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)

This study was undertaken to verify the activity of plasma kininases in hypertension. Male Wistar rats (WIS) were used and three models of experimental hypertension were studied: spontaneously hypertensive rats (SHR), renal hypertensive rats, made according to the method of Goldblatt, DOCA-salt hypertensive rats. Normal Wistar rats, nephrectomized rats and sodium-loaded rats were used as control groups. Plasma from these animals was used to evaluate the kininase activities: kininase II activity (KII) was measured by the hydrolysis of hippuryl-L-histidyl-L-leucine (HHL); kininase I activity (KI) was measured by the hydrolysis of hippuryl-L-arginine (HLA) (CN1 activity) and of hippuryl-L-lysine (HLL) (CN2 activity). The three enzyme activities were characterized by their kinetic constants and the inhibitory pattern of various inhibitors. In normal WIS rats, hydrolysis of HHL proceeds with a Km of 2.55 +/- 0.22 mM and at a Vmax of 0.357 +/- 0.017 mumol/min/ml; the enzyme is inhibited by EDTA, 0-phenanthroline and captopril. HLA has a Km of 6.93 +/- 0.32 mM and a Vmax of 0.748 +/- 0.019 mumol/min/ml while the Km and Vmax values of HLL are 35.8 +/- 1.52 mM and 13.11 +/- 0.40 mumol/min/ml. The hydrolysis of both substrates is inhibited by EDTA, 0-phenanthroline and MERGETPA. KII activity is decreased in WKY and SHR rats (Vmax = 0.241 +/- 0.014 and 0.262 +/- 0.011 mumol/min/ml, respectively). In renal hypertensive rats and DOCA-salt hypertensive rats, the KII activity remained unchanged. CN1 activity was increased in 1K, 1C hypertensive animals (Vmax = 0.866 +/- 0.221 mumol/min/ml) and in DOCA-salt hypertensive rats (Vmax = 1.119 +/- 0.049 mumol/min/ml).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Activity of plasma kininase I and kininase II in hypertensive rats]. 217 85

Angiotensin I converting enzyme (kininase II; ACE) has been described as a peptidyldipeptidase or dipeptidyl carboxypeptidase (EC 3.4.15.1) of the pulmonary endothelial cells, which liberates angiotensin II or inactivates kinins. However, ACE has a much wider distribution and substrate specifity; it is concentrated in human epithelial cells (e.g. brush border of the kidney, placenta, intestine and choroid plexus), neuroepithelial cells (subfornical organ, pallidonigral dendrites, median eminence) and male genital tract (testes, prostate, epididymides, seminal plasma). Its substrates include enkaphalins, the C-terminal extended proenkephalins and a protected chemotactic tripeptide. Recent, mostly in vitro studies with purified ACE, indicate that ACE also cleaves peptides by other than peptidyldipeptidase action. Homogeneous human ACE inactivated substance P in spite of its blocked C-terminus (Met11-NH2) primarily by releasing the C-terminal tripeptide. A blocked C-terminal tripeptide, Arg-Pro-Gly-NH2 was also released from the luteinizing hormone releasing hormone (LHRH). Although ACE shares many properties with carboxypeptidases, it surprisingly cleaves the N-terminal tripeptide greater than Glu1-His2-Trp3 from LHRH. Because human ACE hydrolyzes a variety of peptide hormones, actions of its inhibitors may go well beyond blocking the conversion of angiotensin I.
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PMID:The broad substrate specificity of human angiotensin I converting enzyme. 244 Jun 24

