EC:3.6.4.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

1 mg/kg L-thyroxine was administered to rats for 14 days to evaluate the potential of the hyperthyroid state to induce heart hypertrophy and its effect on myosin adenosine-triphosphatase (ATPase) activity. Evidence of hyperthyroidism such as weight loss, elevation of rectal temperature, increased heart rate and oxygen consumption, was observed in all treated rats. Cardiac enlargement was determined by comparison of wet and dry ventricle weights, myocardial RNA, DNA and protein content. Wet and dry ventricle weights and the level of cardiac RNA and protein were augmented by thyroxine treatment. ATPase activity of cardiac myosin was stimulated as the Ca2+ concentration in the incubation medium increased. No difference was found in Ca2+-activation, salt sensitivity or ATPase activity of unreacted and sulphydrylmodified cardiac myosins from euthyroid or hyperthyroid groups. The results showed that in hyperthyroid rats, in contrast to some other species, the biochemical mechanism responsible for the enhancement of cardiac contractility is not an increased myosin ATPase.
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PMID:Thyroxine-induced cardiomegaly: assessment of nucleic acid, protein content and myosin ATPase of rat heart. 9 43

The effects of a moderate physical training program on the hearts of rats have been studied. The mechanical responses of these hearts are improved. Possible contributing factors in this improvement are increased coronary reserve and capacity to deliver oxygen to the myocardium, increased myocardial glycogen stores and increased turnover of fatty acids through the endogenous triglyceride pool. Myocardial oxidative compounds and high energy phosphate stores are not altered. Major changes are found in the energy utilization pathways. Actomyosin, myosin, and heavy meromyosin ATPase activity and binding activity of isolated sarcoplasmic reticulum are all enhanced. Sulfhydryl control of the active site of myosin ATPase is altered. The biochemical effects of conditioning are short lived when training is decreased or discontinued.
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PMID:Effects of physical training and detraining on intrinsic cardiac control mechanisms. 13 72

The importance of perfusion of the coronary vasculature in the regulation of ATPase activity of myosin in rat myocardial cells has been studied. Quantitative histochemistry was used to determine the activity of the enzyme among cells in tissues that had been either perfused through the coronary system or superfused over the surface of the tissue. Enzymatic activity was measured in cryostatic sections from three different preparations: 1) hearts frozen immediately after removal from the animal; 2) isolated hearts frozen after they had been perfused through the coronary circulation; and 3) isolated papillary muscles or trabeculae that had been superfused after dissection and then frozen. ATPase activity was measured in the isolated tissues at different times after dissection. Both calcium- and actin-activated myosin ATPase activities were uniform among cells in both the ventricles of the hearts frozen immediately after dissection and those that had been perfused through the coronary system. In the superfused tissues, although calcium-activated myosin ATPase activity was uniform, actin-activated ATPase activity was not uniform for about 90 minutes after the dissection, the period required for stabilization of the contraction. The pattern of nonuniformity was complex. In all bundles the lowest enzymatic activity was found in the most superficial cells. In very thin bundles, the cells in the center had the highest activity. In the medium and thicker bundles, there were three concentric zones of actin-activated ATPase activity, the superficial zone with the lowest activity, an intermediate zone with high activity, and a central zone with lower activity. Within each zone, the activity was often greatest in myocardial cells immediately next to blood vessels even though the blood vessels had not been perfused. The transverse distribution of ATPase activity of myosin could be explained by a mechanism in which cells in blood vessels (presumably endothelium) release a substance that upregulates myosin ATPase activity, with the rate of release being related to the local oxygen tension. A downregulating substance may also be produced. The period of stabilization of the contraction coincides with the time during which the pattern of actomyosin ATPase activity is nonuniform. These data suggest that the contractile proteins are regulated by a substance produced by blood vessels in proportion to the local PO2, and possibly in relation to shear force on the vascular endothelium.
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PMID:Contractile proteins in myocardial cells are regulated by factor(s) released by blood vessels. 153 52

