Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:4.6.1.1 (adenylate cyclase)
 19,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Sarcoplasmic reticulum fragments isolated from dog cardiac muscle possess a calcium-accumulating system associated with a series of enzymes linked to glycogenolysis. These enzymes include: adenylate cyclase, cyclic AMP-dependent protein kinase, phosphorylase b kinase, phosphorylase (b/a, 30/1),"debrancher" enzyme, and glycogen (0.3 to 0.7 mg/mg of protein). The sarcoplasmic reticulum preparation produced glucose 1-phosphate and glucose from either endogenous or exogenous glycogen. Both the calcium-accumulating and glycogenolytic enzymes sediment in a single peak at 33% sucrose on a linear continous sucrose density gradient, and the complex remains intact throughout repeated washing. Glycogen particles appear to be associated with the sarcoplasmic reticulum in situ as well as in the isolated microsomal fraction. The sarcoplasmic reticulum-glycogenolytic complex, monitored by a linked enzyme spectrophotometric assay, shows several features: (a) activation of phosphorylase activity to peak rate occurs over a very rapid time course which cannot be duplicated using combinations of purified enzymes; (b) activation is inhibited by protein kinase inhibitor; (c) phosphorylase b functions as in the purified form with respect to AMP (Km, 0.3 mM); (d) in the presence of limiting amounts of glycogen, optimal phosphorylase b activity in the sarcoplasmic reticulum requires the presence of debrancher, and the activity is sensitive to inhibitors of that enzyme such as Tris, which suggests the possiblity that the enzymes bear a specific structual relationship to the glycogen present. Phosphorylase b leads to a activation in the sarcoplasmic reticulum was completely resistant to ethylene glycol bis(beta-aminoethyl either)-N,N'-tetraacetic acid (EGTA). Inhibition of calcium accumulation by or release of bound calcium from sarcoplasmic reticulum by X537A (RO 2-2985) did not alter the EGTA resistance. These results suggest that cardiac sarcoplasmic reticulum is a complex organelle containing functions that may be related to excitation-contraction coupling and intermediary metabolism.
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PMID:Association of gylcogenolysis with cardiac sarcoplasmic reticulum. 0 55

1. Guanylate cyclase of every fraction studied showed an absolute requirement for Mn2+ ions for optimal activity; with Mg2+ or Ca2+ reaction was barely detectable. Triton X-100 stimulated the particulate enzyme much more than the supernatant enzyme and solubilized the particulate-enzyme activity. 2. Substantial amounts of guanylate cyclase were recovered with the washed particulate fractions of cardiac muscle (63-98%), skeletal muscle (77-93%), cerebral cortex (62-88%) and liver (60-75%) of various species. The supernatants of these tissues contained 7-38% of total activities. In frog heart, the bulk of guanylate cyclase was present in the supernatant fluid. 3. Plasma-membrane fractions contained 26, 21, 22 and 40% respectively of the total homogenate guanylate cyclase activities present in skeletal muscle (rabbit), cardiac muscle (guinea pig), liver (rat) and cerebral cortex (rat). In each case, the specific activity of this enzyme in plasma membranes showed a five- to ten-fold enrichment when compared with homogenate specific activity. 4. These results suggest that guanylate cyclase, like adenylate cyclase, and ouabain-sensitive Na+ + K+-dependent ATPase (adenosine triphosphatase), is associated with the surface membranes of cardiac muscle, skeletal muscle, liver and cerebral cortex; however, considerable activities are also present in the supernatant fractions of these tissues which contain very little adenylate cyclase or ouabain-sensitive Na+ + K+-dependent ATPase activities.
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PMID:Guanylate cyclase. Subcellular distribution in cardiac muscle, skeletal muscle, cerebral cortex and liver. 1 Aug 90

