, The heat of shortening and dynamic constants of muscle, Proc R Soc Lond B Biol Sci, vol.126, pp.136-151, 1938.
, Mechanism of adenosine triphosphate hydrolysis by actomyosin, Biochemistry, vol.10, pp.4617-4624, 1971.
, Structure of the actin-myosin complex and its implications for muscle contraction, Science, vol.261, pp.58-65, 1993.
, The swinging lever-arm hypothesis of muscle contraction, Curr Biol, vol.7, pp.112-118, 1997.
, Non-hyperbolic force-velocity relationship in single muscle fibres, Acta Physiol Scand, vol.98, pp.143-156, 1976.
, The velocity of unloaded shortening and its relation to sarcomere length and isometric force in vertebrate muscle fibres, J Physiol, vol.291, pp.143-159, 1979.
, The biphasic force-velocity relationship in frog muscle fibres and its evaluation in terms of cross-bridge function, J Physiol, vol.503, pp.141-156, 1997.
, Double-hyperbolic force-velocity relation in frog muscle fibres, J Physiol, vol.404, pp.301-321, 1988.
, The variation in isometric tension with sarcomere length in vertebrate muscle fibres, J Physiol, vol.184, pp.170-192, 1966.
, The effect of hypertonicity on force generation in tetanized single fibres from frog skeletal muscle, J Physiol, vol.476, pp.531-546, 1994.
, Comparative histochemistry of a flatfish fin muscle and of other vertebrate muscles used for ultrastructural studies, J Muscle Res Cell Motil, vol.8, pp.358-371, 1987.
, Structural changes in the actinmyosin cross-bridges associated with force generation induced by temperature jump in permeabilized frog muscle fibers, Biophys J, vol.77, pp.354-372, 1999.
, The size and the speed of the working stroke of muscle myosin and its dependence on the force, J Physiol, vol.545, pp.145-151, 2002.
, An integrated in vitro and in situ study of kinetics of myosin II from frog skeletal muscle, J Physiol, vol.590, pp.1227-1242, 2012.
, Threedimensional structure of myosin subfragment-1: a molecular motor, Science, vol.261, pp.50-58, 1993.
, Structural mechanism of muscle contraction, Annu Rev Biochem, vol.68, pp.687-728, 1999.
, Conformation of the myosin motor during force generation in skeletal muscle, Nat Struct Biol, vol.7, pp.482-485, 2000.
, Structural mechanism of the recovery stroke in the myosin molecular motor, Proc Natl Acad Sci U S A, vol.102, pp.6873-6878, 2005.
, Recent Improvements in Small Angle X-Ray Diffraction for the Study of Muscle Physiology, Rep Prog Phys, vol.69, pp.2709-2759, 2006.
, Orientation of the essential light chain region of myosin in relaxed, active, and rigor muscle, Biophys J, vol.95, pp.3882-3891, 2008.
, The mechanism of the converter domain rotation in the recovery stroke of myosin motor protein, Proteins, vol.80, pp.2701-2710, 2012.
, Distributions et transformations de Fourier, 1988.
, Probabilitès via l'intégrale de Riemann, 2013.
, Des mathématiques pour la science, 2011.
, Ben-Aim R, editors (1981) Cinétique et dynamiques chimiques, Editions Technip
, Dynamique Chimique. Thermodynamique, cinétique et mécanique statistique, 2005.
, Références du Supplément S1.B du Papier, p.1
, The mechanism of muscular contraction, Science, vol.164, pp.1356-1365, 1969.
, Structure of the actin-myosin complex and its implications for muscle contraction, Science, vol.261, pp.58-65, 1993.
, Mechanism of adenosine triphosphate hydrolysis by actomyosin, Biochemistry, vol.10, pp.4617-4624, 1971.
, Actomyosin interaction in striated muscle, Physiol Rev, vol.77, pp.671-697, 1997.
, The molecular mechanism of muscle contraction, Adv Protein Chem, vol.71, pp.161-193, 2005.
, Atomic structure of scallop myosin subfragment S1 complexed with MgADP: a novel conformation of the myosin head, Cell, vol.97, pp.459-470, 1999.
, Shaking the myosin family tree: biochemical kinetics defines four types of myosin motor, Semin Cell Dev Biol, vol.22, pp.961-967, 2011.
, Structure of the rigor actin-tropomyosin-myosin complex, Cell, vol.150, pp.327-338, 2012.
, Modeling stochastic kinetics of molecular machines at multiple levels: from molecules to modules, Biophys J, vol.104, pp.2331-2341, 2013.
