Rapid Conduction and the Evolution of Giant Axons and Myelinated Fibers

Nervous systems have evolved two basic mechanisms for increasing the conduction speed of the electrical impulse. The first is through axon gigantism: using axons several times larger in diameter than the norm for other large axons, as for example in the well-known case of the squid giant axon. The s...

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Bibliographic Details
Published in:Current biology 2007-01, Vol.17 (1), p.R29-R35
Main Authors: Hartline, D.K., Colman, D.R.
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Animals
Annelida
Axons - physiology
Biological Evolution
Cell Adhesion - physiology
Crustacea
Nerve Fibers, Myelinated - physiology
Neural Conduction - physiology
Vertebrata
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Summary:Nervous systems have evolved two basic mechanisms for increasing the conduction speed of the electrical impulse. The first is through axon gigantism: using axons several times larger in diameter than the norm for other large axons, as for example in the well-known case of the squid giant axon. The second is through encasing axons in helical or concentrically wrapped multilamellar sheets of insulating plasma membrane — the myelin sheath. Each mechanism, alone or in combination, is employed in nervous systems of many taxa, both vertebrate and invertebrate. Myelin is a unique way to increase conduction speeds along axons of relatively small caliber. It seems to have arisen independently in evolution several times in vertebrates, annelids and crustacea. Myelinated nerves, regardless of their source, have in common a multilamellar membrane wrapping, and long myelinated segments interspersed with ‘nodal’ loci where the myelin terminates and the nerve impulse propagates along the axon by ‘saltatory’ conduction. For all of the differences in detail among the morphologies and biochemistries of the sheath in the different myelinated animal classes, the function is remarkably universal.
ISSN:0960-9822
1879-0445
DOI:10.1016/j.cub.2006.11.042