DOCSLIB.ORG

Subject Index

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Subject Index 979 Subject Index Acellularity Asymmetry of embryonic starfish mesenchyme cells: KANEKO AND development of left/right asymmetry: BROWN AND OTHERS 129 WOLPERT 1 Acetylcholinesterase Avian tropomyosin/cholinesterase expression in ascidian embryo zygotes: CROWTHER AND OTHERS 953 localization of bFGF: KALCHEIM AND NEUFELD 203 Acrosome Axis reaction anterior-posterior zona receptors on guinea-pig spermatozoa: JONES AND organizer amount and axial pattern in Xenopus: WILLIAMS 41 STEWART AND GERHART 363 Actin Axogenesis effect of stretch on muscle gene expression: LOUGHNA AND Thy-1 expression in murine olfactory bulb: XUE AND OTHERS 217 OTHERS 851 Adult Axolotl rat embryo perinatnl ndu coexistence of O-2A and O-2A " progenitors: extracellular matrix in neural crest pathways: PERRIS WOLSWIJK AND OTHERS 691 AND OTHERS 533 Aggregation Axon pattern guidance of Dictyostelium discoideum: FOERSTER AND OTHERS 11 axon patterning at rat floor plate: BOVOLENTA AND Aging DODD 435 NGF receptor in rat dental tissue: BYERS AND OTHERS 461 outgrowth Agouti growth associated protein in chick visual system: cellular action of the mouse lethal yellow mutation: BARSH SCHLOSSHAUER AND OTHERS 395 AND OTHERS 683 rat Ammonia prenatal Schwann cell development: MIRSKY AND promotes cAMP accumulation in Dictyostelium: RILEY AND OTHERS 105 BARCLAY 715 regeneration AMP effects of protease inhibitors: FAWCETT AND HOUSDEN cyclic 59 ammonia promotes cAMP accumulation in Dictyostelium: RILEY AND BARCLAY 715 prenatal Schwann cell development: MIRSKY AND Back-transplantation OTHERS 105 of developing avian bowel: ROTHMAN AND OTHERS 411 Antennapedia Basal body control of mesoderm development by homeotic genes: membrane skeleton domains in Tetrahymena: WILLIAMS REUTER AND SCOTT 289 AND OTHERS 935 expression patterns of the two Drosophila Ant promoters: Basic fibroblast growth factor BERMINGHAM AND OTHERS 553 differential growth of facial mesenchyme in vitro: RICHMAN Anterior AND CROSBY 341 -posterior axis during chick mesoderm induction: MITRANI AND OTHERS organizer amount and axial pattern in Xenopus: 387 STEWART AND GERHART 363 effect on DNA synthesis in human cornea: HYLDAHL AND Anteroposterior polarity OTHERS 605 vasa localization in Drosophila maternal-effect mutants: Battery HAY AND OTHERS 425 cell Antibody nerve cell-battery cell complex in hydra: HOBMAYER AND 04 OTHERS 897 prenatal Schwann cell development: MIRSKY AND BEN OTHERS 105 expression in avian embryonic nervous system: POURQUIE Antigen AND OTHERS 743 dorsal eye antigen in mouse: RABACCHI AND OTHERS 521 bFGF Antineurogenic effect differential growth of facial mesenchyme in vitro: RICHMAN Drosophila Notch mutations: PALKA AND OTHERS 167 AND CROSBY 341 Ascidia during chick mesoderm induction: MITRANI AND OTHERS zygotes 387 tropomyosin/cholinesterase expression: CROWTHER AND effect on DNA synthesis in human cornea: HYLDAHL AND OTHERS 953 OTHERS 605 Astrocyte localization in avian embryos: KALCHEIM AND NEUFELD coexistence of O-2£f*tinaM and O-2Andu" progenitors: 203 WOLSWIJK AND OTHERS 691 bicoid Astroglia determination in Drosophila embryo: DRIEVER AND effects of protease inhibitors: FAWCETT AND HOUSDEN 59 OTHERS 811 980 Subject Index Bilateral symmetry interaction organizer amount and axial pattern in Xenopus: STEWART and differentiation of sea urchin mesomeres: KHANER AND GERHART 363 AND WILT 625 Biological clock Schwann cell-neuron: JESSEN AND OTHERS 91 nucleocytoplasmic ratio in early mouse development: movement EVSIKOV AND OTHERS 323 chick marginal zone, hypoblast and primitive streak Blast ocoel formation: STERN 667 formation nerve nucleocytoplasmic ratio in early mouse development: tentacle morphogenesis in hydra: HOBMAYER AND EVSIKOV AND OTHERS 323 OTHERS 887 Blastomere