ATP consumption and efficiency of human single muscle fibers with different myosin isoform composition.

Chemomechanical transduction was studied in single fibers isolated from human skeletal muscle containing different myosin isoforms. Permeabilized fibers were activated by laser-pulse photolytic release of 1.5 mM ATP from p(3)-1-(2-nitrophenyl)ethylester of ATP. The ATP hydrolysis rate in the muscle fibers was determined with a fluorescently labeled phosphate-binding protein. The effects of varying load and shortening velocity during contraction were investigated. The myosin isoform composition was determined in each fiber by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. At 12 degrees C large variations (three- to fourfold) were found between slow and fast (2A and 2A-2B) fibers in their maximum shortening velocity, peak power output, velocity at which peak power is produced, isometric ATPase activity, and tension cost. Isometric tension was similar in all fiber groups. The ATP consumption rate increased during shortening in proportion to shortening velocity. At 12 degrees C the maximum efficiency was similar (0.21-0.27) for all fiber types and was reached at a higher speed of shortening for the faster fibers. In all fibers, peak efficiency increased to approximately 0.4 when the temperature was raised from 12 degrees C to 20 degrees C. The results were simulated with a kinetic scheme describing the ATPase cycle, in which the rate constant controlling ADP release is sensitive to the load on the muscle. The main difference between slow and fast fibers was reproduced by increasing the rate constant for the hydrolysis step, which was rate limiting at low loads. Simulation of the effect of increasing temperature required an increase in the force per cross-bridge and an acceleration of the rate constants in the reaction pathway.

[1]  N. Yagi,et al.  Mechanical study of rat soleus muscle using caged ATP and X‐ray diffraction: high ADP affinity of slow cross‐bridges , 1997, The Journal of physiology.

[2]  C. Gibbs,et al.  Energy production of rat soleus muscle. , 1972, The American journal of physiology.

[3]  R. Woledge The energetics of tortoise muscle , 1968, The Journal of physiology.

[4]  T. Yanagida,et al.  Multiple- and single-molecule analysis of the actomyosin motor by nanometer-piconewton manipulation with a microneedle: unitary steps and forces. , 1996, Biophysical journal.

[5]  G. Cavagna,et al.  Mechanical work, oxygen consumption, and efficiency in isolated frog and rat muscle. , 1987, The American journal of physiology.

[6]  C. Gibbs,et al.  Energy production of rat extensor digitorum longus muscle. , 1973, The American journal of physiology.

[7]  C. Reggiani,et al.  Force‐velocity relations and myosin heavy chain isoform compositions of skinned fibres from rat skeletal muscle. , 1991, The Journal of physiology.

[8]  K C Holmes,et al.  Structural mechanism of muscle contraction. , 1999, Annual review of biochemistry.

[9]  R. Moss,et al.  Shortening velocity in single fibers from adult rabbit soleus muscles is correlated with myosin heavy chain composition. , 1985, The Journal of biological chemistry.

[10]  Y. Zhao,et al.  Kinetic and thermodynamic studies of the cross-bridge cycle in rabbit psoas muscle fibers. , 1994, Biophysical journal.

[11]  H. Higuchi,et al.  Sliding distance between actin and myosin filaments per ATP molecule hydrolysed in skinned muscle fibres , 1991, Nature.

[12]  G. Piazzesi,et al.  The stiffness of skeletal muscle in isometric contraction and rigor: the fraction of myosin heads bound to actin. , 1998, Biophysical journal.

[13]  Y. Goldman,et al.  Kinetics of the actomyosin ATPase in muscle fibers. , 1987, Annual review of physiology.

[14]  M. Kawai,et al.  Force generation and phosphate release steps in skinned rabbit soleus slow-twitch muscle fibers. , 1997, Biophysical journal.

[15]  R. Woledge,et al.  Comparison of energy output during ramp and staircase shortening in frog muscle fibres. , 1995, The Journal of physiology.

[16]  C. Reggiani,et al.  Myofibrillar ATPase activity during isometric contraction and isomyosin composition in rat single skinned muscle fibres. , 1994, The Journal of physiology.

[17]  C. Reggiani,et al.  Myofibrillar ATPase activity in skinned human skeletal muscle fibres: fibre type and temperature dependence. , 1996, The Journal of physiology.

[18]  D. Warshaw,et al.  The molecular mechanics of smooth muscle myosin. , 1998, Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology.

[19]  E. Homsher,et al.  The kinetics of magnesium adenosine triphosphate cleavage in skinned muscle fibres of the rabbit. , 1984, The Journal of physiology.

[20]  S. Howell,et al.  Mechanism of inorganic phosphate interaction with phosphate binding protein from Escherichia coli. , 1998, Biochemistry.

[21]  M. Ferenczi,et al.  The efficiency of contraction in rabbit skeletal muscle fibres, determined from the rate of release of inorganic phosphate , 1999, The Journal of physiology.

[22]  U. K. Laemmli,et al.  Cleavage of Structural Proteins during the Assembly of the Head of Bacteriophage T4 , 1970, Nature.

[23]  M. Bartoo,et al.  The stiffness of rabbit skeletal actomyosin cross-bridges determined with an optical tweezers transducer. , 1998, Biophysical journal.

[24]  J. Corrie,et al.  Direct, real-time measurement of rapid inorganic phosphate release using a novel fluorescent probe and its application to actomyosin subfragment 1 ATPase. , 1994, Biochemistry.

