Development of the central nervous system

2013 ◽  
Author(s):  
Martin E. Atkinson
Keyword(s):  
Spinal Cord ◽  
Nervous System ◽  
Neural Tube ◽  
Large Diameter ◽  
Floor Plate ◽  
Neural Plate ◽  
Ependymal Cells ◽  
High Dose ◽  
Neuronal Processes ◽  
Mantle Layer

The early development of the nervous system, the process of neurulation, has already been outlined in Chapter 8 and illustrated in Figure 8.4. To briefly recap, an area of dorsal ectoderm is induced by the underlying notochord to form the neural plate during the third week of development. The lateral edges of the neural plate rise to form the neural folds which eventually fold over and unite in the midline by the end of the fourth week to produce the neural tube. A distinct cell population on the crest of the neural folds, the neural crest, migrates from the forming neural tube to form various structures, including components of the peripheral nervous system. The closed neural tube consists of a large diameter anterior portion that will become the brain and a longer cylindrical posterior section, the future spinal cord. Initially, the neural plate is a single cell layer, but concentric layers of cells can be recognized by the time the neural tube has closed. An inner layer of ependymal cells surrounds the central spinal canal. Neuroblasts, the precursors of neurons, make up the bulk of the neural tube called the mantle layer; this will become the grey matter of the spinal cord. Neuroblasts do not extend processes until they have completed their differentiation. When the cells in a particular location are fully differentiated, the neuronal processes emerging from the neuroblasts form an outer marginal layer which ultimately becomes the white matter of the spinal cord. Figure 19.1B shows that the neural tube changes shape due to proliferation of cells in the mantle layer. This figure also indicates two midline structures in the roof and floor of the tube, known as the roof plate and floor plate. They are important in the determination of the types of neurons that develop from the mantle layer. The floor plate is induced by the expression of a protein product of a gene called sonic hedgehog (SHH) produced by the underlying notochord; the floor plate then expresses the same gene itself. Neuroblasts nearest to the floor plate receive a high dose of SHH protein and respond by differentiating into motor neurons; as seen in Figure 19.1B, these cells group together to form bilateral ventrolateral basal plates.

Neurodevelopment

2020 ◽  
pp. 91-100
Author(s):  
Karl Zilles ◽  
Nicola Palomero-Gallagher
Keyword(s):  
Spinal Cord ◽  
Nervous System ◽  
Neural Tube ◽  
Neural Plate ◽  
Adult Brain ◽  
The Central Nervous System ◽  
Specialized Region ◽  
The Brain ◽  
Rostral Part ◽  
Human Nervous System

The pre- and post-natal development of the human nervous system is briefly described, with special emphasis on the brain, particularly the cerebral and cerebellar cortices. The central nervous system originates from a specialized region of the ectoderm—the neural plate—which develops into the neural tube. The rostral part of the neural tube forms the adult brain, whereas the caudal part (behind the fifth somite) differentiates into the spinal cord. The embryonic brain has three vesicular enlargements: the forebrain, the midbrain, and the hindbrain. The histogenesis of the spinal cord, hindbrain, cerebellum, and cerebral cortex, including myelination, is discussed. The chapter closes with a description of the development of the hemispheric shape and the formation of gyri.

The role of retinoid-binding proteins in the generation of pattern in the developing limb, the regenerating limb and the nervous system

Development ◽  
1989 ◽  
Vol 107 (Supplement) ◽  
pp. 109-119 ◽  
Author(s):  
M. Maden ◽  
D. E. Ong ◽  
D. Summerbell ◽  
F. Chytil
Keyword(s):  
Nervous System ◽  
Retinoic Acid ◽  
Chick Embryo ◽  
Neural Tube ◽  
Floor Plate ◽  
Limb Bud ◽  
Commissural Axons ◽  
New Information ◽  
Mantle Layer ◽  
Developing Nervous System

We summarise existing data and describe new information on the levels and distribution of cellular retinoic acid-binding protein (CRABP) and cellular retinolbinding protein (CRBP) in the regenerating axolotl limb, the developing chick limb bud and the nervous system of the chick embryo in the light of the known morphogenetic effects of retinoids on these systems. In the regenerating limb, levels of CRABP rise 3- to 4-fold during regeneration, peaking at the time when retinoic acid (RA) is most effective at causing pattern duplications. The levels of CRBP are low. The potency of various retinoids in causing pattern respecification correlates well with the ability of these compounds to bind to CRABP. In the chick limb bud, the levels of CRABP are high and the levels of CRBP are low. Again the binding of various retinoids to CRABP correlates well with their ability to cause pattern duplications. By immunocytochemistry, we show that CRABP is present at high levels in the progress zone of the limb bud and is distributed across the anteroposterior axis in a gradient with the high point at the anterior margin. In the chick embryo, CRABP levels are high and CRBP levels are low. By immunocytochemistry, CRABP is localised primarily to the developing nervous system, labelling cells and axons in the mantle layer of the neural tube. These become the neurons of the commissural system. Also sensory axons label intensely with CRABP whereas motor axons do not and in the mixed nerves at the brachial plexus sensory and motor components can be distinguished on this basis. In the neural tube, CRBP only stains the ventral floor plate. Since the ventral floor plate may be a source of chemoattractant for commissural axons, we suggest on the basis of these staining patterns that RA may fulfill this role and thus be involved morphogenetically in the developing nervous system.