neural crest cell interaction and differentiation of sea urchin differentiation into Schwann cells: SMITH-THOMAS AND mesomeres: KHANER AND WILT 625 OTHERS 925 Blastula patterning late retinal development in embryonic zebrafish: LARISON organizer amount and axial pattern in Xenopus: AND BREMILLER 567 STEWART AND GERHART 363 rearrangement BMP-2A epithelial morphogenesis during Fundulus epiboly: expression during mouse development: LYONS AND WEUKY AND OSTER 373 satellite OTHERS 833 Bone morphogenetic protein-2A (See BMP-2A) myoblasts promote adult muscle fiber remodelling: HINTERBERGER AND BARALD 139 Bowel -myofiber interaction: BISCHOFF 943 back-transplantation of developing avian bowel: ROTHMAN signals AND OTHERS 411 prenatal Schwann cell development: MIRSKY AND Brachydanio rerio OTHERS 105 expression of a homeodomain protein: MOLVEN AND stem OTHERS 279 sex determination, a heritable mutation in murine Tdy: Brain LOVELL-BADGE AND ROBERTSON 635 segmentation Cellular retinoic acid-binding protein (CRABP) PNA binding, cholinesterases and chick brain vesicles: and CRBP in mammalian embryo: MADEN AND OTHERS LAYER AND ALBER 613 75 BrdU Cellular retinol-binding protein (CRBP) differential growth of chick facial mesenchyme in vitro: and CRABP in mammalian embryo: MADEN AND OTHERS R1CHMAN AND CROSBY 341 75 Brush border Central nervous system formation in chick enterocytes: FATH AND OTHERS 449 coexistence of O-2Aperinnlal and O-2Andu" progenitors: WOLSWUK AND OTHERS 691 Cerebellum cAMP PNA binding, cholinesterases and chick brain vesicles: ammonia promotes cAMP accumulation in Dictyostelium: LAYER AND ALBER 613 RILEY AND BARCLAY 715 Chick Cartilage adult rudiment specification in chick: WOLPERT AND brush border formation in enterocytes: FATH AND HORNBRUCH 961 OTHERS 449 caudal brain ectopic expression in Drosophila: MLODZIK AND OTHERS PNA binding, cholinesterases and chick brain vesicles: 271 LAYER AND ALBER 613 C/EBP embryo localization: KUO AND OTHERS 473 BEN expression in embryonic nervous system: Cell POURQUIE AND OTHERS 743 adhesion FGF during mesoderm induction: MITRANI AND Jl/tenascin in mouse small intestine: PROBSTMEIER AND OTHERS 387 OTHERS 313 IGF peptides: RALPHS AND OTHERS 51 battery marginal zone, hypoblast and primitive streak nerve cell-battery cell complex in hydra: HOBMAYER AND formation: STERN 667 OTHERS 897 transforming growth factors: SMITH AND MCLACHLAN communication 905 in Drosophila neurogenesis: BECKER AND TECHNAU 821 limb cycle cartilage rudiment specification: WOLPERT AND coexistence of O-2AJ*™axai and O-2Aadult progenitors: HORNBRUCH 961 WOLSWUK AND OTHERS 691 -quail chimera regulation of MPF in Xenopus oocytes: JOHNSON AND back-transplantation of developing avian bowel: SMITH 149 ROTHMAN AND OTHERS 411 fate visual system interactions between scute, Notch and Delta: CABRERA growth associated protein: SCHLOSSHAUER AND OTHERS 733 395 Subject Index 981 Chimera Culture Drosophila micromass cell communication: BECKER AND TECHNAU 821 differential growth of facial mesenchyme in vitro: mouse RICHMAN AND CROSBY 341 cellular action of the lethal yellow mutation: BARSH AND Cycle OTHERS 683 cell meiosis: DOLCI AND DE FELICI 37 regulation of MPF in Xenopus oocytes: JOHNSON AND quail-chick SMITH 149 back-transplantation of developing avian bowel: Cyclic AMP ROTHMAN AND OTHERS 411 prenatal Schwann cell development: MIRSKY AND OTHERS sex determination, a heritable mutation in murine Tdy: 105 LOVELL-BADGE AND ROBERTSON 635 Cyclin Chondrocyte regulation of MPF in Xenopus oocytes: JOHNSON AND differential growth of chick facial mesenchyme in vitro: SMITH 149 RICHMAN AND CROSBY 341 Cytoplasmic determinant Ciona intestinalis vasa localization in Drosophila maternal-effect mutants: tropomyosin/cholinesterase expression in ascidian HAY AND OTHERS 425 zygotes: CROWTHER AND OTHERS 953 Cytoskeletal