Vertebrate Myogenesis
(Sprache: Englisch)
The development of vertebrate muscle has long been a major area of research in developmental biology. During the last decade, novel technical approaches have allowed us to unravel to a large extent the mechanisms underlying muscle formation, and myogenesis...
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The development of vertebrate muscle has long been a major area of research in developmental biology. During the last decade, novel technical approaches have allowed us to unravel to a large extent the mechanisms underlying muscle formation, and myogenesis has arguably become one of the best-understood paradigms for cellular differentiation. This book concisely summarizes our current knowledge about muscle development in vertebrates, from the determination of muscle precursors to terminal differentiation. Each chapter has been written by an expert in the field, and particular emphasis has been placed on the different developmental and molecular pathways followed by the three types of vertebrate musculature - striated, heart and smooth muscle.
Klappentext zu „Vertebrate Myogenesis “
The development of vertebrate muscle has long been a major area of research in developmental biology. During the last decade, novel technical approaches have allowed us to unravel to a large extent the mechanisms underlying muscle formation, and myogenesis has become one of the best-understood paradigms for cellular differentiation. This book concisely summarizes our current knowledge about muscle development in vertebrates, from the determination of muscle precursors to terminal differentiation. Each chapter has been written by an expert in the field, and particular emphasis has been placed on the different developmental and molecular pathways followed by the three types of vertebrate musculature - skeletal, heart and smooth muscle.
Inhaltsverzeichnis zu „Vertebrate Myogenesis “
- Development of Visceral Smooth Muscles1 Early Appearance of Smooth Muscles
2 Timing of Smooth Muscle Development
3 Morphology of Developing Smooth Muscles
4 Cytological Differentiation
5 Chemical Differentiation
6 Growth of Visceral Smooth Muscles
7 Cell Division and Increase in Cell Number
8 Extracellular Materials and Vascularization
9 Origin of Smooth Muscle Precursors
10 Influence of Endothelium, Epithelium, Connective Tissue and Nerves on Smooth Muscle Development
10.1 Role of Endothelium and Epithelium
10.2 Role of Mesenchymal Cells and the Extracellular Matrix
10.3 Role of Nerves
11 Development of Mechanical Activity
12 Related Processes of Development and Growth
13 Synopsis
- References
- Mammalian Smooth Muscle Differentiation: Origins, Markers and Transcriptional Control