Identification of early developing axon projections from spinal interneurons in the chick embryo with a neuron specific beta-tubulin antibody: evidence for a new ‘pioneer’ pathway in the spinal cord

Development ◽  
1990 ◽  
Vol 108 (4) ◽  
pp. 705-716 ◽  
Author(s):  
H. Yaginuma ◽  
T. Shiga ◽  
S. Homma ◽  
R. Ishihara ◽  
R.W. Oppenheim
Keyword(s):  
Spinal Cord ◽  
Chick Embryo ◽  
Neural Tube ◽  
Floor Plate ◽  
C Cells ◽  
Beta Tubulin ◽  
Cell Groups ◽  
Neuronal Processes ◽  
Longitudinal Association ◽  
Chick Spinal Cord

The early development of interneurons in the chick embryo spinal cord was studied using a monoclonal antibody against a neuron-specific beta-tubulin isoform. Early developing interneurons were divided into two cell groups on the basis of their location and the pattern of growth of their axons. One group is composed of cells that establish a primitive longitudinal pathway (PL-cells), whereas the other group contains cells constituting a circumferential pathway (C-cells). The onset of axonal development in both cell groups occurs at stage (st.) 15 (embryonic day, (E), 2) in the branchial segments, which is prior to axonogenesis of motoneurons. PL-cells develop in the region between the floor plate and the motoneuron nucleus. Their axons are the first neuronal processes (‘pioneer axons’) to arrive in the ventrolateral marginal zone and they project both rostrally and caudally to establish a primitive longitudinal association pathway at the ventrolateral surface of the neural tube. This pathway is formed before axons of C-cells arrive in the ventrolateral region. The first C-cells are initially located in the most dorsal portion of the neural tube, whereas later appearing C-cells are also located in both intermediate and ventral regions of the neural tube. The axons of C-cells project ventrally, without fasciculating, along the lateral border of the neural tube. Some of their axons enter the ipsilateral ventrolateral longitudinal pathway at st. 17. We often observed apparent contacts and interactions between preexisting axons of PL-cells and newly arriving axons of C-cells. The axons of commissural C-cells first enter the floor plate at st. 17 and cross the midline at st. 18. Axons of C cells begin to join the contralateral ventrolateral longitudinal pathway at st. 18+ to st. 19. In the floor plate region, contacts between growth cones and axons were often observed. However, axons in the floor plate at these stages were not fasciculated. These observations establish the timing and pattern of growth of axons from two specific populations of early developing interneurons in the chick spinal cord. Additionally, we have identified an early and apparently previously undescribed ‘pioneer’ pathway that constitutes the first longitudinal pathway in the chick spinal cord.

Analysis of the development of the nervous system of the zebrafish, Brachydanio rerio

Development ◽  
1968 ◽  
Vol 19 (2) ◽  
pp. 109-119
Author(s):  
Judith Shulman Weis
Keyword(s):  
Spinal Cord ◽  
Nervous System ◽  
Neural Crest ◽  
Neural Tube ◽  
Sympathetic Neurons ◽  
Dorsal Surface ◽  
Teleost Fishes ◽  
Brachydanio Rerio ◽  
Solid Structure ◽  
Derivatives Of

In teleost fishes, unlike many other vertebrates, the spinal cord originates as a solid structure, the neural keel, which subsequently hollows out. Unlike vertebrates in which the neural tube is formed from neural folds, and where the neural crest arises from wedge-shaped masses of tissue connecting the neural tube to the general ectoderm, teleosts do not possess a clear morphological neural crest. Initially, the dorsal surface of the keel is broadly attached to the ectoderm as described by Shepard (1961). As the neural primordia become larger and more discrete, the region of attachment narrows, and cells become loose (the ‘loose crest stage’). These cells represent the neural crest. Subsequently they begin to migrate and to differentiate into the various derivatives of neural crest. Both sensory and sympathetic neurons arise from neural crest. At the time of their migration the cells are not morphologically distinguishable.

scholarly journals An overlooked cause of longitudinally extensive spinal cord lesions: Primary central nervous system lymphoma

