Effects of pH on contraction of rabbit fast and slow skeletal muscle fibers.

We have investigated (a) effects of varying proton concentration on force and shortening velocity of glycerinated muscle fibers, (b) differences between these effects on fibers from psoas (fast) and soleus (slow) muscles, possibly due to differences in the actomyosin ATPase kinetic cycles, and (c) whether changes in intracellular pH explain altered contractility typically associated with prolonged excitation of fast, glycolytic muscle. The pH range was chosen to cover the physiological pH range (6.0-7.5) as well as pH 8.0, which has often been used for in vitro measurements of myosin ATPase activity. Steady-state isometric force increased monotonically (by about threefold) as pH was increased from pH 6.0; force in soleus (slow) fibers was less affected by pH than in psoas (fast) fibers. For both fiber types, the velocity of unloaded shortening was maximum near resting intracellular pH in vivo and was decreased at acid pH (by about one-half). At pH 6.0, force increased when the pH buffer concentration was decreased from 100 mM, as predicted by inadequate pH buffering and pH heterogeneity in the fiber. This heterogeneity was modeled by net proton consumption within the fiber, due to production by the actomyosin ATPase coupled to consumption by the creatine kinase reaction, with replenishment by diffusion of protons in equilibrium with a mobile buffer. Lactate anion had little mechanical effect. Inorganic phosphate (15 mM total) had an additive effect of depressing force that was similar at pH 7.1 and 6.0. By directly affecting the actomyosin interaction, decreased pH is at least partly responsible for the observed decreases in force and velocity in stimulated muscle with sufficient glycolytic capacity to decrease pH.

[1]  M. Crow,et al.  Correlated reduction of velocity of shortening and the rate of energy utilization in mouse fast-twitch muscle during a continuous tetanus , 1983, The Journal of general physiology.

[2]  C. Caputo,et al.  Contractile inactivation in frog skeletal muscle fibers. The effects of low calcium, tetracaine, dantrolene, D-600, and nifedipine , 1987, The Journal of general physiology.

[3]  T. Matsuda,et al.  Ordering of the myofilament lattice in muscle fibers. , 1986, Journal of molecular biology.

[4]  B Bigland-Ritchie,et al.  Fatigue of submaximal static contractions. , 1986, Acta physiologica Scandinavica. Supplementum.

[5]  K. Edman The velocity of unloaded shortening and its relation to sarcomere length and isometric force in vertebrate muscle fibres. , 1979, The Journal of physiology.

[6]  R. Cooke,et al.  The effects of ADP and phosphate on the contraction of muscle fibers. , 1985, Biophysical journal.

[7]  M J Kushmerick,et al.  A simple analysis of the "phosphocreatine shuttle". , 1984, The American journal of physiology.

[8]  S. Rapoport,et al.  Metabolic correlates of fatigue and of recovery from fatigue in single frog muscle fibers , 1978, The Journal of general physiology.

[9]  I. Johnston,et al.  Effects of phosphate on the contractile properties of fast and slow muscle fibres from an Antarctic fish. , 1985, The Journal of physiology.

[10]  T. Brown,et al.  Phosphorus NMR spectroscopy of cat biceps and soleus muscles. , 1983, Advances in experimental medicine and biology.

[11]  Ashley Cc,et al.  Effect of changing the composition of the bathing solution upon the isometric tension—pCa relationship in bundles of crustacean myofibrils , 1977 .

[12]  D. Stephenson,et al.  Thermal dependence of maximum Ca2+-activated force in skinned muscle fibres of the toad Bufo marinus acclimated at different temperatures. , 1987, The Journal of experimental biology.

[13]  S. Izawa,et al.  Hydrogen ion buffers. , 1972, Methods in enzymology.

[14]  R L Moss,et al.  Greater hydrogen ion‐induced depression of tension and velocity in skinned single fibres of rat fast than slow muscles. , 1987, The Journal of physiology.

[15]  P. Gardiner,et al.  Contractile and electromyographic characteristics of rat plantaris motor unit types during fatigue in situ. , 1987, The Journal of physiology.

[16]  N. Curtin Buffer power and intracellular pH of frog sartorius muscle. , 1986, Biophysical journal.

[17]  Normal muscle energy metabolism. , 1984, Advances in experimental medicine and biology.

[18]  T. Brown,et al.  31P NMR spectroscopy, chemical analysis, and free Mg2+ of rabbit bladder and uterine smooth muscle. , 1986, The Journal of biological chemistry.

[19]  J. Koretz,et al.  Transient state kinetic studies of proton liberation by myosin and subfragment 1. , 1975, The Journal of biological chemistry.

[20]  G. W. Mainwood,et al.  Is the change in intracellular pH during fatigue large enough to be the main cause of fatigue? , 1986, Canadian journal of physiology and pharmacology.

[21]  M. Kushmerick,et al.  Chemical changes in rat leg muscle by phosphorus nuclear magnetic resonance. , 1985, The American journal of physiology.

[22]  R. Moss,et al.  Shortening velocity in skinned single muscle fibers. Influence of filament lattice spacing. , 1987, Biophysical journal.

[23]  Godfrey L. Smith,et al.  The contribution of intracellular acidosis to the decline of developed pressure in ferret hearts exposed to cyanide. , 1987, The Journal of physiology.

[24]  A. Fabiato,et al.  Effects of pH on the myofilaments and the sarcoplasmic reticulum of skinned cells from cardiace and skeletal muscles. , 1978, The Journal of physiology.

[25]  Clive R. Bagshaw,et al.  The characterization of myosin-product complexes and of product-release steps during the magnesium ion-dependent adenosine triphosphatase reaction. , 1974, The Biochemical journal.

[26]  M. Kushmerick,et al.  Measurements on permeabilized skeletal muscle fibers during continuous activation. , 1987, The American journal of physiology.

[27]  D. Wilkie,et al.  Muscular fatigue investigated by phosphorus nuclear magnetic resonance , 1978, Nature.

[28]  The influence of free calcium on the maximum speed of shortening in skinned frog muscle fibres. , 1986, The Journal of physiology.

[29]  W. H. Elliott,et al.  Data for Biochemical Research , 1986 .

[30]  S. McLaughlin,et al.  The role of fixed and mobile buffers in the kinetics of proton movement. , 1987, Biochimica et biophysica acta.

[31]  R. Rutman,et al.  The "high energy phosphate bond" concept. , 1960, Progress in biophysics and molecular biology.

[32]  J R Smith,et al.  Hydrogen ion buffers for biological research. , 1966, Analytical biochemistry.

[33]  T. Nosek,et al.  It is diprotonated inorganic phosphate that depresses force in skinned skeletal muscle fibers. , 1987, Science.

[34]  J. Kentish The effects of inorganic phosphate and creatine phosphate on force production in skinned muscles from rat ventricle. , 1986, The Journal of physiology.

[35]  C. Ashley,et al.  Effect of changing the composition of the bathing solution upon the isometric tension—pCa relationship in bundles of crustacean myofibrils , 1977, The Journal of physiology.

[36]  H. Westerblad,et al.  Force and membrane potential during and after fatiguing, continuous high-frequency stimulation of single Xenopus muscle fibres. , 1986, Acta physiologica Scandinavica.