Your search keyword '"Ganglion mother cell"' showing total 383 results

1. Neurogenesis in the Insect Central Nervous System and Its Peculiarities in the Brain Mushroom Bodies.

Author

Panov, A. A.

Abstract

Neurogenesis is divided into two main stages: proliferation and differentiation. Neural stem cells were discovered in insects almost a century and a half ago, in 1885, by A.A. Korotneff who called them ganglion cells, while the term neuroblast was introduced by W.M. Wheeler in 1891. Neurogenesis was initially considered a singlestage process, and the smaller daughter cells of the neuroblast were believed to differentiate directly into nerve cells. V. Bauer in 1904 described the ganglion mother cell as a distinct stage and thus established the two-stage nature of neurogenesis. More than a century later, it was found out that two-stage neurogenesis was not the only possible type, and one more, three-stage type was discovered. The latter includes an additional link between the neuroblast and the ganglion mother cell, termed the intermediate neural progenitor. Correspondingly, the traditional neuroblasts are currently termed type I neuroblasts, and those giving rise to intermediate neural progenitors are termed type II neuroblasts. The modern stage of neurogenesis research is characterized by the range of study objects narrowed down practically to a single species, Drosophila melanogaster, and also by application of a great variety of molecular genetic methods capable of revealing the finest mechanisms of neurogenesis. Four different patterns of solitary type I neuroblast activity during insect development have been revealed: (1) only during the embryonic stage; (2) continuously in embryos and larvae; (3) intermittent with a period of quiescence during the late embryonic and the early larval stage; (4) two independent generations of neuroblasts: embryonic and postembryonic. The initial stage of neurogenesis in the mushroom bodies is characterized by longer mitotic activity of neuroblasts and the presence of clusters of neuroblasts of different origins. Some neuroblasts of the mushroom bodies may be type II neuroblasts. A variety of Kenyon cells, the intrinsic cells of the mushroom bodies, is formed at the second stage of neurogenesis. Similar to the descendants of solitary neuroblasts in the cortex, the type of Kenyon cells depends on the time of their formation. [ABSTRACT FROM AUTHOR]

Published

2022

2. Tens versus Four: Two Generations of Neural Progenitors in the Developing Mushroom Bodies of Muscina prolapsa Harris (Diptera, Muscidae).

Author

Panov, A. A.

Abstract

Neurogenesis in the mushroom bodies was studied throughout the larval and pupal development of Muscina prolapsa. The existence of two generations of neural progenitors in the mushroom bodies of insects was established for the first time. Each larval mushroom body has four neuroblasts that divide as type I neuroblasts, producing a daughter neuroblast and a ganglion mother cell. The latter divides symmetrically into two cells that differentiate into Kenyon cells. In the young pupae, 8–11 cells surrounding each neuroblast of the mushroom body and morphologically indistinguishable from ganglion mother cells grow in size and transform into secondary neuroblasts, which repeatedly divide asymmetrically into a daughter secondary neuroblast and a typical ganglion mother cell. Divisions of secondary neuroblasts continue from the 3rd to the 7th day after puparium formation, and during the 7th day, secondary neuroblasts die massively through apoptosis. The fate of four neuroblasts of the larval mushroom body remains obscure. [ABSTRACT FROM AUTHOR]

Published

2020

3. Tens versus Four: Two Generations of Neural Progenitors in the Developing Mushroom Bodies of Muscina prolapsa Harris (Diptera, Muscidae)

Author

A. A. Panov

Subjects

Larva, animal structures, fungi, Neurogenesis, Biology, biology.organism_classification, Ganglion, Cell biology, medicine.anatomical_structure, nervous system, Neuroblast, Insect Science, Muscidae, embryonic structures, Mushroom bodies, medicine, Progenitor cell, Ganglion mother cell, reproductive and urinary physiology

Abstract

Neurogenesis in the mushroom bodies was studied throughout the larval and pupal development of Muscina prolapsa. The existence of two generations of neural progenitors in the mushroom bodies of insects was established for the first time. Each larval mushroom body has four neuroblasts that divide as type I neuroblasts, producing a daughter neuroblast and a ganglion mother cell. The latter divides symmetrically into two cells that differentiate into Kenyon cells. In the young pupae, 8–11 cells surrounding each neuroblast of the mushroom body and morphologically indistinguishable from ganglion mother cells grow in size and transform into secondary neuroblasts, which repeatedly divide asymmetrically into a daughter secondary neuroblast and a typical ganglion mother cell. Divisions of secondary neuroblasts continue from the 3rd to the 7th day after puparium formation, and during the 7th day, secondary neuroblasts die massively through apoptosis. The fate of four neuroblasts of the larval mushroom body remains obscure.

Published

2020

4. Lineage analysis as an analytical tool in the insect central nervous system: Bringing order to interneurons

Author

Boyan, G. S., Williams, J. L. D., Breidbach, O., editor, and Kutsch, W., editor

Published

1995

5. Neural Development in Insects: Neuron Birth, Pathfinding, Synaptogenesis, Competition

Author

Blagburn, Jonathan M., Bacon, Jonathan P., Raymond, Pamela A., editor, Easter, Stephen S., Jr., editor, and Innocenti, Giorgio M., editor

Published

1990

6. Proliferation and Differentiation: Two Sequential Stages of Proliferative Center Activity in Embryonic Mushroom Bodies of Three Orthopterans, Gryllus bimaculatus Deg., Acheta domesticus L., and Schistocerca gregaria Forsk. (Insecta: Orthoptera)

Author

A. A. Panov

Subjects

0106 biological sciences, 0301 basic medicine, animal structures, biology, Orthoptera, Gryllus bimaculatus, fungi, Neurogenesis, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Cell biology, 03 medical and health sciences, 030104 developmental biology, nervous system, Neuroblast, Acheta, Mushroom bodies, Schistocerca, General Agricultural and Biological Sciences, Ganglion mother cell

Abstract

It is shown for the first time that, in three orthopterans (Gryllus bimaculatus, Acheta domesticus, and Schistocerca gregaria), the mushroom body proliferative centers pass two sequential stages of neurogenesis. At the first stage, they are built by symmetrically dividing proneuroblasts the activity of which augments the pool of the stem cells. At the beginning of the second stage, proneuroblasts transform into asymmetrically dividing mushroom body neuroblasts. Similarly to solitary neuroblasts, they give rise to daughter neuroblast and the ganglion mother cell, which divides symmetrically into two cells differentiating into the Kenyon cells. It is believed that the discovered course of neurogenesis in the embryonic proliferative centers of orthopteran mushroom bodies recalls the pattern described in the optic Anlagen of Drosophila melanogaster and other insects.

Published

2019

7. A conserved nuclear receptor, Tailless, is required for efficient proliferation and prolonged maintenance of mushroom body progenitors in the Drosophila brain

Author

Kurusu, Mitsuhiko, Maruyama, Yasushi, Adachi, Yoshitsugu, Okabe, Masataka, Suzuki, Emiko, and Furukubo-Tokunaga, Katsuo

Subjects

*NUCLEAR receptors (Biochemistry), *CELL proliferation, *NEURAL development, *DROSOPHILA, *NEURONS, *GENETIC mutation, *CELL cycle

Abstract

Abstract: The intrinsic neurons of mushroom bodies (MBs), centers of olfactory learning in the Drosophila brain, are generated by a specific set of neuroblasts (Nbs) that are born in the embryonic stage and exhibit uninterrupted proliferation till the end of the pupal stage. Whereas MB provides a unique model to study proliferation of neural progenitors, the underlying mechanism that controls persistent activity of MB-Nbs is poorly understood. Here we show that Tailless (TLL), a conserved orphan nuclear receptor, is required for optimum proliferation activity and prolonged maintenance of MB-Nbs and ganglion mother cells (GMCs). Mutations of tll progressively impair cell cycle in MB-Nbs and cause premature loss of MB-Nbs in the early pupal stage. TLL is also expressed in MB-GMCs to prevent apoptosis and promote cell cycling. In addition, we show that ectopic expression of tll leads to brain tumors, in which Prospero, a key regulator of progenitor proliferation and differentiation, is suppressed whereas localization of molecular components involved in asymmetric Nb division is unaffected. These results as a whole uncover a distinct regulatory mechanism of self-renewal and differentiation of the MB progenitors that is different from the mechanisms found in other progenitors. [Copyright &y& Elsevier]

Published

2009

8. Dual role for DOCK7 in tangential migration of interneuron precursors in the postnatal forebrain

Author

Yilin Tai, Nicholas B. Gallo, Jia Ray Yu, Shinichi Nakamuta, Yu-Ting Yang, Chia-Lin Wang, and Linda Van Aelst

Subjects

rho GTP-Binding Proteins, 0301 basic medicine, Rostral migratory stream, Cellular differentiation, Primary Cell Culture, Biology, Microtubules, Article, Mice, Myosin-Light-Chain Phosphatase, 03 medical and health sciences, Prosencephalon, Neuroblast, Cell Movement, Cell Line, Tumor, Neuroblast migration, Somal translocation, Animals, Guanine Nucleotide Exchange Factors, Humans, reproductive and urinary physiology, Research Articles, Neurons, GTPase-Activating Proteins, Gene Expression Regulation, Developmental, Cell Differentiation, Cell Biology, Anatomy, Embryo, Mammalian, Actins, Olfactory bulb, Cell biology, HEK293 Cells, 030104 developmental biology, Animals, Newborn, nervous system, embryonic structures, Forebrain, rhoA GTP-Binding Protein, Proto-Oncogene Proteins c-akt, Ganglion mother cell, HeLa Cells, Signal Transduction

Abstract

Neuroblasts born postnatally in the ventricular–subventricular zone migrate long distances via the rostral migratory stream (RMS) to the olfactory bulb. Nakamuta et al. show that DOCK7 drives tangential migration of neuroblasts in the RMS by controlling both leading process extension and somal translocation through Rac-dependent and myosin phosphatase–RhoA–interacting protein-dependent pathways, respectively., Throughout life, stem cells in the ventricular–subventricular zone generate neuroblasts that migrate via the rostral migratory stream (RMS) to the olfactory bulb, where they differentiate into local interneurons. Although progress has been made toward identifying extracellular factors that guide the migration of these cells, little is known about the intracellular mechanisms that govern the dynamic reshaping of the neuroblasts’ morphology required for their migration along the RMS. In this study, we identify DOCK7, a member of the DOCK180-family, as a molecule essential for tangential neuroblast migration in the postnatal mouse forebrain. DOCK7 regulates the migration of these cells by controlling both leading process (LP) extension and somal translocation via distinct pathways. It controls LP stability/growth via a Rac-dependent pathway, likely by modulating microtubule networks while also regulating F-actin remodeling at the cell rear to promote somal translocation via a previously unrecognized myosin phosphatase–RhoA–interacting protein-dependent pathway. The coordinated action of both pathways is required to ensure efficient neuroblast migration along the RMS.

