EC:3.4.15.1 - FACTA Search

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

The renin-angiotensin system originally was thought to be responsible for only renovascular hypertension, but the development and use of various inhibitors of this system have produced much evidence for its participation in many forms of hypertensive disease. Tissue renin-angiotensin system also may play a major role in blood pressure control. Chronic clinical as well as animal use of converting enzyme inhibitors results in levels of angiotensin II that are equivalent to those found in the normotensive state and higher than those found in the very acute phase of treatment. The source of this conversion possibly may be due to enzymes unrelated to angiotensin converting enzyme. One such enzyme is a very highly specific serine protease isolated from human cardiac tissue. This enzyme exists in human ventricular tissue at levels four to five times that of angiotensin converting enzyme. During chronic treatment of patients with heart failure, angiotensin I levels become high, and heart tissue levels of angiotensin II may become elevated because of the conversion to angiotensin II by this serine protease. This conversion in turn may possibly increase inotropy of the heart, whereas the peripheral resistance remains low because of the reduction of angiotensin II in the circulation.
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PMID:Angiotensin I and II. Some early observations made at the Cleveland Clinic Foundation and recent discoveries relative to angiotensin II formation in human heart. 193 74

Incubation of human plasma at 37 degrees C for several hours leads to the formation of a non-dialysable vasopressor substance termed the active pressor principle. Some of the chemical and physical natures of active pressor principle were investigated in anesthetized and ganglion blocked rats. It was found to have properties characteristic of protein. The substance was crudely purified to about 25-fold in alcoholic trichloroacetic acid solution after placing the plasma in a boiling water bath for 5 minutes ("active fraction"). After treatment of the vasoactive plasma or "active fraction" with Pronase, the pressor activity was almost abolished. The molecular weight of this fraction as determined by gel filtration was about 68,000. With addition of diisopropyl fluorophosphate before incubation of the plasma, no vasopressor substance was generated. After treatment of the rat with captopril, an angiotensin converting enzyme inhibitor, the pressor effect of incubated plasma was not inhibited. These findings suggest that a vasoactive protein, which is clearly different from renin, is generated during simple incubation of plasma, and that a serine protease is involved in the formation of this substance.
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PMID:Characterization of a vasopressor substance generated in human plasma by incubation. 351 45

BK destroying activity was observed in rat isolated heart perfusates. BK was optimally degraded at pH 8.4 in rat heart. The results indicated that myocardial kinin degradation was due to ACE and a serine protease. These results suggest that bradykinin may have some cardioprotective role during myocardial ischaemia at acidic pH.
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PMID:The release of kininase from rat isolated hearts during myocardial ischaemia. 885 68

1. Functional recordings of smooth muscle tension and biochemical experiments on membrane fractions were performed to characterize angiotensin II (AII) formation in human isolated bladder smooth muscle. 2. A novel human chymase inhibitor CH 5450 (Z-Ile-Glu-Pro-Phe-CO2Me) and a recently developed human chymase substrate Pro11-,D-Ala12)-angiotensin I, claimed to be resistant to angiotensin converting enzyme (ACE) and carboxypeptidase, were used. 3. Angiotensin I (AI) (0.3 microM) induced a contractile response amounting to 58 +/- 5% (n=12) of the initial K+ (124 mM)-induced contractions. This response was reduced to 36 +/- 3% (n=8) by the ACE-inhibitor enalaprilat (10 microM), while pretreatment with soybean trypsin inhibitor (STI 200 microg ml(-1)) or CH 5450 (10 microM) had no effect. However, the combination of enalaprilat and STI reduced the AI-induced contractions to 19 +/- 5% (n=6), and the combination of enalaprilat and CH 5450 caused an almost complete inhibition of the AI-induced contractions to 1+/-1% (n=6). 4. The substrate (Pro11-,D-Ala12)-AI (3 microM) produced contractions which amounted to 57 +/- 4% (n=13) of the initial K+ (124 mM) contractions. These contractions were not affected by enalaprilat (10 microM). On the other hand, STI (200 microg ml(-1)) and CH 5450 (10 microM) added separately, depressed the (Pro11-,D-Ala12)-AI-induced contractions to 34 +/- 5% (n=6) and 24 +/- 4% (n=6), respectively. The combination of enalaprilat and STI or enalaprilat and CH 5450 did not produce any further inhibition. 5. Experiments with detrusor membrane fractions incubated with AI (50 microM) were performed. In the presence of enalaprilat (100 microM), carboxypeptidase inhibitor CPI (10 microg ml(-1)) and aprotinin (15 microM), CH 5450 (10 nM-1 microM) caused a concentration-dependent inhibition of AII formation. 6. The results confirm that AII is a potent contractile agent in the human isolated detrusor muscle. They also indicate that the serine protease responsible for AII formation in the human bladder in vitro is human chymase or an enzyme similar to human chymase.
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PMID:Characterization of angiotensin II formation in human isolated bladder by selective inhibitors of ACE and human chymase: a functional and biochemical study. 924 42

