Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0018801 (heart failure)
 72,216 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. The signal transduction process mediated by cyclic AMP that leads to the characteristic positive inotropic effect (PIE) in association with a positive lusitropic effect (acceleration of rate of twitch relaxation) has been well established. Relationships between accumulation of cyclic AMP, changes in intracellular Ca2+ transients and the PIE differ, however, depending on the mechanism of particular drugs that affect different steps in the metabolism of cyclic AMP. Selective partial agonists of beta 1-adrenoceptors and inhibitors of phosphodiesterase (PDE) III cause the accumulation of less cyclic AMP for a given PIE than does isoproterenol. In addition, in aequorin-microinjected canine ventricular muscle, selective inhibitors of PDE III, OPC 18790 and Org 9731, produced smaller decreases in the responsiveness of myofilaments to Ca2+ ions than isoproterenol, while a partial agonist of beta 1-adrenoceptors, denopamine, elicits a decrease in Ca2+ responsiveness of the same extent as does isoproterenol. 2. Activation of myocardial alpha 1-adrenoceptors, as well as stimulation of receptors for endothelin and angiotensin II, which accelerates hydrolysis of phosphoinositide (PI) to result in production of inositol 1,4,5-trisphosphate (IP3) and diacylglycerol (DAG) are associated with very similar inotropic regulation: (1) the dependence on the species of animals of induction of the PIE; (2) an excellent correlation between the extent of acceleration of hydrolysis of PI and the PIE; (3) isometric contraction curves associated with a negative lusitropic effect; (4) the PIE associated with increases in myofibrillar responsiveness to Ca2+ ions; and (5) the selective inhibition of the PIE by an activator of protein kinase C (PKC), phorbol 12,13-dibutyrate (PDBu), with little effect on the PIE of isoproterenol and Bay k 8644. 3. A novel class of cardiotonic agents, namely, Ca2+ sensitizers such as EMD 53998 and Org 30029, act on the Ca(2+)-binding site of troponin C, increasing the affinity of these sites for Ca2+ ions, or at the actin-myosin interface to facilitate the cycling of cross-bridges. These agents produce a PIE with little change or decrease in Ca2+ transients and may bring about a significant breakthrough in the development of drugs for reversal of myocardial failure in the treatment of congestive heart failure.
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PMID:The effects of various drugs on the myocardial inotropic response. 771 48

The intracellular Ca(2+)-homeostasis may be affected by changes of the extracellular K(+)- and/or Mg(2+)-concentrations. Mg2+ reduces the Ca(2+)-influx via L-type Ca(2+)-channels, facilitates Ca(2+)-uptake into the sarcoplasmic reticulum, modulates the Ca(2+)-induced Ca(2+)-release and the Ca(2+)-binding to troponin C. The extracellular K+ activates the Na+/K(+)-ATPase and changes the membrane potential thereby affecting the mode of action of the Na+/Ca(2+)-exchanger. Especially when intracellular Ca2+ regulation is altered, for example in heart failure, Mg2+ and K+ exert beneficial effects on the frequency-dependent force-generation in human myocardium. Thus, extracellular Mg2+ and K+ influence contraction coupling in the human myocardium.
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PMID:[Effect of changed extracellular K(+) and Mg(2+)-concentration on intracellular Ca(2+) homeostasis, contraction coupling and force-frequency relations in the human myocardium]. 933 87

