EC:3.6.1.3 - FACTA Search

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The purpose of this study was to assess cardiac adaptation to endurance training in rats. After 11 wk of progressive treadmill exercise (1 h/day), gastrocnemius cytochrome c oxidase activity was 38% higher (P less than 0.01) in the trained (n = 20) as compared to control (n = 20) rats. Cardiac Mg2+-stimulated myofibril ATPase activity (0.308 +/- 0.012 vs. 0.324 +/- 0.006 micrometer.mg-1.min-1) did not change nor was there any change in myofibril protein concentration (60.0 +/- 1.12 vs. 59.9 +/- 0.85 mg.g-1). The isolated left ventricular papillary muscle showed no significant change in time-to-peak tension (TPT) or half-relaxation time. Tension output, however, was significantly increased with training, 2.2 +/- 0.3 vs. 1.5 +/- 0.1 g.mm-2 (P less than 0.025). Furthermore, when the papillary preparations were perfused with 0.5 mM lanthanum (La3+) to displace membrane-bound Ca2+, the time course for tension decay was significantly prolonged in the trained muscles (P less than 0.001). We conclude that endurance running of this type does not necessarily increase myofibril ATPase activity or the time course of the isometric twitch of rat papillary muscle. However, tension output per unit area does increase and this appears to be due to a greater amount of Ca2+ being made available to the contractile apparatus.
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PMID:Adaptation of the rat myocardium to endurance training. 20 62

The heat and tension generated by strips of human left ventricle taken from nonfailing hearts were measured at 30 C before and after partial inhibition of ATP splitting by the contractile proteins. We used 2, 3-butanedione monoxime (BDM) (4mM) as the chemical inhibition agent and alterations in solution calcium concentration and stimulus frequency to estimate the heat associated with calcium cycling for a wide range of activation levels. Tension-independent heat (TIH) was used to calculate the total calcium cycled per twitch by assuming that two-thirds of TIH was due to ATP splitting by the sarcoplasmic reticulum CA2+ ATPase with a coupling ratio of 2 Ca2+/ATP split and that one-third of TIH was due to ATP splitting by the sarcolemmal Na+ -K+ ATPase supporting the Na+ -Ca2+ exchanger (1 Ca2+/ATP). The enthalpy of creatine phosphate hydrolysis buffering ATP was taken as -34 KJ/mol. There was a highly positive correlation between TIH and mechanical activation during steady-state and nonsteady-state stimulation. The estimated total calcium turnover per twitch at 39% activation (0.3 Hz pacing rate and 2.5 mM Calcium) was approximately 0.17 nmol/g wet weight. This estimate is less than that calculated from biochemical data describing the cellular content and Ca2+ affinity of major Ca2+ buffers, but is similar to values calculated from recent electron probe microanalysis experiments.
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PMID:Dynamic calcium requirements for activation of human ventricular muscle calculated from tension-independent heat. 149 72

The characteristics of motor units in the iliotibialis posterior muscle of the axolotl hindlimb are described. Tension recording and intracellular electrophysiological methods demonstrate that the physiological properties of the population of motor units are continuously distributed rather than grouped into a series of discrete types. Overlap between motor units occurs and this is positively correlated with motor unit size but negatively correlated with differences in time to peak tension. Immunocytochemical staining with antimyosin antibodies combined with histochemical demonstration of actomyosin ATPase activity revealed at least four types of muscle fibre which were distributed asymmetrically within iliotibialis posterior. The results are discussed in terms of the continuous growth of the muscle and the interactions between muscle and nerve in the formation of the axolotl motor system.
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PMID:Organization of motor units in the axolotl: a continuously growing animal. 201 46

