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

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

Previous studies have shown that erythrocytes from the Milan hypertensive strain of rats (MHS) differ from erythrocytes from the control normotensive strain (MNS). These differences are determined within the stem cells, are genetically associated with the development of hypertension, and are similar to those found between the tubular cells of the two strains. Moreover they seem to be dependent upon the presence of the membrane skeleton proteins. In this paper we describe our studies aimed at identifying some precise protein difference between the membrane skeletons of the two strains, which may cause the cellular differences described above. Milan hypertensive strain and MNS rats were immunized with ghost or membrane skeleton extracts prepared from the other or their own strains. Only MHS rats immunized with MNS ghost or membrane skeleton extracts produced an antibody against a 105 KD protein in about 95% of the animals. This protein has been identified with the recently described cytoskeletal protein adducin on the following bases: the protein binds calmodulin (CaM) and protein kinase C (PKc) in a Ca2+ dependent way. It also binds phosphatidylserine, is the substrate of exogenous PKc, and finally it is purified by high salt extraction of Triton-X100 insoluble erythrocyte cytoskeletons followed by affinity chromatography on CaM-sepharose. Using this antibody the isolation from a mouse spleen library, the characterization and sequencing of a partial cDNA clone coding for this protein has been carried out. In conclusion adducin may be considered a very useful tool to test the hypothesis that the cellular differences between MHS and MNS may be caused by a difference in a membrane skeleton protein.
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PMID:Erythrocyte adducin differential properties in the normotensive and hypertensive rats of the Milan strain. Characterization of spleen adducin m-RNA. 270 90

Previous studies on genetic rat hypertension have shown that polymorphism within the alpha-adducin gene may regulate blood pressure. Adducin is a cytoskeletal protein that may be involved in cellular signal transduction and interacts with other membrane-skeleton proteins that affect ion transport across the cell membrane. There is a high homology between rat and human adducin and pathophysiological similarities between the Milan hypertensive rat strain and a subgroup of patients with essential hypertension. Thus, we designed a case-control study to test the possible association between the alpha-adducin locus and hypertension. One hundred ninety primary hypertensive patients were compared with 126 control subjects. All subjects were white and unrelated. Four multiallelic markers surrounding the alpha-adducin locus located in 4p16.3 were selected: D4S125 and D4S95 mapping at 680 and 20 kb centromeric, and D4S43 and D4S228/E24 mapping at 660 and 2500 kb telomeric. Alleles for each marker were pooled into groups. Comparisons between control subjects and hypertensive patients were carried out by testing the allele-disease association relative to the marker genotype. The maximal association occurred for D4S95 (chi 2(1) 13.33), which maps closest to alpha-adducin. These data suggest that a polymorphism within the alpha-adducin gene may affect blood pressure in humans.
Hypertension 1995 Mar
PMID:Association of the alpha-adducin locus with essential hypertension. 787 56

During vascular development, the expression of tropoelastin (TE) messenger ribonucleic acid (mRNA) has been shown to be time dependent and to form complex patterns along the longitudinal and radial arterial axes. The factors contributing to these patterns of TE expression are not known, but it has been suggested that they reflect phenotypic changes in developing smooth muscle cells (SMC). In order to examine a possible correlation between the developmental state of the SMC and TE expression during lung vascular development, we localized and assessed relative TE mRNA expression in the developing bovine main pulmonary artery (PA), and correlated the observed patterns of TE expression to changes in SMC phenotype as determined by the expression of various developmentally related SMC proteins. Further, because TE expression can be modulated by physical forces such as pressure, fetal PA TE expression was evaluated with regard to changes in fetal arterial pressure. We found that expression of TE mRNA exhibited a biphasic pattern during fetal development. In early gestation, expression was noted throughout the entire PA wall; at midgestation, expression was markedly decreased in the outer wall but maintained in the inner vascular media; at late gestation, reexpression was observed throughout the entire PA wall, albeit in a heterogeneous pattern. Immunohistochemical studies showed that the decrease in SMC TE expression during midgestation coincided with the acquisition of SMC-specific proteins such as smooth muscle myosin heavy chains and desmin. The reexpression of TE late in gestation occurred in these "differentiated" SMC and was temporally associated with a large increase in arterial pressure shown to occur in late gestation. In addition, we identified an SMC population defined by its immunoreactivity to the muscle-specific cytoskeletal protein meta-vinculin that did not express TE mRNA either during fetal PA development or postnatally when PA hypertension was induced. We conclude that both the developmental state of the SMC and hemodynamic forces correlate with the pattern of PA TE mRNA expression during pulmonary vascular development. Further, a subpopulation of SMC defined by meta-vinculin expression exists in the fetal and neonatal bovine vascular wall and does not express detectable levels of TE mRNA regardless of vascular pressure.
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PMID:Expression and localization of tropoelastin mRNA in the developing bovine pulmonary artery is dependent on vascular cell phenotype. 865 85

