Cortical Development
Neural Diversity and Neocortical Organization
1st Edition
Published on 30. September 2013
VIII, 282 pages
978-4-431-54496-8 (ISBN)
Description
This book reviews recent progress in cortical development research, focusing on the mechanisms of neural stem cell regulation, neuronal diversity and connectivity formation, and neocortical organization. Development of the cerebral cortex, the center for higher brain functions such as cognition, memory, and decision making, is one of the major targets of current research. The cerebral cortex is divided into many areas, including motor, sensory, and visual cortices, each of which consists of six layers containing a variety of neurons with different activities and connections. As this book explains, such diversity in neuronal types and connections is generated at various levels. First, neural stem cells change their competency over time, giving sequential rise to distinct types of neurons and glial cells: initially deep layer neurons, then superficial layer neurons, and lastly astrocytes. The activities and connections of neurons are further modulated via interactions with other brain regions, such as the thalamocortical circuit, and via input from the environment. This book on cortical development is essential reading for students, postdocs, and neurobiologists.
More details
Series
Language
English
Place of publication
Tokyo
Japan
Publishing group
Springer Tokyo
Target group
Professional and scholarly
Product notice
Reflowable
Illustrations
VIII, 282 p. 67 illus., 56 illus. in color.
File size
8,51 MB
ISBN-13
978-4-431-54496-8 (9784431544968)
DOI
10.1007/978-4-431-54496-8
Schweitzer Classification
Other editions
Additional editions
Ryoichiro Kageyama | Tetsuo Yamamori
Cortical Development
Neural Diversity and Neocortical Organization
Book
10/2013
1st Edition
Springer
€106.99
Shipment within 10-15 days
Content
- Intro
- Preface
- Contents
- Chapter 1: Dynamic Notch Signaling in Neural Progenitor Cells
- 1.1 Introduction
- 1.2 The Core Pathway of Notch Signaling
- 1.3 Oscillatory Expression of Notch Signaling Genes
- 1.4 The Mechanism of Oscillatory Expression: Lessons from the Segmentation Clock
- 1.5 Basal Progenitors and Outer Subventricular Zone (OSVZ) Progenitors
- 1.6 Sustained Hes1 Expression in Boundary Cells
- 1.7 Downstream Events of Hes1 and Neurog2 Oscillations
- 1.8 Conclusions
- References
- Chapter 2: Proneural Proteins and the Development of the Cerebral Cortex
- 2.1 Introduction
- 2.2 Cellular Functions of Proneural Genes in Telencephalic Development
- 2.2.1 Proneural Genes and the Neuronal Versus Glial Fate Decision
- 2.2.2 Neurogenin Proteins and the Specification of Telencephalic Projection Neurons
- 2.2.3 Ascl1 Protein and the Specification of Telencephalic GABAergic Neurons
- 2.2.4 Proneural Proteins and the Regulation of Neuronal Migration
- 2.2.5 Neurog2 and the Regulation of Axon Projections
- 2.3 Molecular Mechanisms Underlying Proneural Gene Activity
- 2.3.1 Regulation of Proneural Gene Expression and Activity
- 2.3.2 Transcriptional Targets of Proneural Genes
- 2.3.3 Interaction of Proneural Proteins with Other Transcription Factors
- 2.3.4 Cofactors of Proneural Proteins
- 2.4 Conclusion
- References
- Chapter 3: The Role of the Transcription Factor Pax6 in Brain Development and Evolution: Evidence and Hypothesis
- 3.1 Pax6 is a Highly Conserved Transcription Factor
- 3.2 Pax6 in Embryonic Neurogenesis
- 3.3 Pax6 in Postnatal Neurogenesis
- 3.4 Pax6 Expression in the Developing Primate Neocortex
- 3.5 Molecules Downstream of Pax6
- 3.6 Importance of Basal Processes and Possible Involvement of Pax6
- 3.7 The Role of Pax6 in Brain Evolution: A Hypothesis
- 3.8 Pax6: Possible Involvement in Neurodevelopmental Diseases?