, The mechanism of the reverse recovery step, phosphate release, and actin activation of Dictyostelium myosin II, J Biol Chem, vol.283, pp.8153-8163, 2008.
, Direct real-time detection of the actin-activated power stroke within the myosin catalytic domain, Proc Natl Acad Sci U S A, vol.110, pp.7211-7216, 2013.
, Indirect coupling of phosphate release to de novo tension generation during muscle contraction, Proc Natl Acad Sci, vol.92, pp.10482-10486, 1995.
, ATPase kinetics on activation of rabbit and frog permeabilized isometric muscle fibres: a real time phosphate assay, J Physiol, vol.501, pp.125-148, 1997.
, Structural kinetics of myosin by transient time-resolved FRET, Proc Natl Acad Sci U S A, vol.108, pp.1891-1896, 2011.
, Orthovanadate and orthophosphate inhibit muscle force via two different pathways of the myosin ATPase cycle, Biophys J, vol.100, pp.665-674, 2011.
, Three conformational states of scallop myosin S1, Proc Natl Acad Sci U S A, vol.97, pp.11238-11243, 2000.
, How actin initiates the motor activity of Myosin, Dev Cell, vol.33, pp.401-412, 2015.
URL : https://hal.archives-ouvertes.fr/hal-01447817
, Reversal of the crossbridge force-generating transition by photogeneration of phosphate in rabbit psoas muscle fibres, J Physiol, vol.451, pp.247-278, 1992.
, Regulation of contraction in striated muscle, Physiol Rev, vol.80, pp.853-924, 2000.
, The ATP hydrolysis and phosphate release steps control the time course of force development in rabbit skeletal muscle, J Physiol, vol.563, pp.671-687, 2005.
, The working stroke of the myosin II motor in muscle is not tightly coupled to release of orthophosphate from its active site, J Physiol, vol.591, pp.5187-5205, 2013.
, A kinetic model that explains the effect of inorganic phosphate on the mechanics and energetics of isometric contraction of fast skeletal muscle, Proc Biol Sci, vol.277, pp.19-27, 2010.
, Structural changes in myosin motors and filaments during relaxation of skeletal muscle, J Physiol, vol.587, pp.4509-4521, 2009.
, Tension responses to sudden length change in stimulated frog muscle fibres near slack length, J Physiol, vol.269, pp.441-515, 1977.
, The variation in isometric tension with sarcomere length in vertebrate muscle fibres, J Physiol, vol.184, pp.170-192, 1966.
, Muscular contraction, J Physiol, vol.243, pp.1-43, 1974.
URL : https://hal.archives-ouvertes.fr/jpa-00215466
, Changes in conformation of myosin heads during the development of isometric contraction and rapid shortening in single frog muscle fibres, J Physiol, vol.514, issue.2, pp.305-312, 1999.
, Effects of rapid shortening on rate of force regeneration and myoplasmic [Ca2+] in intact frog skeletal muscle fibres, J Physiol, vol.511, pp.171-180, 1998.
, Motion of myosin head domains during activation and force development in skeletal muscle, Proc Natl Acad Sci U S A, vol.108, pp.7236-7240, 2011.
, Rapid regeneration of the actin-myosin power stroke in contracting muscle, Nature, vol.355, pp.638-641, 1992.
, A cross-bridge model that is able to explain mechanical and energetic properties of shortening muscle, Biophys J, vol.68, pp.1966-1979, 1995.
, Proposed mechanism of force generation in striated muscle, Nature, vol.233, pp.533-538, 1971.
, An asymmetry in the phosphate dependence of tension transients induced by length perturbation in mammalian (rabbit psoas) muscle fibres, J Physiol, vol.542, pp.899-910, 2002.
, Skeletal muscle performance determined by modulation of number of myosin motors rather than motor force or stroke size, Cell, vol.131, pp.784-795, 2007.
, The relation between stiffness and filament overlap in stimulated frog muscle fibres, J Physiol, vol.311, pp.219-249, 1981.
, Cross-bridge detachment and attachment following a step stretch imposed on active single frog muscle fibres, J Physiol, vol.498, pp.3-15, 1997.
, Tension transients during steady shortening of frog muscle fibres, J Physiol, vol.361, pp.131-150, 1985.
, Nonlinear cross-bridge elasticity and post-power-stroke events in fast skeletal muscle actomyosin, Biophys J, vol.105, pp.1871-1881, 2013.
, The myosin motor in muscle generates a smaller and slower working stroke at higher load, Nature, vol.428, pp.578-581, 2004.