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Query: UMLS:C0020538 (hypertension)
 170,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Evidence has been presented regarding alterations of contractile behavior muscle biochemistry, and ulstrastructure during the course of the hereditary hamster cardiomyopathy. Also, preliminary structural and mechanical data were presented on the acquired cardiomyopathy of diabetes mellitus in experimental animals. In the hamster model, contractile performance, measured as isometric tension and rate of tension development, was shown to be depressed throughout the course of the disease, whereas normalized force-velocity relationships returned to normal only during the compensated stages of hypertrophy. Force-frequency relationships were depressed in myopathic muscles, indicating the presence of alterations in the muscle activation system, namely, the biochemical and functional integrity of the sarcoplasmic reticulum. Analysis of the contractile proteins in myopathic muscle has revealed depressions of Ca2+ activity in purified myosin in addition to an independently increased neutral protease activity that results in the specific degradation of LC2 of myosin. Sympathetic time and norepinephrine turnover increase progressively during the course of the disease. These changes are accompanied by decreasing tissue levels of neorepinephrine and increasing levels of dopamine, indicating a shift in the rate-limiting step for norepinephrine synthesis. Alterations were also noted in nuclear protein composition and serotonin levels. Microscopically, the myolytic and calcification changes that characterize the hamster cardiomyopathy have been confirmed. In addition, contraction bands and lysosomal changes have been observed that may relate to cateholamine hypersensitivity. In the experimental model of diabetic cardiomyopathy, a significant alteration in relaxation process was demonstrated despite the fact that peak tension development and its rate of development were unaltered. Also, the length dependence of contractile behavior was altered when compared to that of age-matched controls, indicating a potential loss of contractility reserve. When animals with combined hypertension and diabetes were studied, bothe contraction and relaxation processes were affected to a greater degree.
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PMID:Hereditary and acquired cardiomyopathies in experimental animals: mechanical, biochemical, and structural features. 15 9

The rather old conception that endothelial cells possess an autonomous contractile capability has been reevaluated by several suthors during the past ten years on the basis of three different arguments of various validity: (1) After the topical application of inflammatory mediators tmajno et al. regularly found the endothelial nuclei furnished with numerous identations together with many interendothelial "gaps"; Both findings are assumed to be the morphological correlate of an endothelial shortening due to the contraction of the cells. While nuclear indentations seemed to be a rather weak argument to substantiate contractile capabilities, a mechanism other than contraction is outlined for the formation of "gaps"; (2) The second argument in favour of endothelial contractility is the occurrence of cytoplasmic filaments that occasionally form cross striated bundles and/or show a "thick" and "thin" variety. If all these data are assumed to be the morphological evidence for the contractile capability of cells then the conclusion: the more filaments the higher the contractile activity, must be valid. But when compiling those endothelia that are particularly rich in filaments this conclusion does not make sense, because e.g. the endothelium covering the venous valves is crowded with filaments yet an especially high "contractile activity" does not seem very probabble. On the other hand, the supposition that endothelial conttractility is entirely independent of the existence of cytoplasmic filaments leaves the question unanswered what then are the filaments for if not serving mechanical purposes. This line of reasoning is supported by both the localization of the filaments predominantly in those endothelia that have to sustain higher degrees of various mechanical stresses and the fact that filamentous structures significatnly increase in number under the influence of hypertension. (3) The final argument brought forward to substantiate endothelial contractility is the demonstration of actin and tropomyosin in the endothelium of various types of blood vessels that also occur under the influence of hypertension; tbut the significance of these findings as a proof for endothelial contractility is curtailed by the fact that the occurrence of actin alone is not conclusive for any contractile capabilities; Furthermore, a convincing demonstration of myosin in endothelial cells is still lacking and the "thick" filaments are believed to be noncontractile. Hence we suggest that the endothelial filaments together with the myoid proteins do not serve as a means for "contractility" in a true sense but simply act as a design to originate tensile strength.
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PMID:Endothelial contractility - an undecided problem in vascular research. 18 55

1. Family and population studies have reported that blood pressure has a heritability of 30-50%, but simple genetic models do not readily explain the patterns of inheritance of hypertension. 2. Restriction fragment length polymorphisms were used to study allele frequencies of a selection of candidate genes that may be important in determining the genetic component of hypertension. These included the genes for renin, haptoglobin, neuropeptide Y and cardiac myosin beta heavy chain. 3. There was no significant association between alleles at any of these loci and the presence of hypertension in this population, suggesting that the contribution of variation at these loci to the genetic component of the variance in hypertension may be quite small.
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PMID:Polymorphisms of candidate genes in essential hypertension. 135 2

