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Trends in the Functional Morphology and Sensorimotor Control of Feeding Behavior in Salamanders: an Example of the Role of Internal Dynamics in Evolution

Overview
Journal Acta Biotheor
Publisher Springer
Specialty Biology
Date 1985 Jan 1
PMID 3933230
Citations 6
Authors
G Roth
D B Wake
Affiliations
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Abstract

Organisms are self-producing and self-maintaining, or "autopoietic" systems. Therefore, the course of evolution and adaptation of an organism is strongly determined by its own internal properties, whatever role "external" selection may play. The internal properties may either act as constraints that preclude certain changes or they open new pathways: the organism canalizes its own evolution. As an example the evolution of feeding mechanisms in salamanders, especially in the lungless salamanders of the family Plethodontidae, is discussed. In this family a large variety of different feeding mechanisms is found. The authors reconstruct this evolutionary process as a series of "bifurcation points" of either constraints or opportunities forming a sequence of preconditions for the formation of a high-speed projectile tongue characteristic of tropical salamanders. Furthermore, it is shown how parallel evolution of seemingly unrelated domains within an organism such as respiratory physiology, life history biology and pattern of ontogeny has rather direct relevance to the feeding biology, thus demonstrating that organisms always evolve as wholes.

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References
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Lombard R, Wake D . Tongue evolution in the lungless salamanders, family plethodontidae. I. Introduction, theory and a general model of dynamics. J Morphol. 1976; 148(3):265-86. DOI: 10.1002/jmor.1051480302. View
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Wake D, Roth G, Wake M . Tongue evolution in lungless salamanders, family plethodontidae. III. Patterns of peripheral innervation. J Morphol. 1983; 178(3):207-24. DOI: 10.1002/jmor.1051780302. View