Published

2017

9. Magnetic resonance imaging of odorant activity-dependent migration of neural precursor cells and olfactory bulb growth

Author

Leonardo Belluscio, Stephen J. Dodd, Timothy J. Schoenfeld, Heather A. Cameron, Diana M. Cummings, Nikorn Pothayee, and Alan P. Koretsky

Subjects

Male, 0301 basic medicine, Rostral migratory stream, Neurogenesis, Cognitive Neuroscience, Subventricular zone, Biology, Article, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, Neural Stem Cells, Neuroblast, Cell Movement, Neuroblast migration, medicine, Animals, Magnetic Resonance Imaging, Olfactory Bulb, Neural stem cell, Rats, Olfactory bulb, 030104 developmental biology, medicine.anatomical_structure, nervous system, Neurology, Odorants, Ganglion mother cell, Neuroscience, 030217 neurology & neurosurgery

Abstract

Neural progenitors or neuroblasts are produced by precursor cells in the subventricular zone (SVZ) and migrate along the rostral migratory stream (RMS) to the olfactory bulbs (OB) throughout life. In the OB, these adult born neurons either die or replace existing olfactory interneurons, playing a critical role in the stabilization of OB circuitry. Although several aspects of the addition of new neurons into the OB have been studied, it is unclear whether long-distance activity from the OB can regulate the influx of migrating neuroblasts along the RMS. In this study, iron oxide-assisted MRI was used to track the migration of neuroblasts in combination with reversible naris occlusion to manipulate odorant-induced activity. It was found that decreasing olfactory activity led to a decrease in the rate of neuroblast migration along the RMS. Removal of the naris occlusion led to an increase in migratory rate back to control levels, indicating that olfactory activity has regulatory function on neuroblast migration in the RMS. Blocking odorant activity also led to an arrest in OB growth and re-opening the block led to a rapid re-growth returning the bulb size to control levels. Furthermore, pharmacogenetic elimination of the neuroblasts demonstrated that they were required for re-growth of the bulb following sensory deprivation. Together, these results show that sensory activity, neural migration and OB growth are tightly coupled in an interdependent manner.

Published

2017

10. BACE1 Deficiency Causes Abnormal Neuronal Clustering in the Dentate Gyrus

Author

Xiangyou Hu, Qingyuan Fan, Riqiang Yan, Wanxia He, Hailong Hou, and Hoonkyo Suh

Subjects

0301 basic medicine, Biochemistry, Subgranular zone, Mice, Neural Stem Cells, doublecortin, Cell Movement, granule cell layer, Aspartic Acid Endopeptidases, Reelin, lcsh:QH301-705.5, Neurons, lcsh:R5-920, neuronal migration, Extracellular Matrix Proteins, subpial zone, biology, Serine Endopeptidases, Neurogenesis, BACE1, Anatomy, medicine.anatomical_structure, lcsh:Medicine (General), Alzheimer's secretase, Cell Adhesion Molecules, Neuronal, Nerve Tissue Proteins, Article, 03 medical and health sciences, Neuroblast, meninges, reelin, mental disorders, Genetics, medicine, Animals, Dentate gyrus, neuronal cluster, Cell Biology, Granule cell, subgranular zone, Doublecortin, Mice, Inbred C57BL, Reelin Protein, 030104 developmental biology, lcsh:Biology (General), nervous system, Dentate Gyrus, biology.protein, Amyloid Precursor Protein Secretases, Ganglion mother cell, Neuroscience, Gene Deletion, Developmental Biology

Abstract

Summary BACE1 is validated as Alzheimer's β-secretase and a therapeutic target for Alzheimer's disease. In examining BACE1-null mice, we discovered that BACE1 deficiency develops abnormal clusters of immature neurons, forming doublecortin-positive neuroblasts, in the developing dentate gyrus, mainly in the subpial zone (SPZ). Such clusters were rarely observed in wild-type SPZ and not reported in other mouse models. To understand their origins and fates, we examined how neuroblasts in BACE1-null SPZ mature and migrate during early postnatal development. We show that such neuroblasts are destined to form Prox1-positive granule cells in the dentate granule cell layer, and mainly mature to form excitatory neurons, but not inhibitory neurons. Mechanistically, higher levels of reelin potentially contribute to abnormal neurogenesis and timely migration in BACE1-null SPZ. Altogether, we demonstrate that BACE1 is a critical regulator in forming the dentate granule cell layer through timely maturation and migration of SPZ neuroblasts., Graphical Abstract, Highlights • BACE1 deficiency causes abnormal neuronal clusters retained in the mouse SPZ • Mis-migrated neural progenitor cells in the SPZ are destined to form granule cells • Such neural progenitor cells form excitatory neurons but not inhibitor neurons • Elevated levels of reelin contribute to abnormal neuronal maturation and migration, In this article, Yan and colleagues show that BACE1 is required for the proper formation of the granule cell layer. BACE1 deficiency in mice induces retention of clustered doublecortin-positive neuroblasts in the subpial zone (SPZ) and marginal zone (MZ). Upregulation of reelin in Cajal-Retzius cells likely causes timely migration of neuroblasts in SPZ/MZ to form Prox1-positive granule cells.

Published

2017

11. Endocytosis-independent mechanisms of Delta ligand proteolysis

Author

Delwig, Anton, Bland, Christin, Beem-Miller, Micah, Kimberly, Priscilla, and Rand, Matthew D.

Subjects

*ENDOCYTOSIS, *CYTOLOGICAL research, *PROTEOLYSIS, *CELL membranes, *ABSORPTION (Physiology), *CELL physiology

Abstract

Abstract: Delta proteins function as cell surface ligands for Notch receptors in a highly conserved signal transduction mechanism. Delta activates Notch by “trans-endocytosis”, whereby endocytosis of Delta that is in complex with Notch on a neighboring cell induces activating cleavages in Notch. Alternatively, proteolysis of Delta renders the ligand inactive by dissociating the extracellular and cytosolic domains. How proteolysis and trans-endocytosis cooperate in Delta function is not well understood. We now show that Drosophila Delta proteolysis occurs independent of and prior to endocytosis in neuroblasts and ganglion mother cells in vivo and cells in culture. Delta cleavage occurs at two novel sites that we identify in the juxtamembrane (JM) and transmembrane (TM) domains. In addition to the previously identified Kuzbanian ADAM protease, which acts on the JM domain, proteolysis in the TM domain is facilitated by a thiol-sensitive aspartyl protease that is distinct from Presenilin. Furthermore, cleavage in the TM domain is upregulated in the presence of Notch. Overall, Drosophila Delta proteolysis differs from the conventional regulated intramembrane proteolysis (RIP) mechanism by two criteria: (1) TM-domain processing of Delta is not sensitive to Presenilin, and (2) TM and JM domain cleavages occur independently of each other. Altogether, these data support a model whereby proteolysis can modulate Delta ligand activity independently of endocytosis. [Copyright &y& Elsevier]

Published

2006

12. Identification of novel Drosophila neural precursor genes using a differential embryonic head cDNA screen

Author

Brody, Thomas, Stivers, Chad, Nagle, James, and Odenwald, Ward F.

Subjects

*DROSOPHILA, *NEUROBLASTOMA, *GENE expression

Abstract

During Drosophila neuroblast lineage development, temporally ordered transitions in neuroblast gene expression have been shown to accompany the changing repertoire of functionally diverse cells generated by neuroblasts. To broaden our understanding of the biological significance of these ordered transitions in neuroblast gene expression and the events that regulate them, additional genes have been sought that participate in the timing and execution of these temporally controlled events. To identify dynamically expressed neural precursor genes, we have performed a differential cDNA hybridization screen on a stage specific embryonic head cDNA library, followed by whole-mount embryo in situ hybridizations. Described here are the embryonic expression profiles of 57 developmentally regulated neural precursor genes. Information about 2389 additional genes identified in this screen, including 1614 uncharacterized genes, is available on-line at ‘BrainGenes: a search for Drosophila neural precursor genes’ (http://sdb.bio.purdue.edu/fly/brain/ahome.htm). [Copyright &y& Elsevier]

Published

2002

13. Asymmetric Cell Division in Drosophila Neuroblasts

Author

Chwee Tat Koe and Hongyan Wang

Subjects

0301 basic medicine, biology, Spindle orientation, biology.organism_classification, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Neuroblast, Asymmetric cell division, Cleavage furrow, Drosophila (subgenus), Ganglion mother cell, 030217 neurology & neurosurgery

Published

2016

14. C. elegans HAM-1 functions in the nucleus to regulate asymmetric neuroblast division

Author

Pavitra S. Ramachandran, Nancy Hawkins, Khang Hua, Amy Leung, Kyla Hingwing, Maria Wu, and Pei Luan Koh

Subjects

0301 basic medicine, Molecular Sequence Data, Nerve Tissue Proteins, Biology, 03 medical and health sciences, Neuroblast, Neural Stem Cells, Cell cortex, medicine, Asymmetric cell division, Animals, Cell Lineage, ham-1, Amino Acid Sequence, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Cell Nucleus, Neurons, Asymmetric Cell Division, Cell Biology, Cell biology, Nuclear localization, Cell nucleus, 030104 developmental biology, medicine.anatomical_structure, C. elegans, Nucleus, Ganglion mother cell, Nuclear localization sequence, Asymmetric neuroblast division, Developmental Biology

Abstract

All 302 neurons in the C. elegans hermaphrodite arise through asymmetric division of neuroblasts. During embryogenesis, the C. elegans ham-1 gene is required for several asymmetric neuroblast divisions in lineages that generate both neural and apoptotic cells. By antibody staining, endogenous HAM-1 is found exclusively at the cell cortex in many cells during embryogenesis and is asymmetrically localized in dividing cells. Here we show that in transgenic embryos expressing a functional GFP::HAM-1 fusion protein, GFP expression is also detected in the nucleus, in addition to the cell cortex. Consistent with the nuclear localization is the presence of a putative DNA binding winged-helix domain within the N-terminus of HAM-1. Through a deletion analysis we determined that the C-terminus of the protein is required for nuclear localization and we identified two nuclear localization sequences (NLSs). A subcellular fractionation experiment from wild type embryos, followed by Western blotting, revealed that endogenous HAM-1 is primarily found in the nucleus. Our analysis also showed that the N-terminus is necessary for cortical localization. While ham-1 function is essential for asymmetric division in the lineage that generates the PLM mechanosensory neuron, we showed that cortical localization may not required. Thus, our results suggest that there is a nuclear function for HAM-1 in regulating asymmetric neuroblast division and that the requirement for cortical localization may be lineage dependent.

Published

2016

15. Lin28B and Let-7 in the Control of Sympathetic Neurogenesis and Neuroblastoma Development

Author

Marco Kramer, Melanie Hennchen, Isabelle Janoueix-Lerosey, Olivier Delattre, Cécile Pierre-Eugène, Jutta Stubbusch, Thomas Deller, Ikram Abarchan-El Makhfi, Johannes B. Schulte, Uwe Ernsberger, and Hermann Rohrer

Subjects

medicine.medical_specialty, Mice, 129 Strain, Sympathetic Nervous System, Chick Embryo, Biology, Mice, Neuroblastoma, Neuroblast, Internal medicine, Adrenal Glands, medicine, Animals, Progenitor cell, Cell Proliferation, Ganglia, Sympathetic, Neuronal Plasticity, Neuroblast proliferation, Brain Neoplasms, Stem Cells, General Neuroscience, Neurogenesis, RNA-Binding Proteins, Articles, medicine.disease, Sympathetic ganglion, Cell biology, DNA-Binding Proteins, MicroRNAs, medicine.anatomical_structure, Endocrinology, Adrenal medulla, Ganglion mother cell

Abstract

The RNA binding protein Lin28B is expressed in developing tissues and sustains stem and progenitor cell identity as a negative regulator of theLet-7family of microRNAs, which induces differentiation. Lin28B is activated in neuroblastoma (NB), a childhood tumor in sympathetic ganglia and adrenal medulla. Forced expression of Lin28B in embryonic mouse sympathoadrenal neuroblasts elicits postnatal NB formation. However, the normal function of Lin28B in the development of sympathetic neurons and chromaffin cells and the mechanisms involved in Lin28B-induced tumor formation are unclear. Here, we demonstrate a mirror-image expression ofLin28BandLet-7ain developing chick sympathetic ganglia.Lin28Bexpression is not restricted to undifferentiated progenitor cells but, is observed in proliferating noradrenergic neuroblasts.Lin28knockdown in cultured sympathetic neuroblasts decreases proliferation, whereasLet-7inhibition increases the proportion of neuroblasts in the cell cycle. Lin28B overexpression enhances proliferation, but only during a short developmental period, and it does not reduceLet-7a. Effects ofin vivo Lin28Boverexpression were analyzed in theLSL-Lin28BDBHiCremouse line. Sympathetic ganglion and adrenal medulla volume and the expression level ofLet-7awere not altered, althoughLin28Bexpression increased by 12- to 17-fold. In contrast,Let-7aexpression was strongly reduced inLSL-Lin28BDbhiCreNB tumor tissue. These data demonstrate essential functions for endogenousLin28andLet-7in neuroblast proliferation. However,Lin28Boverexpression neither sustains neuroblast proliferation nor affects let-7 expression. Thus, in contrast to other pediatric tumors,Lin28B-induced NB is not due to expansion of proliferating embryonic neuroblasts, and Let-7-independent functions are implicated during initial NB development.SIGNIFICANCE STATEMENTLin28A/B proteins are highly expressed in early development and maintain progenitor cells by blocking the biogenesis and differentiation function of Let-7 microRNAs. Lin28B is aberrantly upregulated in the childhood tumor neuroblastoma (NB). NB develops in sympathetic ganglia and adrenal medulla and is elicited by forced Lin28B expression. We demonstrate that Lin28A/B and Let-7 are essential for sympathetic neuroblast proliferation during normal development. Unexpectedly, Lin28B upregulation in a mouse model does not affect neuroblast proliferation, ganglion size, and Let-7 expression during early postnatal development. Lin28B-induced NB, in contrast to other pediatric cancers, does not evolve from neuroblasts that continue to divide and involves Let-7-independent functions during initial development.