One of the most salient physiological characteristics of cardiac muscle is that a dilated heart pumps more vigorously, a phenomenon known as the Frank-Starling relationship (see Allen and Kentish, 1985). At least two cellular mechanisms participate in this phenomenon: the reduction of the interfilament lattice spacing which favors the formation of cross-bridges (Wang and Fuchs, 1995) and the increased affinity of troponin C (TnC) for calcium (Ca2+) (Babu et al., 1988). In the latter case, it has been established that TnC itself is not the length sensor (Moss et al., 1991). The intracellular structure(s) able to sense changes in cell length has always been challenged and is still not known. We previously observed on intact isolated cardiac cells that active tension is more closely related to passive tension than to sarcomere length per se (Cazorla et al., 1997). This might have some physiological implications in the working heart since we found that sub-epicardial cells are more supple than sub-endocardial cells. In the present work on skinned cells, we studied the relationship between different levels of passive tension (modulated by a mild trypsin digestion) and the shift in pCa50 of tension-pCa relations induced by a stretch of cells from 1.9 to 2.3 microns sarcomere length. A significant correlation was obtained between passive tension and the stretch-induced shift in pCa50, or stretch-sensitivity of the active force. These observations led us to assume that titin might play a role in sensing cell length to modulate the contractile activity. Besides, it is known that myocardial infarcted cells are less sensitive to stretch. We propose that, in such a rat model, alterations of titin might participate in heart failure.
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PMID:Is titin the length sensor in cardiac muscle? Physiological and physiopathological perspectives. 1098 82

Levosimendan (Simdax) is a new inodilator developed specifically for the treatment of decompensated heart failure. Its inotropic mechanism is based on calcium sensitisation of myofilaments and its vasodilator actions are related to the opening of ATP-dependent K-channels in the vasculature. Since the inotropic action of levosimendan does not require an increase in cytosolic free calcium, it is less arrhythmogenic than the conventional parenteral beta-agonist inotropes or PDE III inhibiting drugs. Due to the calcium-dependent binding of the drug to troponin C, levosimendan, unlike some other calcium-sensitising drugs, does not prolong diastolic relaxation of the myocytes but acts in synergy with the intramyocellular calcium levels. Furthermore, due to the anti-ischaemic effects of the K-channel opening in myocytes, levosimendan can be used during myocardial ischaemia. In clinical trials, levosimendan has dose-dependently increased cardiac output and decreased pulmonary capillary wedge pressure in patients with heart failure. On the other hand, it also increases heart rate and decreases blood pressure in these patients. In major clinical trials, where patients with decompensated heart failure have been treated with levosimendan, a reduction of overall mortality in comparison to placebo or dobutamine has been seen. This interesting finding should be verified in prospective outcome trials. In any case, the safety of levosimendan during myocardial ischaemia makes this drug valuable in the short-term treatment of decompensated heart failure.
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PMID:Levosimendan: a parenteral calcium-sensitising drug with additional vasodilatory properties. 1132 69

Ca2+ sensitizers act on the central mechanism (Ca2+ binding affinity of troponin C) and/or downstream mechanisms (thin filament regulation of actin and direct action on crossbridge cycling) of cardiac E-C coupling. Ca2+ sensitizers have mechanistic and energetic advantages over the agents that act through the upstream mechanism (intracellular Ca2+ mobilization). Ca2+ sensitizers and the agents that act through cyclic AMP-mediated signaling process have been postulated to belong to different classes, however, recent experimental findings revealed that certain Ca2+ sensitizers, such as levosimendan, OR 1896 and UD-CG 212 Cl, require cyclic AMP-mediated signaling for induction of the Ca2+ sensitizing effect. No clinically available agents act primarily via Ca2+ sensitization, but the positive inotropic effect of pimobendan and levosimendan is partly due to an increase in myofilament Ca2+ sensitivity. These agents are the hybrid of Ca2+ sensitizer and PDE III inhibitor. The extent of contribution of Ca2+ sensitizing effect of these agents to the clinical effectiveness to improve the hemodynamics in patients with heart failure is uncertain. Nevertheless pieces of evidence have been accumulating that these agents with Ca2+ sensitizing effect are clinically more effective than the agents that act purely via the upstream mechanism.
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PMID:Mechanism of action of Ca2+ sensitizers--update 2001. 1185 58