Zofenopril calcium (one-half calcium salt) is a prodrug ester analog of captopril whose biological effects are manifested by its active component, SQ 26,333. Because of the relative insolubilities of both zofenopril calcium and SQ 26,333, zofenopril potassium salt and SQ 26,703, the arginine salt of the active ACE (angiotensin I converting enzyme) inhibitory moiety of zofenopril, were employed in many of the following studies. The in vitro and in vivo pharmacological effects of zofenopril have been evaluated and comparisons have been made to captopril. In vitro, SQ 26,703 was more potent than captopril as an inhibitor of rabbit lung ACE (IC50 = 8 vs. 23 nM). SQ 26,703 was also a potent inhibitor of angiotensin I (AI)-induced contractions (EC50 = 3 nM) and a potentiator of bradykinin-induced contractions (EC50 = 1 nM) of isolated guinea pig ileum, while it had no effect on the inotropic effects of angiotensin II, BaCl2, PGE1, histamine, serotonin, or acetycholine in the same tissue, signifying that zofenopril is a specific inhibitor of ACE. In vivo, the potency of SQ 26,703 was equal to or greater than that of captopril as an inhibitor of an AI pressor response when given intravenously to rats, dogs, and monkeys. After oral administration of equimolar doses, zofenopril was the more effective and longer lasting ACE inhibitor in all three species. In SHR, doses of 6.6 and 22.0 mg/kg, p.o. lowered pressure by 20 and 33 mm Hg, respectively, while 30 mg/kg of captopril lowered pressure by 25 mm Hg.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Preclinical pharmacology of zofenopril, an inhibitor of angiotensin I converting enzyme. 248 83

A peptidyl dipeptidase-4 (bacterial PDP-4) was purified to near homogeneity from a supernatant of Pseudomonas maltophilia extracellular medium. Bacterial PDP-4 is a single-polypeptide-chain enzyme, 82 kDa, with an alkaline isoelectric point. Peptides susceptible to hydrolysis by bacterial PDP-4 include angiotensin 1, bradykinin, enkephalins, atriopeptin 2, and smaller synthetic peptides. N-acylated tripeptides are hydrolyzed, but free tripeptides are not. A free carboxy terminus is required for hydrolysis. Peptides with ultimate and penultimate Pro residues are not hydrolyzed. The enzyme does not require an anion for activity. Bacterial PDP-4 was inhibited by EDTA and the dipeptide Phe-Arg. Thiorphan was an inhibitor only at levels well above those required for inhibition of neutral metalloendopeptidase (NEP), an enzyme for which thiorphan is specific. A second NEP and thermolysin inhibitor, phosphoramidon, did not inhibit bacterial PDP-4. The potent angiotensin-converting enzyme inhibitor lisinopril was not inhibitory. Bacterial PDP-4 is distinguished from a similar enzyme from Escherichia coli, which is not susceptible to EDTA inhibition, and one from Corynebacterium equi, which hydrolyzes free tripeptides. These data indicate that the bacterial PDP-4 catalytic site is unlike those of other enzymes that function either wholly or in part as peptidyl dipeptidases.
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PMID:A peptidyl dipeptidase-4 from Pseudomonas maltophilia: purification and properties. 253 48

We have examined pulmonary effects of bradykinin (Bk) in vivo and in vitro in guinea pigs and their potential inhibition by antagonists of Bk B1 and B2 receptors. Bk was a potent bronchoconstrictor in vivo and caused contractions of isolated, epithelium-denuded trachealis. D-Arg[Hyp3,D-Phe7]-Bk (NPC567) and D-arg[Hyp3,Thi5,8,D-Phe7]-Bk (NPC349), B2 receptor antagonists, were weak inhibitors of Bk-induced bronchoconstriction in vivo and were virtually inactive as antagonists of Bk-induced airway smooth muscle contraction. Several other B2 antagonists as well as B1 antagonist, des-Arg9-[Leu8]-Bk, did not inhibit Bk-induced tracheal contraction. The B1 receptor agonist des-Arg9-Bk was without effect on tracheal tone. Tracheal responses to Bk were unaffected by antagonists of muscarinic, histamine, serotonin, and catecholamine receptors. The inability of the antagonists to inhibit Bk is unlikely to be due to their degradation, because NPC567 was only weakly active in the presence of inhibitors of kininase I (EC 3.4.11.2), kininase II (EC 3.4.15.1), and neutral endopeptidase (EC 3.4.24.11). These studies were corroborated by ligand binding experiments in guinea pig and ovine airways. In [3H]Bk binding, the Bk antagonists had no effect in guinea pig trachea, slightly displaced [3H]Bk in ovine trachea, and inhibited approximately 60% of total specific binding in lung. des-Arg9-[Leu8]-Bk and several other agents, including atropine, neurokinin A, substance P, and vasoactive intestinal peptide, had no effect on lung Bk binding. Bk and its analogs were not degraded during the binding assay. These data suggest that pulmonary tissue, particularly in the large airways, contains a novel Bk binding site, a B3 receptor, which may be involved in Bk-induced bronchoconstriction.
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PMID:Evidence for a pulmonary B3 bradykinin receptor. 254 44

