Animal cells and systems

The Korean Society for Integrative Biology (한국통합생물학회)
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Anuran Metamorphosis: a Model for Gravitational Study on Motor Development

  • Jae Seung (Department of Life Science, College of Liberal Arts and Sciences, Yonsei University) ;
  • Jin Cheul (Department of Life Science, College of Liberal Arts and Sciences, Yonsei University) ;
  • In-Ho (Institute of Space and Astronautical Science) ;
  • Park, In-Ho (Department of Life Science, College of Liberal Arts and Sciences, Yonsei University)
  • Published : 2000.09.01
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Abstract

Limbs and supporting structures of an organism experience a full weight of its own when it lands from water, because neutral buoyancy in the aquatic habitat will be no longer available in the terrestrial world. Metamorphosis of anuran amphibians presents 8 good research model to examine how this transition from non-loading to weight-loading affects development of motor capacity at the time of their first emergence on land. Our video analysis of the transitional anurans, Rana catesbeiana, at Gosner stage 46 (the stage of complete transformation) demonstrated that the take-off speed increased 1.23-fold after the first six hours of weight-loading on the wet ground. It did not increase further during the following three days of loading, and was close to the level of mature frogs with different body mass. During development of larvae in deep water with no chance of landing through metamorphosis, both tension and power of a hindlimb anti-gravity muscle increased 5-fold between stages 37 and n. However, the muscle contractility increased more rapidly when the larvas could access the wet ground by their natural landing behavior after stages 41-42. Muscle power, one of major factors affecting locomotory speed, was 1.29-fold greater in the loaded than in the non-loaded larvae at the transitional stage. Thus, weight-loading had a potentially significant effect on the elevation of motor capacity, with a similar extent of increment in locomotory speed and muscle power during the last stages of metamorphosis. Such a motor adjustment of the froglets in a relatively short transitional period would be important for effective ecological interactions and survival in their inexperienced terrestrial life.

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References

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