerebral hemispheres from embryonic day 4 (E4) to the first neonatal day (P1) were studied by histochemical labeling with a tomato (Lycopersicon esculentum) lectin. The histochemical analysis revealed lectin-reactive cells in the nervous parenchyma on day E4. Between E4 (5.7 ± 1.35 mm length) and E17 (8.25 ± 1.2 mm length), the lectin-reactive cells were identified as ameboid microglia and observed starting from the subventricular layer, distributed throughout the mantle layer and in the proximity of the blood vessels. After day E13, the lectin-reactive cells exhibited elongated forms with small branched processes, and were considered primitive ramified microglia. Later, between E18 (5.85 ± 1.5 mm cell body length) and P1 (3.25 ± 0.6 mm cell body length), cells with more elongated branched processes were observed, constituting the ramified microglia. Our findings provide additional information on the migration and differentiation of microglial cells, whose ramified form is observed at the end of embryonic development. The present paper focused on the arrangement of microglial cells in developing cerebral hemispheres of embryonic and neonatal chicks, which are little studied in the literature. Details of morphology, morphometry and spatial distribution of microglial cells contributed to the understanding of bird and mammal central nervous system ontogeny. Furthermore, the identification and localization of microglial cells during the normal development could be used as a morphological guide for embryonic brain injury researches.

Loss of function of the tuberous sclerosis 2 tumor suppressor gene results in embryonic lethality characterized by disrupted neuroepithelial growth and development

Germline defects in the tuberous sclerosis 2 (TSC2) tumor suppressor gene predispose humans and rats to benign and malignant lesions in a variety of tissues. The brain is among the most profoundly affected organs in tuberous sclerosis (TSC) patients and is the site of development of the cortical tubers for which the hereditary syndrome is named. A spontaneous germline inactivation of the Tsc2 locus has been described in an animal model, the Eker rat. We report that the homozygous state of this mutation (Tsc2Ek/Ek) was lethal in mid-gestation (the equivalent of mouse E9.5–E13.5), when Tsc2 mRNA was highly expressed in embryonic neuroepithelium. During this period homozygous mutant Eker embryos lacking functional Tsc2 gene product, tuberin, displayed dysraphia and papillary overgrowth of the neuroepithelium, indicating that loss of tuberin disrupted the normal development of this tissue. Interestingly, there was significant intraspecies variability in the penetrance of cranial abnormalities in mutant embryos: the Long–Evans strain Tsc2Ek/Ek embryos displayed these defects whereas the Fisher 344 homozygous mutant embryos had normal-appearing neuroepithelium. Taken together, our data indicate that the Tsc2 gene participates in normal brain development and suggest the inactivation of this gene may have similar functional consequences in both mature and embryonic brain.

The novel cytoskeleton-associated protein Neuronal protein 22: Elevated expression in the developing rat brain

Neuronal development and process targeting is mediated by proteins of the cytoskeleton. However, the signaling pathways underlying these mechanisms are complex and have not yet been fully elucidated. Neuronal protein 22 (NP22) has been identified as a cytoskeleton-associated protein. It colocalizes with microtubules and actin, the two major components of the cytoskeleton. It contains numerous signaling motifs and induces process formation in non-neuronal cells. Expression of rat NP22 (rNP22) rises incrementally at specific time points during brain development, with the greatest elevation occurring during synaptogenesis in the rat brain. its neuronal localization is primarily at the plasma membrane of the soma in the embryonic brain and progresses into homogeneous expression in the postnatal rat brain. Data suggest that NP22 may play a role in mediating the molecular events governing development of the neuronal architecture. Furthermore, its sustained expression in postnatal brain implies a function in the maintenance of neuronal morphology.