- 3.9 Future Perspectives
- References
- Chapter 4: Regulatory Mechanisms Underlying the Neurogenesis-to-Gliogenesis Switch by Neural Stem Cells
- 4.1 Introduction
- 4.2 Stem Cell Development and Progenitor Heterogeneity
- 4.3 Stochastic Differentiation
- 4.4 Deterministic Differentiation
- 4.5 Acquisition of Gliogenic Competence
- 4.6 Timing of Differentiation
- 4.7 Concluding Remarks
- References
- Chapter 5: Specification of GABAergic Neocortical Interneurons
- 5.1 GABAergic Interneurons of the Cerebral Cortex
- 5.2 Neocortical Interneurons Originate from the Ventral Telencephalon
- 5.3 Spatial and Temporal Origins of Interneuron Subtypes
- 5.3.1 The Four Major Classes of Neocortical Interneurons
- 5.3.2 MGE-Derived Interneurons
- 5.3.3 CGE-Derived Interneurons
- 5.3.4 Interneuron Markers Beyond PV, SST, RELN, and VIP
- 5.4 Interneuron Specification by Transcription Factors
- 5.4.1 Telencephalic GABAergic Cell Fate Specification
- 5.4.2 GABAergic Cell Fate Specification Within the Ventricular and Subventricular Zones
- 5.4.3 Postmitotic Regulation of Interneuron Development
- 5.4.4 Transcriptional Cascades for Specific Interneuron Subtypes
- 5.5 Interneuron Migration and Integration into the Cerebral Cortex
- 5.5.1 Initiation of Tangential Migration Towards the Developing Neocortex
- 5.5.2 Tangential Migration Within the Neocortex
- 5.5.3 Radial Migration During Laminar Fate Determination
- 5.5.4 Migration of Hippocampal Interneuron Precursors Through the Neocortex
- 5.6 Novel Concepts in Neocortical Interneuron Development
- References
- Chapter 6: Regulation of Cortical Circuit Formation
- 6.1 Regulation of Cortical Circuit Formation
- 6.2 General Structure of Cortical Connectivity
- 6.3 Corticofugal Neurons
- 6.3.1 Development of Corticofugal Tracts
- 6.3.2 Guidance Factors and Receptors that Direct Corticofugal Axons
- 6.4 The Formation of Intracortical Circuits
- 6.4.1 The Development of Callosal Projecting Neurons
- 6.4.2 Factors that Regulate Selectivity of the Synapse: From Intra-Columnar and Intra-Laminar Connectivity to Microcircuits
- 6.4.3 The Regulation of Dendritic Structures
- 6.5 Molecular Identity of Cortical Neurons: Layer and Area Identity as Determinants of Connectivity
- 6.5.1 Transcription Factors in Lower Layers
- 6.5.2 Transcription Factors in Superficial Layers
- 6.5.3 Area-Specific TF
- References
- Chapter 7: Neocortical Neurogenesis and Circuit Assembly
- 7.1 Excitatory Neuron Production, Migration, and Laminar Organization
- 7.2 Inhibitory Interneuron Production, Migration, and Laminar Distribution
- 7.3 Neocortical Circuits
- 7.3.1 Functional Columns
- 7.3.2 Canonical Neocortical Circuit
- 7.4 Neocortical Circuit Assembly
- 7.4.1 Microcircuit Construction
- 7.4.1.1 Projection-Dependent Specificity
- 7.4.1.2 Lineage-Dependent Specificity
- 7.4.1.3 Interneuron Synaptic Targeting Specificity
- 7.4.1.4 Interneuron Electrical-Coupling Specificity
- 7.4.2 Long-Range Connection Establishment
- 7.4.2.1 Thalamocortical Projections
- 7.4.2.2 Corticofugal and Callosal Projections
- 7.4.3 Activity-Dependent Modification of Neocortical Circuits
- 7.5 Concluding Remarks
- References
- Chapter 8: Hierarchical Organization of Neocortical Neuron Types
- 8.1 Introduction
- 8.2 Pyramidal Cell Organization
- 8.2.1 Extracortical Target Differences Between Layers
- 8.2.2 Selective Cholinergic Modulation of Superficial and Deep Pyramidal Cells
- 8.3 Organization of L5 Pyramidal Cells Innervating the Striatum and Pontine Nuclei
- 8.3.1 L5 Pyramidal Cell Heterogeneity
- 8.3.1.1 L5 Sublaminar Structures in the Frontal Cortex
- 8.3.1.2 Firing Pattern Diversity Among L5 Pyramidal Cells
- 8.3.1.3 L5 COM Cell Heterogeneity