1. We tested the hypotheses that coupling between oxidative metabolism and force in noradrenaline (NOR)-activated rabbit aorta is controlled (a) by an energy-dependent step or steps in receptor-operated coupling mechanisms upstream to myosin light chain (MLC) kinase, or (b) by energy limitation of MLC kinase-mediated phosphorylation of the MLC or actin-activated myosin ATPase. 2. Oxidative energy production was rapidly inhibited by decreasing organ bath PO2 to less than 30 mmHg. There was no difference, comparing KCl- or NOR-induced force, in the rates of decrease of [PCr] (phosphocreatine) or [ATP] following inhibition of oxidative energy production. (In this report we use the term [PCr] and [ATP] to indicate mean tissue values). Initial rates of decrease in [PCr] and [ATP] following inhibition of oxidative energy production were 0.05 mM/min and 0.06 mM/min, respectively. 3. Despite similar decreases in mean tissue [PCr] and [ATP], relaxations of KCl-induced contractions following inhibition of oxidative energy production were markedly delayed and were blunted compared to relaxations seen during NOR-induced contractions. The threshold mean tissue [PCr] and [ATP] for relaxation during KCl stimulation were 0.25 and 0.60 to 0.80 mM, respectively. During NOR stimulation, threshold values of [PCr] and [ATP] were 0.50 mM and 0.80 mM, respectively. Mean tissue [PCr] and [ATP] levels at 50% relaxation of KCl-induced force were less than 0.1 mM and 0.1 mM, respectively. Fifty per cent relaxation of NOR-induced force occurred at [PCr] and [ATP] values of 0.35 mM and 0.65 mM, respectively. 4. MLC phosphorylation levels decreased during relaxation of NOR force evoked by inhibition of oxidative energy production. There was no change in the level of MLC phosphorylation following inhibition of oxidative energy production in KCl-contracted muscle even at mean tissue [PCr] and [ATP] lower than values associated with decreases in MLC phosphorylation during relaxations of NOR-induced force. 5. Oxygen-induced redevelopment of force during NOR exposure was not dependent on extracellular Ca2+. Mean tissue [PCr] increased prior to onset of O2-evoked force redevelopment. Increases in MLC phosphorylation were seen at the time of onset of force redevelopment. 6. Oxidative metabolism-contraction coupling during NOR-stimulation seems not to be due to energy limitation of the MLC kinase reaction or actin-activated myosin ATPase. Data suggest the rate-limiting step is an energy-dependent reaction in receptor-operated coupling mechanisms upstream to MLC kinase.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Rate-limiting energy-dependent steps controlling oxidative metabolism-contraction coupling in rabbit aorta. 153 69

The sequence of events that leads to irreversible injury of the ischaemic myocardium is poorly understood but it is axiomatic that lack of oxygen will impair regeneration of ATP. In the globally-ischaemic heart a contracture develops which is independent of raised cytoplasmic free Ca2+ and which has been attributed to activation of actomyosin by nucleotide-free actomyosin cross-bridges ('rigor complexes') which form at low ATP concentrations. Single, metabolically-poisoned or anoxic cardiomyocytes show comparable behaviour, shortening before a significant rise in cytoplasmic free Ca2+ occurs. To explain the close temporal relationship that exists between cell shortening and the onset of the free Ca2+ rise we have predicted that, during myocyte shortening, a precipitous fall in cytosolic ATP concentration occurs, the result of rigor-complexes activating myosin ATPase, which then perturbs ionic homeostasis. Here we show, by means of continuous measurements of cytosolic ATP using firefly luciferase microinjected into single, isolated cardiomyocytes, that cell shortening coincides with an abrupt fall in cytosolic ATP.
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PMID:Bioluminescent measurement in single cardiomyocytes of sudden cytosolic ATP depletion coincident with rigor. 162 46

A mathematical formula was derived from an active cross-bridge model to express the changes in the active myocardial force which occurred during systole. Using the formula and the assumption that the energy expenditure for cross-bridge cycling (Um) was a linear function of the force-time integral (FTI), we developed formulae describing the left ventricular Um versus FTI relation, the Um versus force relation, and the Um versus pressure-volume area (PVA) relation. There were strong disagreements between the model predictions and the experimental findings relating oxygen consumption of the heart versus the PVA relation. These differences may have resulted from the oversimplification of important mechanical and/or biochemical properties of the myocardium in the model. However, the model appeared to accurately reproduce the Fenn effect (effect of contraction modes on energy liberation) for the myocardium as well as the effect of catecholamine infusion, hypothermia, and hypothyroidism on the changes in the binding rate of Ca2+ with the regulatory proteins, the myosin ATPase activity, the peak force developed, and the myocardial energy expenditure. We present this work as an intermediate step towards a complete theoretical linkage between the molecular biology, dynamics, and energetics of the human heart.
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PMID:Cross-bridge cycling energy of cardiac muscle estimated from an active cross-bridge model. 182 94

After myocardial infarction in rats, muscle performance in the remaining hypertrophied myocardium deteriorates and is associated with a decrease in myosin adenosinetriphosphatase (ATPase) activity and a shift to the V3 myosin heavy-chain isoform. We have previously shown in another model of hypertrophy, secondary to renovascular hypertension, that chronic intermittent adrenergic stimulation with dobutamine (Db) can prevent this biochemical adaptation. The present study was undertaken to assess the effects of chronic Db treatment on cardiac mass, function, metabolism, and myosin biochemistry in animals subjected to chronic myocardial infarction. Four groups of rats were studied: controls, animals treated with Db (2 mg/kg 2X daily for 4 wk), animals subjected to myocardial infarction and killed after 4 wk (MI), and MI animals concurrently treated with Db for 4 wk (MI-Db). The two MI groups were subdivided into those with and without congestive heart failure (CHF). Heart weight was increased by 13% with Db, unchanged in the infarct groups without CHF, and increased by 9 and 22% in the infarct groups with CHF. Db did not have any additional effect on heart weight in these later groups. Infarct weight was greatest in the animals with CHF, and viable myocardium was equivalent in all infarct groups suggesting that CHF was associated with a greater degree of hypertrophy. Ventricular performance, as assessed in an isovolumic heart apparatus, was markedly depressed in both infarct groups with CHF and was not affected by Db. Db increased myosin ATPase activity in control and infarcted animals both with and without congestive heart failure. Myosin oxygen consumption and lactate production were not adversely affected by Db.
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PMID:Effects of chronic dobutamine on cardiac mechanics and biochemistry after myocardial infarction in rats. 199 90