Levosimendan is a new inotropic and vasodilator agent. The inotropic effect is mediated by calcium concentration-dependent conformational changes in troponin C during systole leading to sensitization of the contractile apparatus to calcium ions. The vasodilator effect is mediated by opening potassium channels on vascular smooth muscle. It has a complex pharmacokinetic profile, with a long-acting metabolite that has hemodynamic effects persisting for approximately 1 week. Although it is absorbed orally, it has been developed only for intravenous use thus far. The hemodynamic effects are not reduced and may be enhanced in the presence of beta-blockers, possibly an important attribute when dealing with exacerbation of heart failure caused by or in the presence of beta-blockers. More patients with heart failure have participated in randomized controlled trials of levosimendan than of any other intravenous inotropic agent. Experience with its use after cardiac surgery is limited. Preliminary observations suggest that hemodynamic changes are associated with symptomatic benefit and a reduction in morbidity and mortality in patients with severe heart failure caused by left ventricular systolic dysfunction, compared with placebo in one study and dobutamine in another. Levosimendan may be the first inotropic agent that it is both safe and effective in altering clinical outcomes relevant for patients. Part of this benefit may be achieved because levosimendan allows other inotropic agents that may have adverse effects on patient outcome to be avoided. Further research is required to confirm whether levosimendan reduces mortality and morbidity compared with a placebo and when administered repetitively. If it does, it may become routine therapy for the treatment of severe heart failure.
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PMID:Levosimendan: a new era for inodilator therapy for heart failure? 1201 75

Cardiac troponin C (cTnC) is the Ca(2+)-dependent switch for contraction in heart muscle and a potential target for drugs in the therapy of heart failure. Ca(2+) binding to the regulatory domain of cTnC (cNTnC) induces little structural change but sets the stage for cTnI binding. A large "closed" to "open" conformational transition occurs in the regulatory domain upon binding cTnI(147-163) or bepridil. This raises the question of whether cTnI(147-163) and bepridil compete for cNTnC.Ca(2+). In this work, we used two-dimensional (1)H,(15)N-heteronuclear single quantum coherence (HSQC) NMR spectroscopy to examine the binding of bepridil to cNTnC.Ca(2+) in the absence and presence of cTnI(147-163) and of cTnI(147-163) to cNTnC.Ca(2+) in the absence and presence of bepridil. The results show that bepridil and cTnI(147-163) bind cNTnC.Ca(2+) simultaneously but with negative cooperativity. The affinity of cTnI(147-163) for cNTnC.Ca(2+) is reduced approximately 3.5-fold by bepridil and vice versa. Using multinuclear and multidimensional NMR spectroscopy, we have determined the structure of the cNTnC.Ca(2+).cTnI(147-163).bepridil ternary complex. The structure reveals a binding site for cTnI(147-163) primarily located on the A/B interhelical interface and a binding site for bepridil in the hydrophobic pocket of cNTnC.Ca(2+). In the structure, the N terminus of the peptide clashes with part of the bepridil molecule, which explains the negative cooperativity between cTnI(147-163) and bepridil for cNTnC.Ca(2+). This structure provides insights into the features that are important for the design of cTnC-specific cardiotonic drugs, which may be used to modulate the Ca(2+) sensitivity of the myofilaments in heart muscle contraction.
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PMID:Structure of the regulatory N-domain of human cardiac troponin C in complex with human cardiac troponin I147-163 and bepridil. 1206 Jun 57