Published

2015

16. Size matters! Aurora A controls Drosophila larval development

Author

Stéphanie Le Bras, Lucie Vaufrey, Christine Balducci, René Lafont, Claude Prigent, Institut de Génétique et Développement de Rennes ( IGDR ), Université de Rennes 1 ( UR1 ), Université de Rennes ( UNIV-RENNES ) -Université de Rennes ( UNIV-RENNES ) -Centre National de la Recherche Scientifique ( CNRS ) -Structure Fédérative de Recherche en Biologie et Santé de Rennes ( Biosit : Biologie - Santé - Innovation Technologique ), Biosynthèse des Signaux Peptidiques [IBPS] ( IBPS-BIOSIPE ), Institut de Biologie Paris Seine ( IBPS ), Institut National de la Santé et de la Recherche Médicale ( INSERM ) -Université Pierre et Marie Curie - Paris 6 ( UPMC ) -Centre National de la Recherche Scientifique ( CNRS ) -Institut National de la Santé et de la Recherche Médicale ( INSERM ) -Université Pierre et Marie Curie - Paris 6 ( UPMC ) -Centre National de la Recherche Scientifique ( CNRS ), Institut de Génétique et Développement de Rennes (IGDR), Université de Rennes (UR)-Centre National de la Recherche Scientifique (CNRS)-Structure Fédérative de Recherche en Biologie et Santé de Rennes ( Biosit : Biologie - Santé - Innovation Technologique ), Biosynthèse des Signaux Peptidiques [IBPS] (IBPS-BIOSIPE), Institut de Biologie Paris Seine (IBPS), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique, Université de Rennes 1, 2014–2016, Ligue Contre le Cancer, Structure Fédérative de Recherche en Biologie et Santé de Rennes ( Biosit : Biologie - Santé - Innovation Technologique )-Centre National de la Recherche Scientifique (CNRS)-Université de Rennes 1 (UR1), and Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)

Subjects

0301 basic medicine, animal structures, Cell division, Neurogenesis, Larval development coordination, Aurora A kinase, Cell Cycle Proteins, Spindle Apparatus, Biology, Protein Serine-Threonine Kinases, 03 medical and health sciences, Neuroblast, Neural Stem Cells, Loss of Function Mutation, Animals, Drosophila Proteins, Molecular Biology, Aurora Kinase A, Serine/threonine-specific protein kinase, Neurons, [SDV.GEN]Life Sciences [q-bio]/Genetics, Brain, Embryo, Cell Differentiation, Genetic Pleiotropy, Cell Biology, Phenotype, Cell biology, 030104 developmental biology, Larva, embryonic structures, Drosophila, [ SDV.GEN ] Life Sciences [q-bio]/Genetics, Ganglion mother cell, Cell Division, Developmental Biology, Pupariation

Abstract

International audience; In metazoans, organisms arising from a fertilized egg, the embryo will develop through multiple series of cell divisions, both symmetric and asymmetric, leading to differentiation. Aurora A is a serine threonine kinase highly involved in such divisions. While intensively studied at the cell biology level, its function in the development of a whole organism has been neglected. Here we investigated the pleiotropic effect of Aurora A loss-of-function in Drosophila larval early development. We report that Aurora A is required for proper larval development timing control through direct and indirect means. In larval tissues, Aurora A is required for proper symmetric division rate and eventually development speed as we observed in central brain, wing disc and ring gland. Moreover, Aurora A inactivation induces a reduction of ecdysteroids levels and a pupariation delay as an indirect consequence of ring gland development deceleration. Finally, although central brain development is initially restricted, we confirmed that brain lobe size eventually increases due to additive phenotypes: delayed pupariation and over-proliferation of cells with an intermediate cell-identity between neuroblast and ganglion mother cell resulting from defective asymmetric neuroblast cell division.

Published

2018

17. Downregulation of Sphingosine 1-Phosphate Receptor 1 Promotes the Switch from Tangential to Radial Migration in the OB

Author

Annalisa Zuccotti, Ceren Duman, Hannah Monyer, Horst Penkert, and Julieta Alfonso

Subjects

Doublecortin Domain Proteins, Small-Conductance Calcium-Activated Potassium Channels, Rostral migratory stream, Down-Regulation, Mice, Transgenic, Nerve Tissue Proteins, Neural Cell Adhesion Molecule L1, In Vitro Techniques, Biology, Mice, Paracrine signalling, Organ Culture Techniques, Neuroblast, Cell Movement, Neuroblast migration, Subependymal zone, medicine, Animals, Humans, RNA, Small Interfering, Neurons, Caspase 3, Integrin beta1, General Neuroscience, Neuropeptides, Articles, Olfactory Bulb, CD56 Antigen, Olfactory bulb, Mice, Inbred C57BL, Receptors, Lysosphingolipid, HEK293 Cells, medicine.anatomical_structure, Animals, Newborn, nervous system, Sialic Acids, Neuron, Microtubule-Associated Proteins, Neuroscience, Ganglion mother cell

Abstract

Neuroblast migration is a highly orchestrated process that ensures the proper integration of newborn neurons into complex neuronal circuits. In the postnatal rodent brain, neuroblasts migrate long distances from the subependymal zone of the lateral ventricles to the olfactory bulb (OB) within the rostral migratory stream (RMS). They first migrate tangentially in close contact to each other and later radially as single cells until they reach their final destination in the OB. Sphingosine 1-phosphate (S1P) is a bioactive lipid that interacts with cell-surface receptors to exert different cellular responses. Although well studied in other systems and a target for the treatment of multiple sclerosis, little is known about S1P in the postnatal brain. Here, we report that the S1P receptor 1 (S1P1) is expressed in neuroblasts migrating in the RMS. Usingin vivoandin vitrogain- and loss-of-function approaches in both wild-type and transgenic mice, we found that the activation of S1P1 by its natural ligand S1P, acting as a paracrine signal, contributes to maintain neuroblasts attached to each other while they migrate in chains within the RMS. Once in the OB, neuroblasts cease to express S1P1, which results in cell detachment and initiation of radial migration, likely via downregulation of NCAM1 and β1 integrin. Our results reveal a novel physiological function for S1P1 in the postnatal brain, directing the path followed by newborn neurons in the neurogenic niche.SIGNIFICANCE STATEMENTThe function of each neuron is highly determined by the position it occupies within a neuronal circuit. Frequently, newborn neurons must travel long distances from their birthplace to their predetermined final location and, to do so, they use different modes of migration. In this study, we identify the sphingosine 1-phosphate (S1P) receptor 1 (S1P1) as one of the key players that govern the switch from tangential to radial migration of postnatally generated neuroblasts in the olfactory bulb. Of interest is the evidence that the ligand, S1P, is provided by nearby astrocytes. Finally, we also propose adhesion molecules that act downstream of S1P1 and initiate the transition from tangential chain migration to individual radial migration outside of the stream.

Published

2015

18. Hairy and Enhancer of Split 6 (Hes6) Deficiency in Mouse Impairs Neuroblast Differentiation in Dentate Gyrus Without Affecting Cell Proliferation and Integration into Mature Neurons

Author

Seo Hyun Lee, Jaesang Kim, Sun Shin Yi, Jong Whi Kim, Sung Min Nam, Yo Na Kim, Je Kyung Seong, Yeri Son, Jae Hoon Shin, Yeo Sung Yoon, and Dong Soo Kyeong

Subjects

Doublecortin Domain Proteins, 0301 basic medicine, Doublecortin Protein, Genotype, Fluorescent Antibody Technique, Biology, Nestin, 03 medical and health sciences, Cellular and Molecular Neuroscience, Neural Stem Cells, Neuroblast, Basic Helix-Loop-Helix Transcription Factors, Animals, reproductive and urinary physiology, Cell Proliferation, Mice, Knockout, Neurons, Body Weight, Neuropeptides, Neurogenesis, Cell Differentiation, Cell Biology, General Medicine, beta-Galactosidase, Immunohistochemistry, Neural stem cell, Cell biology, Doublecortin, Mice, Inbred C57BL, Repressor Proteins, Neuroepithelial cell, Ki-67 Antigen, 030104 developmental biology, Bromodeoxyuridine, nervous system, Astrocytes, Dentate Gyrus, biology.protein, NeuN, Microtubule-Associated Proteins, Ganglion mother cell, Neuroscience, Neuroblast differentiation

Abstract

Hes6 is a member of the hairy-enhancer of split homolog (Hes) family of transcription factors and interacts with other Hes family genes. During development, Hes genes are expressed in neural stem cells and progenitor cells. However, the role of Hes6 in adult hippocampal neurogenesis remains unclear. We therefore investigated the effects of Hes6 on adult hippocampal neurogenesis, by comparing Hes6 knockout and wild-type mice. To this end, we immunostained for markers of neural stem cells and progenitor cells (nestin), proliferating cells (Ki67), post-mitotic neuroblasts and immature neurons (doublecortin, DCX), mature neuronal cells (NeuN), and astrocyte (S100β). We also injected 5-bromo-2'-deoxyuridine (BrdU) to trace the fate of mitotic cells. Nestin- and Ki67-positive proliferating cells did now show any significant differences between wild and knockout groups. Hes6 knockout negatively affects neuroblast differentiation based on DCX immunohistochemistry. On the contrary, the ratio of the BrdU and NeuN double-positive cells did not show any significance, even though it was slightly higher in the knockout group. These results suggest that Hes6 is involved in the regulation of neuroblast differentiation during adult neurogenesis, but does not influence integration into mature neurons.