We cultured smooth muscle cells from rat renal preglomerular arterioles by injecting a suspension of iron oxide into the left ventricle, separating the arterioles magnetically, and growing cells from explants. In passaged cultures we ascertained vascular smooth muscle purity of > 98% by morphology; contraction to norepinephrine and angiotensin; positive immunofluorescence staining through the sixth passage with monoclonal antibodies to smooth muscle-specific alpha- and gamma-isoactins, myosin, and desmin; and the absence of von Willebrand factor. Angiotensin II (10(-12)-10(-5) M) induced dose-dependent DNA synthesis and proliferation of subcultured (three times) arteriolar smooth muscle cells from a growth-arrested state (p < 0.01). Angiotensin II (10(-5) M) also induced the cells to express c-fos mRNA. We find no previous report of culture of smooth muscle cells from renal preglomerular arterioles. Our findings also provide evidence that angiotensin II is mitogenic to arteriolar muscle cells and thus may be involved in their hyperplasia accompanying hypertension.
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PMID:Culture of renal arteriolar smooth muscle cells. Mitogenic responses to angiotensin II. 139 76

The cardiovascular system is one of those target-organ systems of senescence where the effects of physiological ageing meet the consequences, accumulated with time, of pathological disorders. In man, these two processes are not easily disentangled, and despite the advances achieved in ultrasonic techniques the approach of structural parameters remains difficult. On the other hand, the morphological and functional unicity of the vascular wall in different species is such that observations made in animals are relevant. In rats, the structure-function relationship can be determined by histomorphometric analysis of the myocardium and vascular wall under standardized conditions of treatment. As the animals get older, the cardiac mass, related or not to body-weight, increases while the cardiac efficacy decreases. Hypertrophy of the heart is accompanied by a change in the enzymatic property of myosin. Simultaneously, the walls of the greater arteries become thicker, more rigid and less compliant, hypertrophy of the smooth muscle cells being an essential component of vascular wall thickening. At the same time, the collagen fraction and the amount of collagen-bound calcium increase. The elastic component decreases, at least relatively, and the elastin-collagen ratio clearly diminishes with age. Altogether, these alterations are not different from those observed in human arterial hypertension. They result in a lesser permeability of the tunica media, facilitate the accumulation in the subendothelium of lipidic and/or proteinic compounds originating in plasma and constitute a link between ageing and atheromatous processes.
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PMID:[Structural approach of vascular aging]. 140 71

The primary mechanism of regulation of smooth muscle contraction involves the phosphorylation of myosin catalyzed by Ca2+/calmodulin-dependent myosin light chain kinase. However, additional mechanisms, both Ca(2+)-dependent and Ca(2+)-independent, can modulate the contractile state of smooth muscle. Protein kinase C was first implicated in the regulation of smooth muscle contraction with the observation that phorbol esters induce slowly developing, sustained contractions. Protein kinase C occurs in at least four Ca(2+)-dependent (alpha, beta I, beta II, and gamma) and four Ca(2+)-independent (delta, epsilon, zeta, and eta) isoenzymes. Only the alpha, beta, epsilon, and zeta isoenzymes have been identified in smooth muscle. Both classes of isoenzymes have been implicated in the regulation of smooth muscle contraction. However, the physiologically important protein substrates of protein kinase C have not yet been identified. Specific isoenzymes may be activated by different contractile agonists, and individual isoenzymes exhibit some degree of substrate specificity. Prolonged activation of protein kinase C can result in its proteolysis to the constitutively active catalytic fragment protein kinase M, which would dissociate from the sarcolemma and phosphorylate proteins such as myosin that are inaccessible to membrane-bound protein kinase C. Protein kinase M induces relaxation of demembranated smooth muscle fibers contracted at submaximal Ca2+ concentrations. We suggest that protein kinase C plays two distinct roles in regulating smooth muscle contractility. Stimuli triggering phosphoinositide turnover or phosphatidylcholine hydrolysis induce translocation of protein kinase C (probably specific isoenzymes) to the sarcolemma, phosphorylation of protein, and a slow contraction. Prolonged association of the kinase with the membrane may lead to proteolysis and release into the cytosol of protein kinase M, resulting in myosin phosphorylation and relaxation.
Hypertension 1992 Nov
PMID:Protein kinase C of smooth muscle. 142 8

The effects of regression of cardiac hypertrophy on myocardial contractility and ventricular myosin isoenzymes were investigated in rats with renovascular hypertension. Six-week-old male Wistar rats were made hypertensive by constriction of one renal artery with a silver clip. Regression of cardiac hypertrophy was induced following the lowering of blood pressure by nephrectomy on the affected side 5-6 weeks after constriction of the renal artery and was maintained for 5-6 weeks. In contrast, myocardial hypertrophy was induced by 10-11 weeks of the hypertensive state. Isometric developed tension of isolated left ventricular papillary muscles was measured, while they were being perfused with Tyrode solution. Left ventricular myosin isoenzymes were separated by pyrophosphate gel electrophoresis. The ventricular to body weight ratio of the nephrectomized group was significantly lower than that of the hypertensive group, although it was greater than that of age-matched normal control rats. There were no significant differences in the isometric developed tension among three groups, the nephrectomized, hypertensive, and normal control rats. However, dT/dtmax tended to decrease in the hypertensive rats and recovered to normal in the nephrectomized rats. The left ventricular myosin isoenzyme pattern was shifted toward VM-3 in hypertensive rats and was shifted back toward VM-1 again in nephrectomized rats.
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PMID:Effects of regression of cardiac hypertrophy on myocardial contractility and ventricular myosin isoenzymes. 148 59

