Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

Previous work from our laboratory indicated that pancreatic islets contain myosin light chain kinase, a calcium- and calmodulin-activated enzyme. This enzyme catalyzes phosphorylation of myosin which, in tissues containing smooth muscle, is believed to permit the ATPase of myosin to be activated by actin. The current report shows that incubating islet cytosol with ATP under conditions that should permit phosphorylation of myosin markedly enhances islet myosin ATPase activity in the presence of actin. It has been suggested that contractile proteins power insulin granule movements in the beta cell. Phosphorylation of myosin may be one of the means of coupling stimuli to insulin secretion.
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PMID:Activation of pancreatic islet myosin ATPase by ATP and actin. 316 Mar 44

We used a modification of Langendorff's isolated perfused nonworking rat-heart model to study the effects of diabetes, insulin-treated diabetes, and hyperinsulinemia on left ventricular pressure, force of ventricular contraction, and myocardial contracture, before, during, and after 20 min of complete normothermic global ischemia. Untreated diabetic rat hearts behaved the same as normal hearts, but insulin-treated diabetic hearts had more ischemic and postischemic contracture (p less than .01), and less return of left ventricular function. Chronic insulin treatment potentiated ischemic contracture in diabetic and nondiabetic rat hearts. These results support the hypotheses that insulin can increase Ca++ actin-myosin ATPase activity, and increase the affinity of myofibrillar receptors for calcium, which may lead to increased ischemic contracture. Insulin as a risk factor in myocardial ischemia, cardiothoracic surgery and cardiac resuscitation, and other pathogenetic factors of "stone heart" development, deserve further investigation.
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PMID:Insulin worsens ischemia-induced myocardial contracture in the isolated rat heart. 351 78

The effect of diabetes on cardiac function was determined in isolated rat hearts. Diabetes was induced by injection of alloxan (doses ranged from 37.5 to 60 mg/kg body wt), and the heart were removed and perfused in the working heart preparation. Doses of alloxan ranging from 37.5 to 42 mg/kg did not consistently alter cardiac function even though serum glucose was elevated and serum thyroid hormones were reduced. Injection of 45 mg/kg of alloxan caused a large increase in serum glucose and a larger decrease in thyroid hormones. In this case, ventricular function was more consistently depressed after 1-2 wk. Function was not altered 48 h after injection of 60 mg kg of alloxan. However, when animals were given 60 mg/kg of alloxan and then maintained on insulin for 7 days, depressed cardiac function developed within 4 days after the insulin treatment was stopped. The decline in function involved a decrease in heart rate peak systolic pressure, and left ventricular +dP/dt. It was associated with greatly reduced serum thyroid hormones (both T3 and T4) and lower ventricular Ca2+-activated myosin ATPase activity. Fasting of rats for 4 days also resulted in decreased serum T3 and T4, depressed cardiac function (although heart rate was unchanged), and lower Ca2+-activated myosin ATPase activity.
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PMID:Decreased myocardial function and myosin ATPase in hearts from diabetic rats. 622 Jun 13

The effects of insulin, T4, and T3 treatment on cardiac function, myosin ATPase activity, and myosin isozyme distribution were studied in alloxan diabetic rats. Diabetes resulted in depressed peak ventricular pressure development, heart rate, and left ventricular +dP/dt. Myocardial Ca2+-activated myosin ATPase activity was reduced in association with lower serum levels of T3 and T4. The V1 isozyme of myosin decreased, and both V2 and V3 isozymes increased. Insulin treatment totally reversed the changes in function, serum thyroid hormones, and myosin ATPase activity. Treatment of diabetic animals with T4 (5 or 10 micrograms/day) prevented the decrease in myosin ATPase but did not prevent the changes in cardiac function, myosin isozymes, or serum T3 levels. Pharmacological doses of T3 (3 micrograms/day) that were adequate to maintain higher than normal serum T3 corrected the decrease in Ca2+-activated myosin ATPase and heart rate but only partially corrected the changes in pressure development and myosin isozyme distribution. Only when serum T3 was increased to four times normal was cardiac function corrected.
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PMID:Cardiac function and myosin ATPase in diabetic rats treated with insulin, T3, and T4. 622 Jun 14

