Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Muscle phosphorylase deficiency (McArdle's disease) has conventionally been considered a disorder of glycogenolysis, and the associated impairment in oxidative metabolism has been largely overlooked. Muscle glycogen normally is the primary oxidative fuel at exercise work loads requiring more than 75-80% of maximal O2 uptake (VO2max). Evidence is presented to support the hypothesis that a limited flux through the Embden-Myerhof pathway in McArdle's disease reduces the capacity to generate NADH required to support a normal VO2max. The extent of the oxidative defect is substrate dependent; i.e., it can be partially corrected by increasing the availability of alternative oxidative substrates (e.g., glucose, free fatty acids) to working muscle. Experiments employing modification of substrate availability closely link the hyperkinetic circulatory response to exercise (i.e., an abnormally large increase in O2 transport to skeletal muscle) and the premature muscle fatigue and cramping of McArdle patients with their oxidative impairment and suggest that a metabolic common denominator in these abnormal responses may be a pronounced decline in the muscle phosphorylation potential ([ATP]/[ADP][Pi]). The hyperkinetic circulation likely is mediated by the local effects on metabolically sensitive skeletal muscle afferents and vascular smooth muscle of K+, Pi, or adenosine or a combination of these substances released excessively from working skeletal muscle. The premature muscle fatigue and cramping of McArdle patients does not appear to be due to depletion of ATP but is associated with an increased accumulation of Pi and probably ADP in skeletal muscle. Accumulations of Pi and ADP are known to inhibit the myofibrillar, Ca2+, and Na+-K+-ATPase reactions.
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PMID:The pathophysiology of McArdle's disease: clues to regulation in exercise and fatigue. 352 13

We evaluated the hypothesis that impaired sarcolemmal function associated with exaggerated potassium release, impaired potassium uptake, or both may contribute to exertional fatigue and abnormal circulatory responses to exercise in McArdle disease (MD). The cellular mechanism of exertional fatigue and muscle injury in MD is unknown but likely involves impaired function of the ATPases that couple ATP hydrolysis to cellular work, including the muscle sodium potassium pump (Na+K+-ATPase). However, the concentration of muscle Na+K+ pumps in MD is not known, and no studies have related exercise increases in blood potassium concentrations to muscle Na+K+ pump levels. We measured muscle Na+K+ pumps (3H-ouabain binding) and plasma K+ in response to 20 minutes of cycle exercise in six patients with MD and in six sex-, age-, and weight-matched sedentary individuals. MD patients had lower levels of 3H-ouabain binding (231 +/- 18 pmol/g w.w., mean +/- SD, range, 210 to 251) than control subjects (317 +/- 37, range, 266 to 371, p < 0.0004), higher peak increases in plasma potassium in response to 45 +/- 7 W cycle exercise (MD, 1.00 +/- 0.15 mmol/L; control subjects, 0.48 +/- 0.09; p < 0.0001), and mean exercise heart rate responses to exercise that were 45 +/- 12 bpm greater than control subjects. Our results indicate that Na+K+ pump levels are low in MD patients compared with healthy subjects and identify a limitation of potassium reuptake that could result in sarcolemmal failure during peak rates of membrane activation and may promote exaggerated potassium-activated circulatory responses to submaximal exercise. The mechanism of the low Na+K+ pump concentrations in MD is unknown but may relate to deconditioning or to disruption of a close functional relationship between membrane ion transport and glycolysis.
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PMID:Reduced levels of skeletal muscle Na+K+ -ATPase in McArdle disease. 944 49

1. The Na+,K+-ATPase or Na+,K+-pump, mediating the active transport of Na+ and K+, which was first identified 40 years ago, is a central target for acute and long-term regulation, as well as for therapeutic intervention. Acute stimulation of the Na+,K+-pump in skeletal muscle by insulin, catecholamines, beta2-agonists or theophylline increases the intracellular uptake of K+ and accounts for the hypokalaemia elicited by these agents. Conversely, digitalis intoxication elicits hyperkalaemia via acute inhibition of the Na+, K+-pump. 2. Simple and accurate methods have been developed for the quantification of the total concentration of Na+,K+-pumps in small (0.5-5 mg) fresh or frozen biopsies of human skeletal muscle, myocardium or other tissues. This has allowed the identification of several long-term regulatory changes in the concentration of this transport system in human tissues. In skeletal muscle, upregulation is induced by training, thyroid hormones or glucocorticoids. Downregulation is seen in hypothyroidism, cardiac insufficiency, myotonic dystrophy, McArdle disease, K+ deficiency and after muscle inactivity. 3. Since the skeletal muscles contain one of the major pools of Na+,K+-pumps, these changes are important for the ability to counterregulate the hyperkalaemia elicited by exercise or the ingestion of K+. Moreover, downregulation or inhibition of the Na+, K+-pumps in skeletal muscle interferes with contractile performance. Since digitalis glycosides bind to the Na+,K+-pump, the muscles constitute a large distribution volume for these agents and are therefore an important determinant for their plasma level. 4. In cardiac insufficiency, the decrease in the concentration of Na+, K+-pumps in the myocardium is over a wide range correlated to the concomitant reduction in ejection fraction. The regulatory and pathophysiological changes in the activity and concentration of Na+, K+-pumps are important for the contractile function of skeletal muscle and heart as well as for K+ homoeostasis and the response to digitalization.
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PMID:Clinical and therapeutic significance of the Na+,K+ pump*. 966 81