2020 ◽  
Author(s):  
Meng Wang ◽  
Baochang Qi ◽  
Jinming Han ◽  
Chunjie Guo ◽  
Limei Qu ◽  
...  
Keyword(s):  
Spinal Cord ◽  
Central Nervous System ◽  
Nervous System ◽  
Central Nervous System Lymphoma ◽  
High Dose Chemotherapy ◽  
Lower Limbs ◽  
Whole Body ◽  
Sensory Loss ◽  
High Dose ◽  
Spinal Cord Lesions

Abstract Background: Primary central nervous system lymphoma (PCNSL ) is a rare and aggressive malignant tumor. It is easy to be misdiagnosed due to its low incidence and unspecific presentations in clinical practice. PCNSL mainly occurs intracranially in the brain while spinal cord is rarely involved. Case presentation: Here we report a 76-year-old woman who had a suspicious tumor history and presented retardant paralysis, bladder dysfunction and sensory loss of the lower limbs. Magnetic resonance imaging (MRI) of the thoracic spine disclosed longitudinally extensive lesions extending from thoracic 4 (T4) to lumbar 1 (L1) vertebral level with an enhanced nodular lesion noting at levels of T10 and T11 . In order to further identify the cause, the whole body 18 F-fluorodeoxyglucose ( 18 F-FDG) positron emission tomography (PET)/computed tomography (CT) was performed and showed a hypermetabolic nodule corresponded to MRI enhancing lesions, which further suggesting the possibility of a tumor. The patient then underwent a surgical resection and spinal cord biopsy confirmed the diagnosis of non-Hodgkin's lymphoma (diffuse large B-cell type). The patient then received a high-dose chemotherapy based on methotrexate combined with Rituximab. Unfortunately, the symptoms of this patient have not been improved significantly after three rounds of chemotherapy. Conclusion: Our case indicates that PCNSL may also serve as a possible cause for longitudinally extensive spinal cord lesions, especially the patients who had a suspicious tumor history, MRI enhancing lesion s in the spinal cord corresponded to hypermetabolic nodules on 18 F-FDG- PET/CT at the same level.

FGF signalling controls the timing of Pax6 activation in the neural tube

Development ◽  
2000 ◽  
Vol 127 (22) ◽  
pp. 4837-4843 ◽  
Author(s):  
N. Bertrand ◽  
F. Medevielle ◽  
F. Pituello
Keyword(s):  
Spinal Cord ◽  
Neural Tube ◽  
Inhibitory Activity ◽  
Neural Plate ◽  
Presomitic Mesoderm ◽  
Pax6 Expression ◽  
Epithelial Development ◽  
Repressive Effect ◽  
Caudal Regression ◽  
Fgf Signalling

We have recently demonstrated that Pax6 activation occurs in phase with somitogenesis in the spinal cord. Here we show that the presomitic mesoderm exerts an inhibitory activity on Pax6 expression. This repressive effect is mediated by the FGF signalling pathway. The presomitic mesoderm displays a decreasing caudorostral gradient of FGF8, and grafting FGF8-soaked beads at the level of the neural tube abolishes Pax6 activation. Conversely, when FGF signalling is disrupted, Pax6 is prematurely activated in the neural plate. We propose that the progression of Pax6 activation in the neural tube is controlled by the caudal regression of the anterior limit of FGF activity. Hence, as part of its posteriorising activity, FGF8 downregulation acts as a switch from early (posterior) to a later (anterior) state of neural epithelial development.

Dorsoventral patterning of the vertebrate neural tube is conserved in a protochordate

Development ◽  
1997 ◽  
Vol 124 (12) ◽  
pp. 2335-2344 ◽  
Author(s):  
J.C. Corbo ◽  
A. Erives ◽  
A. Di Gregorio ◽  
A. Chang ◽  
M. Levine
Keyword(s):  
In Situ Hybridization ◽  
Neural Tube ◽  
Common Ancestor ◽  
Differential Regulation ◽  
Floor Plate ◽  
Ependymal Cells ◽  
Dorsoventral Patterning ◽  
Promoter Fusion ◽  
Dorsal Ectoderm

The notochord and dorsal ectoderm induce dorsoventral compartmentalization of the vertebrate neural tube through the differential regulation of genes such as HNF-3beta, Pax3, Pax6 and snail. Here we analyze the expression of HNF-3beta and snail homologues in the ascidian, Ciona intestinalis, a member of the subphylum Urochordata, the earliest branch in the chordate phylum. A combination of in situ hybridization and promoter fusion analyses was used to demonstrate that the Ciona HNF-3beta homologue is expressed in the ventralmost ependymal cells of the neural tube, while the Ciona snail homologue is expressed at the junction between the invaginating neuroepithelium and dorsal ectoderm, similar to the patterns seen in vertebrates. These findings provide evidence that dorsoventral compartmentalization of the chordate neural tube is not an innovation of the vertebrates. We propose that precursors of the floor plate and neural crest were present in a common ancestor of both vertebrates and ascidians.

