Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.4.15.1 (ACE)
 18,300 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To assess the effects of inhibition of the renin-angiotensin system at different levels on plasma concentrations of components of the system and on renin and angiotensinogen gene expression, marmosets on a low-sodium diet were treated for 1 wk by continuous intraperitoneal infusion with either the renin inhibitor CGP-29287, the ACE inhibitor benazeprilat, the angiotensin II antagonist valsartan, the renin inhibitory monoclonal antibody R-3-36-16, or vehicle. Plasma total immunoreactive renin increased (14- to 20-fold) after all three modes of interference. Plasma angiotensinogen was significantly reduced in the benazeprilat- and valsartan-treated marmosets but not in the CGP-29287-treated animals. Plasma concentration of angiotensin II was significantly decreased in the benazeprilat-, CGP-29287-, and R-3-36-16-treated marmosets and was increased in the valsartan-treated marmosets. Kidney renin mRNA level increased 8- to 15-fold in all groups. Hepatic angiotensinogen mRNA level increased with CGP-29287 treatment but decreased with the other treatments. Kidney angiotensinogen mRNA level was not affected by any treatment. Different modes of inhibition of the renin-angiotensin system have different effects on plasma components of the system and liver angiotensinogen expression.
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PMID:Expression of components of the RAS during prolonged blockade at different levels in primates. 794 12

Polymorphonuclear neutrophils (PMN) participate in the development of myocardial injury during ischaemia/reperfusion and granules released by human neutrophils contain proteases capable of activating prorenin in human plasma and can cleave angiotensin II directly from angiotensin I and angiotensinogen. The purpose of the present study was to investigate whether angiotensin converting enzyme (ACE)-inhibitors exert an in vitro effect on PMN degranulation. Isolated neutrophils were incubated with captopril, lisinopril, enalaprilat or ramiprilat and release of lysozyme and myeloperoxidase was measured from unstimulated and opsonised zymosan stimulated cells. All ACE inhibitors increased neutrophil myeloperoxidase release and lysozyme release by both unstimulated and stimulated cells. In the presence of saline unstimulated PMN released 4.48 +/- 0.68% and zymosan-stimulated cells released 7.28 +/- 0.76% of myeloperoxidase content and the enzyme release increased after incubation with captopril (5.55 +/- 0.71 and 8.74 +/- 0.72%), lisinopril (5.43 +/- 0.57 and 9.02 +/- 0.7%), enalaprilat (6.05 +/- 0.67 and 9.20 +/- 0.82%) and ramiprilat (5.82 +/- 0.69 and 9.26 +/- 0.74%), respectively. In the presence of saline unstimulated PMN released 16.71 +/- 1.28% and zymosanstimulated PMN released 34.42 +/- 1.71% of lysozyme content and the release increased after incubation with captopril (21.15 +/- 1.36 and 42.75 +/- 1.95%), lisinopril (23.95 +/- 1.26 and 39.23 +/- 1.94%), enalaprilat (21.34 +/- 1.32 and 41.59 +/- 1.99%) and ramiprilat (20.88 +/- 1.35 and 37.53 +/- 1.95%) by unstimulated PMN, respectively. The ACE-inhibitory effect of these drugs may therefore be decreased by stimulation of PMN degranulation and neutrophil-dependent angiotensin II forming pathway.
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PMID:Evidence for stimulation of neutrophil degranulation by selected angiotensin converting enzyme inhibitors in vitro. 799 82