After reviewing the controversies in the literature surrounding the regulation of oxidative phosphorylation, a unifying theory to integrate the disparate results would be welcome. Following the traditional biochemical approach to identifying sites of control, one searches for the rate-limiting step in a series of reactions (i.e. a biochemical pathway) that, presumably, will not be at equilibrium. This approach has not succeeded in locating a reaction in cardiac respiratory control that is singularly rate-limiting and may actually be contributing to, rather than clarifying, the problem. There are two major criticisms of this approach. First, even if the step is in disequilibrium, it does not prove that it is rate-limiting (26). Second, a reaction near equilibrium can contribute to regulation of a system (37). In a complex, multiple-reaction integrated pathway such as mitochondrial respiration there are many steps that could potentially share the control of the overall system. Thus this pathway easily lends itself to the possibility of multiple sites of control, each of which could contribute by varying degrees to regulation. In Figure 3 we present one possible network (undoubtedly incomplete) for the distributed control of respiration, which incorporates contributions by the cellular redox state (supply), phosphate metabolite concentrations (either kinetic or thermodynamic), and oxygen. The coordination of the dehydrogenases, phosphate metabolites, and myosin ATPase activity (work) may be orchestrated by a second messenger. Calcium is an attractive candidate for this role (15) as it simultaneously can modulate reducing equivalent supply via the dehydrogenases and ATP use by the myofibrils. The theory of shared control along the path of respiration is not new (37), and has been gaining support from a variety of laboratories (3, 9, 26). Applying this concept to the experimental setting, the relative control strengths for various steps in oxidative phosphorylation have been reported for isolated mitochondria (26). The control coefficients for respiration in isolated myocytes or hearts in vivo remain unknown at this time. If control of respiration occurs at multiple sites, it could account for much of the disagreement in the literature. Experimental conditions, whether intentional or inadvertent, that saturate one or more control mechanisms will increase the relative effect of the other regulatory sites on the remaining range of mitochondrial function. If, for example, the medium surrounding isolated myocytes is such that the cytosolic redox state and pO2 are very high, the phosphate metabolite concentrations could logically be expected to be a major factor influencing the observed rate of oxidative phosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Control of mitochondrial respiration in the heart in vivo. 215 67

We have measured the rate constant for ATP release from myosin heads of Ca2+-activated, demembranated muscle fibers using the technique of phosphate-water oxygen exchange. Single rabbit psoas fibers were held in an activating solution in [18O]water ([MgATP] = 8 mM, ionic strength = 0.2 M, pH = 7.0, 24 degrees C). After about 20% hydrolysis of ATP, product Pi and remaining ATP were isolated, and the distribution of 18O in both molecules was analyzed using a mass spectrometer. The exchange in Pi was similar to that previously reported (Hibberd, M. G., Webb, M. R., Goldman, Y. E., and Trentham, D. R. (1985) J. Biol. Chem. 260, 3496-3501). The amount of 18O in ATP gave a rate constant of about 4 s-1 for ATP release, if it is assumed that each rate constant in the pathway of ATP hydrolysis has the same value for all myosin ATPase sites. However, the distribution of 18O in both released Pi and ATP is not well explained by a single pathway for ATP hydrolysis. We present a model that indicates how such distributions could arise from a range of values for the rate constants for Pi and ATP release from actomyosin, and this range is determined by differences in the amounts of strain in attached crossbridges. The kinetic information obtained from these isotope exchange experiments is compared to show that they give a compatible set of rate constants for actomyosin in fibers.
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PMID:Measurement of the reversibility of ATP binding to myosin in calcium-activated skinned fibers from rabbit skeletal muscle. Oxygen exchange between water and ATP released to the solution. 252 91

Rats were injected intraarterially with a fluorescent dye that binds to capillary endothelium, thereby labeling any capillary through which it has passed. After 10, 15, or 30 sec of circulation of the dye blood flow was interrupted, the gastrocnemius was frozen, and the density and distribution of labeled capillaries were measured in transverse sections of the central portion of the medial head. These tissue sections were then counterstained by the myosin ATPase method for capillaries to mark all capillaries. After 10 sec, 45% of all capillaries were labeled and after 15 sec, 59% of all capillaries were labeled. Thirty seconds after injection, all capillaries were labeled with the fluorescent dye. In all three time intervals, the distributions of labeled capillaries were ordered, suggesting that there is a tissue-level control mechanism for regulating capillary perfusion to maintain relatively short maximal oxygen diffusion distances.
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PMID:Sequential perfusion of skeletal muscle capillaries. 293 14

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