Two highly lead-sensitive ATPases, Na+,K+-ATPase and adenylate cyclase, can be demonstrated cytochemically by the lead precipitation technique in briefly prefixed tissue, provided that the free Pb2+ concentration in the incubation medium is kept below 0.1 mM by a heavy metal chelator. Under conditions suitable for Na+,K+-ATPase activity precipitation of final reaction product (lead phosphate) at the sarcolemma of cardiac muscle is abolished by 0.1-1mM ouabain. In contrast, reaction product deposition at the intramuscular part of the plasma membrane and at intracellular sites is not noticeably affected by the glycoside. These findings indicate either that the sarcolemma is the exclusive location of Na+,K+-ATPase in cardiac muscle or that the presence of the enzyme at other loci is masked by active Na+,K+-independent, ouabain resistant ATPases. Under conditions favoring adenylate cyclase activity, precipitation by Pb2+ of orthophosphate derived, with the help of added cyclic nucleotide phosphodiesterase and 5'-nucleotidase, from cyclic AMP formed from adenylyl imidodiphosphate (AMP-PNP) is seen after prolonged incubation in myocardial cells along the entire course of the plasma membrane and also at the transverse tubules and is particularly intense at the tight junction regions of the intercalated disks. Ouabain has no effect on these reactions. Reaction product deposition is also observed at the sarcolemma in red skeletal muscle and at the terminal cisternae of the sarcoplasmic reticulum in white skeletal muscle, where the reaction is intensified by adrenaline. Sarcoplasmic reticulum of cardiac and of red skeletal muscle exhibits only relatively weak staining attributable to cyclic AMP formation. These observations are in agreement with the results of tissue fractionation studies according to which the plasma membrane is the chief site of adenylate cyclase in heart and in red, but not white skeletal muscle.
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PMID:Cytochemical studies on sarcolemma: Na+, K+-adenosine triphosphatase and adenylate cyclase. 13 Jun 56

Sarcolemmal Ca++-ATPase, Mg++-ATPase, and (Na+-K+)-ATPase activities were increased in late stages of heart failure in myopathic hamsters (BIO 14.6) without any changes in the adenylate cyclase activity. On the other hand, these hamsters at early and moderate stages of heart failure showed depressions in mitochondrial calcium binding and uptake and microsomal calcium binding. Sarcolemmal (Na+-K+)-ATPase was decreased in failing hearts because of substrate lack, oxygen lack, and perfusion with Ca++-free, Na+-free, or K+-free medium. Both Mg++-ATPase and Ca++-ATPase activities of sarcolemma did not change on perfusing the hearts with substrate-free, hypoxic, Na+-free, or K+-free medium. Adenylate cyclase activity decreased on substrate-free or Ca++-free perfusion. Intracellular calcium overload produced by perfusing the hearts with medium containing calcium after Ca++-free perfusion was associated with decrease in all the sarcolemmal-bound enzyme activities. All types of failing hearts employed in this study showed a dramatic shift in the electrolyte composition. Failure of the cardiac muscle to generate contractile force on treatment with trypsin was associated with defects in the functions of sarcolemma, mitochondria, and sarcoplasmic reticulum, whereas such an effect on treatment with phospholipase C was limited to alterations in the activities of sarcolemma. The data suggest that abnormality at the level of sarcolemma plays an important role in the pathogenesis of heart dysfunction; however, the degree and direction of alterations in the sarcolemmal functions seem to be dependent upon the type of heart failure.
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PMID:Role of sarcolemmal changes in cardiac pathophysiology. 13 Jun 63

At least three mechanical changes characterize the response of cardiac muscle to agents that enhance cyclic AMP production. In common with other inotropic interventions, tension is augmented and the rate of tension rise is increased. The third response, acceleration of the rate of relaxation, is characteristic of the actions of beta-adrenergic agonists. These mechanical effects can be attributed to changes in (1) the amount of Ca2+ released during systole, (2) the rate of Ca2+ release at the onset of systole, and (3) the rate at which Ca2+ is reaccumulated by the sarcoplasmic reticulum at the end of systole. The ability of cyclic AMP-dependent protein kinases to phosphorylate the cardiac sarcoplasmic reticulum in vitro parallels stimulation of both Ca2+ transport and Ca2+-activated ATPase. The phosphoprotein formed in the presence of cyclic AMP and protein kinase has the chemical characteristics of a phosphoester, contains mostly phosphoserine, and has an electrophoretic mobility in SDS polyacrylamide gels that corresponds to a protein of 22,000 daltons. This 22,000-dalton protein, tentatively named phospholamban, thus differs from the acyl phosphooprotein formed by the Ca2+-transport ATPase, which as an apparent molecular weight of 90,000 to 100,000 daltons. Phospholamban has not been found in fast skeletal muscle, nor is Ca2+ transport accelerated by cyclic AMP and protein kinase in sarcoplasmic reticulum from these muslces which do not respond to beta-adrenergic agonists with accelerated relaxation. It thus appears likely that phosphorylation of phospholamban correlates both with an increased rate of Ca2+ transport by cardiac sarcoplasmic reticulum in vitro and accelerated relaxation in the intact myocardium. Preliminary findings are consistent with the view that phosphorylation of phospholamban may be related to other actions on Ca2+ fluxes brought about by agents which activate adenylate cyclase in the myocardium, but these interpretations must remain speculative pending more definitive studies.
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PMID:Control of calcium transport in the myocardium by the cyclic AMP-Protein kinase system. 16 80