protein c-kit brush border formation in chick enterocytes: FATH AND developmental expression in mouse embryo: ORR- OTHERS 449 URTREGER AND OTHERS 911 Cytoskeleton Cleavage-arrested embryo growth associated protein in chick visual system: tropomyosin/cholinesterase expression in ascidian SCHLOSSHAUER AND OTHERS 395 zygotes: CROWTHER AND OTHERS 953 CNS Defined medium midline differential growth of chick facial mesenchyme in vitro: DER/flb protein localization in Drosophila: ZAK AND RICHMAN AND CROSBY 341 OTHERS 865 Delta Collagen interactions between scute, Notch and Delta: CABRERA TGF-beta 1 and ECM during lung morphogenesis: HEINE 733 AND OTHERS 29 Dendrogenesis Commissurai neuron Thy-1 expression in murine olfactory bulb: XUE AND axon patterning at rat floor plate: BOVOLENTA AND DODD OTHERS 851 435 DER/flb protein CRBP and CRABP in mammalian embryo: MADEN AND localization OTHERS 75 in Drosophila: ZAK AND OTHERS 865 Computerized image processing Determination aggregation patterns of Dictyostelium discoideum: Drosophila FOERSTER AND OTHERS 11 epidermal requirement for Notch: HOPPE AND Cone GREENSPAN 875 mosaic sex retinal development in embryonic zebrafish: LARISON a heritable mutation in murine Tdy: LOVELL-BADGE AND AND BREM1LLER 567 ROBERTSON 635 Confocal laser scanning microscopy Zfy genes in XY female mice: GUBBAY AND OTHERS 647 Funaria endoplasmic reticulum: MCCAULEY AND HEPLER Diacylglycerol 753 protein kinase C and progesterone-induced maturation: Cornea VARNOLD AND SMITH 597 human Dictyostelium discoideum effect of bFGF on DNA synthesis: HYLDAHL AND aggregation patterns: FOERSTER AND OTHERS 11 OTHERS 605 ammonia promotes cAMP accumulation: RILEY AND Cortical differentiation BARCLAY 715 membrane skeleton domains in Tetrahymena: WILLIAMS Differential splicing AND OTHERS 935 of the Oct2 gene: HATZOPOULOS AND OTHERS 349 CRABP Differentiation antigen and CRBP in mammalian embryo: MADEN AND OTHERS prenatal Schwann cell development: MIRSKY AND
Load more

Recommended publications
  • Clonal Dispersion During Neural Tube Formation 4097 of Neuromeres
    Development 126, 4095-4106 (1999) 4095 Printed in Great Britain © The Company of Biologists Limited 1999 DEV2458 Successive patterns of clonal cell dispersion in relation to neuromeric subdivision in the mouse neuroepithelium Luc Mathis1,*, Johan Sieur1, Octavian Voiculescu2, Patrick Charnay2 and Jean-François Nicolas1,‡ 1Unité de Biologie moléculaire du Développement, Institut Pasteur, 25, rue du Docteur Roux, 75724 Paris Cedex 15, France 2Unité INSERM 368, Ecole Normale Supérieure, 46 rue d’Ulm, 75230 Paris Cedex 05, France *Present address: Beckman Institute (139-74), California Institute of Technology, Pasadena, CA, 91125, USA ‡Author for correspondence (e-mail: [email protected]) Accepted 5 July; published on WWW 23 August 1999 SUMMARY We made use of the laacz procedure of single-cell labelling the AP and DV axis of the neural tube. A similar sequence to visualize clones labelled before neuromere formation, in of AP cell dispersion followed by an arrest of AP cell 12.5-day mouse embryos. This allowed us to deduce two dispersion, a preferential DV cell dispersion and then by a successive phases of cell dispersion in the formation of the coherent neuroepithelial growth, is also observed in the rhombencephalon: an initial anterior-posterior (AP) cell spinal cord and mesencephalon. This demonstrates that a dispersion, followed by an asymmetrical dorsoventral (DV) similar cascade of cell events occurs in these different cell distribution during which AP cell dispersion occurs in domains of the CNS. In the prosencephalon, differences in territories smaller than one rhombomere. We conclude that spatial constraints may explain the variability in the the general arrest of AP cell dispersion precedes the onset orientation of cell clusters.
