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 formation of AII from a metabolite of AI, des-leu10-angiotensin I [A(1-9)] has been studied in centrifugal fractions of rat lung and kidney using gradient elution HPLC to monitor the formation of peptide products. AII-forming activity was present in kidney S2 (22.3 nmol/mg protein/min) but not in kidney P2 centrifugal fractions. Lung S2 fractions showed relatively weak AII-forming activity (0.34 nmole/mg protein/min) whilst no activity was observed in lung P2. Carboxypeptidase N-like activity measured using both Hipp-Arg and Hipp-Lys as synthetic substrates did not parallel AII-forming activity, since this activity was highest in the P2 fractions of both lung and kidney, as were ACE and aminopeptidase activities. Whilst the major peptide produced in kidney S2 was AII (71%) significant amounts of both AIII (23%) and A(2-9) (6%) were also observed. In lung the amounts of these peptides produced as a percentage of the A(1-9) degrading activity were 2.9%, 2.4% and 21% respectively. The AII-forming activity in kidney S2 was not inhibited by enalaprilat, bestatin, amastatin, phosphoramidon or Pro-Phe but was inhibited (31%) by 1 mM cobalt (II). 1,10-Phenanthroline, iodoacetic acid, EDTA and puromycin significantly enhanced the formation of AII and increased the rate of degradation of the substrate, A(1-9). These results support the concept of a sequential carboxypeptidase pathway operating, particularly in kidney, to produce AII from AI. These results provide further evidence of an alternative metabolic pathway for the formation of AII not involving angiotensin converting enzyme.
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PMID:Formation of angiotensin II and other angiotensin peptides from des-leu 10-angiotensin I in rat lung and kidney. 284 26

Protamine given to neutralize heparin after extracorporeal circulation can trigger a catastrophic reaction in some patients. While searching for a biochemical basis for this reaction, protamine was tested as an inhibitor of human plasma carboxypeptidase N (CPN) or kininase I, the inactivator of anaphylatoxins and kinins. Human plasma and CPN purified from human plasma, (Mr = 280 K) or its isolated active subunit (Mr = 48 K) were the sources of enzyme. The hydrolysis of furylacryloyl (FA)-Ala-Lys was measured in a UV spectrophotometer and that of bradykinin and the synthetic C-terminal octapeptide of anaphylatoxin C3a (C3a8) by high performance liquid chromatography. Protamine inhibited the hydrolysis of FA-Ala-Lys by CPN, (IC50 = 3.2 X 10(-7) M); added human serum albumin (30 mg/ml) increased the IC50 to 7 X 10(-6) M. When plasma was the source of CPN, the IC50 was 2 X 10(-6) M. Protamine more effectively inhibited the hydrolysis of bradykinin and C3a8. The IC50 for protamine was 5 X 10(-8) M with CPN and bradykinin, 7 X 10(-8) M with CPN and C3a8 and with the 48 K subunit and bradykinin it was 7 X 10(-8) M of protamine. Heparin competes with CPN for protamine, because in high concentration (18 U/ml) it reverses the inhibition by protamine. Protamine did not inhibit angiotensin I converting enzyme (kininase II) or the endopeptidase 24.11 (enkephalinase). Kinetic studies showed the mechanism of protamine inhibition to be partially competitive; about 10-20% of the hydrolysis of bradykinin by CPN was not inhibited by protamine. Thus, by blocking the inactivation of mediators released in shock, protamine inhibition of CPN may be partially responsible for the catastrophic reaction observed to occur in some patients.
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PMID:Protamine inhibits plasma carboxypeptidase N, the inactivator of anaphylatoxins and kinins. 291 61