- 8.3.1.4 L5 CPn Cell Heterogeneity
- 8.3.2 Excitatory Interlaminar Connections from L2/3 to L5
- 8.3.3 Pyramidal Cell Subtypes in the Cortico-Subcortical Loop
- 8.3.3.1 Morphologies of CCS and CPn Cells
- 8.3.3.2 Hierarchical Connection from CCS to CPn Cells
- 8.3.3.3 Connection Characteristics Within the CCS and CPn Cell Groups
- 8.3.4 Pyramidal Cell Subtypes and Local Reverberating Circuit
- 8.3.5 Relationship Between Corticostriatal Projection Diversity and Basal Ganglia Internal Structure
- 8.3.5.1 Corticostriatal Input Preferences for Individual Basal Ganglia Pathways
- 8.3.5.2 Thalamocortical Input Heterogeneity to the Frontal Cortex
- 8.3.5.3 Mechanism of Induction for Selected Actions Via the Cortico- Basal Ganglia-Thalamic Loop
- 8.3.5.4 Evaluation of Performed Actions Through the Cortico-Striato- Nigro-Striatal Pathway
- 8.4 Pyramidal Cells Projecting to the Parahippocampal Area
- 8.4.1 Multiple Projection Channels from the Frontal Cortex to Perirhinal Cortex
- 8.4.2 Local Circuit Specification is Dependent on Procedural and Declarative Memory Systems
- 8.5 GABAergic Cell Organization
- 8.5.1 Expression Specificity of Molecular Markers in Neocortical GABAergic Cells
- 8.5.2 Firing Pattern Diversity
- 8.5.3 Morphological Diversity
- 8.5.4 Correlation of Molecular Expression with Physiological and Morphological Characteristics
- 8.5.5 Selective Cholinergic Modulation of GABA Cell Subtypes
- 8.6 Synaptic Interactions Between Excitatory and Inhibitory Subnetworks
- References
- Chapter 9: Emerging Roles of Heparan Sulfate in Axon Guidance Signaling
- 9.1 Axon Guidance Molecules
- 9.2 Axon Guidance Receptors
- 9.3 Axon Guidance by Classical Morphogens
- 9.4 Heparan Sulfate: Its Structural and Functional Diversity
- 9.5 HS Biosynthetic Pathway
- 9.6 Roles of HS in Brain Development
- 9.7 Extracellular Sulfatases that Modify HS Structures
- 9.8 Physiologic Roles of Extracellular Sulfatases in the Nervous System
- References
- Chapter 10: The Roles of RECK, a Membrane-Anchored Regulator of Pericellular Proteolysis, in Neural Development
- 10.1 Introduction
- 10.2 Discovery of RECK as a Transformation Suppressor
- 10.3 Properties of RECK Protein
- 10.4 RECK in Cell Behaviors
- 10.5 RECK in Development
- 10.6 RECK in Neurogenesis
- 10.7 RECK in Corticogenesis
- 10.8 RECK in Brain Functions
- 10.9 Future Directions
- References
- Chapter 11: Synapse Formation in the Brain
- 11.1 Introduction
- 11.2 Molecular Mechanism of Synapse Formation in the Cerebellum
- 11.3 IL1RAPL1 Mediates Synapse Formation In Vivo of Olfactory Sensory Neurons in Zebrafish
- 11.4 IL1RAPL1 is a Synapse Organizer of Mouse Cortical Neurons
- 11.5 Interleukin-1 Receptor Accessory Protein (IL-1RAcP) Organizes Neuronal Synaptogenesis as a Cell Adhesion Molecule
- 11.6 Synapse Organizers in the Brain
- References
- Chapter 12: Genomic Imprinting in the Mammalian Brain
- 12.1 Discovery of Imprinting and Roles for Imprinted Genes in Brain Function and Behavior
- 12.2 Regulation of Imprinting
- 12.3 Next-Generation Sequencing and the Analysis of Imprinting in the Brain
- 12.4 Future Directions
- References
- Chapter 13: Genes Selectively Expressed in the Visual Cortex of the Old World Monkey
- 13.1 Introduction
- 13.2 Genes that are Selectively Expressed in V1
- 13.3 SEMA7A Expression in Macaque Cortical Areas
- 13.4 Characteristics of SEMA7A Expression in Subcortical Regions of Macaque Brain
- 13.5 Response of SEMA7A Expression to Monocular Inhibition (MI)
- 13.6 SEMA7A Expression in Visual Cortex During Development
- 13.7 Classification of Selectively V1-Expressed Genes
- 13.8 Expression Patterns of Area-Selective Gene Expressions in Macaque Monkeys and Their Implications
- References
- Index