An aprotinin-insensitive, angiotensin II (Ang II)-forming chymase has recently been identified in human heart tissue. We studied the hydrolysis of Ang I in human lung membranes. The hydrolysis products Ang II, Ang III, Ang-(1-9), Ang-(2-9), Ang-(1-7) and Ang-(8-10) appeared in membrane preparations from four patients. Two metabolic pathways for the formation of Ang II were identified; one depending on ACE activity (1.4 nmol Ang II/min/mg membrane protein) and the other on serine protease activity (2.1 nmol/min/mg). The serine protease activity was inhibitable to only 30 +/- 8% (mean +/- SEM) by aprotinin, suggesting chymase activity to play a role in the Ang I-conversion of human lung.
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PMID:Conversion of angiotensin I to angiotensin II by chymase activity in human pulmonary membranes. 928 34

We have previously shown that nitric oxide (NO) release by the coronary circulation in the failing and nonfailing human heart is, in part, regulated by local kinin production in coronary microvessels. Angiotensin-converting enzyme (ACE) also known as kininase II, inactivates kinins. ACE inhibitors prevent kinin breakdown by ACE, thereby increasing the concentration of bradykinin (BK) and related kinins. The goal of this study was to determine if kinins contribute to the therapeutic action of ACE inhibitors. Six hearts from end-stage heart failure patients were harvested at the time of orthotopic cardiac transplantation. Microvessels were prepared as previously described, and nitrite production, a metabolic product of NO in vitro, was determined by the Griess reaction. Microvessels were incubated in the presence of kininogen and bradykinin, and with the ACE inhibitors ramiprilat, enalaprilat, or captopril. All caused dose-dependent increases in nitrite. For instance, ramiprilat increased nitrite from 76 +/- 5.6 to 155 +/- 15 pmol/min per mg wet weight. Nitrite production in response to ACE inhibition was blocked by N-nitro-L-arginine methyl ester (L-NAME), a NO synthase inhibitor, and icatibant (HOE 140), a B2-kinin receptor-specific antagonist. Furthermore, NO production was prevented by 3 different serine protease inhibitors, which block kallikrein, the enzyme responsible for conversion of kininogen to kinins. Our results indicate that ACE/kininase inhibitors increase NO production by the coronary microvasculature in the failing human heart, through increased available active kinins. The therapeutic action of ACE inhibition in the failing human heart may result in part from increased NO production by coronary microvessels.
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PMID:Angiotensin-converting enzyme inhibitors promote nitric oxide production in coronary microvessels from failing explanted human hearts. 929 67

We determined whether local bradykinin production modulates cardiac adrenergic activity. Depolarization of guinea pig heart sympathetic nerve endings (synaptosomes) with 1 to 100 mmol/L K+ caused the release of endogenous norepinephrine (10% to 50% above basal level). This release was exocytotic, because it depended on extracellular Ca2+, was inhibited by the N-type Ca(2+)-channel blocker omega-conotoxin and the protein kinase C inhibitor Ro31-8220, and was potentiated by the neuronal uptake-1 inhibitor desipramine. Typical of adrenergic terminals, norepinephrine exocytosis was enhanced by activation of prejunctional angiotensin AT1-receptors and attenuated by adrenergic alpha 2-receptors, adenosine A1-receptors, and histamine H3-receptors. Exogenous bradykinin enhanced norepinephrine exocytosis by 7% to 35% (EC50, 17 nmol/L), without inhibiting uptake 1. B2-receptor, but not B1-receptor, blockade antagonized this effect. The kininase II/angiotensin-converting enzyme inhibitor enalaprilat and the addition of kininogen or kallikrein enhanced norepinephrine exocytosis by approximately equal to 6% to 40% (EC50, 20 nmol/L) and approximately equal to 25% to 60%, respectively. This potentiation was prevented by serine protease inhibitors and was antagonized by B2-receptor blockade. Therefore, norepinephrine exocytosis is augmented when bradykinin synthesis is increased or when its breakdown is inhibited. This is the first report of a local kallikrein-kinin system in adrenergic nerve endings capable of generating enough bradykinin to activate B2-receptors in an autocrine/paracrine fashion and thus enhance norepinephrine exocytosis. This amplification process may operate in disease states, such as myocardial ischemia, associated with severalfold increases in local kinin concentrations.
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PMID:Bradykinin B2-receptor activation augments norepinephrine exocytosis from cardiac sympathetic nerve endings. Mediation by autocrine/paracrine mechanisms. 935 50