Congestive heart failure is often preceded by a latent or preclinical phase in which patients are relatively asymptomatic. During this period, there is neuroendocrine activation, left ventricular dysfunction, and remodeling of the heart. The extent to which these activities are interrelated is unclear, but it appears from experimental studies that myocardial damage is associated with chronic sympathetic nervous system activation, left ventricular hypertrophy, and a subsequent increase in left ventricular volume. The nondamaged myocardial tissue demonstrates enhanced messenger RNA for angiotensinogen and angiotensin converting enzyme activity. Angiotensin II along with other trophic signals may prime the cell for "growth." Alteration of left ventricular function may produce unusual loading conditions on the myocardium. Stretch of membrane-bound ion channels may impart mechanical signals that may be transduced and expressed as cellular hypertrophy. Interstitial collagenase may be activated, leading to disruption of the collagen-supporting network. Elongated cells (eccentric hypertrophy), cell slippage, and cell dropout may contribute to the dilatative process. The end product is cardiac dilatation, inefficient left ventricular performance, and congestive heart failure. We have observed that an increase in left ventricular mass is the initial morphological response to acute myocardial damage in a canine model. This occurs at 1 week and is followed by progressive activation of the sympathetic nervous system, left ventricular dilatation, and modest left ventricular dysfunction, a condition that mimics preclinical heart failure in patients. The remodeling process in the canine model, including the increase in mass and volume, may be blocked by angiotensin converting enzyme inhibitor.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Neurohumoral activation in preclinical heart failure. Remodeling and the potential for intervention. 809 70

Several well controlled multicenter trials demonstrated the great value of ACE-inhibitors in the treatment of heart failure. Interestingly, the mechanisms by which ACE-inhibitors improve survival of patients with heart failure are ony poorly understood. Interesting new aspects regarding the role of the renin angiotensin system in the pathophysiology of heart failure emerged from modern methods of molecular biology. For example, several alleles of the angiotensin converting enzyme or angiotensinogen genes were related to hypertension and myocardial infarction in both clinical and experimental studies. Furthermore, local renin angiotensin systems have been demonstrated in various cardiovascular tissues. These tissue renin angiotensin systems are independently regulated and may be activated in heart failure or cardiac hypertrophy. Finally, it has been shown that inhibition of angiotensin converting enzyme affects also the metabolism of bradykinin and aldosterone which may contribute to the overall pharmacodynamic profile of ACE-inhibitors in heart failure.
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PMID:[Growth stimulating properties of angiotensin II on the heart: consequences for therapy of heart failure]. 814 57

The mRNA expression of renin, angiotensinogen and angiotensin converting enzyme (ACE) was determined in the kidneys and livers from spontaneously hypertensive rats (SHR) and Wistar-Kyoto rats (WKY) during chronic treatment with captopril and following its withdrawal. Chronic captopril treatment was associated with a dramatic rise in renin mRNA in the kidney and an elevation in mRNA for ACE in the liver. The release from captopril treatment was associated with a reversal of the increase in kidney renin mRNA but no reversal of the sustained elevation of ACE mRNA in the liver. In situ hybridisation revealed a localisation of renin to the area of the juxtaglomerular apparatus in the kidneys from untreated animals, but recruitment of vascular sites of renin expression in kidneys from captopril-treated animals. In kidneys from released animals, renin mRNA expression was once again confined to the juxtaglomerular apparatus. ACE mRNA was expressed in hepatocytes throughout the livers from animals in all treatment groups. The results highlight a differential effect of captopril withdrawal upon the gene expression of the components of the renin-angiotensin system in kidney and liver.
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PMID:The effect of captopril treatment and its withdrawal on the gene expression of the renin-angiotensin system. 819 25

A comprehensive review of physiological and molecular biological evidence refutes claims for synthesis of renin by cardiac and vascular tissues. Cardiovascular tissue renin completely disappears after binephrectomy. Residual putative reninlike activity, where investigated, has had the characteristics of lysosomal acid proteases. Occasional reports of renin or renin mRNA in vascular and cardiac tissues can be ascribed to failure to remove the kidneys 24 hours beforehand, overloading of detection systems, problems with stringency in identification, and illegitimate transcripts after more than 25 cycles of polymerase chain reaction. Others, using more stringent criteria, have failed to detect cardiac and vascular renin mRNA. Accordingly, a growing number of investigators have concluded that the kidneys are the only source of cardiovascular tissue renin. Although prorenin is secreted from extrarenal tissues as well as from the kidneys, there is no evidence that it is ever converted to renin in the circulation. The kidney is the only tissue with known capacity to convert prorenin to renin and to secrete active renin into the circulation. Accordingly, renin of renal origin determines plasma and hence, extracellular fluid renin levels. In these loci, angiotensin (Ang) I, formed by renin cleavage of circulating and interstitial fluid angiotensinogen, is in turn cleaved by angiotensin converting enzyme, located in plasma and extracellular fluids and on the luminal surface of pulmonary and systemic vascular endothelial cells, to Ang II, which perfuses and bathes the heart and vasculature. Consistent with this model, plasma renin and angiotensin and the antihypertensive action of renin inhibitors, converting enzyme inhibitor, or Ang II antagonists all disappear after binephrectomy. Thus, the plasma renin level, via Ang II formation, determines renin system vasoconstrictor activity, the antihypertensive potential of anti-renin system drugs, and the risk of heart attack in hypertensive patients. This analysis redirects renin research to renal mechanisms that create the plasma renin level, to renal prorenin biosynthesis and its processing to renin, and to their regulated secretion, extracellular distribution, and possible binding to by target tissues. In this context, it is still possible that changes in circulating and interstitial renin substrate or available converting enzyme might exert subtle modulating influences on Ang II formation. However, this analysis redefines the importance of plasma renin measurements to assess clinical situations, because plasma renin is the only known initiator driving the cardiovascular renin-angiotensin system, and its strength can be measured.
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PMID:Renin is not synthesized by cardiac and extrarenal vascular tissues. A review of experimental evidence. 828 85