Chronic increases in haemodynamic load modify the expression of cardiac genes, leading to cardiac hypertrophy and a new phenotype. As an example, changes in the expression of the genes encoding the main contractile proteins, the isomyosin heavy chains, have been associated with modifications of the physiological properties of cardiac muscle. The cellular and molecular mechanisms which either do or do not initiate and maintain these changes in cardiac genomic expression remain to be elucidated. Using in situ hybridization we show that mRNAs encoding a cellular form of fibronectin (c-FN), a protein of the basal membrane which is not or poorly expressed in adult rat heart, are reexpressed as a result of severe hypertension with a similar time course than the beta-heavy chain of myosin (beta-MHC), also mostly expressed in fetal heart. The accumulation of the c-FN mRNAs was found in the wall of coronary arteries whilst that of the beta-MHC mRNAs occurred in the myocytes at the border zone of these arteries. Thus a high pressure in the arteries could be the trigger inducing the synthesis of factors which could, through a gradient, modulate the phenotype of both the smooth muscle cells of the media and the cardiocytes. Besides, using a model of cultured adult rat cardiocytes, we show that the differential expression of the MHC isoforms is dependent on the beta-adrenergic stimulation but that the regulation depends on the stage of development of the cells and differs for the alpha and beta MHC. These 2 complementary approaches for identifying the molecular mechanisms that control cardiac muscle growth should help for understanding cardiac adaptation triggered by haemodynamic overload, such as arterial hypertension as well as cardiac failure.
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PMID:[Changes in heart genome expression in hypertensive diseases]. 149 74

Smooth muscle cell (SMC) proliferation is a poorly understood process that plays a critical role in several pathological states, including atherosclerosis and hypertension. Recent work suggests that the oncogene c-myb and myosin, a ubiquitous cytoskeletal protein, may be directly involved in this process. We have used antisense nonmuscle myosin heavy chain (NMMHC) or c-myb phosphorothiolate oligonucleotides to inhibit proliferation of SMCs in vitro. The suppression of growth is accompanied by reductions in the concentrations of NMMHC and c-myb mRNAs as well as decreases in the levels of the corresponding proteins. The specificity of the antiproliferative effect is underscored by the absence of any detectable growth inhibition with sense NMMHC or c-myb phosphorothiolate oligonucleotides, an antisense c-myb mismatch phosphorothiolate oligonucleotide, or an antisense thrombomodulin phosphorothiolate oligonucleotide. Furthermore, the treatment of SMCs with antisense phosphorothiolate oligonucleotides for as little as 2 hours causes maximal inhibition of cell growth over the next 72 hours. Under these conditions, SMCs attain normal rates of growth over the following 48 hours, which shows that proliferation is suppressed in a reversible fashion by antisense phosphorothiolate oligonucleotides. These experiments indicate that both c-myb and nonmuscle myosin play critical roles in SMC proliferation and that reductions of either mRNA by antisense phosphorothiolate oligonucleotides arrest the process.
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PMID:Antisense nonmuscle myosin heavy chain and c-myb oligonucleotides suppress smooth muscle cell proliferation in vitro. 155 Dec 7

Intracellular calcium concentration ([Ca2+]i)-dependent activation of myosin light chain kinase and its phosphorylation of the 20-kd light chain of myosin is generally considered the primary mechanism responsible for regulation of contractile force in arterial smooth muscle. However, recent data suggest that the relation between [Ca2+]i and myosin light chain phosphorylation is variable and depends on the form of stimulation. The dependence of myosin phosphorylation on [Ca2+]i has been termed the "[Ca2+]i sensitivity of phosphorylation." The [Ca2+]i sensitivity of phosphorylation is "high" when relatively small increases in [Ca2+]i induce a large increase in myosin phosphorylation. Conversely, the [Ca2+]i sensitivity of phosphorylation is "low" when relatively large increases in [Ca2+]i are required to induce a small increase in myosin phosphorylation. There are two proposed mechanisms for changes in the [Ca2+]i sensitivity of phosphorylation: Ca(2+)-dependent decreases in the [Ca2+]i sensitivity of phosphorylation induced by phosphorylation of myosin light chain kinase by Ca(2+)-calmodulin protein kinase II and agonist-dependent increases in the [Ca2+]i sensitivity of phosphorylation by inhibition of a myosin light chain phosphatase. I will review the proposed mechanisms responsible for the regulation of [Ca2+]i and the [Ca2+]i sensitivity of phosphorylation in arterial smooth muscle.
Hypertension 1992 Aug
PMID:Regulation of contraction and relaxation in arterial smooth muscle. 163 54


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