We have purified angiotensin-converting enzyme (ACE, EC 3.4.15.1) from rat brain corpus striatum and rat lung. The brain enzyme has Mr 165,000 by sodium dodecyl sulfate gel electrophoresis, whereas the lung enzyme is 175,000. This difference is not an artifact of preparation since mixture of the two tissues prior to purification results in isolation of two proteins with Mr 165,000 and 175,000. Separation of tryptic fragments of 125I-labeled lung and brain ACE by reverse-phase chromatography yields distinct but similar patterns. No differences between the native enzymes are detected in dansyl-tripeptide cleavage specificity, inhibitor profile, immunological properties, sucrose gradient sedimentation, or gel filtration of ACE from the two tissues. However, lung and brain ACE can be differentiated in their ability to cleave amidated peptides. Both lung and brain ACE cleave Arg-Pro-Lys-Pro-Gln-Gln-Phe-Phe-Gly-Leu-Met-NH2 (substance P) via two pathways. In one pathway, ACE first releases Gly-Leu-Met-NH2 and then dipeptides sequentially from the carboxyl terminus. The other first produces Leu-Met-NH2, and then releases dipeptides to leave substance P 1-5. Lung ACE favors initial tripeptide release 3:1, while the striatal enzyme acts via the two pathways to a similar extent. Lung and striatal ACE also differ in their ability to degrade other amidated peptides. His-Lys-Thr-Asp-Ser-Phe-Val-Gly-Leu-Met-NH2 (substance K) and bombesin are degraded by striatal but not lung ACE. Physalaemin and luteinizing hormone-releasing hormone are cleaved by both enzymes, while eledoisin, kassinin, thyrotropin-releasing hormone, and substance P 5-11 are not cleaved by either enzyme. Physalaemin is degraded more rapidly by the lung enzyme. The coincidence of an ACE isozyme with substance P and substance K in the descending striatonigral pathway and the unique ability of this isozyme to cleave substance P and substance K suggest that one or both of these peptides is a physiological substrate for striatonigral ACE.
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PMID:A rat brain isozyme of angiotensin-converting enzyme. Unique specificity for amidated peptide substrates. 299 Dec 65

The di-acid metabolite of enalapril, enalaprilat, and its lysine analogue lisinopril are potent inhibitors of angiotensin converting enzyme (ACE); they do not contain sulphydryl groups. Both drugs can be assayed by high pressure liquid chromatography and by radioimmunoassay and plasma ACE inhibition remains stable under normal storage conditions. It is therefore possible to study their pharmacokinetics as well as their pharmacodynamic effects in man. Enalaprilat and lisinopril as well as ACE activity have been measured in blood taken during the course of two studies of the effects of these drugs on blood pressure and autonomic responsiveness. A population pharmacokinetic analysis approach applied to a few concentration-time data points in each of a relatively large number of subjects provided average population parameter estimates of the absorption rate constant, volume of distribution and clearance which correspond closely with the limited published data based on conventional pharmacokinetic approaches. It also provided estimates of pharmacodynamic parameters and the concentration of the drug required to produce a 50% ACE inhibition. Population drug concentration data obtained in the course of early clinical evaluations of new drugs may provide a rational basis for dosage regimens with improved efficacy and, in particular, reduced concentration-related toxic effects.
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PMID:Pharmacodynamics and population pharmacokinetics of enalapril and lisinopril. 300 81