Altered adhesion, proliferation and death in neural cultures from adults with schizophrenia

The causes of schizophrenia are unknown, but there is evidence linking subtle deviations in neural development with schizophrenia. Embryonic brain development cannot be studied in an adult with schizophrenia, but neurogenesis and early events in neuronal differentiation can be investigated throughout adult life in the human olfactory epithelium. Our past research has demonstrated that neuronal cultures can be derived from biopsy of the human adult olfactory epithelium. In the present study, we examined mechanisms related to neurogenesis and neuronal differentiation in adults with schizophrenia versus well controls. Forty biopsies were collected under local anaesthesia from ten individuals with DSM III-R schizophrenia and ten age- and sex-matched well controls. All patients, except one, were receiving antipsychotic medication at the time of the biopsy, Immunostaining for neuronal markers indicated that neurogenesis occurred in the biopsies from both patients and controls since all contained cells expressing tubulin and/or olfactory marker protein. The major findings of this study are: 1. biopsies from patients with schizophrenia showed a significantly reduced ability to attach to the culture slide: 29.9% of patient biopsies attached compared to 73.5% of control biopsies; 2. biopsies from patients with schizophrenia had a significantly greater proportion of cells undergoing mitosis: 0.69% in the patients compared to 0.29% in the controls; and 3. dopamine (10 mu M) significantly increased the proportion of apoptotic cells in the control cultures but significantly decreased the proportion in patients' cultures. (C) 1999 Elsevier Science B.V. All rights reserved.

A novel function of the proneural factor Ascl1 in progenitor proliferation identified by genome-wide characterization of its targets

Proneural genes such as Ascl1 are known to promote cell cycle exit and neuronal differentiation when expressed in neural progenitor cells. The mechanisms by which proneural genes activate neurogenesis--and, in particular, the genes that they regulate--however, are mostly unknown. We performed a genome-wide characterization of the transcriptional targets of Ascl1 in the embryonic brain and in neural stem cell cultures by location analysis and expression profiling of embryos overexpressing or mutant for Ascl1. The wide range of molecular and cellular functions represented among these targets suggests that Ascl1 directly controls the specification of neural progenitors as well as the later steps of neuronal differentiation and neurite outgrowth. Surprisingly, Ascl1 also regulates the expression of a large number of genes involved in cell cycle progression, including canonical cell cycle regulators and oncogenic transcription factors. Mutational analysis in the embryonic brain and manipulation of Ascl1 activity in neural stem cell cultures revealed that Ascl1 is indeed required for normal proliferation of neural progenitors. This study identified a novel and unexpected activity of the proneural gene Ascl1, and revealed a direct molecular link between the phase of expansion of neural progenitors and the subsequent phases of cell cycle exit and neuronal differentiation.

Genetische Mechanismen der dorsoventralen Musterbildung im embryonalen Gehirn von Drosophila

