EC:3.6.4.1 - FACTA Search

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Query: EC:3.6.4.1 (myosin ATPase)
1,140 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

MgADP has a more pronounced effect on the relaxation behaviour in tonic vascular smooth muscle compared to phasic smooth muscle. An apparent dissociation constant of 1.3 microM has been reported for a high affinity binding site of vascular smooth muscle cross-bridges. For this high affinity to have an effect on the low energy costs of tension maintenance (latch) it would require that free [ADP] in the region of the contractile proteins (at least sometimes) be as low as 1.3 microM. We ask, in this report, whether [ADP] could be as low as 1.3 microM in vascular smooth muscle. If creatine kinase (CK) is at equilibrium, then micromolar [ADP] is incompatible with measured concentrations of phosphocreatine (PCr), free creatine (Cr) and ATP, which entail a mean equilibrium [ADP] of around 18 microM. But CK may not be quite at equilibrium: if there is net PCr synthesis at the mitochondrion, then maintenance of the steady-state requires that there be net PCr hydrolysis in the region of the contractile proteins up to or equal to the rate of myosin ATPase. We derive a simple relationship between net flux and displacement from equilibrium which we use to argue that an [ADP] of 1.3 microM at the contractile proteins would drive significant net PCr synthesis, incompatible with normal contractile function. Thus the CK system holds [ADP] at about 18 microM near the contractile proteins in vascular smooth muscle. We conclude that smooth muscle [ADP] cannot be far from equilibrium and that a role for ADP (at the low micromolar level) in controlling smooth muscle relaxation is unlikely.
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PMID:The creatine kinase equilibrium, free [ADP] and myosin ATPase in vascular smooth muscle cross-bridges. 773 20

This article is a review on the organization and function of myofibrillar creatine kinase in striated muscle. The first part describes myofibrillar creatine kinase as an integral structural part of the complex organization of myofibrils in striated muscle. The second part considers the intrinsic biochemical and mechanical properties of myofibrils and the functional coupling between myofibrillar CK and myosin ATPase. Skinned fiber studies have been developed to evidence this functional coupling and the consequences for cardiac contraction. The data show that creatine kinase in myofibrils is effective enough to sustain normal tension and relaxation, normal Ca sensitivity and kinetic characteristics. Moreover, the results suggest that myofibrillar creatine kinase is essential in maintaining adequate ATP/ADP ratio in the vicinity of myosin ATPase active site to prevent dysfunctioning of this enzyme. Implications for the physiology and physiopathology of cardiac muscle are discussed.
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PMID:Myofibrillar creatine kinase and cardiac contraction. 780 50

