Convergent evolution in mechanical design of lamnid sharks and tunas

The evolution of 'thunniform' body shapes in several different groups of vertebrates, including whales, ichthyosaurs and several species of large pelagic fishes supports the view that physical and hydromechanical demands provided important selection pressures to optimize body design for lo...

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Bibliographic Details
Published in:Nature 2004-05, Vol.429 (6987), p.61-65
Main Authors: Donley, Jeanine M, Sepulveda, Chugey A, Konstantinidis, Peter, Gemballa, Sven, Shadwick, Robert E
Format: Article
Language:English
Subjects:
Agnatha. Pisces
Animal and plant ecology
Animal, plant and microbial ecology
Animals
Autoecology
Biological and medical sciences
Biological Evolution
Biomechanical Phenomena
Body Constitution
Cetacea
Design
Evolutionary biology
Fish
Fundamental and applied biological sciences. Psychology
Genetics of eukaryotes. Biological and molecular evolution
Humanities and Social Sciences
Lamnidae
Lamniformes
letter
Marine
multidisciplinary
Muscle, Skeletal - anatomy & histology
Muscle, Skeletal - physiology
Science
Science (multidisciplinary)
Sharks
Sharks - anatomy & histology
Sharks - physiology
Swimming
Swimming - physiology
Thunnus
Tuna - anatomy & histology
Tuna - physiology
Vertebrata
Vertebrates
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Summary:The evolution of 'thunniform' body shapes in several different groups of vertebrates, including whales, ichthyosaurs and several species of large pelagic fishes supports the view that physical and hydromechanical demands provided important selection pressures to optimize body design for locomotion during vertebrate evolution. Recognition of morphological similarities between lamnid sharks (the most well known being the great white and the mako) and tunas has led to a general expectation that they also have converged in their functional design; however, no quantitative data exist on the mechanical performance of the locomotor system in lamnid sharks. Here we examine the swimming kinematics, in vivo muscle dynamics and functional morphology of the force-transmission system in a lamnid shark, and show that the evolutionary convergence in body shape and mechanical design between the distantly related lamnids and tunas is much more than skin deep; it extends to the depths of the myotendinous architecture and the mechanical basis for propulsive movements. We demonstrate that not only have lamnids and tunas converged to a much greater extent than previously known, but they have also developed morphological and functional adaptations in their locomotor systems that are unlike virtually all other fishes.
ISSN:0028-0836
1476-4687
DOI:10.1038/nature02435