Some aspects of the genetic and non-genetic control of the amount and rate of calcium cycled during steady-state activation of papillary muscles from right ventricular rabbit myocardium are presented. Genetic reorganization of the intracellular structure of the myocardium is achieved by producing right ventricular pressure overload and thyrotoxic hypertrophy. The mechanical performance of the pressure overload heart is slowed while time to peak tension is increased. These changes are associated with an increase in myothermal economy. In thyrotoxic hypertrophy the rate of mechanical performance is increased while time to peak tension is decreased. These alterations are associated with a decrease in myothermal economy. Tension-independent heat is used as an index of calcium cycling. In pressure overload hearts the amount and rate of calcium cycling is decreased. In contrast in thyrotoxic hypertrophy the amount of calcium cycled is unchanged while the rate is increased. In the pressure overload hearts there is a decrease in sarcoplasmic reticular (SR) Ca++ ATPase, whereas in the thyrotoxic preparations the message is increased. The change in the rate of calcium uptake in pressure overload and thyrotoxic hearts is correlated with a change in the amount of SR Ca++ ATPase mRNA. Calcium cycling was also altered by non-genetic inotropic intervention. Isoproterenol (1 microM) increases the amount of calcium cycled during each contraction relaxation cycle and the rate at which it is removed. These alterations are associated with an increase in force and a foreshortened twitch. Incubating the papillary muscle in high calcium (11 mM) also increases the force and the amount of calcium released into the cytosol. Under these circumstances the rate of uptake is not significantly increased and, accordingly, the isometric twitch is not foreshortened. In the presence of verapamil (14 microM) the peak twitch force is decreased and the isometric myogram is foreshortened. These changes are associated with a decrease in the amount of calcium released during activation and the rate at which it is removed.
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PMID:Genetic and non-genetic control of myocardial calcium. 253 Sep 77

Tension is an important regulator of skeletal muscle hypertrophy in vivo. When increased constant tension is applied to embryonic skeletal muscle fibers differentiated in a tissue culture environment, many of the same biochemical processes associated with muscle hypertrophy in vivo are also stimulated in vitro, e.g., sodium-dependent amino acid transport, Na+,K+-ATPase (sodium pump) activity, protein synthesis, total protein, and myosin heavy chain accumulation. The molecular mechanisms by which tension induces these growth-related changes are unknown, but several models have been tested using whole animal, organ-cultured muscle, and tissue culture model systems. In tissue culture, activation of the plasma membrane sodium pump is closely coupled to, and essential for, stretch and serum-induced skeletal muscle growth. Long-term membrane hyperpolarization is not associated with this sodium pump activation, and muscle growth in vitro is unrelated to the myotube's resting membrane potential, since growth can occur under de-polarizating conditions. Medium growth factors are essential for stretch-induced muscle growth in tissue culture. In medium without growth factor supplements, stretch is able to reduce the rate of atrophy of the cultured muscle cells which are in negative nitrogen balance, but the muscle cells are unable to grow in response to stretch without the presence of some as yet undefined growth factor or factors present in serum. As newer tissue culture environments are designed for growing embryonic skeletal muscle under more in vivo-like conditions, a more complete analysis of the mechanisms by which a physical stimulus (tension) is translated into the biochemical alterations leading to muscle growth will be possible.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Motion into mass: how does tension stimulate muscle growth? 331 13

A method for the continuous measurement of ATP hydrolysis (ATPase) by demembranated muscle fibres has been applied to isometrically held, glycerol-extracted flight muscle fibres from the water-bug Lethocerus, under conditions of high MgATP, neutral pH, and varying ionic strength, Ca2+ and extension. These variables caused parallel changes in isometric tension and ATPase. The slope of ATPase upon tension (delta ATPase/delta Tension; incremental tension cost) remained the same upon extension at either different Ca2+ concentrations or different ionic strength. Isometric activation by Ca2+ gave a higher incremental tension cost. The calculated mechanical rate constant of the work-producing process, measured by the small-amplitude behaviour, was increased by either Ca2+ or ionic strength, and little changed by extension; there was therefore a dissociation between its value and that of the incremental tension cost. The results appear to exclude a two-state crossbridge model for fibrillar insect flight muscle.
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PMID:Dissociation between mechanical performance and the cost of isometric tension maintenance in Lethocerus flight muscle. 403 Oct 48