Myocardial ischemia is characterized by a decrease in phosphocreatine (PCr) and Mg(2+)-ATP contents as well as an accumulation of myosin ATPase reaction products (inorganic phosphate [P(i)], protons, and Mg(2+)-ADP). The possibility that these metabolites play a role in rigor tension development was checked in rat ventricular Triton X-100-skinned fibers. Rigor tension was induced by stepwise decreasing [Mg(2+)-ATP] in the presence or in the absence of 12 mmol/L PCr. To mimic the diastolic ionic environment of the myofibrils, [free Ca2+] was set at 100 nmol/L (pCa 7); [free Mg2+], at 1 mmol/L; and ionic strength, at 160 mmol/L. In control conditions (pH 7.1, with no added P(i) or Mg(2+)-ADP), the pMg(2+)-ATP for half-maximal rigor tension (pMg(2+)-ATP50) was 5.07 +/- 0.03 in the presence of PCr. After withdrawal of PCr, the pMg2+)-ATP50 value was shifted toward higher Mg(2+)-ATP values (3.57 +/- 0.03). Addition of 20 mmol/L P(i) shifted the pMg(2+)-ATP50 to 3.71 +/- 0.04 (P < .05) in the absence of PCr and in the opposite direction to 4.98 +/- 0.02 (P < .01) in the presence of PCr. Acidic pH (6.6) strongly increased pMg(2+)-ATP50 in both the absence (3.90 +/- 0.03, P < .001) and presence (5.44 +/- 0.02, P < .001) of PCr. Conversely, Mg(2+)-ADP (250 mumol/L) decreased pMg(2+)-ATP50 to 3.26 +/- 0.06 (P < .001) in the absence of PCr; at pMg(2+)-ATP 4, no rigor tension was observed until PCr concentration was decreased to < 2 mmol/L. At acidic pH, maximal rigor tension was lower by 29% compared with control conditions, whereas in the presence of Mg(2+)-ADP, maximal rigor tension developed to 143% of the control value; P(i) had no effect. The tension-to-stiffness (measured by the quick length-change technique) ratio was lower in rigor (no PCr and pMg(2+)-ATP 6) than during Ca2+ activation in the presence of both PCr and ATP. Compared with control rigor conditions, this parameter was unchanged by Mg(2+)-ADP and decreased by acidic pH, suggesting a proton-induced decrease in the amount of force per crossbridge. In addition to their known effects on active tension, Mg(2+)-ADP and protons affect rigor tension and influence ischemic contracture development. It is concluded that ischemic contracture and increased myocardial stiffness may be mediated by a decreased PCr and local Mg(2+)-ADP accumulation. This emphasizes the importance of myofibrillar creatine kinase activity in preventing ischemic contracture.
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PMID:Myocardial ischemic contracture. Metabolites affect rigor tension development and stiffness. 815 39

The synthesis of [2-3H]ATP with specific activity high enough to use for 3H NMR spectroscopy at micromolar concentrations was accomplished by tritiodehalogenation of 2-Br-ATP. ATP with greater than 80% substitution at the 2-position and negligible tritium levels at other positions had a single 3H NMR peak at 8.20 ppm in 1D spectra obtained at 533 MHz. This result enables the application of tritium NMR spectroscopy to ATP utilizing enzymes. The proteolytic fragment of skeletal muscle myosin, called S1, consists of a heavy chain (95 kDa) and one alkali light chain (16 or 21 kDa) complex that retains myosin ATPase activity. In the presence of Mg2+, S1 converts [2-3H]ATP to [2-3H]ADP and the complex S1.Mg[2-3H]ADP has ADP bound in the active site. At 0 degrees C, 1D 3H NMR spectra of S1.Mg[2-3H]ADP have two broadened peaks shifted 0.55 and 0.90 ppm upfield from the peak due to free [2-3H]ADP. Spectra with good signal-to-noise for 0.10 mM S1.Mg[2-3H]ADP were obtained in 180 min. The magnitude of the chemical shift caused by binding is consistent with the presence of an aromatic side chain being in the active site. Spectra were the same for S1 with either of the alkali light chains present, suggesting that the alkali light chains do not interact differently with the active site. The two broad peaks appear to be due to the two conformations of S1 that have been observed previously by other techniques. Raising the temperature to 20 degrees C causes small changes in the chemical shifts, narrows the peak widths from 150 to 80 Hz, and increases the relative area under the more upfield peak. Addition of orthovanadate (Vi) to produce S1.Mg[2-2H]ADP.Vi shifts both peaks slightly more upfield without changing their widths or relative areas.
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PMID:[2-3H]ATP synthesis and 3H NMR spectroscopy of enzyme-nucleotide complexes: ADP and ADP.Vi bound to myosin subfragment 1. 835 34