    [Show full text]
  • Stages of Embryonic Development of the Zebrafish
    DEVELOPMENTAL DYNAMICS 2032553’10 (1995) Stages of Embryonic Development of the Zebrafish CHARLES B. KIMMEL, WILLIAM W. BALLARD, SETH R. KIMMEL, BONNIE ULLMANN, AND THOMAS F. SCHILLING Institute of Neuroscience, University of Oregon, Eugene, Oregon 97403-1254 (C.B.K., S.R.K., B.U., T.F.S.); Department of Biology, Dartmouth College, Hanover, NH 03755 (W.W.B.) ABSTRACT We describe a series of stages for Segmentation Period (10-24 h) 274 development of the embryo of the zebrafish, Danio (Brachydanio) rerio. We define seven broad peri- Pharyngula Period (24-48 h) 285 ods of embryogenesis-the zygote, cleavage, blas- Hatching Period (48-72 h) 298 tula, gastrula, segmentation, pharyngula, and hatching periods. These divisions highlight the Early Larval Period 303 changing spectrum of major developmental pro- Acknowledgments 303 cesses that occur during the first 3 days after fer- tilization, and we review some of what is known Glossary 303 about morphogenesis and other significant events that occur during each of the periods. Stages sub- References 309 divide the periods. Stages are named, not num- INTRODUCTION bered as in most other series, providing for flexi- A staging series is a tool that provides accuracy in bility and continued evolution of the staging series developmental studies. This is because different em- as we learn more about development in this spe- bryos, even together within a single clutch, develop at cies. The stages, and their names, are based on slightly different rates. We have seen asynchrony ap- morphological features, generally readily identi- pearing in the development of zebrafish, Danio fied by examination of the live embryo with the (Brachydanio) rerio, embryos fertilized simultaneously dissecting stereomicroscope.
    [Show full text]
  • Expression Patterns of Neural Genes in Euperipatoides Kanangrensis Suggest Divergent Evolution of Onychophoran and Euarthropod Neurogenesis
    Expression patterns of neural genes in Euperipatoides kanangrensis suggest divergent evolution of onychophoran and euarthropod neurogenesis Bo Joakim Eriksson and Angelika Stollewerk1 School of Biological and Chemical Sciences, Queen Mary University of London, London E1 4NS, United Kingdom Edited by Thomas C. Kaufman, Indiana University, Bloomington, IN, and approved November 10, 2010 (received for review June 28, 2010) One of the controversial debates on euarthropod relationships pattern of neurogenesis that has been retained in these groups centers on the question as to whether insects, crustaceans, and and thus cannot be used to resolve euarthropod phylogeny? myriapods (Mandibulata) share a common ancestor or whether Analysis of neurogenesis in a closely related group, the Ony- myriapods group with the chelicerates (Myriochelata). The debate chophora, might shed light on this problem. Although the phy- was stimulated recently by studies in chelicerates and myriapods logenetic position of onychophorans is still debated, many that show that neural precursor groups (NPGs) segregate from the phylogenies group them with euarthropods and possibly tardi- neuroectoderm generating the nervous system, whereas in insects grades in the phylum Arthropoda; thus onychophorans share and crustaceans the nervous tissue is produced by stem cells. Do a common ancestor with euarthropods (8, 19–23). Analyses of the shared neural characters of myriapods and chelicerates repre- neurogenesis in onychophorans suggests that, similar to insects sent derived characters that support the Myriochelata grouping? and crustaceans, single neural precursors are formed in the neu- Or do they rather reflect the ancestral pattern? Analyses of neuro- roectoderm, rather than groups of cells as seen in chelicerates and genesis in a group closely related to euarthropods, the onycho- myriapods (24–26).
