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)

To investigate the mechanism of impaired myocardial function after long-term pressure overload, we studied cardiac muscle mechanical contraction and intracellular calcium transients using the bioluminescent indicator aequorin. Left ventricular papillary muscle preparations were examined from three groups of rats: 1) aging spontaneously hypertensive rats (SHR) with clinical and pathological evidence suggesting heart failure (SHR-F group), 2) age-matched SHRs with no evidence of heart failure (SHR-NF group), and 3) age-matched normotensive Wistar-Kyoto rats (WKY group). Isometric force development was depressed in both SHR groups relative to the WKY group. Resting [Ca2+]i was lower in the SHR-F group, and the time to peak [Ca2+]i was prolonged in this group. The relative increases in peak [Ca2+]i with the inotropic interventions of increased [Ca2+]o and the addition of isoproterenol were similar among groups. Although inotropy increased in all groups with increased [Ca2+]o, after isoproterenol, inotropy increased only in the WKY group. Thus, in SHR myocardium, [Ca2+]i increased after isoproterenol, but inotropy failed to increase. Myosin isozymes were shifted toward the V3 isoform in both SHR groups; the V3 isoform was virtually 100% in papillary muscles from the SHR-F group. These changes may reflect events directly contributing to the development of heart failure or represent adaptive changes to chronic pressure overload and heart failure.
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PMID:Intracellular calcium transients in myocardium from spontaneously hypertensive rats during the transition to heart failure. 201 97

In the present study, the Ca2(+)-sensitivity and myosin light chain patterns of skinned fibers of right atrium and left papillary muscles of 27 patients suffering from mitral valve disease (MVD, moderate heart failure), ischemic cardiomyopathy (ICM, severe heart failure), dilated cardiomyopathy (DCM, severe heart failure), and coronary heart disease (CHD, no heart failure, no atrial hypertrophy) were investigated. Myosin light chains of both chemically skinned and intact samples were studied by two-dimensional gel electrophoresis (2D-PAGE). Ca2(+)-sensitivity of ventricular fibers was about 0.14 pCa-units higher than that of atrial fibers in all groups except dilated cardiomyopathy where this difference was markedly diminished (only 0.06 pCa-units). Generally, Ca2(+)-sensitivity of skinned ventricular fibers was the same among the different heart diseases. Skinned atrial fibers from patients with dilated cardiomyopathy, however, were significantly (about 0.08 pCa-units) more sensitive for Ca2+ than those of the other groups (coronary heart disease, mitral valve disease or ischemic cardiomyopathy) which showed similar Ca2(+)-tension relationships. Ventricle-specific P-light chain forms could be observed in atrial samples from patients of all groups, whereas no atrium-specific light chain forms were detectable in any ventricular sample. It is concluded that there is no difference in Ca2(+)-sensitivity of the ventricular contractile elements of the human heart in different heart diseases. In atrial myocardium, there is an increased Ca2(+)-sensitivity of skinned fibers from hearts with dilated cardiomyopathy which is probably related to an elevation of right atrial pressure.
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PMID:Calcium sensitivity and myosin light chain pattern of atrial and ventricular skinned cardiac fibers from patients with various kinds of cardiac disease. 208 58