Published

2015

19. Prox1 identifies proliferating neuroblasts and nascent neurons during neurogenesis in sympathetic ganglia

Author

Melanie Hennchen, Julia Holzmann, and Hermann Rohrer

Subjects

animal structures, Neuroblast proliferation, fungi, Neurogenesis, Cell cycle, Biology, Embryonic stem cell, Cellular and Molecular Neuroscience, medicine.anatomical_structure, nervous system, Developmental Neuroscience, Neuroblast, embryonic structures, medicine, Neuron, Progenitor cell, Neuroscience, Ganglion mother cell, reproductive and urinary physiology

Abstract

Neurogenesis in embryonic sympathetic ganglia involves neuroblasts that resume proliferation following neuronal differentiation. As cell cycle exit is not associated with neuronal differentiation, the identity of proliferating neuroblasts is incompletely understood. Here, we use sympathetic ganglia of chick embryos to define the timing of neurogenesis and neuroblast identity focusing on the expression and function of the transcription factor Prox1. We show that a large fraction of neuroblasts has initially withdrawn from the cell cycle at embryonic day 3 (E3), which is reflected by a high proportion of p27(+)/Islet1(+) neuroblasts (63%) and low numbers of EdU(+)/Islet1(+) cells (12%). The proportion of proliferating Islet1(+) neuroblasts, identified by EdU pulse labeling and by the absence of the postmitotic marker p27 increases to reach maximal levels at E5, when virtually all neuroblasts are in the cell cycle (95%). Subsequently, the proportion of EdU-labeled and p27(-) neuroblasts is reduced to reach low levels at E11. Interestingly, the expression of the transcription factor Prox1 is restricted to the neuronal lineage, that is, Sox10(+)/Phox2b(+) neuron progenitors, proliferating p27(-)/Islet1(+) neuroblasts and nascent neurons but is rapidly lost in postmitotic neurons. In vitro and in vivo knockdown and overexpression experiments demonstrate effects of Prox1 in the support of neuroblast proliferation and survival. Taken together, these results define the neurogenesis period in the chick paravertebral sympathetic ganglia including an initial cell cycle withdrawal and identify Prox1 as a marker and regulator of proliferating sympathetic neuroblasts.

Published

2015

20. The transcription factor Nerfin-1 prevents reversion of neurons into neural stem cells

Author

Wei Shi, Louise Y. Cheng, Chen-Fang Weng, Anthony T. Papenfuss, Milan Szuperak, and Francesca Froldi

Subjects

Neurons, Neurogenesis, Cellular differentiation, Gene Expression Regulation, Developmental, Cell Differentiation, Cell Dedifferentiation, Biology, Molecular biology, Neural stem cell, Cell biology, Neuroepithelial cell, Drosophila melanogaster, Neural Stem Cells, Neurosphere, Mutation, Genetics, Animals, Drosophila Proteins, Stem cell, Ganglion mother cell, Research Paper, Transcription Factors, Developmental Biology, Adult stem cell

Abstract

Cellular dedifferentiation is the regression of a cell from a specialized state to a more multipotent state and is implicated in cancer. However, the transcriptional network that prevents differentiated cells from reacquiring stem cell fate is so far unclear. Neuroblasts (NBs), the Drosophila neural stem cells, are a model for the regulation of stem cell self-renewal and differentiation. Here we show that the Drosophila zinc finger transcription factor Nervous fingers 1 (Nerfin-1) locks neurons into differentiation, preventing their reversion into NBs. Following Prospero-dependent neuronal specification in the ganglion mother cell (GMC), a Nerfin-1-specific transcriptional program maintains differentiation in the post-mitotic neurons. The loss of Nerfin-1 causes reversion to multipotency and results in tumors in several neural lineages. Both the onset and rate of neuronal dedifferentiation in nerfin-1 mutant lineages are dependent on Myc- and target of rapamycin (Tor)-mediated cellular growth. In addition, Nerfin-1 is required for NB differentiation at the end of neurogenesis. RNA sequencing (RNA-seq) and chromatin immunoprecipitation (ChIP) analysis show that Nerfin-1 administers its function by repression of self-renewing-specific and activation of differentiation-specific genes. Our findings support the model of bidirectional interconvertibility between neural stem cells and their post-mitotic progeny and highlight the importance of the Nerfin-1-regulated transcriptional program in neuronal maintenance.

Published

2015

21. Temporal Patterning in the Drosophila CNS

Author

Chris Q. Doe

Subjects

0301 basic medicine, Central Nervous System, Cell type, animal structures, Time Factors, Cell division, Biology, 03 medical and health sciences, chemistry.chemical_compound, Neuroblast, Neural Stem Cells, Animals, Drosophila Proteins, Progenitor cell, Progenitor, Body Patterning, fungi, Cell Biology, Anatomy, Neural stem cell, Cell biology, 030104 developmental biology, Drosophila melanogaster, chemistry, Ganglion mother cell, Ecdysone, Developmental Biology

Abstract

A small pool of neural progenitors generates the vast diversity of cell types in the CNS. Spatial patterning specifies progenitor identity, followed by temporal patterning within progenitor lineages to expand neural diversity. Recent work has shown that in Drosophila, all neural progenitors (neuroblasts) sequentially express temporal transcription factors (TTFs) that generate molecular and cellular diversity. Embryonic neuroblasts use a lineage-intrinsic cascade of five TTFs that switch nearly every neuroblast cell division; larval optic lobe neuroblasts also use a rapid cascade of five TTFs, but the factors are completely different. In contrast, larval central brain neuroblasts undergo a major molecular transition midway through larval life, and this transition is regulated by a lineage-extrinsic cue (ecdysone hormone signaling). Overall, every neuroblast lineage uses a TTF cascade to generate diversity, illustrating the widespread importance of temporal patterning.

Published

2017

22. A Kinase Duet Performance in the Asymmetric Division of Drosophila Neuroblasts

Author

Christopher A. Johnston

Subjects

Cell division, myosin, Biology, asymmetric cell division, 03 medical and health sciences, neural stem cell, partner of inscuteable, 0302 clinical medicine, Neuroblast, Cell polarity, Asymmetric cell division, Molecular Biology, lcsh:QH301-705.5, 030304 developmental biology, Progenitor, 0303 health sciences, Comment, protein kinase, Cell Biology, respiratory system, Neural stem cell, Cell biology, cell polarity, lcsh:Biology (General), Stem cell, Ganglion mother cell, human activities, neuroblast, 030217 neurology & neurosurgery, Developmental Biology

Abstract

The ability of progenitor stem cells to divide asymmetrically allows for the production of diverse daughter cell fates.[...].

Published

2017

23. Drosophila embryonic type II neuroblasts: origin, temporal patterning, and contribution to the adult central complex

Author

Walsh, Kathleen T. and Doe, Chris Q.

Subjects

0301 basic medicine, animal structures, Lineage (genetic), Biology, 03 medical and health sciences, 0302 clinical medicine, Neuroblast, Progenitor cell, Molecular Biology, Transcription factor, 030304 developmental biology, 0303 health sciences, Neurogenesis, fungi, Embryo, Anatomy, Stem Cells and Regeneration, Embryonic stem cell, Cell biology, 030104 developmental biology, nervous system, embryonic structures, Developmental biology, Ganglion mother cell, Function (biology), 030217 neurology & neurosurgery, Developmental Biology

Abstract

Drosophila neuroblasts are an excellent model for investigating how neuronal diversity is generated. Most brain neuroblasts generate a series of ganglion mother cells (GMCs) that each make two neurons (type I lineage), but sixteen brain neuroblasts generate a series of intermediate neural progenitors (INPs) that each produce 4-6 GMCs and 8-12 neurons (type II lineage). Thus, type II lineages are similar to primate cortical lineages, and may serve as models for understanding cortical expansion. Yet the origin of type II neuroblasts remains mysterious: do they form in the embryo or larva? If they form in the embryo, do their progeny populate the adult central complex, as do the larval type II neuroblast progeny? Here we present molecular and clonal data showing that all type II neuroblasts form in the embryo, produce INPs, and express known temporal transcription factors. Embryonic type II neuroblasts and INPs undergo quiescence, and produce embryonic-born progeny that contribute to the adult central complex. Our results provide a foundation for investigating the development of the central complex, and tools for characterizing early-born neurons in central complex function.

Published

2017

24. Endogenous Brain Repair: Overriding intrinsic lineage determinates through injury-induced micro-environmental signals

Author

Kathryn S Jones and Bronwen Connor

Subjects

0301 basic medicine, Neurogenesis, DLX2, Subventricular zone, Biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Developmental Neuroscience, Neuroblast, nervous system, medicine, Commentary, PAX6, Progenitor cell, Neuroscience, Ganglion mother cell, 030217 neurology & neurosurgery, Developmental Biology, Adult stem cell

Abstract

Adult human neurogenesis has generated excitement over the last 2 decades with the idea that endogenous adult stem cells could act as a potential cell source for brain repair after injury. Indeed, many forms of experimentally induced brain injury including stroke and excitotoxic lesioning can promote proliferation from the subventricular zone and mobilise neuroblasts and oligodendrocyte progenitor cells to migrate through brain parenchyma to damaged regions. However the failure of neuroblasts to mature into appropriate neuronal subtypes for cell replacement has been an issue. Recent work by our group and others has indicated that micro-environmental signals released from areas of cell loss may be able to override intrinsic gene expression lineages and covert neuroblasts into oligodendrocyte progenitor cells. This commentary will discuss the enhanced fate plasticity of both adult neural progenitors and parenchymal NG2 cells after injury, and the importance of understanding brain-injury induced micro-environmental signals in the quest toward promoting endogenous regeneration after injury.

Published

2017

25. Imp/Syp temporal gradients govern decommissioning of Drosophila neural stem cells

Author

Tzumin Lee, Ilan Davis, Tamsin J. Samuels, David Ish-Horowicz, Lu Yang, Ching-Po Yang, and Yaling Huang

Subjects

0303 health sciences, animal structures, fungi, Anatomy, Prospero, Biology, biology.organism_classification, Neural stem cell, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Neuroblast, chemistry, nervous system, Mushroom bodies, embryonic structures, Ecdysone receptor, Developmental biology, Ganglion mother cell, 030217 neurology & neurosurgery, Ecdysone, reproductive and urinary physiology, 030304 developmental biology

Abstract

Timing ofDrosophilaneuroblast decommissioning is controlled in a lineage-specific manner. Following a prepupal ecdysone pulse, the ecdysone receptor and mediator complex cause neuroblasts to shrink. Shrinking is followed by nuclear accumulation of Prospero and cell cycle exit. Only mushroom body (MB) neuroblasts escape early pupal termination. Here, we demonstrate that the opposing temporal gradients of Imp and Syp RNA-binding proteins that govern temporal fate also regulate neuroblast decommissioning. The Imp gradient declines slower in MB neuroblasts so they still express Imp when it is absent from others. The presence of Imp in MB neuroblasts prevents decommissioning partly through inhibiting the mediator complex. Moreover, a timely induction of Imp can protect many non-MB neuroblasts from aging. We also show that the increasing Syp gradient permits Prospero accumulation and neuroblast termination. Together our results reveal that progeny temporal fate and progenitor decommissioning are co-regulated in protracted neuronal lineages.

