How to Build Fast Muscles: Synchronous and Asynchronous Designs1

Abstract In animals, muscles are the most common effectors that translate neuronal activity into behavior. Nowhere is behavior more restricted by the limits of muscle performance than at the upper range of high-frequency movements. Here, we see new and multiple designs to cope with the demands for speed. Extremely rapid oscillations in force are required to power cyclic activities such as flight in insects or to produce vibrations for sound. Such behaviors are seen in a variety of invertebrates and vertebrates, and are powered by both synchronous and asynchronous muscles. In synchronous muscles, each contraction/relaxation cycle is accompanied by membrane depolarization and subsequent repolarization, release of activator calcium, attachment of cross-bridges and muscle shortening, then removal of activator calcium and cross-bridge detachment. To enable all of these to occur at extremely high frequencies a suite of modifications are required, including precise neural control, hypertrophy of the calcium handling machinery, innovative mechanisms to bind calcium, and molecular modification of the cross-bridges and regulatory proteins. Side effects are low force and power output and low efficiency, but the benefit of direct, neural control is maintained. Asynchronous muscles, in which there is not a 1:1 correspondence between neural activation and contraction, are a radically different design. Rather than rapid calcium cycling, they rely on delayed activation and deactivation, and the resonant characteristics of the wings and exoskeleton to guide their extremely high-frequency contractions. They thus avoid many of the modifications and attendant trade-offs mentioned above, are more powerful and more efficient than high-frequency synchronous muscles, but are considerably more restricted in their application.

[1]  M. Fine,et al.  Functional morphology of toadfish sonic muscle fibers: relationship to possible fiber division , 1993 .

[2]  R. Josephson,et al.  Power output by an asynchronous flight muscle from a beetle. , 2000, The Journal of experimental biology.

[3]  J. Pringle,et al.  The excitation and contraction of the flight muscles of insects , 1949, The Journal of physiology.

[4]  J. Johnson,et al.  Parvalbumin content and Ca2+ and Mg2+ dissociation rates correlated with changes in relaxation rate of frog muscle fibres. , 1991, The Journal of physiology.

[5]  B. Block,et al.  Thermogenesis in muscle. , 1994, Annual review of physiology.

[6]  Anatomical study of the innervation pattern of the sonic muscle of the oyster toadfish. , 1989, Brain, behavior and evolution.

[7]  S. Baylor,et al.  Myoplasmic calcium transients in intact frog skeletal muscle fibers monitored with the fluorescent indicator furaptra , 1991, The Journal of general physiology.

[8]  R. Josephson,et al.  Contraction Dynamics of Flight and Stridulatory Muscles of Tettigoniid Insects , 1984 .

[9]  M. Fine,et al.  Seasonal and geographical variation of the mating call of the oyster toadfish Opsanus tau L. , 2004, Oecologia.

[10]  R. Dudley The Biomechanics of Insect Flight: Form, Function, Evolution , 1999 .

[11]  Lawrence C. Rome,et al.  Why animals have different muscle fibre types , 1988, Nature.

[12]  B. Block,et al.  The fastest contracting muscles of nonmammalian vertebrates express only one isoform of the ryanodine receptor. , 1993, Biophysical journal.

[13]  R. Josephson,et al.  A Synchronous Insect Muscle with an Operating Frequency Greater than 500 Hz , 1985 .

[14]  R. Josephson,et al.  100 Hz is not the upper limit of synchronous muscle contraction , 1984, Nature.

[15]  L. Rome,et al.  The whistle and the rattle: the design of sound producing muscles. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[16]  R. Josephson,et al.  Asynchronous muscle: a primer. , 2000, The Journal of experimental biology.

[17]  J. Marden,et al.  From Molecules to Mating Success: Integrative Biology of Muscle Maturation in a Dragonfly , 1998 .

[18]  L. Rome,et al.  Trading force for speed: why superfast crossbridge kinetics leads to superlow forces. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[19]  L. Rome,et al.  Superfast contractions without superfast energetics: ATP usage by SR‐Ca2+ pumps and crossbridges in toadfish swimbladder muscle , 2000, The Journal of physiology.

[20]  C. Franzini-armstrong,et al.  The Ca2+ ATPase content of slow and fast twitch fibers of guinea pig , 1988, Muscle & nerve.

[21]  M. Mendelson ELECTRICAL AND MECHANICAL CHARACTERISTICS OF A VERY FAST LOBSTER MUSCLE , 1969, The Journal of cell biology.