We profiled the concentrations of angiotensin I (Ang I), angiotensin II (Ang II), and angiotensin(1-7) [Ang(1-7)] by the combination of radioimmunoassay and high performance liquid chromatography in the blood of 14-week-old male Wistar-Kyoto (WKY) and spontaneously hypertensive rats (SHR) drinking either tap water or a solution containing ceranapril (30 mg/kg) or lisinopril (20 mg/kg) for 14 days. Differences in the chemical and pharmacokinetic properties of the two converting enzyme inhibitors ruled out class-related effects. Plasma renin activity, angiotensin converting enzyme (ACE) activity, and plasma levels of Ang I and Ang II were the same in vehicle-treated WKY and SHR. In contrast, plasma levels of both Ang(1-7) and vasopressin in SHR were 3.7-fold and 2.6-fold higher, respectively (p < 0.05). Angiotensin converting enzyme inhibition reduced the blood pressure of WKY and SHR, and augmented their intake of water and output of urine. These changes were associated with increases in renin activity and plasma levels of Ang I and Ang(1-7). In both WKY and SHR, lisinopril had a greater effect in inhibiting plasma and cerebrospinal fluid ACE, reducing levels of plasma angiotensinogen, and increasing the concentrations of authentic Ang II. The principal finding of this study is that plasma Ang(1-7) is the sole component of the circulating angiotensin system that is elevated in the established phase of genetic hypertension. The finding that chronic inhibition of ACE augments circulating levels of Ang(1-7) evidenced the existence of functional pathways for the alternate processing of Ang I.
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PMID:Angiotensin(1-7) in the spontaneously hypertensive rat. 828 65

For more than a decade, the inhibition of the renin-angiotensin system in heart failure has been regarded as pure vasodilator therapy. Consequently, the role of the renin-angiotension system has been seen as contributing to hemodynamic overload by vasoconstriction and volume retention. Meanwhile, clinical experience was indicated that important additional aspects of ACE-inhibition in heart failure are attenuation of the enhanced neuroendocrine activity and reversal or prevention of inappropriate trophic reactions of the overloaded myocardium. In overloaded hearts there is enhanced intracardiac formation of angiotensin due to enhanced expression of angiotensinogen and ACE, and due to accumulation of circulating, nephrogenic active renin. In human hearts, a mast-cell-derived chymase, which is not blocked by ACE-inhibition, contributes to intracardiac angiotensin formation. The enhanced intracardiac angiotensin-II formation in overloaded hearts is involved in coronary constriction, impairment of diastolic relaxation, myocyte enlargement and interstitial fibrosis, which aggravate the diastolic impairment. The major problem in overloaded, hypertrophied cardiocytes is the dedifferentiation with instabilization of Ca(++)-homeostasis due to an altered program of gene expression. Dedifferentiated cardiocytes have a reduced expression of sarcoplasmic reticulum Ca(++)-ATPase and an enhanced expression of the sarcolemmal Na+/Ca(++)-exchanger, resulting in an attenuation of active diastole (Ca(++)-reaccumulation into the sarcoplasmic reticulum), a depressed force-frequency relation, and an enhanced susceptibility for fatal arrhythmias. Furthermore, an enhanced local renin-angiotensin system in distensible coronary and systemic arteries seems to contribute to a reduced releasability of endothelium-derived relaxing factor, probably by reducing bradykinin availability. This modulation of endothelial function appears to contribute to the localization and progression of atheroma development in presence of risks factors for atherosclerosis.
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PMID:Pathophysiology of heart failure and the renin-angiotensin-system. 835 33