Previous studies have shown that in rats, diabetes mellitus induces a 45% decrease in cardiac Ca++-activated myosin ATPase activity which is accompanied by a decrease in myosin isoenzyme V1 and an increase in myosin isoenzyme V3 levels. Insulin administration reverts Ca++-activated myosin ATPase activity and myosin isoenzyme distribution to normal levels. It is currently unclear whether the effects of insulin on Ca++-myosin ATPase activity and myosin isoenzyme distribution are direct effects of the hormone or are mediated through insulin-induced alterations in cardiac metabolism. To determine if insulin may exert part of its effects by the latter route, diabetic rats were fed a normal, glucose, or fructose diet. Unlike glucose, fructose can enter the initial steps of the glycolytic pathway in the absence of insulin. Placing diabetic rats on different forms of 60% fructose diets for 4 weeks led to a 20-35% increase in Ca++-activated myosin ATPase activity, which was highly significant (normal Ca++-activated myosin ATPase activity, 0.917 mumol Pi/mg protein X min; diabetic, 0.553 mumol Pi/mg protein X min; diabetic + fructose, 0.661 mumol Pi/mg protein X min). The increase in Ca++-activated myosin ATPase activity was accompanied by increased myosin isoenzyme V1 and decreased myosin isoenzyme V3 levels. Feeding animals a 60% glucose diet did not lead to changes in Ca++-activated myosin ATPase activity or myosin isoenzyme distribution. The fructose-induced increase in Ca++-activated myosin ATPase activity and alteration in myosin isoenzyme distribution occurred in the absence of changes in insulin and thyroid hormone levels or improvement in the general metabolic status of fructose-fed diabetic rats.
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PMID:Fructose feeding increases Ca++-activated myosin ATPase activity and changes myosin isoenzyme distribution in the diabetic rat heart. 623 27

It has been recognized for a long time that changes in hormone secretion can influence cardiac function; however, the biochemical basis for these changes has only recently been clarified. In this review the influences of hormonal status on the contractile protein myosin is discussed. Myosin has a rod-like portion and a globular head and consists of two myosin heavy chains (MHC) and four light chains (LC), two of which are identical. The globular head is the site of an ATP-splitting enzyme, the myosin ATPase, and increases in myosin ATPase activity are closely related to an increased velocity of contraction of the heart. Myosin ATPase activity shows marked response to alterations in thyroid hormone, insulin, glucocorticoid, testosterone and catecholamine levels, but marked animal species differences in this response occur. Thyroid hormone administration to normal rabbits, for example, increases myosin ATPase activity markedly, but the myosin ATPase activity of hyperthyroid rats remains unchanged. In contrast, in hypothyroid rats myosin ATPase activity is markedly decreased but the hypothyroid rabbit shows no such response. These species-related differences in the hormonal response of myosin ATPase activity result from the predominance pattern of specific myosin isoenzymes. In the normal rat heart three myosin isoenzymes, V1, V2 and V3, can be separated electrophoretically. Myosin V1 predominates (70% of total myosin), and has the highest myosin ATPase activity, whereas in rabbits myosin V3, which has a lower myosin ATPase activity, is the predominant isomyosin. Thyroid hormone administration to rabbits induces myosin V1 predominance and therefore increases myosin ATPase activity, whereas in hyperthyroid rats only a small further increase in V1 predominance can occur. The alterations in myosin isoenzyme predominance and myosin ATPase activity are closely correlated to changes in cardiac contractility. Hormone-induced alterations in myosin isoenzyme predominance are mediated through changes in the formation of two isoforms of myosin heavy chain. Changes in the expression of different myosin heavy chain genes are most likely responsible for the thyroid hormone and insulin-induced alterations in myosin isoenzyme predominance. Investigation of the control of myosin heavy chain formation can provide further insights into the hormonal control of a multigene family as well as broaden our understanding of the molecular events which result in altered cardiac contractility.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Hormonal influences on cardiac myosin ATPase activity and myosin isoenzyme distribution. 623 63

Diabetes appears to cause a cardiomyopathy independent of atherosclerotic coronary artery disease and hypertension. Left ventricular papillary muscle function studies in rats made severely diabetic with streptozotocin have shown a slowing of relaxation and a depression of shortening velocity. However, the effects of insulin therapy on the myocardial mechanics of diabetic rats have not been studied. Therefore, rats diabetic for 6-10 weeks were treated with PZI insulin for 2, 6, 10, or 28 days and the mechanical performance of their left ventricular papillary muscles was compared to that of untreated diabetics and age-matched controls; cardiac contractile protein enzymatic activity was also measured. Neither 2 nor 6 days of therapy had any effects on the depressed cardiac muscle performance of diabetic animals, although plasma glucose concentration was restored to normal. By 10 days of therapy, recovery of mechanical performance was nearly complete, and by 28 days of therapy, complete reversal of the altered myocardial mechanics was observed. Crystalline insulin added to the bath (9 mU/ml) had no effect on myocardial mechanics in either diabetics or controls. A gradual recovery of actomyosin and myosin ATPase activity in the hearts of insulin-treated diabetic animals was also found, complementing the mechanical studies. In addition to demonstrating a gradual but complete reversibility of the abnormalities in papillary muscle function in diabetic rats (although control of hyperglycemia was less than ideal), this study confirms that this model of a cardiomyopathy is not a result of streptozotocin-induced cardiac toxicity. Additional data are provided indicating that depressed thyroid hormone levels in diabetic rats are not responsible for the mechanical changes observed.
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PMID:Reversibility of diabetic cardiomyopathy with insulin in rats. 703 May 13

