UMLS:C0011570 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011570 (depression)
172,036 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Like all inhalation anesthetics, halothane (CF3CHBrCl) has a dose-dependent negative inotropic effect on cardiac muscle. The mechanism of the action has not been determined, although effects on glycolysis, mitochondrial respiration and calcium kinetics, and sarcoplasmic reticulum ATPase activity have been suggested. Previous studies of the effect of halothane on the ATPase of contractile protein suffered from design and dosing defects. We have measured ATP splitting by canine cardiac natural actomyosin using extraction and equilibration procedures described previously (Honig, C. R. and Reddy, Y. C. 1973, J. Pharmacol. 184: 330-338). Drug dosing calculations were facilitated by measurement of the partition coefficient of halothane in protein. Halothane shifted the Ca++ concentration effect curve for actomyosin ATPase activity to the right. The maximum depression occurred at pCa 7.0 or 6.5. The effect was dose dependent with less than 10 percent depression at threshold and 50-60 percent depression at peak. Enzyme inhibition was antagonized by high Ca++ concentration, and was reversed by removing halothane from the reaction mixture. We suggest that inhibition of ATP utilization by the contractile system may be a mechanism of the in vivo myocardial depression produced by halothane.
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PMID:Halothane decreases actomyosin ATPase activity: a possible mechanism of the negative inotropic effect. 12 60

We studied hearts from sham-operated and uninfected catheterized rabbits as well as from rabbits at early and late stages of cardiomyopathy and failure after 3 and 6 days of infection with Streptococcus viridans. No ultrastructural abnormalities or biochemical changes in membrane and myofibrillar activities were seen in 3-day uninfected hearts. In 6-day uninfected hearts there were decreased sarcolemmal M2+ ATPase, Na+-K+ ATPase, adenylate cyclase and calcium binding, microsomal calcium binding and uptake, and myofibrillar Ca2+-stimulated ATPase as well as increased mitochondrial calcium uptake. Slight ultrastructural changes also were apparent in 6-day uninfected hearts. At both early and late stages of infective cardiomyopathy and failure there were varying degrees of depression in sarcolemmal Mg2+ ATPase, Na+-K+ ATPase, adenylate cyclase and calcium binding, microsomal calcium binding, calcium uptake and basal ATPase, and myofibrillar Ca2+-stimulated ATPase activities. However, sarcolemmal Ca2+ ATPase and myofibrillar Mg2+ ATPase activities were decreased only after 6 days of infection. Mitochondrial calcium binding and uptake were increased in early stages but decreased in late stages of disease. Furthermore in infected hearts there were defects in mitrochondrial respiration and phosphorylation. Generalized severe myocardial cell damage involving myofibrils, mitochondria, and the sarcotubular system was seen only in late stages of infection. The results demonstrate impairment of different membrane and contractile protein functions as well as ultrastructural abnormalities in bacterial cardiomyopathic hearts which were absent or of lesser magnitude in hearts with only hypertrophy. The findings reported here suggest to use that there is an association between heart failure and changes in function of cellular components during bacterial infective cardiomyopathy.
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PMID:Abnormalities in heart membranes and myofibrils during bacterial infective cardiomyopathy in the rabbit. 13 11

The contractile properties and contractile protein enzymatic activity of skeletal muscle can be altered by neural influences. To determine whether similar influences apply to cardiac muscle, adult rats were chemically sympathectomized by intravenous injection of 6-hydroxydopamine (6-OHDA). After 2 weeks of treatment, rats were anesthetized and an index of myocardial contractility (max dP/dt) was measured in situ. Max dP/dt was depressed in 6-OHDA-treated rats [4560 +/- 420 (mean +/- SE) mm Hg/sec] when compared to controls (6710 +/- 580 mm Hg/sec). Sympathectomy was verified by reduced hemodynamic responsiveness to tyramine injections. After functional measurements had been completed, the heart was excised. Myofibrils were prepared from left ventricular tissue and analyzed for ATPase activity. Myofibrillar protein yield averaged 38 +/- 2 mg/g in controls and was not significantly different in 6-OHDA rats. Myofibrillar ATPase activity was 0.314 +/- 0.014 mumol P1/mg per min in controls. Enzyme activity was significantly reduced to 0.230 +/- 0.020 mumol P1/mg per min in 6-OHDA rats. The results demonstrate that a chronic reduction in sympathetic stimulation to the heart results in a depression of an index of myocardial contractile function which is accompanied by reduced myofibrillar ATPase activity. Acute (16-18 hours) chemical sympathectomy depressed the contractile function index without altering ATPase activity. Bilateral adrenalectomy produced no further decrement in myofibrillar ATPase activity in chronically (2 weeks) sympathectomized rats. Therefore, it appears that the changes in contractile protein enzymatic properties are mediated by sympathetic neural influences and may involve the synthesis of new contractile protein(s) with altered enzymatic properties.
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PMID:Myocardial contractile function and myofibrillar adenosine triphosphatase activity in chemically sympathectomized rats. 13 56