Alterations of cardiac contractility caused by thiamine deficiency were studied on three groups of 2 month old male Wistar rats: B1, fed a thiamine deficient diet, PF pair fed, which received an amount of thiamine free diet determined on the daily consumption of B1 animals, supplemented with appropriate thiamine supply, C ad libitum fed controls. The animals were studied after 35 days of dietary treatment. Force-velocity curves were determined in right ventricle papillary muscles. Shortening velocity was significantly lower in B1 and PF than in C muscles and in B1 than in PF muscles. The ability to develop tension was not altered. Myosin ATPase activity was assayed in preparations of myofibrils and in preparations of purified myosin. Both Ca-Mg activated myofibrillar ATPase activity and Ca-activated myosin ATPase activity were significantly reduced in B1 and PF compared to C myocardium. Furthermore Ca-activated ATPase activity was lower in B1 than in PF myocardium. Myosin isoenzyme distribution was determined by pyrophosphate gel electrophoresis of purified myosin preparations. When compared to C animals both B1 and PF animals showed a myosin electrophoretic pattern shifted towards the slow isoform V3; such a shift was more pronounced in B1 animals. Information concerning excitation-contraction coupling was obtained by determining the steady state and transient force-interval relation and by recording transmembrane action potential. B1 and PF myocardium exhibited, when compared to C, a less sensitivity to a reduction of the interval of stimulation, a faster mechanical restitution, a prolonged action potential duration. Such alterations were generally more pronounced in B1 than in PF myocardium. The results support the view that in the rat cardiac contractility is deeply affected by thiamine deficiency. The alterations of cardiac contractility seem to be caused by adaptive mechanisms rather than by cardiac failure and seem to be attributable for a big part to the reduction of food supply.
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PMID:Altered contractile properties of rat cardiac muscle during experimental thiamine deficiency and food deprivation. 215 36

Myosin form birefringence has been studied in cryostat sections of left ventricular myocardium from the dog and human. The muscle in such sections has been shown to demonstrate the sliding filament phenomenon. The sarcomere length of canine myocardium agreed with that found in comparable electron micrographs. Unexpectedly, it was found that glycerol, normally used as an inert and optically ideal mountant, caused profound change in myosin birefringence. This apparently invalidates results obtained with this mountant. The absolute birefringence found in these sections, whether mounted in glycerol or in an ATP-calcium buffer, corresponded to values found by other workers with skeletal muscle and isolated myosin. However, the birefringent properties (optical path difference: o.p.d.) of well functioning muscle was found to be low, the o.p.d. increasing when exposed to ATP and calcium. Poorly functioning muscle could be distinguished from well functioning muscle on the basis of its higher 'in air' o.p.d. This difference correlated well with physiological assessments of myocardial function or with clinical assessments of cardiac failure. Evidence is presented indicating that changes in apparent birefringence, caused by ATP-calcium or by anoxia, are due to altered orientation of the myosin micelles and can be inhibited by agents that inhibit myosin ATPase activity.
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PMID:Increased myosin orientation during muscle contraction: a measure of cardiac contractility. 383 15

We recently demonstrated dynamic alterations in protein turnover 3 days and 1 month after surgical induction of aortic regurgitation (AR). To characterize protein synthesis and degradation during the long-term plateau phase, we performed [3H]-leucine infusion 2.5 years after induction of AR in 10 New Zealand White rabbits and 12 sham-operated controls. Protein fractional synthesis rates were obtained by analyses of plasma and protein hydrolysates, growth rates from protein concentration and heart weight measurements, and degradation rates by subtraction of growth from synthesis rates. AR (regurgitant fraction 25 +/- 11%) caused a 57% increase in left ventricular (LV) weight in comparison with controls (7.4 +/- 1.7 vs. 4.7 +/- 0.6 g, p < 0.001) and no evidence of heart failure. Although concentrations of total cardiac protein, myosin heavy chain and actin were similar, the enlarged AR hearts had increased amounts of total cardiac protein (1,009 +/- 312 vs. 682 +/- 120 mg/LV, p < 0.05), myosin heavy chain (148 +/- 91 vs. 81 +/- 29 mg/LV, p < 0.05), and actin (73 +/- 42 vs. 44 +/- 16 mg/LV, p < 0.06). Individual protein fractional synthesis and degradation rates were closely balanced. However, myosin fractional synthesis rates were 152% (p < 0.01) greater than those of total cardiac protein in AR animals, while only 52% (p < 0.05) greater in controls (AR vs. controls, p = 0.05). Variations in actin turnover between AR and control animals did not attain statistical significance. Myosin and actin fractional synthesis rates correlated closely in AR rabbits (R = 0.81, p < 0.02), but not among controls (R = 0.41, NS). Thus, selective alterations in myofibrillar protein turnover contribute to the maintenance of increased myofibrillar protein content in the 'compensatory' LV hypertrophy of chronic AR.
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PMID:Protein turnover in compensated chronic aortic regurgitation. 939 5