Human primary hypertension is a polygenic disease; its phenotypic expression is modulated by the environment. Though the kidney can play a major role in the initiation and maintainance of hypertension, many questions remain open. Kidney cross-transplantation demonstrated that hypertension can be transplanted with the kidney in all strains of genetically hypertensive rats where such experiments have been carried out. Data consistent with those in rats were also obtained in humans. Many abnormalities in kidney function and ion transport were described in hypertensive rats and humans, but the logical sequence from genetic-molecular to cellular abnormality that causes hypertension via modification of kidney function is difficult to prove. We established this sequence in Milan hypertensive rats using a variety of experimental techniques (isolated kidney and renal cell function, cell membrane ion transport, cross-immunization with membrane proteins, molecular biology, genetic crosses and manipulation). Such studies led to the identification of a polymorphism in the cytoskeletal protein adducin. This polymorphism seems involved in blood pressure regulation both in rats and humans. Preliminary results suggest that adducin polymorphism affects kidney function by modulating the overall capacity of tubular epithelial cells to transport ions modifying the assembly of actin cytoskeleton.
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PMID:Renal mechanisms of genetic hypertension: from the molecular level to the intact organism. 874 91

Milan hypertensive rats (MHS) develop hypertension because of a primary renal alteration. Both apical and basolateral sodium transport are faster in membrane vesicles derived from renal tubules of MHS than in those of Milan normotensive control rats (MNS). These findings suggest that the increased renal sodium retention and concomitant development of hypertension in MHS may be linked to an altered transepithelial sodium transport. Since this transport is mainly under the control of the Na-K pump, we investigated whether an alteration of the enzymatic activity and/or protein expression of the renal Na,K-ATPase is detectable in prehypertensive MHS. We measured the Na,K-ATPase activity, Rb+ occlusion, turnover number, alpha 1- and beta 1-subunit protein abundance, and alpha 1 and beta 1 mRNA levels in microsomes from renal outer medulla of young (prehypertensive) and adult (hypertensive) MHS and in age-matched MNS. In both young and adult MHS, the Na,K-ATPase activity was significantly higher because of an enhanced number of active pump sites, as determined by Rb+ occlusion maximal binding. The higher number of pump sites was associated with a significant pretranslational increase of alpha 1 and beta 1 mRNA levels that preceded the development of hypertension in MHS. Since a molecular alteration of the cytoskeletal protein adducin is genetically associated with hypertension in MHS and is able to affect the actin-cytoskeleton and Na-K pump activity in transfected renal cells, we propose that the in vivo upregulation of Na-K pump in MHS is primary and linked to a genetic alteration of adducin.
Hypertension 1996 Dec
PMID:Renal Na,K-ATPase in genetic hypertension. 895 91

Human essential hypertension is a polygenic disease whose phenotypic expression is modulated by the environment. Though the kidney could play a major role in the initiation and maintainment of hypertension, many questions remain open. Rat models of primary hypertension provided the substantial information with experiments on kidney cross-transplantation, showing that at least a portion of hypertension could be transplanted with the kidney in all strains where such an experiment has been carried out. Data consistent with those of rats have also been obtained in humans. Many abnormalities in kidney function and cell membrane ion transport have been described in hypertensive rats and humans, but the logical sequence of events from a genetic-molecular abnormality to a cellular abnormality which causes hypertension via a modification of kidney function is difficult to prove. We established this sequence in Milan hypertensive rats using a variety of experimental techniques such as the study of isolated kidney and renal cell function, cell membrane ion transport, cross-immunisation with membrane proteins, molecular biology, genetic crosses and manipulation. Such study led to the identification of a polymorphism in the cytoskeletal protein adducin. Recently, alpha-adducin variants have been associated to both primary hypertension and salt sensitive hypertension. Finally, recent findings strongly support the hypothesis that adducin variants may affect kidney function by modulating the overall capacity of the tubular epithelial cells to transport ions through both a modification in the assembly of actin cytoskeleton, and a modulation of sodium pump activity.
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PMID:Genetic determinants and renal mechanisms in essential hypertension. 900 89