1 Introduction
2 Smooth Muscle Cell Ontogeny
2.1 Evolutionary Concepts
2.2 Embryological Origins of SMC
2.3 Models for Studying SMC Differentiation
3 Molecular Definitions of Smooth Muscle Cell Lineages
3.1 SMC-Restricted Markers
3.2 SMC-Restricted Promoter Activity
4 Future Perspectives
- References
- The Genetics of Murine Skeletal Muscle Biogenesis
1 Introduction
2 The Restriction of Cell Fate and Views on Cell Determination
3 The Somite Is a Source of Multiple Cell Types
4 The Acquisition of Cell Fate in the Somite: Myf5 and Myod Confer Skeletal Muscle Identity
5 Subpopulations of Stem Cells Migrate from the Somite to the Limb
6 Extrinsic Factors Direct Cell Identity in the Somite
7 Manipulations of the Myf5 Locus and Distal Rib Phenotypes: the Complexities of Gene Regulation
8 Conclusions
- References
- Somite Patterning: a Few More Pieces of the Puzzle
1 Introduction
2 Segmental Plate Morphology
3 Somite Differentiation
3.1 Muscle Formation
3.1.1 Epaxial and Hypaxial Muscle Derivatives
3.1.2 A Distinct Embryonic Origin for Epaxial and Hypaxial Muscles?
3.1.3 Epaxial Muscle Formation
3.1.4 Hypaxial Muscle Formation
3.1.5 A Second Wave
... mehr
of Proliferative Muscle Progenitors
3.2 Dermis Formation
4 Tissue and Molecular Regulation of Somite Differentiation
4.1 The Notochord and Floor Plate Exert a Ventralizing Activity on the Somite: a Role for Sonic Hedgehog?
4.2 Dorsalizing Activity of Wnt Molecules in the Dorsal Ectoderm and Neural Tube
4.3 Tissue and Molecular Regulation of Myogenesis: an Instructive or Permissive Process?
5 Conclusion
- References
- Transcription Factors in Skeletal Myogenesis of Vertebrates
1 Myogenesis
2 Determination and Differentiation of Muscle Precursor Cells
2.1 MRFs
2.1.1 Myf5
2.1.2 MyoD
2.1.3 Myogenin
2.1.4 MRF4
2.2 MEF2 Transcription Factors
3 Hypaxial Muscle Development
3.1 Pax3
3.2 Lbx1
3.3 Mox2
4 Regeneration of Skeletal Muscle
4.1 MRFs
4.2 Pax?
4.3 MNF
5 Perspectives
- References
- Hypaxial Muscle Development
1 Introduction
2 Developmental Anatomy of Trunk Skeletal Muscles in Amniotes
3 Markers for Hypaxial Muscle Precursors
4 Specification of Hypaxial Muscle Precursors
4.1 Cues from the Lateral Mesoderm
4.2 Cues from the Surface Ectoderm
4.3 Master Regulator Pax3
5 Specification of Migratory Muscle Precursors
5.1 Somitic Competence
5.2 Localized Lateral Signals for the Recruitment of Limb Muscle Precursors
5.3 The Role of Scatter Factor/Hepatocyte Growth Factor and cMet in the Delamination of Migratory Muscle Precursors
5.4 The Role of Lbx1 in Target Recognition of Limb Muscle Precursors
6 Building a Regulatory Network for Hypaxial Muscle Development
- References
- Inhibition of Skeletal Muscle Development: Less Differentiation Gives More Muscle