The myocardium's response to increased stress or load is not stereotyped. Differences have been observed in the heart's molecular composition and performance characteristics when exposed to stress. Myosin isoforms gradually change during development of hypertrophy, whereas collagen levels change only during the chronic phase of hypertrophy. Cardiac hypertrophy can regress if treated with antihypertensive drugs, but the myocardium of the post-hypertrophic heart no longer has the same composition as it did before hypertrophy. In rat studies of the effects of antihypertensive drugs on cardiac functional reserve, captopril showed a regression of hypertrophy associated with a lower baseline stroke volume and, after dobutamine stress, a dose-dependent rise in stroke volume. In untreated rates captopril showed no change in stroke volume. In hydralazine-treated rats, there was no change in reserve after dobutamine stress, whereas propranolol treatment resulted in partial regression and a slight change in stroke volume. Overall, our data suggests that development of hypertension and hypertrophy plays a role in changes in the molecular structure of the myocardium, especially during the chronic phase of hypertrophy and heart failure. This complex process cannot be explained by one factor but involves a combination of factors. Identification of each factor would be of importance for the development of appropriate therapeutic agents.
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PMID:Myocardial response to stress in cardiac hypertrophy and heart failure: effect of antihypertensive drugs. 1041 26

Dilated cardiomyopathy (DCM) is characterized by dilation and impaired contraction of the left ventricle or both; it is a relevant cause of heart failure and a common indication for heart transplantation. It may be idiopathic, familial/genetic, viral, autoimmune or immune-mediated, associated with a viral infection. Myocarditis is an inflammatory disease of the myocardium; it may be idiopathic, infectious or autoimmune and may heal or lead to DCM. Thus, in a patient subset, myocarditis and DCM are thought to represent the acute and chronic stages of an organ-specific autoimmune disease of the myocardium. In keeping with this hypothesis, autoimmune features in patients with myocarditis/DCM include: familial aggregation, a weak association with HLA-DR4, abnormal expression of HLA class II on cardiac endothelium on endomyocardial biopsy, detection of organ- and disease-specific cardiac autoantibodies in the sera of affected patients and of symptom-free relatives. The organ-specific cardiac autoantibodies detected by immunofluorescence are directed against multiple antigens. One of these, first identified using immunoblotting and confirmed by ELISA, is the cardiac-specific alpha-myosin isoform. Myosin fulfils the expected criteria for organ-specific autoimmunity, in that immunization with cardiac but not skeletal myosin reproduces, in susceptible mouse strains, the human disease phenotype of myocarditis/DCM; in addition, alpha-myosin is entirely cardiac-specific. The organ-specific cardiac autoantibodies detected by immunofluorescence in symptom-free relatives were associated with echocardiographic features suggestive of early disease. Short-term follow-up is in keeping with this interpretation, although extended follow-up is necessary to define better the role of the antibody as predictor of disease susceptibility in healthy subjects at risk of myocarditis/DCM, such as first-degree relatives.
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PMID:Cardiac autoantibodies to myosin and other heart-specific autoantigens in myocarditis and dilated cardiomyopathy. 1190 78

