Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Genomic basis for antifreeze glycopeptide heterogeneity and abundance in Antarctic fishes
- Cold-inducible gene transcription: Δ9-desaturases and the adaptive control of membrane lipid composition
- Ion transport in teleosts: identification and expression of ion transporting proteins in branchial and intestinal epithelia of the European eel
- Temperature adaptation: selective expression of myosin heavy chain genes and muscle function in carp
- Crustacean genes involved in growth
- Use of the zebrafish for studies of genes involved in the control of development
- Myosin heavy chain isogene expression in carp
- Rainbow trout myosin heavy chain polymorphism during development
- Transient expression of reporter genes in fish as a measure of promoter efficiency
- The use of transient lacZ expression in fish embryos for comparative analysis of cloned regulatory elements
- Molecular characterization of prolactin receptor in tilapia
- Index
Myosin heavy chain isogene expression in carp
Published online by Cambridge University Press: 04 August 2010
- Frontmatter
- Contents
- List of contributors
- Preface
- Genomic basis for antifreeze glycopeptide heterogeneity and abundance in Antarctic fishes
- Cold-inducible gene transcription: Δ9-desaturases and the adaptive control of membrane lipid composition
- Ion transport in teleosts: identification and expression of ion transporting proteins in branchial and intestinal epithelia of the European eel
- Temperature adaptation: selective expression of myosin heavy chain genes and muscle function in carp
- Crustacean genes involved in growth
- Use of the zebrafish for studies of genes involved in the control of development
- Myosin heavy chain isogene expression in carp
- Rainbow trout myosin heavy chain polymorphism during development
- Transient expression of reporter genes in fish as a measure of promoter efficiency
- The use of transient lacZ expression in fish embryos for comparative analysis of cloned regulatory elements
- Molecular characterization of prolactin receptor in tilapia
- Index
Summary
Introduction
The myosin heavy chain (MyoHC) plays a central role in cell motility and muscle contraction of all species, and a better understanding of the molecular diversity present between different isoforms of this protein is necessary if we are to understand the fine tuning of locomotion at the molecular level. In skeletal muscle the myosin molecule is located in the thick filament of the myofibril and together with actin takes part in the mechanism by which the chemical energy of ATP is converted into mechanical work. In its native state, striated muscle myosin is a hexameric protein consisting of two ‘heavy’ polypeptide chains of approximately 220 kD each and four ‘light’ chains approximately 17–20 kD each (Weeds & Lowey, 1971). Both the heavy and light chains of myosin exist as multiple isoforms which produce distinct isoforms of myosin all with similar, but not identical, structure and function (Gros & Buckingham, 1987).
The two myosin heavy chains intertwine at their more carboxyl regions forming an α-helical coiled-coil, about 150 nm long, termed the rod region of the molecule. The NH2 region of each individual MyoHC molecule consists of a globular head about 19 nm long and 5 nm wide (at the widest point) such that the myosin molecule as a whole contains two head regions. The head region of the MyoHC forms the ‘crossbridge’ between the thick and thin filaments of the sarcomere. It contains an actin binding domain, the sites where the myosin light chains interact and the region where the ATPase activity of the molecule is localized (Craig, 1986).
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- Information
- Gene Expression and Manipulation in Aquatic Organisms , pp. 123 - 148Publisher: Cambridge University PressPrint publication year: 1996