The influence of MgATP on the Ga(++)-activated isometric tension of skinned frog muscle fibers was examined in solutions containing: Mg(++) = 5 mM, creatine phosphate (CP) = 14.5 mM, creatinephosphokinase (CPK) = 1 mg/ml, total EGTA = 7 mM, CaCl(2), KCl, imidazole >/= 20 mM so that ionic strength = 0.15, pH = 7.00, and MgATP = 2 mM, 0.1 mM, or 20 microM. CP and CPK were necessary for these experiments as determined experimentally by their effect on the tension-Ca(++) relation, which was saturated for CP >/= 14.5 mM. This was interpreted to mean that sufficient CP was present to effectively buffer MgATP intracellularly. Decreasing MgATP shifts the tension-pCa curve to higher pCa (-log Ca(++)) so that, for half-maximal tension: pCa(1/2) = 4.5 for MgATP = 2 mM, pCa(1/2) = 5.1 for MgATP = 0.1 mM, and pCa(1/2) = 5.8 for MgATP = 20 microM; maximum isometric tension is the same in all cases, however. If MgATP was decreased to 1 microM, tension at Ga(++) > 10(-8) M was 84% of the maximum Ca(-+)-activated tension in 2 mM MgATP and increased only slightly to 90% for pCa = 4.5. Weber (1970, In The Physiology and Biochemistry of Muscle as Food, Volume 2, E. J. Briskey, R. G. Cassens, and B. B. Marsh, University of Wisconsin Press, Madison, Wis.), using similar solutions, observed similar shifts in half-maximal calcium activation of rabbit myofibril ATPase rates. In explanation, Weber and Bremel (1971, In Contractility of Muscle Cells and Related Processes, R. J. Podolsky, editor, Prentice-Hall, Inc., Englewood Cliffs, N.J.; Bremel and Weber, 1972, Nat. New Biol., 238:97) have described a mechanism whereby, at low ATP, "rigor complexes" are formed between myosin and thin filament actin and, in turn, alter the calcium affinity of one class of the two Ca(++)-binding sites on troponin, so that the thin filament is "turned on" for contraction at lower Ca(++) levels. Tension data from skinned fibers substantially supports this hypothesis. A stability constant for CaEGTA of 2.62 x 10(10) M(-1) was determined, with the help of F. N. Briggs, in solutions similar to those used for skinned fibers and was the same for 100 and 300 mM KCl.
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PMID:Calcium-activated tension of skinned muscle fibers of the frog. Dependence on magnesium adenosine triphosphate concentration. 454 90

Comparative energetics of chicken latissimus dorsi muscles, tonic anterior (ALD) and phasic posterior (PLD), were investigated by measuring initial heat production. Heat components were analyzed in terms of the equation: E = A + W + alpha(F)(DeltaL) + f(P, t) As the muscles were stretched by increments, heat produced in isometric twitches and tetani decreased in a linear fashion. Two processes are involved: one tension independent, the activation heat, or A; and the other tension dependent, W(i) + alpha(F)(DeltaL) + f(P, t). In twitches, A, per unit tension, is equivalent in the PLD and ALD. Tension-dependent heat, per unit tension, is greater in the PLD due to W(i); but tension-time-related heat, f(P, t), per unit tension, is similar in both muscles. In tetanic contractions, differences in A and f(P, t), per unit tension, are attributed to the greater V(max) in the PLD. The differences in the energetics of isometric contractions in the PLD and ALD, therefore, can be explained by inherent differences in tension development, compliance, and myosin and reticular ATPase activities. Data from isotonic twitches were quantified by means of the equivalent tension technique. Both muscles exhibited an extra heat associated with shortening, alpha(F)(DeltaL). In the PLD, the ratio alpha(F)/P(ot) is greater; it is load independent and (1/2) the value of a/P(o) in both muscles. Enthalpy efficiency, W(e) + W(i)/E, is comparable in both muscles. A Fenn effect is observed only when isotonic energy liberation is compared to a decreasing isometric energy expenditure base line.
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PMID:Energetics of contraction in phasic and tonic skeletal muscles of the chicken. 473 Jun 69