Reactive oxygen species (ROS) have been reported to alter cardiac myofibrillar function as well as myofibrillar enzymes such as myosin ATPase and creatine kinase (CK). To understand their precise mode and site of action in myofibrils, the effects of the xanthine/xanthine oxidase (X/XO) system or of hydrogen peroxide (H2O2) have been studied in the presence and in the absence of phosphocreatine (PCr) in Triton X-100-treated cardiac fibers. We found that xanthine oxidase (XO), with or without xanthine, induced a decrease in maximal Ca(2+)-activated tension. We attributed this effect to the high contaminating proteolytic activity in commercial XO preparations, since it could be prevented a protease inhibitor, phenylmethylsulfonyl fluoride (PMSF), and it could be mimicked by trypsin. In further experiments, XO was pre-treated with 1 mmo1/L PMSF. Superoxide anion production by the X/XO system, characterized by electron paramagnetic resonance spin-trapping technique, was not altered by PMSF. A slight increase in maximal force was then observed either with X/XO (100 mumol/L per 30 mIU/mL) or H2O2. pMgATP-rigor tension relationships have been established in the presence and in the absence of PCr to separate the effects of ROS on myosin ATPase and myofibrillar-bound CK. In the absence of PCr, pMgATP50, the pMgATP necessary to induce half-maximal rigor tension, was reduced from 5.03 +/- 0.17 (n = 21) to 4.22 +/- 0.22 (n = 4) after 25 minutes of incubation in the presence one of 30 mIU/mL. XO and 100 mumol/L xanthine or to 4.04 +/- 0.1 (n = 11) after incubation in the presence of 2.5 mmol/L H2O2. The ROS effects were partially prevented or antagonized by 1 mmol/L dithiothreitol. No effect was observed on pMgATP50 when PCr was absent. pCa-tension relationships have been evaluated to assess the effects of ROS on active tension development. Incubations with H2O2 induced on increase in Ca2+ sensitivity and resting tension when MgATP was provided through myofibrillar CK (PCr and MgADP as substrates) but not when MgATP was added directly. These results suggest that myofibrillar CK was inhibited by ROS. Active stiffness and the time constant of tension changes after quick stretches applied to the fibers were dose-dependently increased by H2O2 only in the presence of PCr. In addition, myofibrillar CK but not myosin ATPase enzymatic activity was depressed after incubation with either ROS. These results suggest that ROS mainly alters CK in myofibrils, probably by the oxidation of its essential sulfhydryl groups. Such CK inactivation results in a decrease in the intramyofibrillar ATP-to-ADP ratio. The effects of ROS on cytosolic and bound CKs may take part in the overall process of myocardial stunning after cardiac ischemia and reperfusion.
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PMID:Creatine kinase is the main target of reactive oxygen species in cardiac myofibrils. 863 32

The in vitro motility of fluorescent actin filaments over heavy meromyosin (HMM) was studied in the presence of the nonionic detergent Triton X-100. Below 0.004% Triton X-100 concentration, motility was not affected. Above 0.007%, motility was not observed because actin filaments were dissociated from HMM. In the Triton X-100 concentration range of 0.004-0.007%, the sliding actin filaments dissociated from HMM with a delay. The dissociation delay time decreased with increasing Triton X-100 concentration, increasing ATP (adenosine-5'-triphosphate) concentration, and increasing temperature. The delayed acto-HMM dissociation was absent when weak-binding kinetic intermediates of the myosin ATPase cycle (M.ATP and M.ADP-Pi) were used. The presence of sliding movement was necessary to evoke the delayed acto-HMM dissociation. The acto-HMM dissociation delay was independent of actin filament length. For a given Triton X-100 concentration, the dissociation delay time was found to be inversely proportional to sliding velocity, indicating that actin filaments travel a more or less constant distance prior to dissociation from HMM. The actin-activated HMM ATPase activity was not inhibited by Triton X-100; rather, it was slightly enhanced. The results imply the presence of a motility-associated conformational change in acto-HMM.
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PMID:Delayed dissociation of in vitro moving actin filaments from heavy meromyosin induced by low concentrations of Triton X-100. 939 25

