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)

All four components of the kallikrein-kinin system--kininogens, tissue kallikreins, kinins, and kininases--have been found in human male genital secretions. Kinins are continuously released from seminal plasma kininogens through limited proteolysis by kininogenases like tissue kallikrein from prostate and sperm acrosin. Kinins are the terminal effectors of the kallikrein-kinin system and increase sperm motility and sperm metabolism at nanomolar concentrations. Recent investigations indicate that these effects are possibly mediated by a specific sperm membrane integrated bradykinin receptor, subtype B2. The two major kininase that are present in seminal plasma are kininase II and neutral metallo-endopeptidase. Kininase II, which is identical with angiotensin-converting enzyme, is also involved in the renin-angiotensin system as it converts angiotensin I into angiotensin II and thus is the connecting enzyme of both systems. Apart from the observed effects of kinins on sperm motility, the kallikrein-kinin system is thought to be involved in the regulation of spermatogenic functions of the testis: in the rat, kallikrein activates Sertoli cell function, increases the relative number of spermatocytes and the [3H] thymidine incorporation of testicular tissue, enhances glucose-intake, and increases testicular blood flow. Clinical trials showed that systemic administration of kallikrein may be particularly useful for treatment of infertile men suffering from asthenozoospermia and/or oligozoospermia. During kallikrein therapy, the number of spermatozoa and both quantitative and qualitative sperm motility increased, and a significant improvement of the conception rate was achieved. An increased sperm number was also observed after application of the specific kininase II inhibitor captopril.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Possible effects of the kallikrein-kinin system on male reproductive functions. 131 46

This study was aimed at evaluating the factors responsible for the marked renal hemodynamic effect of 6-day treatment with lisinopril. Blood pressure (BP) and renal blood flow (RBF) were monitored in six groups of rabbits. Animals treated with lisinopril for 6 days (Group I) had lower BP (77 +/- 3 mm Hg) than normal controls (Groups II/III, 106 +/- 3 mm Hg, P < .05) or those given lisinopril acutely (Group IV, 93 +/- 8 mm Hg, P < .05). In addition, RBF was higher in Group I (81 +/- 2 ml/min) than in Groups II/III (54 +/- 5 ml/min, P < .05) or Group IV (66 +/- 8 ml/min, P < .05). Intrarenal arterial infusion of a B2 bradykinin receptor antagonist, D-Arg-O-[Hyp-3-Thi-5,8-D-Phe-7]bradykinin, had no effect on either BP or RBF in Group I. Administration of lisinopril for 6 days also resulted in attenuation of the vasoconstrictor responses to renal nerve stimulation (Group V). Intravenous infusion of D-Arg-O-[Hyp-3-Thi-5,8-D-Phe-7]bradykinin had no effect on the responses to nerve stimulation in lisinopril-treated rabbits (Group V) or their controls (Group VI). Moreover, D-Arg-O-[Hyp-3-Thi-5,8-D-Phe-7]bradykinin given i.v. did not alter the BP or RBF in Groups V and VI. The results indicate that angiotensin converting enzyme inhibition over a 6-day period is more effective than acute inhibition in lowering BP and dilating the renal vascular bed. The use of bradykinin antagonists did not indicate kinin involvement in the long-term effect of lisinopril on BP and RBF.
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PMID:Enhanced blood pressure and renal hemodynamic effect of chronic versus acute lisinopril administration in the rabbit. 132 3

The effects of ACE-inhibitors on bradykinin metabolism and bradykinin-induced endothelium-dependent relaxation were studied in isolated coronary arteries and endothelial cells in culture. The results suggest that ACE-inhibitors affect coronary vascular tone by at least two endothelium-dependent and bradykinin-mediated mechanisms: First, ACE-inhibitors decrease endothelial bradykinin degredation which is accompanied by an augmented bradykinin mediated endothelium-dependent relaxation. Second, ACE-inhibitors evoke endothelium-dependent relaxations in coronary arteries stimulated with threshold concentrations of bradykinin, which cannot be attributed to an inhibition of bradykinin degradation. The effect appears to represent a new mechanism which may be based on an interaction of the bradykinin receptor and the angiotensin converting enzyme on the cellular level.
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PMID:Effects of converting enzyme inhibition on endothelial bradykinin metabolism and endothelium-dependent vascular relaxation. 133 49