In Vertebraten und Insekten ist während der frühen Entwicklung des zentralen Nervensystems (ZNS), welches sich aus dem Gehirn und dem ventralen Nervensystem (VNS) zusammensetzt, die Unterteilung des Neuroektoderms (NE) in diskrete Genexpressions-Domänen entscheidend für die korrekte Spezifizierung neuraler Stammzellen. In Drosophila wird die Identität dieser Stammzellen (Neuroblasten, NB) festgelegt durch die positionellen Informationen, welche von den Produkten früher Musterbildungsgene bereitgestellt werden und das Neuroektoderm in anteroposteriorer (AP) und dorsoventraler (DV) Achse unterteilen. Die molekulargenetischen Mechanismen, welche der DV-Regionalisierung zugrunde liegen, wurden ausführlich im embryonalen VNS untersucht, sind für das Gehirn jedoch weitestgehend unverstanden. rnIm Rahmen dieser Arbeit wurden neue Erkenntnisse bezüglich der genetischen Mechanismen gewonnen, welche die frühembryonale Anlage des Gehirns in DV-Achse unterteilen. So konnte gezeigt werden, dass das cephale Lückengen empty spiracles (ems), das Segmentpolaritätsgen engrailed (en), sowie der „Epidermal growth factor receptor“ (EGFR) und das Gen Nk6 homeobox (Nkx6) für Faktoren codieren, die als zentrale Regulatoren die DV Musterbildung in der Gehirnanlage kontrollieren. Diese Faktoren interagieren zusammen mit den ebenso evolutionär konservierten Homöobox-Genen ventral nervous system defective (vnd), intermediate neuroblasts defective (ind) und muscle segment homeobox (msh) in einem komplexen, regulatorischen DV-Netzwerk. Die im Trito (TC)- und Deutocerebrum (DC) entschlüsselten genetischen Interaktionen basieren überwiegend auf wechselseitiger Repression. Dementsprechend sorgen 1) Vnd und Ems durch gegenseitige Repression für eine frühe DV-Unterteilung des NE, und 2) wechselseitige Repression zwischen Nkx6 und Msh, als auch zwischen Ind und Msh für die Aufrechterhaltung der Grenze zwischen intermediärem und dorsalem NE. 3) Sowohl Ind als auch Msh sind in der Lage, die Expression von vnd zu inhibieren. Ferner konnte gezeigt werden, dass Vnd durch Repression von Msh als positiver Regulator von Nkx6 fungiert. Überdies beeinflusst Vnd die Expression von ind in segment-spezifischer Art und Weise: Vnd reprimiert ind-Expression im TC, sorgt jedoch für eine positive Regulation von ind im DC durch Repression von Msh. Auch der EGFR-Signalweg ist an der frühen DV-Regionalisierung des Gehirns beteiligt, indem er durch positive Regulation der msh-Repressoren Vnd, Ind und Nkx6 dazu beiträgt, dass die Expression von msh auf dorsales NE beschränkt bleibt. Ferner stellte sich heraus, dass das AP-Musterbildungsgen ems die Expression der DV-Gene kontrolliert und umgekehrt: Ems ist für die Aktivierung von Nkx6, ind und msh in TC und DC erforderlich ist, während Nkx6 und Ind zu einem späteren Zeitpunkt benötigt werden, um ems im intermediären DC gemeinsam zu reprimieren. Überdies konnte gezeigt werden, dass das Segmentpolaritätsgen en Aspekte der Expression von vnd, ind und msh in segment-spezifischer Art und Weise reguliert. En reprimiert ind und msh, hält jedoch vnd-Expression im DC aufrecht; im TC wird En benötigt, um die Expression von Msh herunter zu regulieren und somit die Aktivierung von ind dort zu ermöglichen.rnrnZusammengenommen zeigen diese Ergebnisse, dass AP Musterbildungsfaktoren in umfangreichen Maß die Expression der DV Gene im Gehirn (und VNS) kontrollieren. Ferner deuten diese Daten darauf hin, dass sich das „Konzept der ventralen Dominanz“, welches für die DV-Musterbildung im VNS postuliert wurde, nicht auf das genregulatorische Netzwerk im Gehirn übertragen lässt, da Interaktionen zwischen den beteiligten Faktoren hauptsächlich auf wechselseitiger (und nicht einseitiger) Repression basieren. Zudem scheint das Konzept der ventralen Dominanz auch für das VNS nicht uneingeschränkt zu gelten, da in dieser Arbeit u.a. gezeigt werden konnte, dass dorsal exprimiertes Msh in der Lage ist, intermediäres ind zu reprimieren. Interessanterweise ist gegenseitige Repression von Homöodomänen-Proteinen im sich entwickelnden Neuralrohr von Vertebraten weit verbreitet und darüberhinaus essenziell für den Aufbau diskreter DV-Vorläuferdomänen, und weist insofern eine große Ähnlichkeit zu den in dieser Arbeit beschriebenen DV-Musterbildungsvorgängen im frühembryonalen Fliegengehirn auf.rn

Postnatal mouse subventricular zone neuronal precursors can migrate and differentiate within multiple levels of the developing neuraxis

The mammalian subventricular zone (SVZ) of the lateral wall of the forebrain ventricle retains a population of proliferating neuronal precursors throughout life. Neuronal precursors born in the postnatal and adult SVZ migrate to the olfactory bulb where they differentiate into interneurons. Here we tested the potential of mouse postnatal SVZ precursors in the environment of the embryonic brain: (i) a ubiquitous genetic marker, (ii) a neuron-specific transgene, and (iii) a lipophilic-dye were used to follow the fate of postnatal day 5–10 SVZ cells grafted into embryonic mouse brain ventricles at day 15 of gestation. Graft-derived cells were found at multiple levels of the neuraxis, including septum, thalamus, hypothalamus, and in large numbers in the midbrain inferior colliculus. We observed no integration into the cortex. Neuronal differentiation of graft derived cells was demonstrated by double-staining with neuron-specific β-tubulin antibodies, expression of the neuron-specific transgene, and the dendritic arbors revealed by the lipophilic dye. We conclude that postnatal SVZ cells can migrate through and differentiate into neurons within multiple embryonic brain regions other than the olfactory bulb.