A considerable number of experimental, epidemiological and clinical studies are now available which point to an important role of Mg2+ in the etiology of cardiovascular pathology. In human subjects, hypomagnesemia is often associated with an imbalance of electrolytes such as Na+, K+ and Ca2+. Abnormal dietary deficiency of Mg2+ as well as abnormalities in Mg2+ metabolism play important roles in different types of heart diseases such as ischemic heart disease, congestive heart failure, sudden cardiac death, atheroscelerosis, a number of cardiac arrhythmias and ventricular complications in diabetes mellitus. Mg2+ deficiency results in progressive vasoconstriction of the coronary vessels leading to a marked reduction in oxygen and nutrient delivery to the cardiac myocytes. Numerous experimental and clinical data have suggested that Mg2+ deficiency can induce elevation of intracellular Ca2+ concentrations, formation of oxygen radicals, proinflammatory agents and growth factors and changes in membrane perrmeability and transport processes in cardiac cells. The opposing effects of Mg2+ and Ca2+ on myocardial contractility may be due to the competition between Mg2+ and Ca2+ for the same binding sites on key myocardial contractile proteins such as troponin C, myosin and actin. Stimulants, for example, catecholamines can evoke marked Mg2+ efflux which appears to be associated with a concomitant increase in the force of contraction of the heart. It has been suggested that Mg2+ efflux may be linked to the Ca2+ signalling pathway. Depletion of Mg2+ by alcohol in cardiac cells causes an increase in intracellular Ca2+, leading to coronary artery vasospasm, arrhythmias, ischemic damage and cardiac failure. Hypomagnesemia is commonly associated with hypokalemia and occurs in patients with hypertension or myocardial infarction as well as in chronic alcoholism. The inability of the senescent myocardium to respond to ischemic stress could be due to several reasons. Mg2+ supplemented K+ cardioplegia modulates Ca2+ accumulation and is directly involved in the mechanisms leading to enhanced post ischemic functional recovery in the aged myocardium following ischemia. While many of these mechanisms remain controversial and in some cases speculative, the beneficial effects related to consequences of Mg2+ supplementation are apparent. Further research are needed for the incorporation of these findings toward the development of novel myocardial protective role of Mg2+ to reduce morbidity and mortality of patients suffering from a variety of cardiac diseases.
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PMID:Protective role of magnesium in cardiovascular diseases: a review. 1234 4

Ca(2+)-sensitizers are inotropic agents that modify the response of myofilaments to Ca2+, and are potentially valuable drugs in the treatment of heart failure. These agents have diverse chemical structures, and in some cases also have effects as inhibitors of phosphodiesterase activity. Advantages of their actions include vasodilation combined with inotropic effects. Reduction in the amounts of Ca2+ required to activate the myofilaments also lowers the oxygen consumption required for Ca2+ transport, lowers the threat of arrhythmias, and may blunt Ca(2+)-dependent transcriptional and translational mechanisms leading to hypertrophy and failure. Although diastolic abnormalities and impaired relaxation were thought to be potential undesirable effects of Ca(2+)-sensitizers, studies of hearts beating in situ indicate that this may not be a major problem. We focus here on Ca(2+)-sensitizers that act on cardiac troponin C, the Ca2+ receptor that triggers activation of the actin-myosin interaction. Structural studies have identified a unique mode of Ca2+ signaling in cardiac troponin C that should aid in targeting drugs to the heart. Moreover, identification of docking sites of Ca(2+)-sensitizers on troponin C suggest new directions for rational drug design.
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PMID:Molecular actions of drugs that sensitize cardiac myofilaments to Ca2+. 1237 9

Proper contractile function of the heart depends on intact excitation-contraction processes and ion homeostasis of the myocytes. The Ca2+ ion activates contraction through its binding to troponin C. However, Ca2+ homeostasis is tightly linked to Na+ regulation because the primary mechanism for Ca2+ efflux in cardiac myocytes is via electrogenic Na+/Ca2+-exchange. While altered Ca2+-homeostasis has been demonstrated in animal models of heart failure and failing human cardiac tissue, the role of dysfunctional Na+ handling processes in altered excitation-contraction coupling remains obscure. Furthermore, altered Na+ handling has been implicated in a wide range of cellular processes, such as regulation of membrane potential, pH, and growth. This review will discuss (1) the evidence for altered [Na+]i homeostasis in the failing human heart, (2) how alterations in the Na+ electrochemical gradient can influence Ca2+ handling, contractile function, and a number of other cellular processes, and (3) the potential defects in Na+ channels and transporters that may underlie altered [Na+]i in the failing human heart.
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PMID:[Na+]i handling in the failing human heart. 1265 Aug 66


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