Catecholamine-sensitive adenylate cyclase, cyclic nucleotide phosphodiesterase, adenosine 3', 5'-monophosphate (cyclic AMP)-dependent protein kinase, kinase substrate, and phosphoprotein phosphatase have variously been reported to be present in preparations of myocardial cellular membranes that function in the movement of Ca2+ in and out of the cell and in intracellular Ca2+ translocations, indicating that these membranees possess the equipment for the formation and destruction of cyclic Amp as well as for the initiation, effectuation, and termination of a possible membrane action of the nucleotide. It has also been observed that phosphorylation of seryl residues of protein in sarcolemma- and sarcotubule-rich myocardial subcellular fractions by cyclic AMP activated intrinsic and extrinsic protein kinases confers upon these membran structures an enhanced ability to bind or take up Ca2+ and that dibutyryl cyclic AMP, like adrenaline, produces in intact cardiac muscle simultaneous increases in contractile force and in the uptake of extracellular Ca2+. These findings are suggestive of a second messenger role of cyclic AMP in the beta-adrenoreceptor-mediated actions of catecholamines on myocardial contractile force and relaxation, in which Ca2+ would serve as a third messenger and be subject, respectively, to more effective removal from its binding sites on troponin. An alternative interpretation regards Ca2+ and cyclic AMP as interdependent twin second messengers in the catecholamine-induced inotropism. Since the physiological meaning of the reported effects of cyclic AMP on isolated myocardial membrane preparations is far from established an instances of a dissociation between the effects of catecholamines on myocardial contractile force and cyclic AMP levels have been observed, there is still room for hypotheses that relegate cyclic AMP to a nonobligatory, at most, supportive role in the action of the catecholamines on cardiac contraction.
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PMID:Adenosine 3',5'-monophosphate, the myocardial cell membrane, and calcium. 17 10

Cyclic AMP content, adenylate cyclase (EC 4.6.1.1) activity and phosphodiesterase I (EC 3.1.4.1) activity of the hind leg skeletal muscle and cardiac muscle in 60- and 150-day-old normal and myopathic (UM-X7.1) hamsters were examined. In 60-day-old myopathic animals, cardiac cyclic AMP levels were higher and phosphodiesterase I activity was lower, without any changes in the basal adenylate cyclase activity, whereas in 150-day-old myopathic hamsters, cardiac cyclic AMP and basal adenylate cyclase activity were lower, without any changes in the homogenate phosphodiesterase I activity. On the other hand, basal adenylate cyclase and phosphodiesterase I activities in the skeletal muscle homogenate from 60- and 150-day-old myopathic animals were not different from the normal values but the skeletal muscle cyclic AMP levels were significantly less in 60-day-old myopathic hamsters only. The plasma cyclic AMP levels in 60-day-old myopathic hamsters, unlike 150-day-old myopathic animals, were higher than the normal. Although these results reveal differences in myopathic cardiac and skeletal muscles, it is concluded that changes in adenylate cyclase-cyclic AMP system in myopathy are dependent upon the degree of disease.
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PMID:Studies on adenylate cyclase-cyclic AMP system of the myopathic hamster (UM-X7.1) skeletal and cardiac muscles. 17 52