The bradykinin receptor antagonists [D-Phe7]bradykinin, D-Arg[Hyp3,D-Phe7]bradykinin and D-Arg[Hyp3,Thi5,8,D-Phe7]bradykinin were tested for their ability to serve as substrates for kininase II (angiotensin converting enzyme) purified from rabbit lung. By HPLC, the peptides were not measurably degraded over 30 minutes. Under identical conditions, bradykinin was completely degraded to bradykinin (1-7). When hippuryl-His-Leu was used as a substrate for kininase II, the D-Phe7-substituted bradykinins acted as weak noncompetitive inhibitors. While the peptides were poor substrates for kininase II, they were short-lived when injected intravenously. D-Arg[Hyp3,D-Phe7]bradykinin was completely degraded to small fragments in less than 2 minutes. In diluted serum in vitro, a single product was observed with elution consistent with loss of arginine, suggestive of metabolism by kininase I.
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PMID:D-Phe7-substituted peptide bradykinin antagonists are not substrates for kininase II. 254 27

Since angiotensin converting enzyme (ACE) metabolizes bradykinin, the hypotensive effect of ACE inhibitors could be partly due to an increased bradykinin activity. We therefore investigated the influence of HOE K86-4321 [D-Arg-(Hyp2-Thi5,8-DPhe7)-bradykinin], a selective bradykinin-2 receptor antagonist, on the effects of enalaprilat (0.3 and 3.0 mg/kg) and zofenoprilat (0.1 and 1.0 mg/kg) on the heart rate, mean arterial blood pressure, cardiac output and total peripheral resistance in rats. Both enalaprilat and zofenoprilat reduced mean arterial pressure (from 110 +/- 7 to 85 +/- 6 and from 108 +/- 9 to 72 +/- 9 mmHg, respectively; P less than 0.05) and total peripheral resistance (from 515 +/- 35 to 413 +/- 29 and from 495 +/- 45 to 310 +/- 25 x 10(-3) mmHg/litre per min per kg, respectively; P less than 0.05); the heart rate and cardiac output changed little. In the presence of HOE K86-4321, which by itself did not affect the haemodynamic variables measured, the effects of the two ACE inhibitors were significantly reduced. These results suggest that bradykinin-2 receptor-mediated vasodilation, although not involved in blood pressure regulation, influences the reduction in blood pressure induced by enalaprilat and zofenoprilat in normotensive rats. Furthermore, at comparable ACE-inhibiting doses, zofenoprilat was more effective in reducing mean arterial pressure, which might be related to the presence of a sulphydryl group.
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PMID:The haemodynamic effects of two angiotensin converting enzyme inhibitors, enalaprilat and zofenoprilat, in the rat: evidence for the involvement of bradykinin. 256 Nov 43

To assess residues essential for catalysis by prokaryotic peptidyl dipeptidase-4, the enzyme was subjected to chemical modification by a series of reagents. Treatment with either tetranitromethane or N-acetylimidazole abolished catalytic activity. Hydroxylamine reversed inactivation by acetylimidazole only. Thus, an essential tyrosine is indicated. Enzymatic activity also was quenched by either trinitrobenzenesulfonic acid or diethyl pyrocarbonate. Inactivation by these reagents was not reversed by hydroxylamine. These data suggest an essential lysine. The competitive inhibitor Phe-Arg protected partially against inactivation by tetranitromethane, and fully against inactivation by N-acetylimidazole. The substrate Hip-Phe-Arg protected against inactivation by trinitrobenzenesulfonic acid and diethyl pyrocarbonate. Thus, both tyrosine and lysine are located at the catalytic site.
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PMID:Amino acid residues essential for catalysis by peptidyl dipeptidase-4 from Pseudomonas maltophilia. 256 25