Published

2017

26. Steroid hormone induction of temporal gene expression in Drosophila brain neuroblasts generates neuronal and glial diversity

Author

Brandon Mark, Mubarak Hussain Syed, and Chris Q. Doe

Subjects

0301 basic medicine, Cellular differentiation, chemistry.chemical_compound, 0302 clinical medicine, Neural Stem Cells, Biology (General), 0303 health sciences, D. melanogaster, General Neuroscience, Neurogenesis, Brain, Gene Expression Regulation, Developmental, Cell Differentiation, General Medicine, Anatomy, Neural stem cell, Cell biology, neurogenesis, Medicine, Drosophila, Stem cell, neuroblast, temporal identity, Ecdysone, Research Article, animal structures, neural progenitor, QH301-705.5, Science, hormone, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Neuroblast, transcription factors, Animals, Transcription factor, 030304 developmental biology, General Immunology and Microbiology, fungi, Embryonic stem cell, 030104 developmental biology, chemistry, nervous system, Ecdysone receptor, Developmental biology, Ganglion mother cell, 030217 neurology & neurosurgery, Neuroscience

Abstract

An important question in neuroscience is how stem cells generate neuronal diversity. During Drosophila embryonic development, neural stem cells (neuroblasts) sequentially express transcription factors that generate neuronal diversity; regulation of the embryonic temporal transcription factor cascade is lineage-intrinsic. In contrast, larval neuroblasts generate longer ˜50 division lineages, and currently only one mid-larval molecular transition is known: Chinmo/Imp/Lin-28+ neuroblasts transition to Syncrip+ neuroblasts. Here we show that the hormone ecdysone is required to down-regulate Chinmo/Imp and activate Syncrip, plus two late neuroblast factors, Broad and E93. We show that Seven-up triggers Chinmo/Imp to Syncrip/Broad/E93 transition by inducing expression of the Ecdysone receptor in mid-larval neuroblasts, rendering them competent to respond to the systemic hormone ecdysone. Importantly, late temporal gene expression is essential for proper neuronal and glial cell type specification. This is the first example of hormonal regulation of temporal factor expression in Drosophila embryonic or larval neural progenitors.SummaryHormone induction of temporal gene expression in neural progenitors

Published

2017

27. EphA4 Regulates Neuroblast and Astrocyte Organization in a Neurogenic Niche

Author

Joanne C. Conover, Fred W. Kolling, Craig E. Nelson, Matthew B. Eastman, Alexandra G. Trausch, Krysti Todd, and Kasey L. Baker

Subjects

0301 basic medicine, Male, animal structures, Rostral migratory stream, Neurogenesis, Subventricular zone, Cell Communication, Biology, 03 medical and health sciences, Mice, 0302 clinical medicine, Prosencephalon, Neuroblast, Neural Stem Cells, Cell Movement, Neuroblast migration, medicine, Animals, Kinase activity, Stem Cell Niche, reproductive and urinary physiology, Research Articles, Cells, Cultured, Mice, Knockout, General Neuroscience, Receptor, EphA4, Gene Expression Regulation, Developmental, Neural stem cell, Olfactory bulb, 030104 developmental biology, medicine.anatomical_structure, nervous system, Astrocytes, embryonic structures, Neuroscience, Ganglion mother cell, 030217 neurology & neurosurgery

Abstract

Significant migration cues are required to guide and contain newly generated rodent subventricular zone (SVZ) neuroblasts as they transit along the lateral ventricles and then through the anterior forebrain to their ultimate site of differentiation in the olfactory bulbs (OBs). These cues enforce strict neuroblast spatial boundaries within the dense astroglial meshwork of the SVZ and rostral migratory stream (RMS), yet are permissive to large-scale neuroblast migration. Therefore, the molecular mechanisms that define these cues and control dynamic interactions between migratory neuroblasts and surrounding astrocytes are of particular interest. We found that deletion of EphA4 and specifically ablation of EphA4 kinase activity resulted in misaligned neuroblasts and disorganized astrocytes in the RMS/SVZ, linking EphA4 forward signaling to SVZ and RMS spatial organization, orientation, and regulation. In addition, within a 3 week period, there was a significant reduction in the number of neuroblasts that reached the OB and integrated into the periglomerular layer, revealing a crucial role for EphA4 in facilitating efficient neuroblast migration to the OB. Single-cell analysis revealed thatEPHA4and itsEFNbinding partners are expressed by subpopulations of neuroblasts and astrocytes within the SVZ/RMS/OB system resulting in a cell-specific mosaic, suggesting complex EphA4 signaling involving both homotypic and heterotypic cell–cell interactions. Together, our studies reveal a novel molecular mechanism involving EphA4 signaling that functions in stem cell niche organization and ultimately neuroblast migration in the anterior forebrain.SIGNIFICANCE STATEMENTThe subventricular zone neurogenic stem cell niche generates highly migratory neuroblasts that transit the anterior forebrain along a defined pathway to the olfactory bulb. Postnatal and adult brain organization dictates strict adherence to a narrow migration corridor. Subventricular zone neuroblasts are aligned in tightly bundled chains within a meshwork of astrocytes; however, the cell–cell cues that organize this unique, cell-dense migration pathway are largely unknown. Our studies show that forward signaling through the EphA4 tyrosine kinase receptor, mediated by ephrins expressed by subpopulations of neuroblasts and astrocytes, is required for compact, directional organization of neuroblasts and astrocytes within the pathway and efficient transit of neuroblasts through the anterior forebrain to the olfactory bulb.

Published

2017

28. Neuroblast niche position is controlled by Phosphoinositide 3-kinase-dependent DE-Cadherin adhesion

Author

Sarah E. Siegrist, Matthew C. Pahl, Karsten H. Siller, Susan E. Doyle, and Lindsay Ardiff

Subjects

0301 basic medicine, Green Fluorescent Proteins, Morphogenesis, Mitosis, Biology, 03 medical and health sciences, Phosphatidylinositol 3-Kinases, Neuroblast, Neural Stem Cells, Cancer stem cell, Cell Adhesion, Animals, Drosophila Proteins, Cell adhesion, Cell Proliferation, Neurons, Cadherin, food and beverages, Brain, Gene Expression Regulation, Developmental, Cell Biology, Stem Cells and Regeneration, Cadherins, Cell biology, Haematopoiesis, 030104 developmental biology, Drosophila melanogaster, embryonic structures, Stem cell, Ganglion mother cell, Neuroglia

Abstract

Correct positioning of stem cells within their niche is essential for tissue morphogenesis and homeostasis. How stem cells acquire and maintain niche position remains largely unknown. Here, we show that a subset of brain neuroblasts (NBs) in Drosophila utilize Phosphoinositide 3-kinase (PI3-kinase) and DE-cadherin to build adhesive contact for NB niche positioning. NBs remain within their native microenvironment when levels of PI3-kinase activity and DE-cadherin are elevated in NBs. This occurs through PI3-kinase-dependent regulation of DE-Cadherin-mediated cell adhesion between NBs and neighboring cortex glia, and between NBs and their ganglion mother cell daughters. When levels of PI3-kinase activity and/or DE-Cadherin are reduced in NBs, NBs lose niche position and relocate to a non-native brain region that is rich in neurosecretory neurons, including those that secrete some of the Drosophila insulin-like peptides. Linking levels of PI3-kinase activity to the strength of adhesive attachment could provide cancer stem cells and hematopoietic stem cells with a means to cycle from trophic-poor to trophic-rich microenvironments.

Published

2017

29. The Hunchback temporal transcription factor establishes, but is not required to maintain, early-born neuronal identity

Author

Minoree Kohwi, Keiko Hirono, Chris Q. Doe, Ellie S. Heckscher, and Matthew Q Clark

Subjects

0301 basic medicine, Cellular differentiation, Mitosis, Biology, 03 medical and health sciences, 0302 clinical medicine, Neural Stem Cells, Developmental Neuroscience, Krüppel, Neuroblast, medicine, Animals, Drosophila Proteins, Neurons, Motor Neurons, FOS: Clinical medicine, fungi, Neurosciences, Gene Expression Regulation, Developmental, Cell Differentiation, Motor neuron, biology.organism_classification, Neural stem cell, DNA-Binding Proteins, Drosophila melanogaster, 030104 developmental biology, medicine.anatomical_structure, nervous system, Drosophila, Neuron, Neuroscience, Ganglion mother cell, Locomotion, 030217 neurology & neurosurgery, Research Article, Transcription Factors

Abstract

Background: Drosophila and mammalian neural progenitors typically generate a diverse family of neurons in a stereotyped order. Neuronal diversity can be generated by the sequential expression of temporal transcription factors. In Drosophila, neural progenitors (neuroblasts) sequentially express the temporal transcription factors Hunchback (Hb), Kruppel, Pdm, and Castor. Hb is necessary and sufficient to specify early-born neuronal identity in multiple lineages, and is maintained in the post-mitotic neurons produced during each neuroblast expression window. Surprisingly, nothing is currently known about whether Hb acts in neuroblasts or post-mitotic neurons (or both) to specify first-born neuronal identity. Methods: Here we selectively remove Hb from post-mitotic neurons, and assay the well-characterized NB7-1 and NB1-1 lineages for defects in neuronal identity and function. Results: We find that loss of Hb from embryonic and larval post-mitotic neurons does not affect neuronal identity. Furthermore, removing Hb from post-mitotic neurons throughout the entire CNS has no effect on larval locomotor velocity, a sensitive assay for motor neuron and pre-motor neuron function. Conclusions: We conclude that Hb functions in progenitors (neuroblasts/GMCs) to establish heritable neuronal identity that is maintained by a Hb-independent mechanism. We suggest that Hb acts in neuroblasts to establish an epigenetic state that is permanently maintained in early-born neurons.

Published

2017

30. Neuroblast niche position is controlled by PI3-kinase dependent DE-Cadherin adhesion

Author

Sarah E. Siegrist, Lindsay Ardiff, Susan E. Doyle, Matthew C. Pahl, and Karsten H. Siller

Subjects

0301 basic medicine, Cadherin, Morphogenesis, food and beverages, Anatomy, Biology, Cell biology, 03 medical and health sciences, Haematopoiesis, 030104 developmental biology, 0302 clinical medicine, Neuroblast, Cancer stem cell, embryonic structures, Stem cell, Cell adhesion, Molecular Biology, Ganglion mother cell, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Correct positioning of stem cells within their niche is essential for tissue morphogenesis and homeostasis. How stem cells acquire and maintain niche position remains largely unknown. Here, we show that a subset of brain neuroblasts (NBs) in Drosophila utilize Phosphoinositide 3-kinase (PI3-kinase) and DE-cadherin to build adhesive contact for NB niche positioning. NBs remain within their native microenvironment when levels of PI3-kinase activity and DE-cadherin are elevated in NBs. This occurs through PI3-kinase-dependent regulation of DE-Cadherin-mediated cell adhesion between NBs and neighboring cortex glia, and between NBs and their ganglion mother cell daughters. When levels of PI3-kinase activity and/or DE-Cadherin are reduced in NBs, NBs lose niche position and relocate to a non-native brain region that is rich in neurosecretory neurons, including those that secrete some of the Drosophila insulin-like peptides. Linking levels of PI3-kinase activity to the strength of adhesive attachment could provide cancer stem cells and hematopoietic stem cells with a means to cycle from trophic-poor to trophic-rich microenvironments.

Published

2017

31. Drosophila melanogaster Neuroblasts: A Model for Asymmetric Stem Cell Divisions

Author

Emmanuel Gallaud, Tri Thanh Pham, and Clemens Cabernard

Subjects

0301 basic medicine, Cell division, fungi, Biology, Cell fate determination, Neural stem cell, Spindle apparatus, Cell biology, 03 medical and health sciences, 030104 developmental biology, Neuroblast, Asymmetric cell division, Stem cell, Ganglion mother cell

Abstract

Asymmetric cell division (ACD) is a fundamental mechanism to generate cell diversity, giving rise to daughter cells with different developmental potentials. ACD is manifested in the asymmetric segregation of proteins or mRNAs, when the two daughter cells differ in size or are endowed with different potentials to differentiate into a particular cell type (Horvitz and Herskowitz, Cell 68:237–255, 1992). Drosophila neuroblasts, the neural stem cells of the developing fly brain, are an ideal system to study ACD since this system encompasses all of these characteristics. Neuroblasts are intrinsically polarized cells, utilizing polarity cues to orient the mitotic spindle, segregate cell fate determinants asymmetrically, and regulate spindle geometry and physical asymmetry. The neuroblast system has contributed significantly to the elucidation of the basic molecular mechanisms underlying ACD. Recent findings also highlight its usefulness to study basic aspects of stem cell biology and tumor formation. In this review, we will focus on what has been learned about the basic mechanisms underlying ACD in fly neuroblasts.