Chymase is a chymotrypsin-like serine protease secreted from mast cells. Mammalian chymases are classified into two subgroups (alpha and beta) according to structure and substrate specificity; human chymase is an alpha-chymase. An important action of chymase is the ACE-independent conversion of Ang I to Ang II, but chymase also degrades the extracellular matrix, activates TGF-beta1 and IL-1beta, forms 31-amino acid endothelins and is involved in lipid metabolism. Under physiological conditions, the role of chymase in blood vessels is uncertain. In pathological situations, however, chymase may be important. In animal models of hypertension and atherosclerosis, chymase may be involved in lipid deposition and intimal and smooth muscle hyperplasia, at least in some vessels. In addition, chymase has pro-angiogenic properties. In human diseased blood vessels (e.g. atherosclerotic and aneurysmal aorta; remodeled pulmonary blood vessels), there are increases in chymase-containing mast cells and/or in chymase-dependent conversion of Ang I to Ang II. These findings have raised the possibility that inhibition of chymase may have a role in the therapy of vascular disease. The effects of chymase can theoretically be attenuated either by reducing availability of the enzyme, with a mast cell stabiliser, or alternatively with specific chymase inhibitors. The mast cell stabiliser, tranilast, was shown to be beneficial in animal models of atherosclerosis, where a prevention protocol was used, but was not effective in clinical trials where it was administered after angioplasty. Chymase inhibitors could have the advantage of being effective even if used after injury. Several orally active inhibitors, including SUN-C8257, BCEAB, NK3201 and TEI-E548, are now available. These have yet to be tested in humans, but promising results have been obtained in animal models of atherosclerosis and angiogenesis. It is concluded that orally active inhibitors of chymase may have a place in the treatment of vascular diseases where injury-induced mast cell degranulation contributes to the pathology.
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PMID:Vascular chymase: pathophysiological role and therapeutic potential of inhibition. 1498 62

The present report describes how the soluble germinal angiotensin I-converting enzyme (gACE) appears in the epididymal fluid, where it has been identified in some laboratory rodents and domestic ungulates. We showed that this gACE results from an active proteolytic process that releases the enzyme's extracellular domain from sperm in a precise spatiotemporal location during epididymal transit and that this process involves serine protease activity. Using polyclonal antibodies against the C-terminal intracellular sequence of ACE, a fragment of approximately 10 kDa was detected on the sperm extract only in the epididymal region, where the gACE release occurs. The fluid enzyme was purified, and the cleavage site was determined by mass spectrometry to be between Arg622 and Leu623 of the mature sheep gACE sequence (equivalent to Arg627 and Arg1203 of the human mature gACE and somatic ACE sequences, respectively). Thereafter, the C-terminal Arg was removed, leaving Ala621 as a C-terminal. Using an in vitro assay, gACE cleavage from sperm was strongly increased by the presence of epididymal fluid from the release zone, and this increase was inhibited specifically by the serine protease-inhibitor AEBSF but not by para-aminobenzamidine. None of the other inhibitors tested, such as metallo- or cystein-protease inhibitors, had a similar effect on release. It was also found that this process did not involve changes in gACE phosphorylation.
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PMID:Shedding of the germinal angiotensin I-converting enzyme (gACE) involves a serine protease and is activated by epididymal fluid. 1598 22

An alkaline serine protease that hydrolyzes soybean protein into strong angiotensin I-converting enzyme inhibitory hydrolysates was isolated from alkalophilic Bacillus sp. SS103 and purified. The enzyme was purified by ammonium sulfate precipitation followed by gel filtration, cationic exchange column chromatography, and anionic exchange column chromatography. When run on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and isoelectric focusing gel, the purified enzyme gave a 36-kDa band and pI 5.5, respectively. The enzyme showed maximum activity at pH 11.0 and 50 degrees C. This enzyme activity was highly inhibited by aprotinin, suggesting it belongs to the serine protease class of enzymes. The K (m) and V (max) of the enzyme, when casein was used for the substrate, were 9.7 x 10-4 mM and 244 microg/minute, respectively. From the results of this study, it is concluded that the purified alkaline protease isolated from Bacillus sp. SS103 should be further studied for production of biofunctional hydrolysates.
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PMID:Purification and characterization of an alkaline serine protease producing angiotensin I-converting enzyme inhibitory peptide from Bacillus sp. SS103. 1637 56

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