This review updates some recent advances of a new and exciting developments in basic and clinical cardiology: a) the role, in the congestive heart failure (CHF), of the neurohormonal systems (NHS) which act to maintain circulatory homeostatic equilibrium, and b) the therapeutic implications of such a role. Six NHS, acting in CHF, have presently been identified: three of them induce vasoconstriction and sodium retention (sympathetic nervous systems, renin-angiotensin-aldosterone system and arginine-vasopressine system); the remaining three offset or balance the former ones, acting, therefore as "counterregulators" (prostaglandins--PGE2 and PGI2--, dopaminergic system and atrial natriuretic factor). Each one of these NHS influences the "compensatory" mechanisms of heart failure, acting on the target-organs both by direct effects and by interaction with other NHS; consequently, in heart failure, all the NHS are stimulated with the respective increase in the plasma levels of their agents. In asymptomatic stages of ventricular dysfunction the stimulation of the vasodilator-and-natriuretic systems appears to be predominant and able to maintain circulatory equilibrium. However, as the heart dysfunction increases and becomes symptomatic, the vasoconstrictor and sodium-retaining forces appear to predominate; this phenomenon becomes increasingly apparent as the functional class becomes more advanced. The hyperstimulation of these last systems has an extremely important role in the pathophysiology and clinical manifestations of congestive heart failure, as well as in its prognosis. Therefore, the attempts to correct these neurohormonal imbalance in patients with heart failure has a sound rational basis, not only to improve the symptoms and the exercise capacity but also to increase the survival of these patients. At the present time, amongst the potential pharmacological interventions acting on NHS in CHF, the blockade of the SRA system with ACE-inhibitors is generally accepted as the most feasible, the safer and the most effective therapeutic tool. In fact, its application has broadened from an earlier use in severe CHF to other symptomatic stages of cardiac failure, including the milder forms. In addition, preliminary data strongly suggest its unique usefulness in asymptomatic phases of ventricular dysfunction. Looking back at the medical therapy of heart failure, it can be concluded that we are starting a new era. Throughout 200 years (since the introduction of digitalis) the therapeutic goal in CHF has been the improvement of symptoms. With the developments of the present decade, a new and exciting goal is being offered to these patients, called by Packer "the second frontier", that is, the prolongation of their lives.
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PMID:[Neuro-hormonal mechanisms in heart insufficiency--from physiopathology to treatment]. 257 35

Bradykinin (BK) (Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9) was degraded by rat brain synaptic membranes at a rate comparable to that found for Met-enkephalin, but approximately 40 times the rate for vasopressin and oxytocin. The catabolic pathway for BK and its metabolites was elucidated through the use of high performance liquid chromatography for metabolite identification and peptidase inhibitors for blocking specific cleavage sites. BK was hydrolyzed at three sites: at the -Phe5-Ser6- bond by metalloendopeptidase 24.15, at the -Pro7-Phe8- bond by an apparently novel peptidyl dipeptidase, and at the -Phe8-Arg9 bond by a carboxypeptidase B-like enzyme. Each enzyme contributed about equally to BK degradation under the assay conditions used. Some of the resulting metabolites were further hydrolyzed: BK(1-8) to BK(1-7) + Phe by a DFP inhibitable prolyl carboxypeptidase-like enzyme, BK(1-8) to BK(1-5) + BK(6-8) by metalloendopeptidase 24.15, BK(1-7) slowly to BK(1-5) by a second peptidyl dipeptidase which was captopril inhibited, and Phe-Arg to Phe + Arg by a bestatin-inhibited dipeptidase. A number of properties of the individual enzymes were determined including sensitivity to a variety of peptidase inhibitors. These results provide a starting point for investigating the potential physiological role of each enzyme in BK function in the brain.
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PMID:Degradation of bradykinin and its metabolites by rat brain synaptic membranes. 260 54


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