Mant (2'(3')-O-(N-methylanthraniloyl)) labeled nucleotides have proven to be useful tools in the study of the kinetic mechanism of the myosin ATPase by fluorescence spectroscopy. The sensitivity of the mant fluorophore to its local environment also makes it suitable to investigate the exposure of bound nucleotides to solvent from collisional quenching measurements. Here we present the crystal structure of mant-ADP and beryllium fluoride complexed with Dictyostelium discoideum myosin motor domain (S1dC) at 1.9 A resolution. We complement the structural approach with an investigation of the accessibility of the mant moiety to solvent using acrylamide quenching of fluorescence emission. In contrast to rabbit skeletal myosin subfragment 1, where the mant group is protected from acrylamide (Ksv=0.2 M-1), the fluorophore is relatively exposed when bound to Dictyostelium myosin motor domain (Ksv= 1.4 M-1). Differences between the Dictyostelium structure and that of vertebrate skeletal subfragment 1, in the region of the nucleotide binding pocket, are proposed as an explanation for the differences observed in the solvent accessibility of complexed mant-nucleotides. We conclude that protection of the mant group from acrylamide quenching does not report on overall closure of the nucleotide binding pocket but reflects more local structural changes.
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PMID:X-ray crystal structure and solution fluorescence characterization of Mg.2'(3')-O-(N-methylanthraniloyl) nucleotides bound to the Dictyostelium discoideum myosin motor domain. 940 48

Myosin forms stable ternary complexes with ADP and the phosphate analogues, fluoroaluminate (Al F4-), fluoroberyllate (BeFn) or orthovanadate (Vi); these ternary complexes mimic transient intermediates in the myosin ATPase cycle. Moreover, we previously demonstrated that these complexes may mimic different myosin ATPase reaction intermediates corresponding to separate steps in the cross-bridge cycle [Maruta, S., Henry, G. D., Sykes, B. D. & Ikebe, M. (1993) J. Biol. Chem. 268, 7093-7100]. Park et al. suggested that the changing conformation of ATP during hydrolysis stresses the active site of myosin subfragment-1 (S-1) through protein-nucleotide contacts at the gamma-phosphate and nucleotide base, and the stress-induced strain in the cross-bridge may be the mechanism by which energy in ATP is transferred to the myosin structure [Park, S., Ajtai, K. & Burghardt, T. P. (1997) Biochemistry 36, 3368-3372]. In the present study, the photoactive ADP analogue, 3'-O-(N-methylanthraniloyl)-2-azido-ADP (Mant-2-N3-ADP), and the 19F-labeled ADP analogue, 2-[(trifluoromethylnitrophenyl)aminoethyl]diphosphate, were employed to examine conformational differences in protein-nucleotide contact in the ATP-binding site that may correlate with energy transduction. Mant-2-N3-ADP was trapped within the active site of skeletal and smooth muscle myosin in the presence of AlF4-, BeFn or Vi. For both skeletal and smooth muscle myosins, trapped Mant-2-N3-ADP was covalently linked to the 25-kDa N-terminal fragment of S-1 of both myosin/Mant-2-N3-ADP/AlF4- and BeFn complexes, presumably at Trp130. However, the efficiency of the incorporation was much higher for skeletal than for smooth muscle myosin suggesting that the conformations of the adenine-binding pockets of the two myosins are somewhat different. Although the amount of Mant-2-N3-ADP trapped in the presence of AlF4- and BeFn was the same for both myosins, the efficiency of photolabeling skeletal muscle myosin was approximately two times higher for BeFn complex than for AlF4- complex. The 19F-NMR spectra of the bound 2-[(trifluoromethylnitrophenyl)aminoethyl]diphosphate in the ternary complexes formed in the presence of AlF4-, BeFn or Vi showed small but distinguishable differences. Taken together, these results indicate that there is some variation in the protein-nucleotide contacts at the nucleotide base among the ternary complexes studied, and these differences mimic separate steps occurring transiently during the contractile cycle.
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PMID:Analysis of stress in the active site of myosin accompanied by conformational changes in transient state intermediate complexes using photoaffinity labeling and 19F-NMR spectroscopy. 954 69