Gram-negative endotoxin (Escherichia coli, 4 mg/kg) was found to produce a sustained fall in systemic arterial pressure, left ventricular pressure, and cardiac output that could be blocked by the histamine antagonist diphenhydramine. Histamine infusion was found to produce a parallel depression of systemic arterial pressure. Further, endotoxemia was found to produce a significant depression of myocardial contractility (dP/dt max) that could also be blocked by diphenhydramine. Cardiac myofibrillar adenosine triphosphatase (ATPase) activity from endotoxin-shocked hearts was found to be depressed, ATPase activity from subendocardial myofibrils being more depressed than that from subepicardial myofibrils. Myofibrillar ATPase activity was significantly protected by pretreating the animals with diphenhydramine. It is concluded that the initial hemodynamic phase of endotoxin shock is histamine-mediated and that this hemodynamic depression can be blocked with diphenhydramine. Further, it appears that endotoxin is capable of depressing myocardial contractility by depressing contractile protein function (myofibrillar ATPase activity)--the subendocardial surface more so than the subepicardial surface--and this depression of myocardial contractility can be blocked with diphenhydramine.
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PMID:Diphenhydramine protection of the failing myocardium during gram-negative endotoxemia. 15 4

Methionine incorporation into proteins of the fibrillating dog heart perfused by donor circulation was investigated. In the heart in which fibrillation was induced by electric current under conditions of adequate oxygen supply a 50-55% increase of methionine S35 incorporation into the contractile protein fraction of both ventricles was observed. In the heart in which fibrillation appeared after anoxia, methionine S35 incorporation into the sum total proteins of the atria showed 40-60% depression, into the sarcoplasmic - 36 -53%, and into the contractile proteins of both ventricles - 18 -30% decrease.
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PMID:[Protein biosynthesis in the fibrillating perfused heart during normal oxygenation and following anoxia]. 127 12

To determine the effects of moderate ethanol consumption on the mechanical, biochemical, and structural characteristics of the heart, myocardial mechanical performance, contractile protein enzyme activity, and the number and size of myocytes were measured in male Fischer 344 rats after the ingestion of 30% oral ethanol. Papillary muscles removed from the left ventricle were greater in length, weight, and cross-sectional area than the corresponding muscles from the right side. However, no differences were found between control and ethanol-treated myocardium when either the left or right side was compared separately. Chronic ethanol ingestion resulted in an increase in resting tension in left ventricular muscles, with no alteration in peak developed tension. Moreover, time to peak tension was significantly prolonged, whereas a depression was observed in the peak rate of isometric tension development. Isotonically, left muscles from ethanol-treated rats revealed a prolongation of time to peak shortening and a marked depression in the velocity of shortening at physiological loads. No changes were noted in muscles from the right ventricle. Contractile protein enzyme activity revealed no differences in myofibrillar Mg(2+)-ATPase activity in right and left ventricular myocardium between control and ethanol-treated rats in the presence of EGTA. However, at physiological activating levels of calcium, an upward shift of the myofibrillar Mg(2+)-ATPase activity-calcium curve occurred in left myocardium, whereas a depression in this relation was seen in the right ventricle. As a result of chronic ethanol intake, a decrease was noted in the volume percent of myocardium occupied by myocytes, and that myocyte cell volume per nucleus was found to remain essentially constant throughout the various layers of the ventricular wall. Importantly, a 14% significant decrease in the total number of myocyte nuclei was demonstrated in the left ventricular myocardium of rats on chronic ethanol consumption. Thus, chronic but moderate alcohol ingestion resulted in depressed contractile performance, alterations in myofibrillar Mg(2+)-ATPase activity, and myocyte loss. These events may serve to function as preliminary indicators of the onset of heart failure of alcoholic origin in this animal model.
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PMID:Myocardial mechanical, biochemical, and structural alterations induced by chronic ethanol ingestion in rats. 138 62

Inhalational anesthetics and ventricular hypertrophy have adverse effects on cardiac muscle contraction. The effects of 1, 2, and 3% halothane on the contractile protein and sarcoplasmic reticulum, but not the sarcolemma, were examined in normal left ventricular tissue from rabbits that underwent a sham surgical procedure (n = 5) and in left ventricular hypertrophied tissue from surgically induced aortic coarctation (n = 7). Muscle samples were mechanically "skinned" to disrupt the sarcolemma. Fiber bundles were mounted in photodiode transducers and bathed in a series of solutions designed to examine the contractile protein [Ca2+]-tension responses or to examine Ca2+ storage by and release from the sarcoplasmic reticulum. Hill equation analysis of the [Ca2+]-tension relationship of the contractile protein was performed. Compared to normal muscle, hypertrophied muscle was associated with an 8.2% decrease in the [Ca2+] necessary for 50% maximum tension (more sensitive to Ca2+) (P less than 0.001) and an increase in the slope constant of 23% (P less than 0.001). In normal and hypertrophied tissue, each 1% of halothane incrementally decreased the contractile protein response to maximal [Ca2+] by 5% (P less than 0.01), increased the [Ca2+] at 50% maximum tension by 5% (P less than 0.01), and had no effect on the slope of the Hill equation. Halothane also inhibited Ca2+ storage by the sarcoplasmic reticulum. In normal muscle, 1, 2, and 3% halothane decreased the stored Ca2+ to 42, 22, and 9%, respectively, of Ca2+ storage without halothane (P less than 0.001). However, hypertrophied muscle demonstrated slightly less depression (P less than 0.05 by analysis of variance).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Left ventricular hypertrophy in rabbits does not exaggerate the effects of halothane on the intracellular components of cardiac contraction. 138 68