The incidence of mortality from cardiovascular diseases in higher in diabetic patients. The cause of this accelerated cardiovascular disease is multifactorial and, although atherosclerotic cardiovascular disease in association with well-defined risk factors has an influence on morbidity and mortality in diabetics, myocardial cell dysfunction independent of vascular defects have also been defined. We postulate that these adverse cardiac effects could presumably result as a consequence of the following sequence of events. Major abnormalities in myocardial carbohydrate and lipid metabolism occur as a result of insulin deficiency. These changes are closely linked to the accumulation of various acylcarnitine and coenzyme derivatives. Abnormally high amounts of metabolic intermediates could cause disturbances in calcium homeostasis either directly or indirectly through structural and functional subcellular membrane alterations. Over time, chronic abnormalities such as reduced myosin ATPase activity, decreased ability of the sarcoplasmic reticulum to take up calcium as well as depression of other membrane enzymes such as Na(+)-K+ ATPase and Ca(2+)-ATPase leads to changes in calcium homeostasis and eventually to cardiac dysfunction. More importantly from the point of view of pharmacological intervention, during the initial stages, acute disturbances in both the glucose and FFA oxidative pathways may provide the initial biochemical lesion from which further events ensue. Thus therapies which target these metabolic aberrations in the heart during the early stages of diabetes, in effect, can potentially delay or impede the progression of more permanent sequelae which could ensue from otherwise uncontrolled derangements in cardiac metabolism. There is little dispute that an attempt should be made to lower raised plasma triglyceride and FFA levels. This would decrease the heart's reliance on fatty acids and, hence, overcome the fatty acid inhibition of myocardial glucose utilization. In this regard, the likely application of fatty acid oxidation inhibitors (CPT inhibitors, beta-oxidation inhibitors, sequestration of mitochondrial CoA) is also apparent.
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PMID:Myocardial substrate metabolism: implications for diabetic cardiomyopathy. 776 Mar 40

This cross-sectional investigation sought to determine the relationship between selected metabolic, endocrine, and anthropometric factors and skeletal muscle UCP3 mRNA in healthy adult humans. Twenty-four healthy adults (13 male and 11 female) across a range of aerobic capacity, age, and body composition were studied. Muscle biopsies were obtained from the vastus lateralis, from which UCP3 mRNA was quantified by Northern blot, and fiber type was determined by use of the myosin ATPase staining procedure. In addition, resting energy expenditure and maximum rate of oxygen consumption were determined by indirect calorimetry, body composition was determined by dual-energy X-ray absorptiometry, and fasting plasma leptin and insulin were determined by ELISA. UCP3 mRNA was correlated positively with the percent type I fibers (r = 0.842, P < 0.001), plasma leptin (r = 0.454, P = 0.026), and plasma insulin (r = 0.615, P < 0.001) and inversely to age (r = -0.411, P = 0.046). Stepwise multiple regression analysis determined that percent type I muscle fibers was the best predictor of vastus lateralis UCP3 mRNA, and no other variable entered the equation (model r(2) = 0.66). This study suggests that of the variables measured, UCP3 mRNA is primarily related to skeletal muscle fiber type in healthy adults. The factors that contribute to fiber-specific differences in UCP3 mRNA expression will need to be examined in future studies.
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PMID:Metabolic and anthropometric factors related to skeletal muscle UCP3 gene expression in healthy human adults. 1221 79

The purpose of this study was to evaluate the effects of hyperglycemia on skeletal muscle recovery following disuse-induced muscle atrophy in rats. Wistar rats were grouped as streptozotocin-induced diabetic rats and non-diabetic rats. Both ankle joints of each rat were immobilized to induce atrophy of the gastrocnemius muscles. After two weeks of immobilization and an additional two weeks of recovery, tail blood and gastrocnemius muscles were isolated. Serial cross sections of muscles were stained for myosin ATPase (pH 4.5) and alkaline phosphatase activity. Serum insulin and muscle insulin-like growth factor-1 (IGF-1) levels were also measured. Serum insulin levels were significantly reduced in the diabetic rats compared to the non-diabetic controls. The diameters of type I, IIa, and IIb myofibers and capillary-to-myofiber ratio in the isolated muscle tissue were decreased after immobilization in both treatments. During the recovery period, these parameters were restored in the non-diabetic rats, but not in the diabetic rats. In addition, muscle IGF-1 levels after recovery increased significantly in the non-diabetic rats, but not in the diabetic rats. We conclude that decreased levels of insulin and IGF-1 and impairment of angiogenesis associated with diabetes might be partly responsible for the inhibition of regrowth in diabetic muscle.
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PMID:Hyperglycemia inhibits recovery from disuse-induced skeletal muscle atrophy in rats. 2470 96


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