Although renin and angiotensinogen are known to be subject to feedback regulation, the effects of angiotensin II (Ang II) on the regulation of angiotensin converting enzyme (ACE) gene expression and enzymatic activity have not yet been studied. Therefore, the effects of exogenous Ang II infusion and ACE inhibition on ACE mRNA expression were examined. Ang II was infused intravenously in male Sprague-Dawley rats for 3 days at 100 (low dose), 300 (medium dose), or 1,000 (high dose) ng/kg per minute (n = 8 for each group). Compared with control (vehicle infusion, n = 8), Ang II infusion increased plasma Ang II concentration (62, 101, 126 [p < 0.05], and 187 [p < 0.05] fmol/ml) and mean arterial blood pressure (106, 119 [p < 0.05], 134 [p < 0.05], and 125 mm Hg for control, low, medium, and high doses, respectively). Ang II infusion decreased ACE mRNA levels in the lung (57%, 52%, and 51%; p < 0.05 for each) and testis (49%, 63%, and 53% of control for low, medium, and high doses, respectively; p < 0.05 for each), two major sites of ACE synthesis. There was, albeit less pronounced, a parallel decrease in pulmonary ACE activity (4.38, 3.92, 3.07 [p < 0.05], and 3.48 [p < 0.05] nM/mg per minute for control, medium, and high doses, respectively). In contrast, serum (54, 50, 48, and 38 [p < 0.05] nM/ml per minute) and testicular (2.63, 2.08 [p < 0.05], 2.24, and 2.18 nM/mg per minute for control, low, medium, and high doses, respectively) ACE activities displayed only minimal change in animals infused with Ang II.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Feedback regulation of angiotensin converting enzyme activity and mRNA levels by angiotensin II. 838 Mar 58

Intravital microscopy was used in a preparation of rat cremaster muscle that was isolated from its normal blood supply and externally perfused with a physiological solution, thus allowing exclusion of circulating converting enzyme, renin, and angiotensinogen. The arterioles studied were classified as second-, third-, and fourth-order arterioles with mean diameters of 60.5, 29.9, and 14.8 microns, respectively. Topical administration of 1 nmol/mL angiotensin I or 1 nmol/mL tetradecapeptide renin substrate induced marked vasoconstrictions (i.e., 38.5%, 61.5%, and 90.1% and 25%, 34%, and 88% for second-, third-, and fourth-order arterioles with angiotensin I and tetradecapeptide renin substrate, respectively). The angiotensin converting enzyme inhibitor quinapril significantly inhibited the vasoconstrictions caused by either angiotensin I or tetradecapeptide renin substrate. Almost no vasoconstriction was found when angiotensinogen-rich renin-free plasma containing either 2.45 nmol/mL of angiotensinogen or 1.2 micrograms/mL renin was administered. Conversely, these two compounds induced significant constrictions in cremaster muscle preparations in which normal blood perfusion (and thus circulating renin and angiotensinogen) was left in place. We concluded that, in skeletal muscle, 1) the microvascular network is a very effective site of local angiotensin converting enzyme activity and consequently an important target site of angiotensin converting enzyme inhibitors; 2) the effects of tetradecapeptide renin substrate are very different from those of angiotensinogen from plasma and suggest that a large part of the effect of tetradecapeptide renin substrate was due to its nonspecific hydrolysis; and 3) at the microvascular level, circulating renin and angiotensinogen are more effective in inducing arteriolar constriction, in the presence of their substrate or associated enzyme, than local renin and angiotensinogen.
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PMID:Arteriolar constriction and local renin-angiotensin system in rat microcirculation. 838 4


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