The noncovalent fluorescent probe 6-propionyl-2-(dimethylamino)naphthalene (prodan) binds stoichiometrically to myosin subfragment-1 (S-1) without affecting the ATPase and actin-binding properties of S-1. Neither ATP nor actin interferes with the prodan binding. Free prodan exhibits a green emission peak at 520 nm. However, the prodan bound to S-1 and the S-1.ADP complex shows blue emission peaks at 460 and 450 nm, respectively, which allow easy separation of the fluorescence contributions from the free and bound probes. In the S-1.ADP.Pi state, the blue emission peak is further shifted to 445 nm with a large (4.5-fold) fluorescence enhancement. Thus, prodan in the presence of S-1 exhibits predominantly blue fluorescence only during ATP hydrolysis, and so visualizes the ATPase reaction continuously. The initial velocities of the steady state of the Mg2+-, Ca2+-, and actin-activated ATPases can be conveniently calculated from the blue fluorescence changes. The ability of different nucleoside triphosphates (NTP) to enhance the blue fluorescence of prodan follows the order ATP > CTP > UTP > ITP > GTP. This order agrees with those of the extent of hydrophobicity near the ribose of the corresponding nucleoside diphosphates (NDP) trapped to S-1 with orthovanadate (Vi) [Hiratsuka, T. (1984) J. Biochem. (Tokyo) 96, 155-162] and the ability of different NTPs to support force production in muscle fibers [Regnier, M., et al. (1993) Biophys. J. 64, A250]. The rate of formation of the corresponding S-1.NDP.Vi complex also follows this order, whereas the NTPase rate follows the reverse order. These results indicate that nucleotide-induced changes in prodan fluorescence correspond to the nucleotide-induced conformational states of S-1. Thus, the use of prodan in studies of the myosin ATPase offers a new and promising approach not only to monitoring the ATPase reaction but also to investigating the structural changes during ATP hydrolysis.
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PMID:Prodan fluorescence reflects differences in nucleotide-induced conformational states in the myosin head and allows continuous visualization of the ATPase reactions. 958 28

Ischaemic myocardium undergoes calcium-independent contracture at millimolar tissue ATP, though in actomyosin solutions ATP must be reduced to micromolar before rigor complexes form. This contracture is associated with myosin ATPase activity that may contribute to tissue de-energization. Here we used isolated rat cardiomyocytes permeabilized with digitonin to analyse in parallel how rigor and myosin ATPase activity are modulated by metabolic conditions that develop during ischaemia. At pH 7.1 and 37 degrees C rigor and myosin ATPase showed co-ordinated bell-shaped dependence on ATP concentration over 3-1000 microM. Rigor, but not myosin ATPase, was inhibited by acidosis (pH 6.2), indicating reduced efficiency of cross-bridge cycling, while both parameters were stimulated by ADP (< or = 1 mM) and unaffected by inorganic phosphate (Pi, 30 mM), AMP, Mg2+, lactate or inhibition of adenylate kinase with diadenosine pentaphosphate. Combined acidosis and high ADP inhibited rigor, while Pi attenuated the enhancement of rigor by ADP. Thus, rigor complex formation activates myosin ATPase in the intact myofilament array, modulated by ADP, Pi and acidosis in the ranges that occur in ischaemia. There was no evidence that adenylate kinase might attenuate falling ATP/ADP ratio at the myofilaments. In combination these effects are sufficient to resolve the apparent discrepancy between ATP concentrations triggering rigor in actomyosin and onset of contracture in ischaemic myocardium. Since rigor contracture activates myosin ATPase it is likely to exacerbate ATP depletion and thereby limit vital cell functions. This positive feedback is consistent with the abrupt depletion of ATP observed in individual cardiomyocytes undergoing deenergization contracture.
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PMID:Modulation of rigor and myosin ATPase activity in rat cardiomyocytes. 971 Aug 3

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