Muscle fiber-type variation in lizards (Squamata) and phylogenetic reconstruction of hypothesized ancestral states

doi:10.1242/jeb.01903

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First published online November 17, 2005
Journal of Experimental Biology 208, 4529-4547 (2005)
Published by The Company of Biologists 2005
doi: 10.1242/jeb.01903

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Muscle fiber-type variation in lizards (Squamata) and phylogenetic reconstruction of hypothesized ancestral states

Kevin E. Bonine¹^,*, Todd T. Gleeson² and Theodore Garland, Jr³

¹ Department of Ecology and Evolutionary Biology, University of Arizona, P.O. Box 210088 Tucson, AZ 85721, USA,
² Department of Integrative Physiology, University of Colorado, Boulder, CO 80309, USA
³ Department of Biology, University of California Riverside, CA 92521, USA

^* Author for correspondence (e-mail: kebonine{at}u.arizona.edu)

Accepted 28 September 2005

Previously, we found that phrynosomatid lizards, a diverse groupcommon in the southwestern USA, vary markedly in fiber-typecomposition of the iliofibularis (a hindlimb muscle importantin locomotion). Phrynosomatidae comprises three subclades: theclosely related sand and horned lizards, and their relativesthe Sceloporus group. The variation in muscle fiber-type compositionfor 11 phrynosomatid species is attributable mainly to differencesbetween the sand- and horned-lizard subclades. Here, we expandthe phrynosomatid database with three additional species andcompare these results with data collected for 10 outgroup (distantlyrelated) species. Our goal was to determine if the patternsfound in Phrynosomatidae hold across a broader phylogeneticrange of the extant lizards and to elucidate the evolution of musclefiber-type composition and related traits. To allow for meaningful comparisons,data were collected from species that are primarily terrestrial andrelatively small in size (3.5–65 g body mass). Resultsindicate that the fiber-type variation observed within the Phrynosomatidaealmost spans the range of variation observed in our sample of24 species from eight families. However, one species of Acanthodactylus(Lacertidae) had a consistent region of large tonic fibers (thatdid not stain darkly for either succinic dehydrogenase or myosinATPase activity), a fiber-type only occasionally seen in theother 23 species examined. Many species have a large proportionof either fast-twitch glycolytic (FG; e.g. sand lizards and Aspidoscelis)or fast-twitch oxidative-glycolytic (FOG) fibers (e.g. hornedlizards), with the slow-oxidative proportion occupying only1–17% of the iliofibularis. Importantly, the negativerelationship between FG and FOG composition observed in Phrynosomatidaeappears to be a characteristic of lizards in general, and couldlead to functional trade-offs in aspects of locomotor performance,as has previously been reported for Lacertidae. Reconstructionof ancestral trait values by use of phylogenetically based statisticalmethods indicates especially large changes in fiber-type compositionduring the evolution of horned lizards.

Key words: comparative method, fiber type, fiber-type composition, histochemistry, Phrynosomatidae, phylogeny, skeletal muscle

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