    [Show full text]
  • Cephalic Neurulation in the Mouse Embryo Analyzed by SEM and Morphometry
    THE ANATOMICAL RECORD 203:375-396 (1982) Cephalic Neurulation in the Mouse Embryo Analyzed by SEM and Morphometry ANTONE G. JACOBSON AND PATRICK P.L. TAM Department of Zoology. Uniuersity of Texas, Austin, TX 78712 (A.G.J.) and Department of Anatomy, (‘hinese University of Hong Kong, Shatin, N.T., Hong Kong IP.PL.T) ABSTRACT A detailed account of mouse neurulation is given based mostly on SEM analysis over 20 hr of development. Many observations and measure- ments were made on staged living embryos and on embryos prepared for scanning and light microscopy to help deduce what mechanisms may contribute to neural tube formation. Each lateral half of the early cephalic neural plate makes a convex bulge, opposite to the way it must fold to form a tube. Underlying mesenchyme and matrix are reported to have a role in forming these bulges. Processes that form the tube must overcome this opposed folding and the forces that produce it. Crani- al flexure begins long before tube formation. The flexure commences at the rostra1 tip of the cephalic neural plate, then the apex of the flexure migrates caudally to the mesencephalic region. Early appearance of this flexure imposes a mechanical impediment to tube closure in forebrain and midbrain regions. Tube closure begins in the cervical region exactly where the neural plate is reflected dorsally by a bend in the embryo. This bend may mechanically assist closure in this region. Cells of the mouse neural plate are reported to contain organized microfilaments and mi- crotubules, and the plate cells appear to change shape (reduce apical area and in- crease cell height) in the same manner as that suggested in embryos of some other species to contribute to neural tube formation.
    [Show full text]
  • R-Cadherin Expression During Nucleus Formation in Chicken Forebrain Neuromeres
    The Journal of Neuroscience, June 1995, 15(6): 4157-4172 R-Cadherin Expression during Nucleus Formation in Chicken Forebrain Neuromeres Susanne I. I. GBnzler and Christoph Redies Department of Biochemistry, Max Planck Institute for Developmental Biology, D-72072 Tiibingen, Germany The primordial neuroepithelium of the vertebrate forebrait dahl, 1924; Vaage, 1969; Kuhlenbeck, 1973; Puelleset al., 1987; consists of transverse and longitudinal morphogenetic Puelles and Rubenstein, 1993) that represent independentmor- compartments (“neuromeres”). During development, neu- phogenetic fields (Bergquist and KallCn, 1953a,b, 1954; Keyser, rons born in the ventricular zone of each neuromere mi- 1972; Puelleset al., 1987). The boundariesbetween neuromeres grate outward to the mantle zone. Here, neuroblasts grad- often coincide with primordial fiber tracts and restrict cell lin- ually accumulate and aggregate either into sheets (“lami- eage and migration. Generally, they coincide with the borders nae”) or into roundish structures (“nuclei”). As brain ar- of expressionof generegulatory proteins (reviewed in Lumsden, chitecture matures, sets of nuclei and laminae derived from 1990, 1993; Figdor and Stern, 1993; Krumlauf et al., 1993; Puel- several neuromeres become connected by fiber tracts to les and Rubenstein, 1993; Wilson et al., 1993). form functional circuits. We show by immunostaining and During development, a percentageof cells born in the prolif- in situ hybridization techniques that, in the E3-E5 chicken erative (ventricular) zone of each neuromerebecome postmitotic embryo, the cell adhesion molecule R-cadherin is ex- and migrate as neuroblastsoutward into the mantle zone (Sauer, pressed in several stripes and patches in the forebrain neu- 1935; Fujita, 1964; Morest, 1970) in two or three sustained roepithelium.