We have studied the degradation of bradykinin, lysyl bradykinin and des-Arg9-bradykinin by the angiotensin converting enzyme. Bradykinin was cleaved at two sites to produce the pentapeptide Arg-Pro-Pro-Gly-Phe plus dipeptides Ser-Pro and Phe-Arg. Lysyl bradykinin was cleaved similarly to release the same dipeptides plus the hexapeptide Lys-Arg-Pro-Pro-Gly-Phe. The tripeptidase activity of ACE was observed when des-Arg9-bradykinin was digested. A single cleavage yielded the above pentapeptide plus Ser-Pro-Phe. Although des-Arg9-bradykinin was the most rapidly digested, when mixtures of des-Arg9-bradykinin and bradykinin or lysyl bradykinin were tested, virtually all of the bradykinin and most of the lysyl bradykinin was digested prior to the onset of digestion of des-Arg9-bradykinin. This was shown to be due to inhibition of des-Arg9-bradykinin cleavage by kinins and kinin-degradation products. The order in terms of potency was bradykinin greater than lysyl bradykinin greater than Ser-Pro much greater than Phe-Arg greater than Arg-Pro-Pro-Gly-Phe. The concentration of chloride ion was an important parameter which affected the rate of digestion of each substrate examined. des-Arg9-bradykinin was not digested by ACE in the absence of sodium chloride and the rate of digestion increased as the chloride concentration was increased to 100-150 mM. On the other hand, increasing NaCl concentration was inhibitory for bradykinin digestion. The rate of Lys-bradykinin digestion was increased from 0 to 1 mM NaCl and decreased thereafter up to physiologic concentration. A half-maximal rate was seen at 100-150 mM NaCl compared to no salt. Of the divalent cations examined, cupric ion inhibited further digestion of des-Arg9-bradykinin at physiologic concentrations. Our data indicate that the rate of degradation of kinins and the nature of the stable final cleavage products in plasma or serum (studied in vitro) are dependent upon the effects of chloride ion, metal ions, and the kinetic effects of multiple metabolites produced by at least two kininases.
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PMID:Studies of the digestion of bradykinin, Lys-bradykinin, and des-Arg9-bradykinin by angiotensin converting enzyme. 301 4

A sensitive radioimmunoassay (RIA) capable of measuring either lisinopril (1-[N2-[(S)-1-carboxy-3-phenylpropyl]-L-lysyl] -L-proline) or enalaprilat (1-[N-[(S)-1-carboxy-3-phenylpropyl]-L-alanyl] -L-proline), the active metabolite of enalapril has been developed. A suitable antiserum was raised against an immunogen prepared from conjugation of lisinopril, the lysyl analogue of enalapril, with succinoylated keyhole limpet hemocyanin. A novel radiotracer was also prepared for use in the assay by acylation of the epsilon amine group on the lysyl side chain of lisinopril with N-succinimidyl [2,3-3H]propionate. The antiserum was used at a final dilution of 1:44,500 and the sensitivity of the assay for enalaprilat was estimated at 2 pmol/mL plasma sample and 0.4 pmol/mL for lisinopril. Enalapril, the ethyl ester of enalaprilat, exhibited little cross-reactivity (0.005%), and several other compounds (captopril, proline, lysine, tyrosine, hippuric acid, and tryptophan) were found not to crossreact. In rabbits given a 2.03 mumol/kg iv dose of enalapril, plasma concentrations of enalaprilat were determined by the RIA technique and compared with an estimation of the enalaprilat concentrations derived from the extent of inhibition of plasma angiotensin converting enzyme (ACE). The plasma levels estimated by ACE inhibition were less than those obtained by the RIA in the first 45 min but were always greater in the samples taken after this time. Both assay methods showed that the conversion of enalapril to enalaprilat was rapid, and also indicated that there was initial rapid clearance of enalaprilat from the plasma.
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PMID:Radioimmunoassay for the quantitation of lisinopril and enalaprilat. 301 33

Angiotensin-converting enzyme (ACE; dipeptidyl carboxypeptidase, EC 3.4.15.1) from monkey brain was partially purified 274-fold with 4.5% yield. The optimum pH of the enzyme was 8.2, and its Km was 3.3 mM, with hippuryl-His-Leu as the substrate in 300 mM NaCl. Its molecular weight (Mr) was estimated to be approximately 260,000 by gel filtration on Sephadex G-200. On high-performance liquid chromatographic analysis, ACE hydrolyzed neo-kyotorphin Thr-Ser-Lys-Tyr-Arg) with liberation of kyotorphin (Tyr-Arg), the [Met]enkephalin releaser. ACE also converted [Met]enkephalin-Arg6-Phe7 to [Met]enkephalin; then the enzyme slowly hydrolyzed the resulting [Met]enkephalin. The Km values of the enzyme for neo-kyotorphin and [Met]enkephalin-Arg6-Phe7 were 0.58 and 0.30 mM respectively. Thus, brain ACE may have a role in the formation of kyotorphin and [Met]enkephalin from their precursors but has little part in [Met]enkephalin degrading processes.
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PMID:Hydrolysis of neo-kyotorphin (Thr-Ser-Lys-Tyr-Arg) and [Met]enkephalin-Arg6-Phe7 by angiotensin-converting enzyme from monkey brain. 302 52