Inhibitors of the angiotensin-converting enzyme (ACE = kininase II) by definition have a dual action: prevention of angiotensin II generation and inhibition of kinin degradation. Although the first mechanism is generally accepted, it may not by itself be sufficient to explain the acute blood pressure-lowering action of these compounds. Studies in experimental and clinical hypertension, including the use of selective angiotensin II and bradykinin receptor antagonists, suggest additional vasodilator, non-renin-dependent mechanisms in their action on blood flow and blood pressure. Inhibition of kinin degradation by ACE inhibitors will amplify kinin-mediated reactions on local vessel tone, in particular, if kinin generation is stimulated or this situation is experimentally mimicked by addition of exogenous bradykinin. The acute blood pressure-lowering action of ACE inhibitors is inhibited by indomethacin-type cyclooxygenase inhibitors, suggesting a contribution of bradykinin-induced release of vasodilator prostaglandins to their action. Bradykinin stimulates the phospholipase-dependent release of arachidonic acid from membrane phospholipids, allowing for subsequent generation of its metabolites, the eicosanoids. This stimulation is receptor-mediated and involves one or more types of B2 receptors, coupled via G-proteins to intracellular messenger systems that control cytosolic calcium levels. Bradykinin-induced changes in vessel tone are transient, caused by a rapidly developing tachyphylaxis at the receptor level. The potent vasodilator action of systemic bradykinin administration is not consistently reflected in studies performed on isolated blood vessels. This is probably due to the indirect nature of kinin-mediated vasomotor responses, i.e., the release of vasoactive mediators, most notably the eicosanoids and endothelium-derived relaxing factor (EDRF).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Converting enzyme inhibitors and the interaction between kinins and eicosanoids. 169 63

Mean arterial pressure (BP) was measured in conscious, spontaneously hypertensive rats (SHR). Oral administration of the angiotensin I-converting enzyme inhibitor (ACEI) CGS 16617 significantly lowered BP. In contrast, the thromboxane synthetase inhibitor (TxSI) CGS 12970 lacked an antihypertensive action in SHR. When administered concurrently, the TxSI significantly potentiated the antihypertensive actions of the ACEI. Inhibition of thromboxane synthetase did not potentiate the antihypertensive actions of metoprolol or verapamil, indicating that a specific interaction exists between a TxSI and an ACEI. The antihypertensive actions of CGS 16617 also were potentiated by the cyclooxygenase inhibitor indomethacin, a result suggesting that CGS 12970 may enhance the action of CGS 16617 by inhibiting the action of vasoconstrictor prostaglandins produced after administration of an ACEI. The potentiation of the antihypertensive actions of CGS 16617 by CGS 12970 remained unaffected by either the kallikrein inhibitor aprotinin or a bradykinin receptor antagonist. Thus, although the interaction between an ACEI and a TxSI is a prostaglandin-dependent mechanism, it is not mediated by endogenous kinins. Inhibition of thromboxane synthetase significantly stimulated renin release and significantly attenuated the pressor response to exogenously administered angiotensin II. An increase in the dependency of BP upon the renin-angiotensin system and attenuation of the vascular actions of angiotensin II may serve to explain the potentiation of the antihypertensive action of ACEI after inhibition of thromboxane synthetase. The interaction between ACEI and TxSI was not restricted to SHR, because a TxSI potentiated the actions of an ACEI in both normotensive and deoxycorticosterone acetate/Na hypertensive rats.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Inhibition of thromboxane synthetase potentiates the antihypertensive action of an angiotensin-converting enzyme inhibitor by a prostaglandin-dependent but kinin-independent mechanism. 192 Jan 18

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

Angiotensin-converting enzyme kininase II reduces bradykinin metabolism in vitro and in vivo. However, consistent changes in circulating bradykinin levels after the angiotensin-converting enzyme inhibitor captopril have not been reported. The kallikrein-kinin system has been suggested to be a local hormonal system concerned with regional blood flow, and hence circulating levels may not reflect local tissue levels of kinins. Anesthetized dogs given captopril had a significant increase in urinary kinin excretion without a change in circulating bradykinin levels or in urinary kallikrein. These changes in renal kinins were accompanied by a decrease in blood pressure and renal vasodilation. The hypotension and renal vasodilation produced by captopril were not attenuated either by pretreatment with the angiotension receptor antagonist Sar1-Ileu8-angiotensin II or by reduction of endogenous prostaglandin production with indomethacin. Postischemic renal vasodilation after temporary renal artery occlusion was also associated with increased urinary kinin levels. These results demonstrate that captopril effectively inhibits renal angiotensin-converting enzyme and that the renal kallikrein-kinin system may play an important role in regulating the renal vasculature and may contribute to the renal hemodynamic effects of captopril. Many polypeptide hormone membrane receptors are self-regulated by endogenous tissue concentrations of the peptide hormone. Infusions of bradykinin into rats reduced specific bradykinin receptors. A similar decrease in bradykinin receptor numbers without change in receptor affinity was demonstrated after captopril administration. These results provide indirect evidence that angiotensin-converting enzyme/kininase inhibition by captopril increases local tissue concentration of kinins, which may contribute to the hypotensive effect.
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PMID:Effect of angiotensin-converting enzyme inhibition on circulating and local kinin levels. 612 71