Tension P0 and ATPase activity J0 of glycerinated single muscle fibers under isometric concentration as well as the velocity V0 of unloaded shortening were measured as a function of substrate concentration [S]. The stiffness of fibers with sinusoidal length changes at 1 kHz was used as a qualitative measure of the amount of rigor complex. P0 is an increasing function of [S] at low substrate concentrations and has a broad maximum at about 10-40 micrometers MgATP. In this concentration range, 10-40 micrometers, V0 still has a very small value. Then it increases and finally reaches at a plateau at about 1 mM MgATP. J0 increases as P0 does. However, it reaches at a saturated level at about the same concentration as V0. Either 0.5 mM 8-BrATP or 1 mM PPi was added to the substrate solutions to reduce the amount of rigor complex at low substrate concentrations. The addition of PPi of 8-BrATP decreases P0 dominantly at low concentrations of substrate and shifts the maximum to about 100 micrometers MgATP. 8-BrATP considerably increases V0 at low substrate concentrations while V0 is decreased by added PPi. The temperature coefficients, Q10 values were obtained for P0, J0, and V0. The values are essentially constant, 2.1-2.4, in the cases of P0 and J0, and about the same values were found for V0 at very low substrate concentrations. However, they become about 3.3 in the concentration range from 34 micrometers and 2.3 mM. The P-V relation was obtained at 11 micrometers and 2.3 micrometers MgATP. The normalized P-V relation at 11 micrometers was unchanged when 8-BrATP was added. The results are discussed in connection with the mechanism of actomyosin-ATPase activity as well as that of the elementary cycle of the motive force generation.
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PMID:Substrate-concentration of dependences of tension, shortening velocity and ATPase activity of glycerinated single muscle fibers. 627 76

The mechanism of contraction in rabbit fast-twich, and bovine and rabbit cardiac muscle was examined using functionally skinned fibers, ATPase activity of myofibrils, and cardiac or skeletal troponin-tropomyosin regulated actin heavy meromyosin. The Ca2+ and Sr2+ activation properties for the different measures of contraction were evaluated. (1) Tension in rabbit and bovine cardiac skinned fibers and rabbit cardiac myofibrillar ATPase were activated equally well by either Ca2+ or Sr2+. By contrast, rabbit adductor magnus (fast-twich) skinned fibers required substantially higher [Sr2+] than [Ca2+] for activation, as did rabbit myofibrils from back muscle (fast-twitch). (2) Substantially more Sr2+ than Ca2+ was also required for activation of skeletal muscle actin heavy meromyosin ATPase, controlled by either the skeletal or cardiac troponin-tropomyosin complex, similar to the activation of fast-twitch muscle. (3) The absence of correlation between the divalent cation selectivity properties of actin heavy meromyosin ATPase controlled by cardiac troponin-tropomyosin and cardiac muscle tension or myofibrillar ATPase activation by Ca2+ and Sr2+ suggests that troponin, if primarily responsible for the activation of cardiac muscle, has very different in vivo and in vitro binding properties. (4) The close correlation between percentage of maximal Ca2+- and Sr2+-activated myofibrillar ATPase and tension in skinned fibers strongly justifies the use of myofibrillar ATPase, in contrast to a reconstituted troponin-tropomyosin actin heavy meromyosin ATPase system, as a biochemical measure of contraction.
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PMID:Ca2+ and Sr2+ activation: comparison of cardiac and skeletal muscle contraction models. 644 3

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