Human essential hypertension is a polygenic disease whose phenotypic expression is modulated by the environment. Though the kidney could play a major role in the initiation and maintainment of hypertension, many questions remain open. Rat models of primary hypertension provided the substantial information with experiments on kidney cross-transplantation showing that at least a portion of hypertension could be transplanted with the kidney in all strains where such experiment has been carried out. Data consistent with those of rats have also been obtained in humans. Many abnormalities in kidney function and cell membrane on transport have been described in hypertensive rats and humans but the logical sequence of events going from a genetic-molecular abnormality to a cellular abnormality which causes hypertension via a modification of kidney function is difficult to prove. We established this sequence in Milan hypertensive rats using a variety of experimental techniques such as the study of isolated kidney and renal cell function, cell membrane ion transport, cross-immunisation with membrane proteins, molecular biology, genetic crosses and manipulation. Such study led to the identification of a polymorphism in the cytoskeletal protein adducin and to the demonstration of its role in blood pressure control. Recently, alpha-adducin variants have been associated to both human primary hypertension and salt sensitive hypertension. Finally, recent findings strongly support the hypothesis that adducin variants may affect kidney function by modulating the overall capacity of the tubular epithelial cells to transport ions through both a modification in the assembly of actin cytoskeleton, and a modulation of sodium pump activity.
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PMID:Renal genetic mechanisms of essential hypertension. 937 22

The individual variation in the efficacy of and tolerability to antihypertensive drugs in human essential hypertension is linked to the genetic heterogeneity of this multifactorial disease. Different approaches have been pursued in the attempt to correlate a specific responsiveness to the therapy with some phenotypic traits of the patients, such as the renin-angiotensin profile or the characteristics of cell ion transports. More recently, a genetic approach to the study of the mechanisms underlying hypertension has led to the identification of some quantitative trait loci or genes that influence blood pressure in both animal models and patients. Also, individual variation to therapy can now be studied from the genetic point of view using pharmacogenomics, that is, the study of the genes or loci which are involved in determining the responsiveness to a given drug. Only a few examples of this approach are available to date. Our group has identified a polymorphism of the genes for the cytoskeletal protein, adducin, which is linked to both rat and human hypertension, sodium sensitivity and to the pressor responsiveness to diuretic therapy. These results, together with the indication that adducin can play a functional role by modulating the cellular sodium transport, have led to the identification of a new antihypertensive compound, which could be a candidate for the selective treatment of those patients in whom alterations of the renal sodium handling are associated with specific genetic traits such as the polymorphism for adducin.
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PMID:Pharmacogenomics: a new approach to individual therapy of hypertension? 952 26

In Milan hypertensive rats (MHS) the sequence of events going from renal function to cell membrane ion transport abnormalities and finally to the molecular defect responsible of hypertension has been established. A polymorphism of the cytoskeletal protein adducin has been identified as a likely culprit for hypertension in these rats. Two point mutations in MHS alpha- (F316Y) and beta- (Q529R) adducin genes have been shown to be associated with hypertension in genetic crosses of MHS and MNS rats. Also in humans, a polymorphism of alpha-adducin gene (Gly460Trp) has been found to be significantly associated both to hypertension and salt sensitivity. Studies aimed at clarifying the functional role of alpha-adducin variants have shown that adducin from the MHS rats is able to stimulate Na-KATPase activity both after transfection in renal tubular cells and after incubation with the enzyme in a cell-free system. Also the human hypertensive alpha-adducin variant displays the same activity of MHS adducin in a cell-free system. Therefore, both in humans and in rats, adducin polymorphisms may affect blood pressure and kidney function by modulating the overall capacity of tubular epithelial cells to transport ions, through variations of the Na-KATPase activity. However adducin polymorphisms account for only a portion of hypertension both in humans and rats. Therefore additive or epistatic interactions with other genes involved in renal sodium handling need to be studied.
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PMID:Adducin in essential hypertension. 967 91


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