    [Show full text]
  • Homeotic Gene Action in Embryonic Brain Development of Drosophila
    Development 125, 1579-1589 (1998) 1579 Printed in Great Britain © The Company of Biologists Limited 1998 DEV1254 Homeotic gene action in embryonic brain development of Drosophila Frank Hirth, Beate Hartmann and Heinrich Reichert* Institute of Zoology, University of Basel, Rheinsprung 9, CH-4051 Basel, Switzerland *Author for correspondence (e-mail: [email protected]) Accepted 18 February; published on WWW 1 April 1998 SUMMARY Studies in vertebrates show that homeotic genes are absence of labial, mutant cells are generated and positioned involved in axial patterning and in specifying segmental correctly in the brain, but these cells do not extend axons. identity of the embryonic hindbrain and spinal cord. To Additionally, extending axons of neighboring wild-type gain further insights into homeotic gene action during CNS neurons stop at the mutant domains or project ectopically, development, we here characterize the role of the homeotic and defective commissural and longitudinal pathways genes in embryonic brain development of Drosophila. We result. Immunocytochemical analysis demonstrates that first use neuroanatomical techniques to map the entire cells in the mutant domains do not express neuronal anteroposterior order of homeotic gene expression in the markers, indicating a complete lack of neuronal identity. Drosophila CNS, and demonstrate that this order is An alternative glial identity is not adopted by these mutant virtually identical in the CNS of Drosophila and mammals. cells. Comparable effects are seen in Deformed mutants but We then carry out a genetic analysis of the labial gene in not in other homeotic gene mutants. Our findings embryonic brain development. Our analysis shows that demonstrate that the action of the homeotic genes labial loss-of-function mutation and ubiquitous overexpression of and Deformed are required for neuronal differentiation in labial results in ectopic expression of neighboring the developing brain of Drosophila.
    [Show full text]
  • Boundary Formation and Compartition in the Avian Diencephalon
    The Journal of Neuroscience, July 1, 2001, 21(13):4699–4711 Boundary Formation and Compartition in the Avian Diencephalon Camilla W. Larsen, Lori M. Zeltser, and Andrew Lumsden Medical Research Council Centre for Developmental Neurobiology, King’s College London, London SE1 1UL, England The diencephalon comprises three functionally distinct regions: boundary does not. Similarly, there is no lineage restriction synencephalon, dorsal thalamus, and ventral thalamus. Pat- between the parencephalon and the more rostral forebrain terning of the diencephalon has been proposed to involve (secondary prosencephalon). Subdivision of the parencephalon subdivision of its anteroposterior axis into segments, neuro- into ventral and dorsal thalamus involves the formation of a meres or prosomeres (Bergquist and Kallen, 1954; Vaage, 1969; narrow intraparencephalic territory, the zona limitans intrathal- Figdor and Stern, 1993; Rubenstein et al., 1994; Redies et al., amica (zli). This is correlated with the acquisition of cell lineage 2000; Yoon et al., 2000). However, the number and sequence of restriction at both anterior and posterior borders of the zli, the diencephalic neuromeres, or even their existence, are uncer- appearance of boundary-specific properties, and Gbx2 and tain. We have examined the proposed subdivisions by morphol- Dlx2 expression in dorsal thalamic and ventral thalamic territo- ogy, gene expression, acquisition of boundary-specific pheno- ries, respectively. At stage 22, the synencephalon is divided into types, and cell lineage restriction. We find that at stage 16 in two domains, distinguished by differential gene expression and chick the diencephalon is divided into synencephalon and tissue morphology, but associated with neither a boundary parencephalon. The synencephalon exhibits neuromeric mor- phenotype nor cell lineage restriction.