In renal hypertensive rats with pressure overload left ventricular hypertrophy the angiotensin converting enzyme inhibitor ramipril, given in a high blood pressure lowering dose as well as in a low, non-antihypertensive dose, prevented and regressed left ventricular hypertrophy. These beneficial effects were abolished by coadministration of the specific bradykinin receptor antagonist (HOE 140) in the prevention--but not in the regression studies. Vascular function of rats with pressure overload left ventricular hypertrophy was impaired, whereas treated animals showed a reversal to normal. The angiotensin II subtype AT1 receptor antagonist, losartan, was barely active in the prevention, however markedly active in the regression of left ventricular hypertrophy. From these experimental studies in rats with pressure overload left ventricular hypertrophy and vascular dysfunction we conclude that inhibition of bradykinin degradation induced by ramipril may contribute to the antihypertrophic action during the prevention phase, whereas attenuation of angiotensin II formation may be more important during the regression period. In another model, the spontaneously hypertensive rat (SHR and stroke prone SHR)--a non-renal hypertensive model--cardiac left ventricular hypertrophy could be reduced by chronic high-dose ramipril treatment in prevention and regression studies, whereas the low dose regimen only reduced left ventricular hypertrophy in the regression experiments. In addition, both doses improved the myocardial capillary supply to the heart leading to improved function and metabolism. In comparison, vascular hypertrophy of the mesenteric artery could only be prevented by early-onset high dose treatment with the angiotensin converting enzyme inhibitor but not once hypertrophy has been established.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Experimental evidence for effects of ramipril on cardiac and vascular hypertrophy beyond blood pressure reduction. 764 9

1. The ability of bradykinin and its analogues to depolarize rat and mouse superior cervical ganglia was studied by use of in vitro grease-gap recording techniques, and the ability of antagonists selective for bradykinin receptor subtypes to block their effects was examined. 2. Bradykinin (3 microM) depolarized ganglia from both species, although the magnitude of the maximal response was less in mouse (15 +/- 5%, n = 7) than rat tissue (33 +/- 6%, n = 7), relative to muscarine (1 microM). 3. Interleukin 1 beta (30 u ml-1 for 18 h at 37 degrees C) increased the depolarization caused by bradykinin (3 microM) in mouse ganglia from 15% to 54% (P < 0.001, n = 12). Responses to the B1 receptor agonist, [des-Arg10]-kallidin (3 microM) were similarly potentiated but this was only detected after inhibition of peptidase activity with 10 microM captopril (4% to 35%, n = 5). 4. In ganglia from both species the rank order of agonist potency was bradykinin = [Lys0]-bradykinin >> [des-Arg10]-kallidin. However, like responses to [des-Arg10]-kallidin in mouse tissue, both the potency of bradykinin and the maximal depolarization achieved (EC50 = 912 nM; 80%, n = 11) was enhanced following inhibition of angiotensin converting enzyme with 10 microM captopril (EC50 = 50 nM; 135%, n = 4). 5. Responses to bradykinin were selectively antagonized by the B2 receptor antagonist, Hoe 140 but not by the B1 antagonist, [Leu8]-bradykinin1-8. From Schild analysis the pA2 value for Hoe 140 in mouse tissue was 9.65, although the slope of the regression line was significantly greater than unity, indicating non-competitive kinetics (slope = 1.88 +/- 0.18, n = 9). The depolarization caused by [Lys0]-bradykinin was also antagonized by Hoe 140 (3 nM).6. Thus the predominant bradykinin receptor in mouse superior cervical ganglia is compatible with a B2 subtype. Furthermore the depolarizations caused by B1 and B2 agonists in this tissue can be increased following exposure to interleukin l beta, and by blocking peptide degradation with captopril.
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PMID:Bradykinin receptors in mouse and rat isolated superior cervical ganglia. 767 Jul 39

The heart is composed of highly differentiated cardiac myocytes, which constitute parenchyma, and stroma or connective tissue. Fibrillar collagen turnover in the heart and its valve leaflets, in particular, is dynamic and essential to tissue repair. Emerging evidence further suggests connective tissue is a metabolically active entity, where peptide hormones are generated and degraded and, in turn, these peptides regulate collagen turnover. This concept arose from quantitative in vitro autoradiography using an iodinated derivative of lisinopril (125I-351A) as ligand to localize angiotensin converting enzyme (ACE) binding density within the heart. A heterogeneous distribution was found: low-density ACE binding within atria and ventricles; high ACE binding density at sites of high collagen turnover, such as valve leaflets, adventitia, and fibrous tissue of diverse etiologic origins. ACE-producing cells at these latter sites were identified by monoclonal ACE antibody. They included valvular interstitial cells (VIC) and fibroblast-like cells each of which also contained alpha-smooth muscle actin and the transcript for type I collagen (in situ hybridization). Substrate utilization in cultured VIC was found to include angiotensin I and bradykinin. Angiotensin II and bradykinin receptor-ligand binding was observed in VIC and at fibrous tissue sites. Connective tissue ACE is independent of circulating angiotensin II. In vivo, fibrous tissue formation is attenuated by ACE inhibition or antagonism of AT1 receptor. Angiotensin II and bradykinin are stimulatory and inhibitory, respectively, to cultured adult cardiac fibroblast collagen synthesis suggesting a paradigm of reciprocal regulation to fibroblast collagen turnover. Stroma and its cellular constituents represent a dynamic metabolic entity that regulates its own peptide hormone composition and turnover of fibrillar collagen. These findings may provide insights that could be used to advantage to either promote or forestall fibrous tissue formation depending on the nature of cardiovascular disease.
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PMID:Connective tissue and repair in the heart. Potential regulatory mechanisms. 775 73


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