In the first part of this paper, a short review of the literature on the effects of catecholamines, Ca2+, and cyclic AMP on the biochemical, electrical, and mechanical properties of the heart is presented. It is concluded that the effects of epinephrine on activation of glycogenolysis and on the inotropic response of cardiac muscle are both mediated by the combined actions of Ca2+ and cyclic AMP. Since the inotropic response precedes the glycogenolytic response it is evident that increased energy metabolism is a consequence of increased heart work and not a causative factor. The available data suggest that increased tissue cyclic AMP levels resulting from catecholamine stimulation of adenyl cyclase activity alter cardiac mechanics by modulation of the basic calcium flux cycle of the heart. These effects may be mediated by cyclic AMP-stimulated phosphorylation of specific proteins located in the sarcolemma, sarcoplasmic reticulum, and myofilaments via one or more protein kinases, although experimental verfication of the possible relationship between protein phosphorylation and altered Ca2+ binding properties at specific sites in the membranes is at present largely lacking. The increased rate of tension development induced by catecholamines appears to be caused by an increased rate of Ca2+ influx across the sarcolemma during the plateau phase of the action potential, whereas the increased rate of relaxation is probably attributable to an increased rate of sequestration of intracellular Ca2+ by the sarcoplasmic reticulum. In the second part of the paper, data are presented using a working rat heart preparation to illustrate the effect of catecholamines in facilitating Ca2+ entry across the sarcolemma. Decreased left ventricular pressure development induced by addition of ruthenium red or verapamil to inhibit Ca2+ influx was relieved in a concentration-dependent manner by catecholamines. Curves of percentage change of left ventricular pressure against external Ca2+ concentration are presented which show that epinephrine increased the sensitivity of the heart to Ca2+ whereas verapamil decreased it. A half-maximal increase of left ventricular pressure was obtained with 0.6 mM Ca2+ in control hearts, 0.3 mM Ca2+ with epinephrine, and 2.9 mM Ca2+ with verapamil (10(-7)-treated hearts. Verapamil combined with epinephrine at the above concentrations gave a half-miximal increase of left ventricular pressure with 1.3 mM Ca2+. These results are discussed in relation to a model for the Ca2+ flux in the heart.
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PMID:Epinephrine, cyclic AMP, calcium, and myocardial contractility. 17 96

Cholera toxin, an activator of adenylate cyclase in a wide variety of cells, is a substrate for the phosphotransferase reaction catalyzed by purified cyclic adenosine 5'-monophosphate dependent bovine cardiac muscle protein kinase and the protein associated with human erythrocyte membranes. Phosphorylation occurs when the toxin is dissociated with 5-20 mM dithiothreitol and is restricted to the A1 or "adenylate cyclase activating" subunit of the toxin.
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PMID:Phosphorylation of the active, A1 component of cholera toxin by protein kinase. 18 Oct 50

1. The basal and fluoride-stimulated activities of adenylate cyclase, and the maximal activities of 3':5'-cyclic AMP phosphodiesterase and 3':5'-cyclic GMP phosphodiesterase, together with the Km values for their respective substrates, were measured in muscle, liver and nervous tissues from a large range of animals to provide information on the mechanism of control of cyclic AMP concentrations in these tissues. High activities of adenylate cyclase and cyclic AMP diesterase are found in nervous tissues and in the more aerobic muscles (e.g. insect flight muscles, cardiac muscle and some vertebrate skeletal muscles). The activities of these enzymes in liver are similar to those in the heart of the same animal. The Km values for the enzymes from different tissues and animals are remarkably similar. 2. The comparison of cyclic AMP phosphodiesterase and cyclic GMP phosphodiesterase activities suggests that in vertebrate tissues only one enzyme (the high-Km enzyme), which possesses dual specificity, exists, whereas in invertebrate tissues there are at least two phosphodiesterases with separate specificities. 3. A simple quantitative model to explain the control of the steady-state concentrations of cyclic AMP is proposed. The maximum increase in cyclic AMP concentration predicted by comparison of basal with fluoride-stimulated activities of adenylate cyclase is compared with the maximum increases in concentration produced in the intact tissue by hormonal stimulation: reasonable agreement is obtained. The model is also used to predict the actual concentrations and the rates of turnover of cyclic AMP in different tissues and, where possible, these values are compared with reported values. Reasonable agreement is found between predicted and reported values. The possible physiological significances of different rates of turnover of cyclic AMP and the different ratios of high- and low-Km phosphodiesterases in different tissues are discussed.
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PMID:Activities and some properties of adenylate cyclase and phosphodiesterase in muscle, liver and nervous tissues from vertebrates and invertebrates in relation to the control of the concentration of adenosine 3':5'-cyclic monophosphate. 18 42


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