Developmental Overview of Central Neuroanatomy

2017 ◽  
Author(s):  
Peggy Mason
Keyword(s):  
Spinal Cord ◽  
Central Nervous System ◽  
Cerebrospinal Fluid ◽  
Nervous System ◽  
Cerebral Cortex ◽  
Neural Tube ◽  
The Central Nervous System ◽  
Dorsal Telencephalon ◽  
Adult Spinal Cord ◽  
The Brain

The central nervous system develops from a proliferating tube of cells and retains a tubular organization in the adult spinal cord and brain, including the forebrain. Failure of the neural tube to close at the front is lethal, whereas failure to close the tube at the back end produces spina bifida, a serious neural tube defect. Swellings in the neural tube develop into the hindbrain, midbrain, diencephalon, and telencephalon. The diencephalon sends an outpouching out of the cranium to form the retina, providing an accessible window onto the brain. The dorsal telencephalon forms the cerebral cortex, which in humans is enormously expanded by growth in every direction. Running through the embryonic neural tube is an internal lumen that becomes the cerebrospinal fluid–containing ventricular system. The effects of damage to the spinal cord and forebrain are compared with respect to impact on self and potential for improvement.

scholarly journals Signals from the notochord and floor plate regulate the region-specific expression of two Pax genes in the developing spinal cord

Development ◽  
1993 ◽  
Vol 117 (3) ◽  
pp. 1001-1016 ◽  
Author(s):  
M.D. Goulding ◽  
A. Lumsden ◽  
P. Gruss
Keyword(s):  
Gene Expression ◽  
Spinal Cord ◽  
Neural Tube ◽  
Neural Progenitor Cells ◽  
Expression Patterns ◽  
Primitive Streak ◽  
Floor Plate ◽  
Neural Patterning ◽  
Specific Expression ◽  
Early Effect

Members of the paired box (Pax) gene family are expressed in discrete regions of the developing central nervous system, suggesting a role in neural patterning. In this study, we describe the isolation of the chicken homologues of Pax-3 and Pax-6. Both genes are very highly conserved and share extensive homology with the mouse Pax-3 and Pax-6 genes. Pax-3 is expressed in the primitive streak and in two bands of cells at the lateral extremity of the neural plate. In the spinal cord, Pax-6 is expressed later than Pax-3 with the first detectable expression preceding closure of the neural tube. When the neural tube closes, transcripts of both genes become dorsoventrally restricted in the undifferentiated mitotic neuroepithelium. We show that the removal of the notochord, or implantation of an additional notochord, dramatically alter the dorsoventral (DV) expression patterns of Pax-3 and Pax-6. These manipulations suggest that signals from the notochord and floor plate regulate the establishment of the dorsoventrally restricted expression domains of Pax-3 and Pax-6 in the spinal cord. The rapid changes to Pax gene expression that occur in neural progenitor cells following the grafting of an ectopic notochord suggest that changes to Pax gene expression are an early effect of the notochord on spinal cord patterning.

Induction of floor plate differentiation by contact-dependent, homeogenetic signals

Development ◽  
1993 ◽  
Vol 117 (1) ◽  
pp. 205-218 ◽  
Author(s):  
M. Placzek ◽  
T.M. Jessell ◽  
J. Dodd
Keyword(s):  
Axon Guidance ◽  
Neural Tube ◽  
Floor Plate ◽  
Cell Patterning ◽  
Neural Plate ◽  
Neural Cells ◽  
Cellular Mechanisms ◽  
Prechordal Mesoderm ◽  
Specific Antigens ◽  
Inductive Signals

The floor plate is located at the ventral midline of the neural tube and has been implicated in neural cell patterning and axon guidance. To address the cellular mechanisms involved in floor plate differentiation, we have used an assay that monitors the expression of floor-plate-specific antigens in neural plate explants cultured in the presence of inducing tissues. Contact-mediated signals from both the notochord and the floor plate act directly on neural plate cells to induce floor plate differentiation. Floor plate induction is initiated medially by a signal from the notochord, but appears to be propagated to more lateral cells by homeogenetic signals that derive from medial floor plate cells. The response of neural plate cells to inductive signals declines with embryonic age, suggesting that the mediolateral extent of the floor plate is limited by a loss of competence of neural cells. The rostral boundary of the floor plate at the midbrain-forebrain junction appears to result from the lack of inducing activity in prechordal mesoderm and the inability of rostral neural plate cells to respond to inductive signals.

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