Physical and Chemical Properties of Rubber-Like Elastic Fibres from the Octopus Aorta

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Journal of Experimental Biology 114,239-257 (1985)
Published by Company of Biologists 1985

Physical and Chemical Properties of Rubber-Like Elastic Fibres from the Octopus Aorta

Robert E. Shadwick ¹ and John M. Gosline ¹

¹ Department of Zoology, University of British Columbia, Vancouver, B. C, Canada V6T2A9

We investigated the physical and chemical properties of highlyextensible elastic fibres from the octopus aorta. These fibresare composed of an insoluble rubber-like protein which we callthe octopus arterial elastomer. The amino acid composition ofthis protein is different from that of other known protein rubbers,being relatively low in glycine and high in acidic and basicresidues. Up to extensions of 50%, mechanical data from nativeelastic fibres fit a theoretical curve for an ideal Gaussianrubber with elastic modulus G = 4.65 x 10⁵ N m^-2, and this isunchanged by prolonged exposure to formic acid. Thermoelastictests on this protein indicate that the elastic force arisesprimarily from changes in conformational entropy, as predictedby the kinetic theory of rubber elasticity. Analysis of thenon-Gaussian behaviour of the elastic fibres at extensions greaterthan 50% suggests that the molecular chains in this octopusprotein are somewhat less flexible than those in resilin orelastin. Some speculations on the molecular design of theseprotein rubbers are made.

Key words: Elastic fibres, rubber-like, octopus aorta.

Accepted on July 6, 1984

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