Structural and Regulatory Evolution of Cellular Electrophysiological Systems

Overview

Journal Evol Dev

Specialty Biology

Date 2009 Sep 17

PMID 19754717

Citations 7

Authors

Barbara Rosati

David McKinnon

Affiliations

Soon will be listed here.

Abstract

Cellular electrophysiological systems, like developmental systems, appear to evolve primarily by means of regulatory evolution. It is suggested that electrophysiological systems share two key features with developmental systems that account for this dependence on regulatory evolution. For both systems, structural evolution has the potential to create significant problems of pleiotropy and both systems are predominantly computational in nature. It is concluded that the relative balance of physical and computational tasks that a biological system has to perform, combined with the probability that these tasks may have to change significantly during the course of evolution, will be major factors in determining the relative mix of regulatory and structural evolution that is observed for a given system. Physiological systems that directly interface with the environment will almost always perform some low-level physical task. In the majority of cases this will require evolution of protein function in order for the tasks themselves to evolve. For complex physiological systems a large fraction of their function will be devoted to high-level control functions that are predominantly computational in nature. In most cases regulatory evolution will be sufficient in order for these computational tasks to evolve.

Citing Articles

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Transmural gradients in ion channel and auxiliary subunit expression.

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Allometric scaling of electrical excitation and propagation in the mammalian heart.

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Regulatory evolution and voltage-gated ion channel expression in squid axon: selection-mutation balance and fitness cliffs.

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