1 Introduction
2 Secreted Signalling Molecules
2.1 Fibroblast Growth Factor Family
2.2 Transforming Growth Factor ? Superfamily
3 Extracellular Matrix
4 Transcription Factors
4.1 Notch
4.2 Twist
4.3 Id
4.4 Msxl
5 Summary
- References
- Control of Muscle Size During Embryonic, Fetal, and Adult Life
1 Introduction
2 Somite Patterning and Specification of Myogenic Cells
3 Allocation of Cells to the Dorsal Somite Compartment
4 Migration of Muscle Precursor Cells
5 Balance Between Proliferation and Differentiation
6 Muscle Growth in the Embryonic, Fetal, and Neonatal Periods of Development
7 Embryonic and Fetal Muscle Fibers
8 Embryonic, Fetal, and Adult Myoblasts
9 Number of Embryonic and Fetal Myoblasts and Fiber Formation
10 Innervation and Muscle Fiber Number and Size
11 Muscle Hypertrophy and Regeneration
12 Programmed Cell Death During Muscle Development
13 Recruitment of Myogenic Cells from Adult Pluripotent Stem Cells
- References
- Cadherins in Skeletal Muscle Development
1 Cadherins
1.1 Cadherin Structure and Interactions
1.2 Cadherins and Catenins
2 Cadherins in Myogenesis
2.1 M-Cadherin
2.2 N-Cadherin
2.3 R-Cadherin
3 Summary and Outlook
- References
- Slow Myosins in Muscle Development
1 Introduction
2 Myosin Heavy Chain Genes
3 Slow Myosin Heavy Chain Genes in Avian Skeletal Muscle
4 Slow Myosin Heavy Chain Genes in Mammalian Skeletal Muscle
5 Slow MyHC Genes in Fish Skeletal Muscle
6 Hedgehog Family of Signaling Molecules and Slow Myosin Expression in Skeletal Muscle Development
7 Innervation and Calcineurin Responsive Pathways and the Control of Slow MyHC Expression in Skeletal Muscle
8 Slow MyHC Expression in the Developing Heart
9 Summary
- References
- Molecular Characterization of Early Cardiac Development
1 Introduction
2 Molecular Control of Heart Field and Tubular Heart Formation
2.1 Conserved Regulatory Circuits Control Heart Field Formation in Insects and Vertebrates
2.1.1 Heart Field Formation in Vertebrates
2.1.2 Heart Formation in Insects
2.1.3 Nkx Homeobox Genes
2.1.4 GATA Genes
2.2 Hypoblast and Anterior Endoderm Are Involved in Myocardial Specification and Differentiation
2.3 Identification of Signalling Molecules Involved in Cardiac Specification and Differentiation
2.3.1 The Role of BMP2 in Heart Induction
2.4 Other Cardiogenic Signals
2.4.1 Wnt Signals Interfere with Heart Formation in Vertebrates
2.4.2 FGF Cooperates with BMP2
2.4.3 Cerberus
2.4.4 Cripto
2.5 Heart Tube Formation
3 Molecular Control of Cardiac Chamber Formation
3.1 Transcriptional Regulators of Chamber Formation
3.2 Cell-Cell Interaction in Chamber Formation
3.3 Popeye Genes - a Novel Family of Muscle-Restricted Genes
- References
3.2 Dermis Formation
4 Tissue and Molecular Regulation of Somite Differentiation
4.1 The Notochord and Floor Plate Exert a Ventralizing Activity on the Somite: a Role for Sonic Hedgehog?
4.2 Dorsalizing Activity of Wnt Molecules in the Dorsal Ectoderm and Neural Tube
4.3 Tissue and Molecular Regulation of Myogenesis: an Instructive or Permissive Process?
5 Conclusion
- References
- Transcription Factors in Skeletal Myogenesis of Vertebrates
1 Myogenesis
2 Determination and Differentiation of Muscle Precursor Cells
2.1 MRFs
2.1.1 Myf5
2.1.2 MyoD
2.1.3 Myogenin
2.1.4 MRF4
2.2 MEF2 Transcription Factors
3 Hypaxial Muscle Development
3.1 Pax3
3.2 Lbx1
3.3 Mox2
4 Regeneration of Skeletal Muscle
4.1 MRFs
4.2 Pax?
4.3 MNF
5 Perspectives
- References
- Hypaxial Muscle Development
1 Introduction
2 Developmental Anatomy of Trunk Skeletal Muscles in Amniotes
3 Markers for Hypaxial Muscle Precursors
4 Specification of Hypaxial Muscle Precursors
4.1 Cues from the Lateral Mesoderm
4.2 Cues from the Surface Ectoderm
4.3 Master Regulator Pax3
5 Specification of Migratory Muscle Precursors
5.1 Somitic Competence
5.2 Localized Lateral Signals for the Recruitment of Limb Muscle Precursors
5.3 The Role of Scatter Factor/Hepatocyte Growth Factor and cMet in the Delamination of Migratory Muscle Precursors
5.4 The Role of Lbx1 in Target Recognition of Limb Muscle Precursors
6 Building a Regulatory Network for Hypaxial Muscle Development
- References
- Inhibition of Skeletal Muscle Development: Less Differentiation Gives More Muscle
1 Introduction
2 Secreted Signalling Molecules
2.1 Fibroblast Growth Factor Family
2.2 Transforming Growth Factor ? Superfamily
3 Extracellular Matrix
4 Transcription Factors
4.1 Notch
4.2 Twist
4.3 Id
4.4 Msxl
5 Summary
- References
- Control of Muscle Size During Embryonic, Fetal, and Adult Life
1 Introduction
2 Somite Patterning and Specification of Myogenic Cells
3 Allocation of Cells to the Dorsal Somite Compartment
4 Migration of Muscle Precursor Cells
5 Balance Between Proliferation and Differentiation
6 Muscle Growth in the Embryonic, Fetal, and Neonatal Periods of Development
7 Embryonic and Fetal Muscle Fibers
8 Embryonic, Fetal, and Adult Myoblasts
9 Number of Embryonic and Fetal Myoblasts and Fiber Formation
10 Innervation and Muscle Fiber Number and Size
11 Muscle Hypertrophy and Regeneration
12 Programmed Cell Death During Muscle Development
13 Recruitment of Myogenic Cells from Adult Pluripotent Stem Cells
- References
- Cadherins in Skeletal Muscle Development
1 Cadherins
1.1 Cadherin Structure and Interactions
1.2 Cadherins and Catenins
2 Cadherins in Myogenesis
2.1 M-Cadherin
2.2 N-Cadherin
2.3 R-Cadherin
3 Summary and Outlook
- References
- Slow Myosins in Muscle Development
1 Introduction
2 Myosin Heavy Chain Genes
3 Slow Myosin Heavy Chain Genes in Avian Skeletal Muscle
4 Slow Myosin Heavy Chain Genes in Mammalian Skeletal Muscle
5 Slow MyHC Genes in Fish Skeletal Muscle
6 Hedgehog Family of Signaling Molecules and Slow Myosin Expression in Skeletal Muscle Development
7 Innervation and Calcineurin Responsive Pathways and the Control of Slow MyHC Expression in Skeletal Muscle
8 Slow MyHC Expression in the Developing Heart
9 Summary
- References
- Molecular Characterization of Early Cardiac Development
1 Introduction
2 Molecular Control of Heart Field and Tubular Heart Formation
2.1 Conserved Regulatory Circuits Control Heart Field Formation in Insects and Vertebrates
2.1.1 Heart Field Formation in Vertebrates
2.1.2 Heart Formation in Insects
2.1.3 Nkx Homeobox Genes
2.1.4 GATA Genes
2.2 Hypoblast and Anterior Endoderm Are Involved in Myocardial Specification and Differentiation
2.3 Identification of Signalling Molecules Involved in Cardiac Specification and Differentiation
2.3.1 The Role of BMP2 in Heart Induction
2.4 Other Cardiogenic Signals
2.4.1 Wnt Signals Interfere with Heart Formation in Vertebrates
2.4.2 FGF Cooperates with BMP2
2.4.3 Cerberus
2.4.4 Cripto
2.5 Heart Tube Formation
3 Molecular Control of Cardiac Chamber Formation
3.1 Transcriptional Regulators of Chamber Formation
3.2 Cell-Cell Interaction in Chamber Formation
3.3 Popeye Genes - a Novel Family of Muscle-Restricted Genes
- References
... weniger
Bibliographische Angaben
- 2002, 242 Seiten, Maße: 23,5 cm, Gebunden, Englisch
- Herausgegeben:Brand-Saberi, Beate
- Verlag: Springer
- ISBN-10: 3540431780
- ISBN-13: 9783540431787
Sprache:
Englisch
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