Published

2017

32. Quiescent neuronal progenitors are activated in the juvenile guinea pig lateral striatum and give rise to transient neurons

Author

Aldo Fasolo, Chiara Rolando, Maria Armentano, Federico Luzzati, Paolo Peretto, L. Bonfanti, Elisa Vigna, Livio Oboti, and Giulia Nato

Subjects

Male, Neurons, External capsule, Neurogenesis, Dentate gyrus, Guinea Pigs, Hippocampus, Subventricular zone, Anatomy, Biology, Neural stem cell, Cell biology, Tissue Culture Techniques, medicine.anatomical_structure, Neural Stem Cells, nervous system, Neuroblast, medicine, Animals, Female, Molecular Biology, Ganglion mother cell, Developmental Biology

Abstract

In the adult brain, active stem cells are a subset of astrocytes residing in the subventricular zone (SVZ) and the dentate gyrus (DG) of the hippocampus. Whether quiescent neuronal progenitors occur in other brain regions is unclear. Here, we describe a novel neurogenic system in the external capsule and lateral striatum (EC-LS) of the juvenile guinea pig that is quiescent at birth but becomes active around weaning. Activation of neurogenesis in this region was accompanied by the emergence of a neurogenic-like niche in the ventral EC characterized by chains of neuroblasts, intermediate-like progenitors and glial cells expressing markers of immature astrocytes. Like neurogenic astrocytes of the SVZ and DG, these latter cells showed a slow rate of proliferation and retained BrdU labeling for up to 65 days, suggesting that they are the primary progenitors of the EC-LS neurogenic system. Injections of GFP-tagged lentiviral vectors into the SVZ and the EC-LS of newborn animals confirmed that new LS neuroblasts originate from the activation of local progenitors and further supported their astroglial nature. Newborn EC-LS neurons existed transiently and did not contribute to neuronal addition or replacement. Nevertheless, they expressed Sp8 and showed strong tropism for white matter tracts, wherein they acquired complex morphologies. For these reasons, we propose that EC-LS neuroblasts represent a novel striatal cell type, possibly related to those populations of transient interneurons that regulate the development of fiber tracts during embryonic life.

Published

2014

33. The RanGEFBj1 promotes prospero nuclear export and neuroblast self-renewal

Author

Chris Q. Doe, Keiko Hirono, and Tasha Joy

Subjects

animal structures, biology, fungi, Prospero, biology.organism_classification, Cellular and Molecular Neuroscience, nervous system, Developmental Neuroscience, Neuroblast, embryonic structures, Ran, Nuclear transport, Stem cell, Nuclear export signal, Neuroscience, Ganglion mother cell, reproductive and urinary physiology, Neuroblast differentiation

Abstract

Drosophila larval neuroblasts are a model system for studying stem cell self-renewal and differentiation. Here, we report a novel role for the Drosophila gene Bj1 in promoting larval neuroblast self-renewal. Bj1 is the guanine-nucleotide exchange factor for Ran GTPase, which regulates nuclear import/export. Bj1 transcripts are highly enriched in larval brain neuroblasts (in both central brain and optic lobe), while Bj1 protein is detected in both neuroblasts and their neuronal progeny. Loss of Bj1 using both mutants or RNAi causes a progressive loss of larval neuroblasts, showing that Bj1 is required to maintain neuroblast numbers. Loss of Bj1 does not result in neuroblast apoptosis, but rather leads to abnormal nuclear accumulation of the differentiation factor Prospero, and premature neuroblast differentiation. We conclude that the Bj1 RanGEF promotes Prospero nuclear export and neuroblast self-renewal. © 2014 Wiley Periodicals, Inc. Develop Neurobiol 75: 485–493, 2015

Published

2014

34. Astrocytic and Vascular Scaffolding for Neuroblast Migration in the Rostral Migratory Stream

Author

Kamila Fabianová, Andrea Schreiberova, Viera Almášiová, Marcela Martončíková, Enikö Račeková, and Juraj Blasko

Subjects

Doublecortin Domain Proteins, Male, Scaffold, genetic structures, Rostral migratory stream, Subventricular zone, Biology, Cerebral Ventricles, Cellular and Molecular Neuroscience, Neural Stem Cells, Developmental Neuroscience, Neuroblast, Cell Movement, Neuroblast migration, medicine, Animals, Rats, Wistar, Analysis of Variance, Tissue Scaffolds, Neuropeptides, Embryogenesis, Olfactory Bulb, Rats, Olfactory bulb, medicine.anatomical_structure, nervous system, Neurology, Astrocytes, Blood Vessels, Female, Cell Adhesion Molecules, Microtubule-Associated Proteins, Neuroscience, Ganglion mother cell

Abstract

New neurons are continuously being added to the olfactory bulb (OB) of adult rodents that are generated in the subventricular zone (SVZ), distant by a few millimeters. Neuronal precursors have to overcome this long distance without the radial-glial migratory scaffold, in contrast to migration mode during embryonic development. The previous model explains migration of precursors from the SVZ through the rostral migratory stream (RMS) to the OB as a movement of neuroblasts along each other, ensheathed by astroglial tubes. Recent results indicate that blood vessels are suitable candidates for neuronal migration guidance in the RMS. These novel findings have changed the former concept accounting for neuronal precursor migration. The aim of our study was to map a pattern of vascularization in the RMS of adult rats and to investigate mutual relations among blood vessels, neuroblasts and astrocytes in this area. Detailed morphological analysis revealed that blood vessels in the RMS are organized in a specific manner. In most of the RMS extent, blood vessels run parallel to the outline of the migratory pathway. Interestingly, the caudal part of the RMS has a unique vasculature organization in which blood vessels create a spiral-like configuration. Chains of neuroblasts enveloped by astrocytes largely align along blood vessels. The exception is the caudal part of the RMS where neuroblasts do not follow non - parallel blood vessels. Our morphological findings suggest that blood vessels and astrocytes may cooperatively form physical substrate - scaffold for the neuroblasts migration in the RMS of adult rats.

Published

2014

35. Orthodenticle is required for the development of olfactory projection neurons and local interneurons in Drosophila

Author

Silvia Biagini, Sonia Sen, K. VijayRaghavan, and Heinrich Reichert

Subjects

Nervous system, animal structures, QH301-705.5, Science, Biology, Cell fate determination, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Neuroblast, medicine, Biology (General), Gap gene, 030304 developmental biology, Olfactory interneuron, 0303 health sciences, Neuroectoderm, MARCM, fungi, Anatomy, Cell biology, medicine.anatomical_structure, Otd, nervous system, Antennal lobe, Drosophila, General Agricultural and Biological Sciences, Ganglion mother cell, 030217 neurology & neurosurgery, Research Article

Abstract

The accurate wiring of nervous systems involves precise control over cellular processes like cell division, cell fate specification, and targeting of neurons. The nervous system of Drosophila melanogaster is an excellent model to understand these processes. Drosophila neurons are generated by stem cell like precursors called neuroblasts that are formed and specified in a highly stereotypical manner along the neuroectoderm. This stereotypy has been attributed, in part, to the expression and function of transcription factors that act as intrinsic cell fate determinants in the neuroblasts and their progeny during embryogenesis. Here we focus on the lateral neuroblast lineage, ALl1, of the antennal lobe and show that the transcription factor-encoding cephalic gap gene orthodenticle is required in this lineage during postembryonic brain development. We use immunolabelling to demonstrate that Otd is expressed in the neuroblast of this lineage during postembryonic larval stages. Subsequently, we use MARCM clonal mutational methods to show that the majority of the postembryonic neuronal progeny in the ALl1 lineage undergoes apoptosis in the absence of orthodenticle. Moreover, we demonstrate that the neurons that survive in the orthodenticle loss-of-function condition display severe targeting defects in both the proximal (dendritic) and distal (axonal) neurites. These findings indicate that the cephalic gap gene orthodenticle acts as an important intrinsic determinant in the ALl1 neuroblast lineage and, hence, could be a member of a putative combinatorial code involved in specifying the fate and identity of cells in this lineage.

Published

2014

36. Neuroblast lineage identification and lineage-specific Hox gene action during postembryonic development of the subesophageal ganglion in the Drosophila central brain

Author

Jennifer K. Lovick, Bruno Bello, Volker Hartenstein, Philipp A. Kuert, and Heinrich Reichert

Subjects

animal structures, Lineage (evolution), Biology, Neural Stem Cells, Neuroblast, Animals, Cell Lineage, Hox gene, Molecular Biology, Neural cell, Genetics, Microscopy, Confocal, Antp, fungi, MARCM, Genes, Homeobox, Brain, Gene Expression Regulation, Developmental, Cell Biology, Hox, Immunohistochemistry, Embryonic stem cell, Ganglia, Invertebrate, Cell biology, Supraesophageal ganglion, embryonic structures, Drosophila, Dfd, Scr, Ganglion mother cell, lineage, Developmental Biology

Abstract

The central brain of Drosophila consists of the supraesophageal ganglion (SPG) and the subesophageal ganglion (SEG), both of which are generated by neural stem cell-like neuroblasts during embryonic and postembryonic development. Considerable information has been obtained on postembryonic development of the neuroblasts and their lineages in the SPG. In contrast, very little is known about neuroblasts, neural lineages, or any other aspect of the postembryonic development in the SEG. Here we characterize the neuroanatomy of the larval SEG in terms of tracts, commissures, and other landmark features as compared to a thoracic ganglion. We then use clonal MARCM labeling to identify all adult-specific neuroblast lineages in the late larval SEG and find a surprisingly small number of neuroblast lineages, 13 paired and one unpaired. The Hox genes Dfd, Scr, and Antp are expressed in a lineage-specific manner in these lineages during postembryonic development. Hox gene loss-of-function causes lineage-specific defects in axonal targeting and reduction in neural cell numbers. Moreover, it results in the formation of novel ectopic neuroblast lineages. Apoptosis block also results in ectopic lineages suggesting that Hox genes are required for lineage-specific termination of proliferation through programmed cell death. Taken together, our findings show that postembryonic development in the SEG is mediated by a surprisingly small set of identified lineages and requires lineage-specific Hox gene action to ensure the correct formation of adult-specific neurons in the Drosophila brain.

Published

2014

37. A novel, unusual (at least for beetles) mode of Kenyon cell production in the diving beetle Cybister lateralimarginalis Deg. (Coleoptera: Dytiscidae)

Author

A. A. Panov

Subjects

Cybister lateralimarginalis, animal structures, Kenyon cell, biology, Cell division, fungi, Dytiscidae, Zoology, Large nucleus, biology.organism_classification, General Biochemistry, Genetics and Molecular Biology, nervous system, Neuroblast, Botany, Mushroom bodies, General Agricultural and Biological Sciences, Ganglion mother cell

Abstract

Kenyon cell production in the mushroom bodies of Cybister lateralimarginalis is a peculiar process. It has been found that each proliferative center contains one giant neuroblast, which divides unequally, and its smaller daughter cell becomes the 2nd order neuroblast dividing unequally as well. The smaller daughter cell of this neuroblast becomes a ganglion mother cell. The latter, as usual, divides equally producing two Kenyon cells.

Published

2014

38. Mechanisms of neuronal migration in the adult brain

Author

Masato Sawada, Kazunobu Sawamoto, and Naoko Kaneko

Subjects

0301 basic medicine, Neurons, Brain Mapping, Rostral migratory stream, Regeneration (biology), Neurogenesis, Brain, Biochemistry, Olfactory bulb, 03 medical and health sciences, Cellular and Molecular Neuroscience, 030104 developmental biology, nervous system, Neuroblast, Neural Stem Cells, Cell Movement, Neuroblast migration, Animals, Humans, Neurochemistry, Psychology, Neuroscience, Ganglion mother cell

Abstract

Adult neurogenesis was first observed nearly 60 years ago, and it has since grown into an important neurochemistry research field. Much recent research has focused on the treatment of brain diseases through neuronal regeneration with endogenously generated neurons. In the adult brain, immature neurons called neuroblasts are continuously generated in the ventricular-subventricular zone (V-SVZ). These neuroblasts migrate rapidly through the rostral migratory stream to the olfactory bulb, where they mature and are integrated into the neuronal circuitry. After brain insult, some of the neuroblasts in the V-SVZ migrate toward the lesion to repopulate the injured tissue. This notable migratory capacity of V-SVZ-derived neuroblasts is important for efficiently regenerating neurons in remote areas of the brain. As these neurons migrate for long distances through adult brain tissue, they are supported by various guidance cues and structures that act as scaffolds. Some of these mechanisms are unique to neuroblast migration in the adult brain, and are not involved in migration in the developing brain. Here, we review the latest findings on the mechanisms of neuroblast migration in the adult brain under physiological and pathological conditions, and discuss various issues that still need to be resolved. This article is part of the mini review series "60th Anniversary of the Japanese Society for Neurochemistry".