    [Show full text]
  • The Ontogenesis of Cranial Neuromeres in the Rat Embryo II
    J. Embryol. exp. Morph. 88, 231-247 (1985) 231 Printed in Great Britain © The Company of Biologists Limited 1985 The ontogenesis of cranial neuromeres in the rat embryo II. A transmission electron microscope study FIONA TUCKETT AND GILLIAN M. MORRISS-KAY Department of Human Anatomy, University of Oxford, South Parks Road, Oxford OX1 3QX, U.K. SUMMARY The morphogenesis of rhombomeres (neuromeres) caudal to the preotic sulcus during neurulation in rat embryos is described. A model is proposed to explain the development of the characteristic neuromeric sulci and interneuromeric gyri based on the cytoskeletal elements and the kinetic behaviour of the neural epithelium. Evidence obtained from a study of control, cytochalasin D-treated and colchicine-treated embryos, at the electron microscopic level, supports the proposed model. The longitudinally expanding cranial neural epithelium bulges between microtubule blocks present within the interneuromeric gyri, causing a bulge to develop along the line of least resistance, away from the microfilament-rich luminal border of the neuromeric sulcus region. INTRODUCTION Neuromeres have been observed as a segmental arrangement of sulci and gyri within the early neural tube of all vertebrate embryos. Their characteristic morphology is illustrated in Fig. 1. This study addresses the question of how the sulci and gyri develop from an initially straight neural epithelium, and how their structure is maintained. Observations on a variety of vertebrates (chick, fish, urodeles) led Kallen (1956) to propose that the formation of neuromeric sulci was the result of mitotic patterning within the neural epithelium. His model is based on transverse sections of the neural epithelium during the formation of a neuromere, which he termed a 'proliferation centre'.
    [Show full text]
  • Genetic Mechanisms Underlying Neuromere Specification During Embryonic Brain Development of Drosophila
    GENETIC MECHANISMS UNDERLYING NEUROMERE SPECIFICATION DURING EMBRYONIC BRAIN DEVELOPMENT OF DROSOPHILA Inauguraldissertation zur Erlangung der Würde eines Doktors der Philosophie vorgelegt der Philosophisch-Naturwissenschaftlichen Fakultät der Universität Basel von Simon Gabriel Sprecher aus Basel (BS) Basel 2005 Zoologisches Institut der Universität Basel Biozentrum/Pharmazentrum Klingelbergstrasse 50 CH-4056 Basel Genehmigt von der Philosophisch-Naturwissenschaftlichen Fakultät auf Antrag von Prof Dr. Heinrich Reichert (Fakultätsverantwortlicher) Prof Dr. Reinhard Stocker (Korreferent) Basel, den 5. Juli 2005 Dekan Prof. Dr. Hans-Jakob Wirz …………… - 2 - CONTENTS 1. Summary .......................................................................................................................4 2. Introduction ..................................................................................................................5 2.1. primary anteroposterior axis formation in the Drosophila embryo ...................5 2.2. Development of the central nervous system (CNS) ...........................................5 2.2.1. Neurectoderm formation ........................................................................ 5 2.2.2. Formation of columnar domains............................................................. 7 2.2.3. Neuroblast formation.............................................................................. 8 2.2.4. Primary lineage formation...................................................................... 9 2.3. The embryonic
    [Show full text]
  • Neuroblast Lineage Identification and Lineage-Specific Hox Gene Action
    Developmental Biology 390 (2014) 102–115 Contents lists available at ScienceDirect Developmental Biology journal homepage: www.elsevier.com/locate/developmentalbiology Neuroblast lineage identification and lineage-specific Hox gene action during postembryonic development of the subesophageal ganglion in the Drosophila central brain Philipp A. Kuert a,n, Volker Hartenstein b, Bruno C. Bello a, Jennifer K. Lovick b, Heinrich Reichert a a Biozentrum, University of Basel, Basel, Switzerland b Department of Molecular, Cell and Developmental Biology, University of California, Los Angeles, California, USA article info abstract Article history: The central brain of Drosophila consists of the supraesophageal ganglion (SPG) and the subesophageal Received 22 November 2013 ganglion (SEG), both of which are generated by neural stem cell-like neuroblasts during embryonic and Received in revised form postembryonic development. Considerable information has been obtained on postembryonic develop- 23 March 2014 ment of the neuroblasts and their lineages in the SPG. In contrast, very little is known about neuroblasts, Accepted 29 March 2014 neural lineages, or any other aspect of the postembryonic development in the SEG. Here we characterize Available online 5 April 2014 the neuroanatomy of the larval SEG in terms of tracts, commissures, and other landmark features as Keywords: compared to a thoracic ganglion. We then use clonal MARCM labeling to identify all adult-specific Neuroblast neuroblast lineages in the late larval SEG and find a surprisingly small number of neuroblast lineages, 13 lineage paired and one unpaired. The Hox genes Dfd, Scr, and Antp are expressed in a lineage-specific manner in Hox these lineages during postembryonic development. Hox gene loss-of-function causes lineage-specific Dfd Scr defects in axonal targeting and reduction in neural cell numbers.