To determine the effects of chronic nonocclusive coronary constriction on cardiac hemodynamics, myocardial structure, and contractile protein enzyme activity, the left coronary artery was narrowed in rats, and measurements of ventricular pump function, extent and localization of tissue damage, and myofibrillar Mg2+ and Ca2+ myosin adenosinetriphosphatase (ATPase) activities were measured 3 mo later. In the presence of coronary artery stenosis averaging 56%, two different degrees of depression in global cardiac performance were identified, and the animals were divided in two groups. In the first group, left ventricular end-diastolic pressure (LVEDP) was increased and LV+ and/or--the first derivative of LV pressure (dP/dt) were decreased, whereas in the second group end-diastolic and peak systolic LV pressures, LV+ and -dP/dt and right ventricular dynamics were all impaired. Thus left ventricular dysfunction and failure occurred with coronary narrowing. Structurally, multiple foci of replacement fibrosis were found across the left ventricular wall, but the number of these lesion profiles was 2.6-fold larger in failing animals than in rats with cardiac dysfunction. Biochemically, Mg(2+)-ATPase activity in myofibrils and Ca2+ myosin ATPase were not altered biventricularly. On the other hand, a shift from V1 to V3 myosin isoenzymic content occurred in the failing left ventricle. In conclusion, the late impairment in ventricular pump function associated with prolonged coronary artery stenosis appears to be sustained more by the magnitude of myocardial damage than by defects in contractile protein enzyme activity.
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PMID:Long-term coronary stenosis in rats: cardiac performance, myocardial morphology, and contractile protein enzyme activity. 163 51

The effects of renovascular hypertension on the biochemical, contractile, and electrical performance of myocardial tissue from rats of various ages has been examined. Male Fischer rats, 2, 7, 12, and 17 months old, were made hypertensive by constriction of the left renal artery. Ten weeks after the onset of hypertension, left ventricular papillary muscles were isolated from those four groups when 5, 10, 15, and 20 months old, respectively. Mechanical performance and transmembrane electrical events were recorded simultaneously. Contractile protein enzyme activity was determined in the same hearts from which papillary muscles were used for acquisition of mechanical and electrical information. There was a slight increase in blood pressure in control groups as a function of age while blood pressure maintained a range of approximately 179-188 mm Hg for all hypertensive groups. Heart weight of control animals increased significantly from 5 months to 20 months of age from 539 +/- 26 to 1088 +/- 56 mg, representing an increase of 101%. In hypertensive animals, heart weight increased 50% in 5-month-, 15% in 10-month-, 50% in 15-month-, and 11.7% in 20-month-old animals. Although control groups revealed alterations in mechanical, electrical, and biochemical parameters that increased as a function of age, the magnitude of the biochemical, contractile, and electrical response to hypertension varied monotonically with the extent of myocardial hypertrophy, rather than age per se. Adaptation to the stress of hypertension was observed in each age group, and was revealed as prolongation of mechanical and electrical timing parameters, depression of the load-velocity relation, and contractile protein enzyme activity. Thus, the stress of hypertension, which was tolerated by the 10- and 20-month-old animals with lesser relative hypertrophy and lesser changes in measured parameters, may represent a differential adaptation to the stress of hypertension.
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PMID:Myocardial biochemical, contractile, and electrical performance after imposition of hypertension in young and old rats. 293 44

Previous studies in hearts of female rats have demonstrated that ventricular hypertrophy due to systolic overload, when combined with hypertrophy induced by a chronic swimming program, results in increased cardiac performance and enhanced contractile protein activity compared with the effects of hypertension alone. To explore how a chronic running program affects the function of hypertensive hearts, renal hypertension was created in female rats, and the animals were subjected to a program of chronic treadmill running. Running alone caused enhanced cardiac function, an increase in myosin adenosinetriphosphatase (ATPase) activity, and an increase in the percent of the V1 myosin isoenzyme. Hypertension alone caused cardiac hypertrophy with a depression in myosin ATPase activity and a decrease in the percent of the V1 isoenzyme. Running improved cardiac function in hearts of normotensive rats but had no effect in hearts of hypertensive rats. Despite the diminished myosin ATPase activity in hearts of hypertensive runners and the decrease in percent of the V1 isoenzyme, cardiac function was well maintained. The results demonstrate that a chronic running program in hypertensive rats, in contrast to a chronic swimming program, had virtually no effect on cardiac performance or contractile proteins. The dissociation between myocardial performance and the contractile proteins implicates other biochemical mechanisms in the adaptations observed.
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PMID:Combined effects of hypertension and chronic running program on rat heart. 295 51

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