The cross-bridge cycle in muscle. Mechanical, biochemical, and structural studies on single skinned rabbit psoas fibers to characterize cross-bridge kinetics in muscle for correlation with the actomyosin-ATPase in solution.

A characteristic and important feature of myocardium is the modulation of tension when stimulated or possibly even when unstimulated. In addition, resistance to stretch and its variation in unstimulated heart muscle is an important factor in myocardial function. These features may occur in some new light when viewed from some recent advances in understanding of cross-bridge action and regulation of muscle. For this reason we give a short review of such advances. Firstly, we summarize some of our earlier results obtained in experiments designed to see whether and to what extent actomyosin ATPase data obtained in solution might apply in muscle. Secondly, we present a recently developed experimental approach to estimate the rate constants that determine the cycling of cross-bridges between weak-binding, 'non-force-generating' states and strong-binding, 'force-generating' states. The estimated rate constants confirm the prediction of cross-bridge models derived from in vitro studies that the step which is rate-limiting in solution also determines the rate of force-generation in the cross-bridge cycle in muscle. Experiments at various Ca++ concentrations imply that a major mechanism of regulation is the control of the transition from the weak-binding, 'non-force-generating' states to the strong-binding, 'force-generating' states while the number of activated interaction sites appears unchanged and always at its maximum. This implies that changes in the force-pCa relation cannot be interpreted without detailed analysis of cross-bridge kinetics, and that factors other than Ca++ may have the potential to modulate muscle activity, both in stimulated and unstimulated muscle, by affecting cross-bridge kinetics.

[1]  D. Trentham,et al.  The mechanism of ATP hydrolysis catalyzed by myosin and actomyosin, using rapid reaction techniques to study oxygen exchange. , 1981, The Journal of biological chemistry.

[2]  A. Hill The heat of shortening and the dynamic constants of muscle , 1938 .

[3]  S. Rosenfeld,et al.  The ATPase mechanism of skeletal and smooth muscle acto-subfragment 1. , 1984, The Journal of biological chemistry.

[4]  E. Eisenberg,et al.  Mechanism of action of troponin . tropomyosin. Inhibition of actomyosin ATPase activity without inhibition of myosin binding to actin. , 1981, The Journal of biological chemistry.

[5]  R. Simmons,et al.  The dependence of force and shortening velocity on substrate concentration in skinned muscle fibres from Rana temporaria. , 1984, The Journal of physiology.

[6]  E. Eisenberg,et al.  Cooperative binding of myosin subfragment-1 to the actin-troponin-tropomyosin complex. , 1980, Proceedings of the National Academy of Sciences of the United States of America.

[7]  R. Cooke,et al.  All myosin heads form bonds with actin in rigor rabbit skeletal muscle. , 1980, Biochemistry.

[8]  E. Taylor,et al.  Mechanism of adenosine triphosphate hydrolysis by actomyosin. , 1971, Biochemistry.

[9]  E. Taylor,et al.  Energetics and mechanism of actomyosin adenosine triphosphatase. , 1976, Biochemistry.

[10]  Leepo C. Yu,et al.  Equatorial x-ray intensities and isometric force levels in frog sartorius muscle. , 1979, Journal of molecular biology.

[11]  E. Eisenberg,et al.  Evidence for cross-bridge attachment in relaxed muscle at low ionic strength. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[12]  A. Huxley,et al.  The relation between stiffness and filament overlap in stimulated frog muscle fibres. , 1981, The Journal of physiology.

[13]  Steven B Marston,et al.  The rates of formation and dissociation of actin-myosin complexes. Effects of solvent, temperature, nucleotide binding and head-head interactions. , 1982, The Biochemical journal.

[14]  E. Eisenberg,et al.  Inhibition of actomyosin ATPase activity by troponin-tropomyosin without blocking the binding of myosin to actin. , 1982, The Journal of biological chemistry.

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

[16]  H E Huxley,et al.  The Mechanism of Muscular Contraction , 1965, Scientific American.

[17]  L. Teichholz,et al.  The relation between calcium and contraction kinetics in skinned muscle fibres , 1970, The Journal of physiology.

[18]  Steven B Marston,et al.  Evidence for a complex between myosin and ADP in relaxed muscle fibres. , 1972, Nature: New biology.

[19]  J. Sleep,et al.  Dependence of adenosine triphosphatase activity of rabbit psoas muscle fibres and myofibrils on substrate concentration. , 1985, The Journal of physiology.

[20]  D. Mornet,et al.  Structure of the actin–myosin interface , 1981, Nature.

[21]  B. Brenner,et al.  Equatorial x-ray diffraction from single skinned rabbit psoas fibers at various degrees of activation. Changes in intensities and lattice spacing. , 1985, Biophysical journal.

[22]  H. Huxley Structural difference between resting and rigor muscle; evidence from intensity changes in the lowangle equatorial x-ray diagram. , 1968, Journal of molecular biology.

[23]  E. Eisenberg,et al.  The rate-limiting step in the actomyosin adenosinetriphosphatase cycle. , 1984, Biochemistry.

[24]  E. Eisenberg,et al.  Mechanism of actomyosin adenosine triphosphatase. Evidence that adenosine 5'-triphosphate hydrolysis can occur without dissociation of the actomyosin complex. , 1979, Biochemistry.

[25]  P. Wagner Effect of skeletal muscle myosin light chain 2 on the Ca2+-sensitive interaction of myosin and heavy meromyosin with regulated actin. , 1984, Biochemistry.

[26]  B. Brenner,et al.  X-ray diffraction evidence for cross-bridge formation in relaxed muscle fibers at various ionic strengths. , 1984, Biophysical journal.

[27]  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.

[28]  J. Haselgrove,et al.  X-ray evidence for radial cross-bridge movement and for the sliding filament model in actively contracting skeletal muscle. , 1973, Journal of molecular biology.

[29]  A. Huxley,et al.  Structural Changes in Muscle During Contraction: Interference Microscopy of Living Muscle Fibres , 1954, Nature.

[30]  E. Eisenberg,et al.  Rate-limiting step in the actomyosin adenosinetriphosphatase cycle: studies with myosin subfragment 1 cross-linked to actin. , 1985, Biochemistry.

[31]  E. Eisenberg,et al.  Binding of gizzard smooth muscle myosin subfragment 1 to actin in the presence and absence of adenosine 5'-triphosphate. , 1983, Biochemistry.

[32]  A. Huxley,et al.  Proposed Mechanism of Force Generation in Striated Muscle , 1971, Nature.

[33]  Steven B Marston The nucleotide complexes of myosin in glycerol-extracted muscle fibres. , 1973, Biochimica et biophysica acta.

[34]  H. Huxley,et al.  Changes in the Cross-Striations of Muscle during Contraction and Stretch and their Structural Interpretation , 1954, Nature.