Published

2016

39. Abdominal-B and caudal inhibit the formation of specific neuroblasts in the Drosophila tail region

Author

Christian Berger, Gerhard M. Technau, Olaf Vef, Oliver Birkholz, and Ana Rogulja-Ortmann

Subjects

Central Nervous System, Tail, animal structures, CNS development, Cellular differentiation, ParaHox, Apoptosis, Biology, Terminal neuromeres, Abdominal-B, Hox genes, Neural Stem Cells, Neuroblast, Neuroblasts, Image Processing, Computer-Assisted, Animals, Drosophila Proteins, Hox gene, Molecular Biology, In Situ Hybridization, DNA Primers, Homeodomain Proteins, fungi, Cell Differentiation, Stem Cells and Regeneration, Neuromere, Immunohistochemistry, Molecular biology, Neural stem cell, Segmental patterning, Drosophila melanogaster, Microscopy, Fluorescence, nervous system, embryonic structures, Caudal, Drosophila, Ganglion mother cell, Drosophila Protein, Transcription Factors, Developmental Biology

Abstract

The central nervous system of Drosophila melanogaster consists of fused segmental units (neuromeres), each generated by a characteristic number of neural stem cells (neuroblasts). In the embryo, thoracic and anterior abdominal neuromeres are almost equally sized and formed by repetitive sets of neuroblasts, whereas the terminal abdominal neuromeres are generated by significantly smaller populations of progenitor cells. Here we investigated the role of the Hox gene Abdominal-B in shaping the terminal neuromeres. We show that the regulatory isoform of Abdominal-B (Abd-B.r) not only confers abdominal fate to specific neuroblasts (e.g. NB6-4) and regulates programmed cell death of several progeny cells within certain neuroblast lineages (e.g. NB3-3) in parasegment 14, but also inhibits the formation of a specific set of neuroblasts in parasegment 15 (including NB7-3). We further show that Abd-B.r requires cooperation of the ParaHox gene caudal to unfold its full competence concerning neuroblast inhibition and specification. Thus, our findings demonstrate that combined action of Abdominal-B and caudal contributes to the size and composition of the terminal neuromeres by regulating both the number and lineages of specific neuroblasts.

Published

2013

40. Dynamic changes in the transcriptional profile of subventricular zone-derived postnatally born neuroblasts

Author

Hannah Monyer, Julieta Alfonso, and Konstantin Khodosevich

Subjects

Embryology, animal structures, Transcription, Genetic, Rostral migratory stream, Neurogenesis, Subventricular zone, Nerve Tissue Proteins, Biology, Transcriptome, Mice, Lateral ventricles, Neural Stem Cells, Neuroblast, Cell Movement, Lateral Ventricles, Neuroblast migration, medicine, Animals, reproductive and urinary physiology, Neurons, fungi, Gene Expression Regulation, Developmental, Cell Differentiation, Anatomy, Olfactory Bulb, Olfactory bulb, Cell biology, medicine.anatomical_structure, nervous system, embryonic structures, Ganglion mother cell, Signal Transduction, Developmental Biology

Abstract

The subventricular zone (SVZ) of the lateral ventricles is a major neurogenic region in the postnatal mammalian brain. Thousands of neuroblasts are generated daily throughout the life of an animal. Newly born neuroblasts migrate via the rostral migratory stream (RMS) into the olfactory bulb where they mature into distinct neuronal subtypes. Neuroblasts exiting the SVZ retain the ability to proliferate, however, proliferation declines in the course of migration to the olfactory bulb. While migrating in the RMS, neuroblasts receive a plethora of stimuli that modify transcription according to the local microenvironment, and eventually modulate neuroblast migration. In the target area, the olfactory bulb, neuroblasts develop into mature neurons. In this review, we discuss dynamic changes of the transcriptome that occur during the “lifetime” of a neuroblast, thereby governing the activation or inhibition of distinct genes/pathways that are responsible for proliferation, migration and differentiation.

Published

2013

41. The p21-activated kinase Mbt is a component of the apical protein complex in central brain neuroblasts and controls cell proliferation

Author

Juliane Melzer, Rolf Urbach, Karoline F. Kraft, and Thomas Raabe

Subjects

Embryo, Nonmammalian, animal structures, Mitosis, Apoptosis, Cell Count, Spindle Apparatus, Biology, Neural Stem Cells, Neuroblast, GTP-Binding Proteins, Tubulin, Cell polarity, Animals, Drosophila Proteins, Progenitor cell, Molecular Biology, Cell Proliferation, Cell Size, Binding Sites, Apical cortex, Asymmetric Cell Division, fungi, Brain, Cell Polarity, Gene Expression Regulation, Developmental, Neural stem cell, Cell biology, Enzyme Activation, Actin Cytoskeleton, Phenotype, nervous system, Larva, Multiprotein Complexes, embryonic structures, Mushroom bodies, Drosophila, Protein Kinases, Ganglion mother cell, Developmental Biology

Abstract

The final size of the central nervous system is determined by precisely controlled generation, proliferation and death of neural stem cells. We show here that the Drosophila PAK protein Mushroom bodies tiny (Mbt) is expressed in central brain progenitor cells (neuroblasts) and becomes enriched to the apical cortex of neuroblasts in a cell cycle- and Cdc42-dependent manner. Using mushroom body neuroblasts as a model system, we demonstrate that in the absence of Mbt function, neuroblasts and their progeny are correctly specified and are able to generate different neuron subclasses as in the wild type, but are impaired in their proliferation activity throughout development. In general, loss of Mbt function does not interfere with establishment or maintenance of cell polarity, orientation of the mitotic spindle and organization of the actin or tubulin cytoskeleton in central brain neuroblasts. However, we show that mbt mutant neuroblasts are significantly reduced in cell size during different stages of development, which is most pronounced for mushroom body neuroblasts. This phenotype correlates with reduced mitotic activity throughout development. Additionally, postembryonic neuroblasts are lost prematurely owing to apoptosis. Yet, preventing apoptosis did not rescue the loss of neurons seen in the adult mushroom body of mbt mutants. From these results, we conclude that Mbt is part of a regulatory network that is required for neuroblast growth and thereby allows proper proliferation of neuroblasts throughout development.

Published

2013

42. Apoptosis of Glutamatergic Neurons Fails to Trigger a Neurogenic Response in the Adult Neocortex

Author

Jean M. Hébert, Wenfei Kang, Nicholas McKeehan, and Frank Diaz

Subjects

Doublecortin Domain Proteins, Doublecortin Protein, Neurogenesis, Oligodendrocyte Transcription Factor 2, Apoptosis, Mice, Transgenic, Neocortex, Nerve Tissue Proteins, Biology, Article, Mice, Glutamatergic, Glutamates, Neuroblast, Basic Helix-Loop-Helix Transcription Factors, medicine, Animals, Diphtheria Toxin, Neurons, Caspase 8, General Neuroscience, Dentate gyrus, Neuropeptides, Up-Regulation, Olfactory bulb, medicine.anatomical_structure, nervous system, Nerve Degeneration, Microglia, Microtubule-Associated Proteins, Neuroscience, Ganglion mother cell

Abstract

Adult neurogenesis is actively studied in part because of the potential to manipulate endogenous neural stem and progenitor cells for tissue repair. Although constitutive generation of neurons in the adult rodent olfactory bulb and hippocampal dentate gyrus is widely accepted and stroke-induced generation of striatal inhibitory neurons consistently observed, evidence supporting the generation of neurons in the neocortex after neuronal loss remains slim. Nevertheless, a few studies suggested that targeted apoptosis of neocortical glutamatergic neurons could trigger the generation of new ones in the adult brain. In light of such studies, we tested whether apoptosis of glutamatergic cortical neurons using two novel transgenic approaches in mice, an inducible Caspase-8 protein and an inducible diphtheria toxin gene, results in new neurons. After a thorough analysis, no new neurons were detected in the neocortex. Interestingly, an increase in the expression of the neuroblast marker DCX was observed in both models, in some cases in cells with morphologies previously associated with poststroke neuroblasts, but DCX+cells coexpressed the oligodendrocyte precursor marker Olig2, suggesting caution when using DCX as a marker for neuroblasts after injury. Given that the adult neocortex lacks an innate potential to regenerate lost glutamatergic neurons, future strategies should concentrate on manipulating the differentiation potential of endogenous or exogenous precursor cells.

Published

2013

43. Proliferation and Cell Cycle Dynamics in the Developing Stellate Ganglion

Author

Hideki Enomoto, Kylie N. Cane, Colin R. Anderson, David G. Gonsalvez, Kerry A. Landman, and Heather M. Young

Subjects

Time Factors, animal structures, Tyrosine 3-Monooxygenase, Green Fluorescent Proteins, Stellate Ganglion, Mice, Transgenic, Biology, Models, Biological, Mice, Neuroblast, Tubulin, Precursor cell, Animals, Humans, reproductive and urinary physiology, Cell Proliferation, Homeodomain Proteins, Neurons, Analysis of Variance, SOXE Transcription Factors, Cell growth, Phenylurea Compounds, General Neuroscience, Cell Cycle, Proto-Oncogene Proteins c-ret, Age Factors, Gene Expression Regulation, Developmental, Articles, Cell cycle, Embryo, Mammalian, Embryonic stem cell, Cell biology, Mice, Inbred C57BL, Ki-67 Antigen, Phenotype, Bromodeoxyuridine, nervous system, embryonic structures, Neuron differentiation, Stem cell, Ganglion mother cell, Transcription Factors

Abstract

Cell proliferation during nervous system development is poorly understood outside the mouse neocortex. We measured cell cycle dynamics in the embryonic mouse sympathetic stellate ganglion, where neuroblasts continue to proliferate following neuronal differentiation. At embryonic day (E) 9.5, when neural crest-derived cells were migrating and coalescing into the ganglion primordium, all cells were cycling, cell cycle length was only 10.6 h, and S-phase comprised over 65% of the cell cycle; these values are similar to those previously reported for embryonic stem cells. At E10.5, Sox10+cells lengthened their cell cycle to 38 h and reduced the length of S-phase. As cells started to express the neuronal markers Tuj1 and tyrosine hydroxylase (TH) at E10.5, they exited the cell cycle. At E11.5, when >80% of cells in the ganglion were Tuj1+/TH+neuroblasts, all cells were again cycling. Neuroblast cell cycle length did not change significantly after E11.5, and 98% of Sox10−/TH+cells had exited the cell cycle by E18.5. The cell cycle length of Sox10+/TH−cells increased during late embryonic development, and ∼25% were still cycling at E18.5. Loss ofRetincreased neuroblast cell cycle length at E16.5 and decreased the number of neuroblasts at E18.5. A mathematical model generated from our data successfully predicted the relative change in proportions of neuroblasts and non-neuroblasts in wild-type mice. Our results show that, like other neurons, sympathetic neuron differentiation is associated with exit from the cell cycle; sympathetic neurons are unusual in that they then re-enter the cell cycle before later permanently exiting.