    [Show full text]
  • Conserved Genetic Patterning Mechanisms in Insect and Vertebrate Brain Development
    Heredity (2005) 94, 465–477 & 2005 Nature Publishing Group All rights reserved 0018-067X/05 $30.00 www.nature.com/hdy REVIEW Insights into the urbilaterian brain: conserved genetic patterning mechanisms in insect and vertebrate brain development R Lichtneckert and H Reichert Institute of Zoology, Biozentrum/Pharmazentrum, University of Basel, Klingelbergstrasse 50, CH-4056 Basel, Switzerland Recent molecular genetic analyses of Drosophila melanogaster of the otd/Otx and ems/Emx gene families can functionally and mouse central nervous system (CNS) development replace each other in embryonic brain patterning. Homologous revealed strikingly similar genetic patterning mechanisms in genes involved in dorsoventral regionalization of the CNS in the formation of the insect and vertebrate brain. Thus, in both vertebrates and insects show remarkably similar patterning and insects and vertebrates, the correct regionalization and neuronal orientation with respect to the neurogenic region (ventral in identity of the anterior brain anlage is controlled by the cephalic insects and dorsal in vertebrates). This supports the notion gap genes otd/Otx and ems/Emx, whereas members of the that a dorsoventral body axis inversion occurred after the Hox genes are involved in patterning of the posterior brain. separation of protostome and deuterostome lineages in A third intermediate domain on the anteroposterior axis of the evolution. Taken together, these findings demonstrate con- vertebrate and insect brain is characterized by the expression of served genetic patterning mechanisms in insect and vertebrate the Pax2/5/8 orthologues, suggesting that the tripartite ground brain development and suggest a monophyletic origin of the plans of the protostome and deuterostome brains share a brain in protostome and deuterostome bilaterians.
    [Show full text]
  • Neuroembryology and Functional Anatomy of Craniofacial Clefts
    Published online: 2020-01-15 Free full text on www.ijps.org DOI: 10.4103/0970-0358.57184 Review Article Neuroembryology and functional anatomy of craniofacial clefts Ember L. Ewings, Michael H. Carstens Division of Plastic and Reconstructive Surgery, Department of Surgery at Saint Louis University School of Medicine, Saint Louis, MO Address for correspondence: Dr. Michael Carstens, Division of Plastic Surgery, Department of Surgery, St. Louis University Health Sciences Centre, 3635, Vista Avenue at Grand Boulevard, P.O. Box 15250, Saint Louis, MO 63110-0250. E-mail: [email protected] ABSTRACT The master plan of all vertebrate embryos is based on neuroanatomy. The embryo can be anatomically divided into discrete units called neuromeres so that each carries unique genetic traits. Embryonic neural crest cells arising from each neuromere induce development of nerves and concomitant arteries and support the development of speciÞ c craniofacial tissues or developmental Þ elds. Fields are assembled upon each other in a programmed spatiotemporal order. Abnormalities in one Þ eld can affect the shape and position of developing adjacent Þ elds. Craniofacial clefts represent states of excess or deÞ ciency within and between speciÞ c developmental Þ elds. The neuromeric organization of the embryo is the common denominator for understanding normal anatomy and pathology of the head and neck. Tessier’s observational cleft classiÞ cation system can be redeÞ ned using neuroanatomic embryology. Reassessment of Tessier’s empiric observations demonstrates a more rational rearrangement of cleft zones, particularly near the midline. Neuromeric theory is also a means to understand and deÞ ne other common craniofacial problems.
    [Show full text]