In serum of 530 patients with various lung diseases and in 70 healthy control subjects, kininase I (E.C. 3.4.17.3) and kininase II (E.C. 3.4.15.1) were measured spectrophotometrically using hippuryl-L-arginine for estimation of kininase Ia (KIa), hippuryl-L-lysine for kininase Ib (KIb) and hippuryl-L-histidyl-L-leucine for kininase II (KII). KIa and KIb were significantly elevated (p less than 0.02) in lung cancer and sarcoidosis, compared to tuberculosis and healthy controls. There was an increase (p less than 0.05) in lung cancer in relation to sarcoidosis, chronic obstructive bronchitis, tuberculosis, pulmonary fibrosis and healthy control subjects. KII was significantly elevated in sarcoidosis (p less than 0.0001). According to the histological types of lung cancer, no differences of KIa, KIb and KII have been found. The ratio KIa/KIb X KII was 2.3 in lung cancer and 6.7 in the group with sarcoidosis. These results show that the determination of kininases can be used for diagnosis of lung diseases.
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PMID:Kininase I and II activities in serum of patients with lung diseases. 302 81

Stopped-flow radiationless energy-transfer kinetics have been used to examine the effects of chloride on the hydrolysis of Dns-Lys-Phe-Ala-Arg by angiotensin converting enzyme. The kinetic constants for hydrolysis at pH 7.5 and 22 degrees C in the presence of 300 mM sodium chloride were KM = 28 microM and kcat = 110 s-1, and in its absence, KM = 240 microM and kcat = 68 s-1. The apparent binding constant for chloride was 4 mM, and the extent of chloride activation in terms of kcat/KM was 14-fold. The effects of chloride on the pre-steady-state were examined at 2 degrees C. In the presence of chloride, two distinct enzyme-substrate complexes were observed, suggesting multiple steps in substrate binding. The initial complex was formed during the mixing period (kobsd greater than 200 s-1) while the second complex was formed much more slowly (kobsd = 40 s-1 when [S] = 5 microM and [NaCl] = 150 mM). Strikingly, in the absence of chloride, only a single, rapidly formed enzyme-substrate complex was observed. These results are consistent with a nonessential activator kinetic mechanism in which the slow step reflects conversion of an initially formed complex, (E X Cl- X S)1, to a more tightly bound complex, (E X Cl- X S)2.
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PMID:Observation of a chloride-dependent intermediate during catalysis by angiotensin converting enzyme using radiationless energy transfer. 303 49

Effects of the pentapeptide renin inhibitor (RI-78; Phe(4Cl)-Phe-Val-Tyr-Lys-NH2) and the angiotensin converting enzyme (ACE) inhibitor (teprotide) on mean arterial pressure (MAP) were examined in conscious monkeys (M. fascicularis). In salt depleted normotensive monkeys with a MAP of 95 +/- 4 mmHg and plasma renin activity (PRA) of 15.9 +/- 2.7 ngAI/ml/h, a bolus injection of a dose of 375 micrograms/kg of RI-78 caused a prompt hypotensive effect. Maximal hypotensive action was seen within 1 min, and MAP returned to the basal level within 15 min. With this dose, MAP was reduced by 20 +/- 6 mmHg. Teprotide (1 mg/kg) decreased MAP and reached a nadir after 13 min. There was no significant difference between maximal hypotensive responses seen with RI-78 (375 micrograms/kg) and with teprotide (1 mg/kg). Hypotensive effects of RI-78 and teprotide were also examined in acute renal hypertensive monkeys with a MAP of 125 +/- 5 mmHg and a PRA of 27.1 +/- 5.7 ngAI/ml/h. Again, similar hypotensive effects were observed. We conclude that antihypertensive effect of RI-78 is comparable to that seen with teprotide.
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PMID:Hypotensive effects of the renin inhibitor (RI-78) and the converting enzyme inhibitor (teprotide) in conscious monkeys. 303

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