Published

2013

44. Enhanced dendritogenesis and axogenesis in hippocampal neuroblasts of LRRK2 knockout mice

Author

Frank Gillardon, Jürgen Winkler, Dagmar Galter, Zacharias Kohl, Marie Paus, and Nada M.-B. Ben Abdallah

Subjects

Doublecortin Domain Proteins, Neurogenesis, Protein Serine-Threonine Kinases, Hippocampal formation, Biology, Leucine-Rich Repeat Serine-Threonine Protein Kinase-2, Hippocampus, Mice, Neural Stem Cells, Neuroblast, Animals, RNA, Messenger, Molecular Biology, Mice, Knockout, Neurons, General Neuroscience, Dentate gyrus, Neuropeptides, Cell Differentiation, Dendrites, Axons, nervous system diseases, Doublecortin, Mice, Inbred C57BL, Neuroepithelial cell, Ki-67 Antigen, Bromodeoxyuridine, Gene Expression Regulation, nervous system, biology.protein, Neurology (clinical), NeuN, Microtubule-Associated Proteins, Neuroscience, Ganglion mother cell, Developmental Biology

Abstract

Adult neurogenesis, the formation of new neurons in the mammalian forebrain, is one important mechanism maintaining lifelong neuronal plasticity. The generation and maturation of adult neural stem and progenitor cells is impaired in models of neurodegenerative diseases, in particular Parkinson's disease (PD). Monogenetic forms of PD were identified and associated with several genes including the leucine-rich-repeat kinase 2 (LRRK2). Some of the underlying mechanisms in neurodegenerative diseases are closely linked to neuronal plasticity, and induce changes in adult neurogenesis, neuritic maintenance, synaptic transmission, and neural connectivity. We investigated adult neurogenesis and neuritic development of newly formed neurons in the hippocampal dentate gyrus of LRRK2 knockout mice. Proliferation and survival of newly generated cells were unchanged. However, the expression profile of maturation markers in surviving newly generated cells was altered. While immature neuronal phenotypes were significantly increased, the mature neuronal phenotype of surviving cells remained unchanged. Importantly, the absolute number of immature doublecortin positive neuroblasts was significantly increased in the hippocampus of LRRK2 knockout mice. These neuroblasts presented extended dendritic length with a more complex arborization. Furthermore, LRRK2 deletion resulted in an increased volume of the axonal mossy fiber bundle projecting from dentate granule cells to CA3 pyramidal neurons. Our findings suggest that LRRK2 influences neurogenesis and particularly neuronal morphogenesis. As neurogenesis and the pre-/post- synaptic compartments are significantly altered in PD, our data advance LRRK2 as a potent candidate in addressing neuroregenerative processes.

Published

2013

45. Endogenous electric currents might guide rostral migration of neuroblasts

Author

Min Zhao, Jin Pu, Dongguang Wei, Ebenezer N. Yamoah, Tingrui Pan, Brian Reid, Lin Cao, and Siwei Zhao

Subjects

Scientific Reports, Purinergic receptor, Subventricular zone, Endogeny, Anatomy, Biology, Biochemistry, Neural stem cell, Olfactory bulb, Receptors, Purinergic P2Y1, medicine.anatomical_structure, Neural Stem Cells, nervous system, Neuroblast, Cell Movement, Neuroblast migration, Genetics, medicine, Animals, Molecular Biology, Neuroscience, Ganglion mother cell

Abstract

Mechanisms that guide directional migration of neuroblasts from the subventricular zone (SVZ) are not well understood. We report here that endogenous electric currents serve as a guidance cue for neuroblast migration. We identify the existence of naturally occurring electric currents (1.5±0.6 μA/cm2, average field strength of ∼3 mV/mm) along the rostral migration path in adult mouse brain. Electric fields of similar strength direct migration of neuroblasts from the SVZ in culture and in brain slices. The purinergic receptor P2Y1 mediates this migration. The results indicate that naturally occurring electric currents serve as a new guidance mechanism for rostral neuronal migration.

Published

2013

46. Ontogeny of the Arachnid Central Nervous System

Author

Weygoldt, Peter and Barth, Friedrich G., editor

Published

1985

47. Dicer-1 regulates proliferative potential of Drosophila larval neural stem cells through bantam miRNA based down-regulation of the G1/S inhibitor Dacapo

Author

Animesh Banerjee and Jagat Kumar Roy

Subjects

0301 basic medicine, Ribonuclease III, animal structures, Cell Survival, Down-Regulation, Cell Count, Biology, S Phase, 03 medical and health sciences, Neuroblast, Neural Stem Cells, DACAPO, Cyclin-dependent kinase, Animals, Drosophila Proteins, Cell Lineage, Molecular Biology, Cell Proliferation, Genetics, fungi, MARCM, Cell Cycle, G1 Phase, Nuclear Proteins, Cell Biology, Cell cycle, Neural stem cell, Cell biology, MicroRNAs, 030104 developmental biology, Drosophila melanogaster, Larva, Mutation, biology.protein, Ganglion mother cell, RNA Helicases, Developmental Biology, Dicer

Abstract

The present work elucidates the role of miRNA in cell cycle regulation during brain development in Drosophila. Here we report that lineage specific depletion of dicer-1, a classically acknowledged miRNA biogenesis protein in neuroblasts leads to a reduction in their numbers and size in the third instar larval central brain. These brains also showed lower number of mitotically active cells and when homozygous mitotic clones were generated in an otherwise heterozygous dicer-1 mutant background via MARCM technique, they showed reduced number of progeny cells in individual clones, substantiating the adverse effect of the loss of dicer-1 on the proliferative potential of neuroblasts. bantam miRNA, which has been classically reported to be involved in tissue growth was found to express in neuroblasts and undergo reduced expression in Dicer-1 depleted background in the third instar larval brain. Reduction in the number and proliferative potential of neuroblasts in bantam mutant background implies a pivotal role played by bantam miRNA in maintenance of neuroblast number. Since, in both Dicer-1 and bantam depleted genetic backgrounds, Dacapo, an inhibitor of cyclin E-Cdk complex, was found to have elevated expression, we put forward a molecular mechanism involving bantam-Dacapo-Cyclin E/Cdk complex that regulates the G1-S phase transition of Drosophila neuroblasts.

Published

2016

48. The Snail Family Member Worniu Is Continuously Required in Neuroblasts to Prevent Elav-Induced Premature Differentiation

Author

Kristin J. Robinson, Sen-Lin Lai, Chris Q. Doe, and Michael R. Miller

Subjects

animal structures, Cellular differentiation, Snail, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Prophase, Neuroblast, biology.animal, Animals, Drosophila Proteins, Molecular Biology, Metaphase, Transcription factor, Neurons, Genetics, Sequence Analysis, RNA, fungi, Cell Differentiation, Cell Biology, Cell biology, Drosophila melanogaster, Phenotype, Neuroblast delamination, ELAV Proteins, nervous system, embryonic structures, Ganglion mother cell, Transcription Factors, Developmental Biology

Abstract

Summary Snail family transcription factors are best known for regulating epithelial-mesenchymal transition (EMT). The Drosophila Snail family member Worniu is specifically transcribed in neural progenitors (neuroblasts) throughout their lifespan, and worniu mutants show defects in neuroblast delamination (a form of EMT). However, the role of Worniu in neuroblasts beyond their formation is unknown. We performed RNA-seq on worniu mutant larval neuroblasts and observed reduced cell-cycle transcripts and increased neural differentiation transcripts. Consistent with these genomic data, worniu mutant neuroblasts showed a striking delay in prophase/metaphase transition by live imaging and increased levels of the conserved neuronal differentiation splicing factor Elav. Reducing Elav levels significantly suppressed the worniu mutant phenotype. We conclude that Worniu is continuously required in neuroblasts to maintain self-renewal by promoting cell-cycle progression and inhibiting premature differentiation.

Published

2012

49. Drosophila Polycomb complexes restrict neuroblast competence to generate motoneurons

Author

Michael D. Cleary, Johnny J. Touma, and Frank Weckerle

Subjects

Interneuron, Repressor, Biology, Epigenesis, Genetic, Competence (law), Krüppel, Neuroblast, Interneurons, medicine, Animals, Drosophila Proteins, Cell Lineage, Progenitor cell, Molecular Biology, Loss function, Motor Neurons, Polycomb Repressive Complex 1, Cell Differentiation, Anatomy, Drosophila melanogaster, medicine.anatomical_structure, Multiprotein Complexes, Mutation, Neuroscience, Ganglion mother cell, Developmental Biology

Abstract

Similar to mammalian neural progenitors, Drosophila neuroblasts progressively lose competence to make early-born neurons. In neuroblast 7-1 (NB7-1), Kruppel (Kr) specifies the third-born U3 motoneuron and Kr misexpression induces ectopic U3 cells. However, competence to generate U3 cells is limited to early divisions, when the Eve+ U motoneurons are produced, and competence is lost when NB7-1 transitions to making interneurons. We have found that Polycomb repressor complexes (PRCs) are necessary and sufficient to restrict competence in NB7-1. PRC loss of function extends the ability of Kr to induce U3 fates and PRC gain of function causes precocious loss of competence to make motoneurons. PRCs also restrict competence to make HB9+ Islet+ motoneurons in another neuroblast that undergoes a motoneuron-to-interneuron transition, NB3-1. In contrast to the regulation of motoneuron competence, PRC activity does not affect the production of Eve+ interneurons by NB3-3, HB9+ Islet+ interneurons by NB7-3, or Dbx+ interneurons by multiple neuroblasts. These findings support a model in which PRCs establish motoneuron-specific competence windows in neuroblasts that transition from motoneuron to interneuron production.

Published

2012

50. MARK2/Par-1 guides the directionality of neuroblasts migrating to the olfactory bulb

Author

Pierre-Marie Lledo, Orly Reiner, Sheyla Mejia-Gervacio, Richard Belvindrah, Kerren Murray, and Tamar Sapir

Subjects

Rostral migratory stream, Neurogenesis, Green Fluorescent Proteins, Subventricular zone, Cell Cycle Proteins, Protein Serine-Threonine Kinases, Biology, Mice, Cellular and Molecular Neuroscience, Organ Culture Techniques, Neural Stem Cells, Neuroblast, Cell Movement, Interneurons, Neuroblast migration, medicine, Animals, Molecular Biology, Cell Biology, Olfactory Bulb, Olfactory bulb, Mice, Inbred C57BL, medicine.anatomical_structure, Animals, Newborn, nervous system, Forebrain, Ganglion mother cell, Neuroscience

Abstract

In rodents and most other mammals studied, neuronal precursors generated in the subventricular zone (SVZ) migrate to the adult olfactory bulb (OB) to differentiate into interneurons called granule and periglomerular cells. How the newborn cells navigate in the postnatal forebrain to reach precisely their target area is largely unknown. However, it is often thought that postnatal neurogenesis recapitulates the neuronal development occurring during embryogenesis. During brain development, intracellular kinases are key elements for controlling cell polarization as well as the coupling between polarization and cellular movement. We show here that the polarity kinase MARK2 maintains its expression in the postnatal SVZ-OB system. We therefore investigated the potential role of this kinase in adjusting postnatal neuroblast migration. We employed mouse brain slices maintained in culture, in combination with lentiviral vector injections designed to label neuronal precursors with GFP and to diminish the expression of MARK2. Time-lapse video microscopy was used to monitor neuroblast migration in the postnatal forebrain from SVZ precursors to cells populating the OB. We found that reduced MARK2 expression resulted in altered migratory patterns and stalled neuroblasts in the rostral migratory stream (RMS). In agreement with the observed migratory defects, we report a diminution of the proportion of cells reaching the OB layers. Our study reveals the involvement of MARK2 in the maintenance of the migratory direction in postnatally-generated neuroblasts and consequently on the control of the number of newly-generated neurons reaching and integrating the appropriate target circuits.

Published

2012