[25]  M. Ferenczi,et al.  The ATPase activity in isometric and shortening skeletal muscle fibres. , 1998, Advances in experimental medicine and biology.

[26]  R. Balaban,et al.  Efficiency of human skeletal muscle in vivo: comparison of isometric, concentric, and eccentric muscle action. , 1997, Journal of applied physiology.

[27]  M. Ferenczi,et al.  Rate of phosphate release after photoliberation of adenosine 5'-triphosphate in slow and fast skeletal muscle fibers. , 1998, Biophysical journal.

[28]  K. Ranatunga Temperature dependence of mechanical power output in mammalian (rat) skeletal muscle , 1998, Experimental physiology.

[29]  G. Elzinga,et al.  Myofibrillar ATPase activity and mechanical performance of skinned fibres from rabbit psoas muscle. , 1994, The Journal of physiology.

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

[31]  N. Alpert,et al.  Kinetic differences at the single molecule level account for the functional diversity of rabbit cardiac myosin isoforms , 1999, The Journal of physiology.

[32]  Biomechanics goes quantum , 1991, Nature.

[33]  Toshio Yanagida,et al.  A single myosin head moves along an actin filament with regular steps of 5.3 nanometres , 1999, Nature.

[34]  H. Sugi,et al.  Comparison of unitary displacements and forces between 2 cardiac myosin isoforms by the optical trap technique: molecular basis for cardiac adaptation. , 1998, Circulation research.

[35]  L. Leinwand,et al.  Type IIx myosin heavy chain transcripts are expressed in type IIb fibers of human skeletal muscle. , 1994, The American journal of physiology.

[36]  R. Cooke,et al.  Depletion of phosphate in active muscle fibers probes actomyosin states within the powerstroke. , 1998, Biophysical journal.

[37]  G. P. Reid,et al.  The development and application of photosensitive caged compounds to aid time-resolved structure determination of macromolecules , 1992, Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences.

[38]  D. Pette,et al.  Fast myosin heavy chain diversity in skeletal muscles of the rabbit: heavy chain IId, not IIb predominates. , 1993, European journal of biochemistry.

[39]  D. Biral,et al.  Myosin heavy chain composition of single fibres from normal human muscle. , 1988, The Biochemical journal.

[40]  The dependence on extent of shortening of the extra energy liberated by rapidly shortening frog skeletal muscle. , 1981, The Journal of physiology.

[41]  G. Stienen,et al.  Increase in ATP consumption during shortening in skinned fibres from rabbit psoas muscle: effects of inorganic phosphate. , 1996, The Journal of physiology.

[42]  M J Kushmerick,et al.  Effects of pH on contraction of rabbit fast and slow skeletal muscle fibers. , 1988, Biophysical journal.

[43]  E. Eisenberg,et al.  Rate of force generation in muscle: correlation with actomyosin ATPase activity in solution. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[44]  G. P. Reid,et al.  Kinetics of relaxation from rigor of permeabilized fast-twitch skeletal fibers from the rabbit using a novel caged ATP and apyrase. , 1994, Biophysical journal.

[45]  C. Reggiani,et al.  Force‐velocity properties of human skeletal muscle fibres: myosin heavy chain isoform and temperature dependence. , 1996, The Journal of physiology.

[46]  G. Brooks,et al.  Muscular efficiency during steady-rate exercise: effects of speed and work rate. , 1975, Journal of applied physiology.

[47]  H. Huxley,et al.  Millisecond time-resolved changes in x-ray reflections from contracting muscle during rapid mechanical transients, recorded using synchrotron radiation. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[48]  A. Huxley,et al.  Actin compliance: are you pulling my chain? , 1994, Biophysical journal.

[49]  C. Gibbs,et al.  Energetics of fast‐ and slow‐twitch muscles of the mouse. , 1993, The Journal of physiology.

[50]  L. Larsson,et al.  Maximum velocity of shortening in relation to myosin isoform composition in single fibres from human skeletal muscles. , 1993, The Journal of physiology.

[51]  G. Stienen,et al.  Influence of inorganic phosphate and pH on ATP utilization in fast and slow skeletal muscle fibers. , 1995, Biophysical journal.

[52]  R. Alberty Standard Gibbs free energy, enthalpy, and entropy changes as a function of pH and pMg for several reactions involving adenosine phosphates. , 1969, The Journal of biological chemistry.

[53]  R. Fitts,et al.  Force-velocity and force-power properties of single muscle fibers from elite master runners and sedentary men. , 1996, The American journal of physiology.

[54]  M. Ferenczi,et al.  ATPase kinetics on activation of rabbit and frog permeabilized isometric muscle fibres: a real time phosphate assay , 1997, The Journal of physiology.

[55]  C. Gibbs,et al.  Shortening heat in slow- and fast-twitch muscles of the rat. , 1996, The American journal of physiology.

[56]  M. Ferenczi,et al.  Structural changes in the actin-myosin cross-bridges associated with force generation induced by temperature jump in permeabilized frog muscle fibers. , 1999, Biophysical journal.

[57]  C. Reggiani,et al.  Chemo‐mechanical energy transduction in relation to myosin isoform composition in skeletal muscle fibres of the rat , 1997, The Journal of physiology.

[58]  R. Davies,et al.  The chemical energetics of muscle contraction. II. The chemistry, efficiency and power of maximally working sartorius muscles , 1969, Proceedings of the Royal Society of London. Series B. Biological Sciences.