[22]  F. Ladich Sound‐generating and ‐detecting motor system in catfish: Design of swimbladder muscles in doradids and pimelodids , 2001, The Anatomical record.

[23]  J. Marden,et al.  Alternative splicing, muscle contraction and intraspecific variation: associations between troponin T transcripts, Ca(2+) sensitivity and the force and power output of dragonfly flight muscles during oscillatory contraction. , 2001, The Journal of experimental biology.

[24]  R. Tregear,et al.  The relationship of adenosine triphosphatase activity to tension and power output of insect flight muscle. , 1975, The Journal of physiology.

[25]  C. Heizmann,et al.  Correlation of parvalbumin concentration with relaxation speed in mammalian muscles. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[26]  D. Young,et al.  Mechanisms of sound-production and muscle contraction kinetics in cicadas , 1983, Journal of comparative physiology.

[27]  L. Rome,et al.  Mutually exclusive muscle designs: the power output of the locomotory and sonic muscles of the oyster toadfish (Opsanus tau) , 2001, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[28]  Ruth E. Hartley,et al.  An integrated view. , 1973 .

[29]  M. Fine,et al.  Comparison of sarcoplasmic reticulum capabilities in toadfish (Opsanus tau) sonic muscle and rat fast twitch muscle , 1998, Journal of Muscle Research & Cell Motility.

[30]  B. Block,et al.  Expression of sarcoplasmic reticulum Ca(2+)-ATPase isoforms in marlin and swordfish muscle and heater cells. , 1996, The American journal of physiology.

[31]  H. Y. Elder HIGH FREQUENCY MUSCLES USED IN SOUND PRODUCTION BY A KATYDID. II. ULTRASTRUCTURE OF THE SINGING MUSCLES , 1971 .

[32]  Lawrence C. Rome,et al.  The Quest for Speed: Muscles Built for High-Frequency Contractions. , 1998, News in physiological sciences : an international journal of physiology produced jointly by the International Union of Physiological Sciences and the American Physiological Society.

[33]  R. Josephson,et al.  Synchronous and Asynchronous Muscles in Cicadas , 1981 .

[34]  Olavi Sotavalta,et al.  The flight-tone (wing-stroke frequency) of insects (Contributions to the problem of insect flight 1.) , 1947 .

[35]  R. Josephson Extensive and intensive factors determining the performance of striated muscle. , 1975, The Journal of experimental zoology.

[36]  T. Bullock Neuroethological Role of Dynamic Traits of Excitable Cells: A Proposal for the Physiological Basis of Slothfulness in the Sloth , 1983 .

[37]  C. Skoglund,et al.  FUNCTIONAL ANALYSIS OF SWIM-BLADDER MUSCLES ENGAGED IN SOUND PRODUCTION OF THE TOADFISH , 1961, The Journal of biophysical and biochemical cytology.

[38]  R. Josephson,et al.  The efficiency of an asynchronous flight muscle from a beetle. , 2001, The Journal of experimental biology.

[39]  A. Huxley Muscle structure and theories of contraction. , 1957, Progress in biophysics and biophysical chemistry.

[40]  K. D. Roeder Movements of the thorax and potential changes in the thoracic muscles of insects during flight. , 1951, The Biological bulletin.

[41]  J. Vigoreaux,et al.  An Integrated View of Insect Flight Muscle: Genes, Motor Molecules, and Motion. , 1999, News in physiological sciences : an international journal of physiology produced jointly by the International Union of Physiological Sciences and the American Physiological Society.

[42]  J. Marden,et al.  Alternative splicing, muscle calcium sensitivity, and the modulation of dragonfly flight performance. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[43]  P. Walsh,et al.  Reexamination of metabolic potential in the toadfish sonic muscle. , 1987, The Journal of experimental zoology.

[44]  D. A. Williams,et al.  Contractile properties and temperature sensitivity of the extraocular muscles, the levator and superior rectus, of the rabbit. , 1994, The Journal of physiology.

[45]  K. Conley,et al.  Structural correlates of speed and endurance in skeletal muscle: the rattlesnake tailshaker muscle , 1996, The Journal of experimental biology.

[46]  H. Rahn,et al.  Temperature dependence of rattling frequency in the rattlesnake, Crotalus v. viridis. , 1954, Science.

[47]  J. Hirsch,et al.  Continuous adult development of multiple innervation in toadfish sonic muscle. , 1998, Journal of neurobiology.