Intrinsic muscle abnormalities affecting skeletal muscle are often reported during chronic heart failure (CHF). Because myosin is the molecular motor of force generation, we sought to determine whether its dysfunction contributes to skeletal muscle weakness in CHF and, if so, to identify the underlying causative factors. Severe CHF was induced in rats by aortic stenosis. In diaphragm and soleus muscles, we investigated in vitro mechanical performance, myosin-based actin filament motility, myosin heavy (MHC) and light (MLC) chain isoform compositions, MLC integrity, caspase-3 activation, and oxidative damage. Diaphragm and soleus muscles from CHF exhibited depressed mechanical performance. Myosin sliding velocities were 16 and 20% slower in CHF than in sham in diaphragm (1.9 +/- 0.1 vs. 1.6 +/- 0.1 microm/s) and soleus (0.6 +/- 0.1 vs. 0.5 +/- 0.1 microm/s), respectively (each P < 0.05). The ratio of slow-to-fast myosin isoform did not differ between sham and CHF. Immunoblots with anti-MLC antibodies did not detect the presence of protein fragments, and no activation of caspase-3 was evidenced. Immunolabeling revealed oxidative damage in CHF muscles, and MHC was the main oxidized protein. Lipid peroxidation and expression of oxidized MHC were significantly higher in CHF than in shams. In vitro myosin exposure to increasing ONOO(-) concentrations was associated with an increasing amount of oxidized MHC and a reduced myosin velocity. These data provide experimental evidence that intrinsic myosin dysfunction occurs in CHF and may be related to oxidative damage to myosin.
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PMID:Oxidative stress of myosin contributes to skeletal muscle dysfunction in rats with chronic heart failure. 1704 Sep 75

Myosin motors are central to diverse cellular processes in eukaryotes. Homologues of the myosin chaperone UNC-45 have been implicated in the assembly and function of myosin-containing structures in organisms from fungi to humans. In muscle, the assembly of sarcomeric myosin is regulated to produce stable, uniform thick filaments. Loss-of-function mutations in Caenorhabditis elegans UNC-45 lead to decreased muscle myosin accumulation and defective thick filament assembly, resulting in paralyzed animals. We report that transgenic worms overexpressing UNC-45 also display defects in myosin assembly, with decreased myosin content and a mild paralysis phenotype. We find that the reduced myosin accumulation is the result of degradation through the ubiquitin/proteasome system. Partial proteasome inhibition is able to restore myosin protein and worm motility to nearly wild-type levels. These findings suggest a mechanism in which UNC-45-related proteins may contribute to the degradation of myosin in conditions such as heart failure and muscle wasting.
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PMID:The UNC-45 chaperone mediates sarcomere assembly through myosin degradation in Caenorhabditis elegans. 1743 72

Cardiac muscle performance can be determined by factors intrinsic to each cardiac muscle cell, such as protein isoform expression. One protein whose expression plays a major role in determining cardiac performance is myosin. Myosin is the heart's molecular motor which transduces the chemical energy from ATP hydrolysis into the mechanical energy of each heartbeat. Alterations of myosin isoform expression are routinely associated with acquired and inherited cases of cardiomyopathy. For example, human heart failure is consistently associated with increased expression of a slow myosin motor isoform and a concomitant decreased expression of the heart's fast myosin motor isoform. Further, mutations of the cardiac myosin gene are the most common cause of inherited hypertrophic cardiomyopathy. Transgenic animal studies have provided insight into cardiac functional effects caused by myosin isoform gene switching (fast-to-slow myosin or slow-to-fast myosin) or by expression of a disease-related mutant motor. More direct structure-function analysis using acute gene transfer of myosin motors provides evidence that the inotropic state of cardiac muscle can be affected by motor protein isoform shifting independent of intracellular calcium handling. Because most therapies for the diseased heart target intracellular calcium handling, acute gene transfer of cardiac molecular motors to modulate heart performance offers a novel therapeutic strategy for the compromised heart. Although the development of safe vectors for therapeutic myosin gene delivery are in their infancy, studies focused on acute genetic engineering of the heart's molecular motor will provide a foundation for therapeutic vector development and insight into mechanisms that contribute to cardiomyopathy.
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PMID:Modulation of cardiac performance by motor protein gene transfer. 1837 81


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