Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0018801 (heart failure)
72,216 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The angiotensin-converting enzyme (ACE) is an integral part of two enzymatic cascades, one leading to the generation of angiotensin II and the other to the degradation of bradykinin. The great variety of cardiovascular effects mediated by these vasoactive peptides and the efficacy of ACE inhibitors in the treatment of hypertension and heart failure emphasize the prominent role of ACE in the cardiovascular system. Early in this decade convincing experimental evidence demonstrated the induction of this enzyme in several pathophysiological conditions, including myocardial infarction and left ventricular hypertrophy. In parallel, a deletion/insertion (D/I) polymorphism of the human ACE gene was characterized that is related to 14-50% of the interindividual variance in serum ACE activity. More recently this polymorphism has been implicated in the pathogenesis of a variety of cardiovascular disorders, including myocardial infarction, left ventricular hypertrophy, hypertension, diabetic and IgA nephropathy, carotid artery thickening, and lacunar cerebral stroke. However, the associations between the ACE D/I polymorphism and most of these conditions were found to be inconsistent when additional populations were investigated. This contribution reviews the current evidence on the relationship between the ACE D/I polymorphism and cardiovascular disease.
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PMID:Polymorphism of the angiotensin-converting enzyme gene and cardiovascular disease. 942 19

The endothelium controls vascular smooth muscle tone by secreting relaxing and contracting factors. There is a constant release of endothelium-derived relaxing factors (EDRFs) under basal conditions. In addition, the endothelium can increase the release of EDRFs in response to humoral stimulation by vasoactive substances such as acetylcholine or bradykinin. Under physiological conditions, the most important stimulus to the release of EDRFs is an increase in blood flow leading to increased shear stress on endothelial cells. Recent experimental studies raised the possibility that bradykinin plays an important role in the regulation of vascular tone at rest and during flow-stimulated conditions. Bradykinin is a very potent vasodilator that exerts its vasodilatory actions by causing endothelial release of nitric oxide, prostacyclin and/or a hyperpolarising factor [endothelium-derived hyperpolarising factor (EDHF)]. This concept is also supported by recent studies in humans demonstrating that bradykinin contributes to the regulation of coronary vascular tone under resting and flow-stimulated conditions. This mechanism has now been shown to be important in both human peripheral and coronary arteries. Angiotensin converting enzyme (ACE) inhibitors not only reduce angiotensin II, but also increase bradykinin levels, since the angiotensin converting enzyme is identical to kininase II, an enzyme that degrades bradykinin. This raises the possibility that beneficial vascular effects of ACE inhibitors may be related to increased availability of bradykinin. Indeed, we have recently shown that ACE inhibition improves flow-dependent, endothelium-mediated vasodilation and that this beneficial effect of ACE inhibition is bradykinin dependent. These findings raise the possibility that the beneficial effects of ACE inhibition in heart failure and coronary artery disease might be partly due to improved endothelial function.
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PMID:Endothelial function and bradykinin in humans. 942 44

In addition to being accepted therapy in hypertension and heart failure, ACE inhibitors may well offer a new dimension in anti-ischaemic therapy. Currently, anti-ischaemic properties have been demonstrated by ACE inhibitors in selected patient groups, including patients with left ventricular dysfunction with or without a direct temporal relationship with myocardial infarction. Anti-ischaemic effects of ACE inhibitors become apparent late after initiation of treatment and suggest a structural rather than a functional effect. Underlying mechanisms may include a reduction in ventricular dilatation and (abnormal) cardiac hypertrophy, leading to less myocardial oxygen demand and, possibly, improved subendocardial blood supply, and vasculoprotective effects, i.e. anti-atherosclerotic and antiremodelling properties, a beneficial effect on the fibrinolytic system and an improvement in abnormal endothelial vasodilator function. The latter aspect is most probably the pivotal mode of action where the anti-ischaemic profile of ACE inhibition is concerned. An improvement in endothelial dysfunction has been shown in patients with mild to moderate coronary artery disease [Trial on Reversing ENdothelial Dysfunction (TREND)]. It is of importance that, in both clinical experiments and human studies, the role of bradykinin appears central in the structural and functional cardiovascular effects of ACE inhibition. This is particularly true for the improvement of impaired endothelial function. Myocardial ischaemia evokes vasoconstrictor neurohormonal activation, which may lead to coronary vasoconstriction in diseased coronary segments. The subsequent abnormal endothelial function leads to diminished coronary flow and also increases systemic vasotone and afterload, thus unfavourably altering the myocardial oxygen supply/demand ratio. Under laboratory conditions, acute ACE inhibition counteracts this activation in humans. However, it is speculated that this anti-ischaemic mechanism may become operative and clinically important during long term oral ACE inhibitor therapy when endothelial function improves, and may subsequently protect against the vasoconstrictor effect of neurohormonal activation. As it is unlikely that the mechanisms mentioned above are only relevant in patients with ventricular dysfunction or heart failure, several large controlled trials are currently examining the long term anti-ischaemic and cardiovascular protective effects of ACE inhibition in patients at risk of a cardiovascular event [Heart Outcomes Prevention Evaluation study (HOPE)], with a normal cardiac function [Prevention of Events with ACE inhibition study (PEACE)] or in all patients with coronary artery disease irrespective of cardiac function [EUropean trial of Reduction Of cardiac events with Perindopril in stable coronary Artery disease (EUROPA)].
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PMID:Bradykinin-mediated cardiovascular protective actions of ACE inhibitors. A new dimension in anti-ischaemic therapy? 942 46

Dual inhibition of neutral endopeptidase 24.11 (NEP) and angiotensin-converting enzyme (ACE) offers the potential for improved therapy of hypertension and cardiac failure. S 21402-1 [(2S)-2-[(2S,3R)-2-thiomethyl-3-phenylbutanamido] propionic acid] is a sulfhydryl-containing potent inhibitor of both NEP (Ki = 1.7 nM) and ACE (Ki = 4.5 nM). S 21402-1 and the sulfhydryl-containing ACE inhibitor captopril were administered to rats by intraperitoneal injection (0, 0.3, 3, 30, 300 mg/kg). Urine was collected for 4 h; then plasma and kidneys were collected. The difference in NEP and ACE inhibition by S 21402-1 in vivo was greater than 1000-fold. All doses of S 21402-1 inhibited NEP, as indicated by plasma NEP activity, radioinhibitor binding to kidney sections, urinary sodium excretion and bradykinin-(1-7)/bradykinin-(1-9) ratio. However, only 300 mg/kg S 21402-1 inhibited ACE, as indicated by plasma angiotensin II/angiotensin I ratio, renin and angiotensinogen levels. Although S 21402-1 (30 and 300 mg/kg) inhibited renal NEP, as indicated by the bradykinin-(1-7)/bradykinin-(1-9) ratio in kidney, S 21402-1 had no effect on renal ACE, as indicated by the angiotensin II/angiotensin I ratio in kidney. Moreover, captopril was greater than 10-fold more potent than S 21402-1 as an ACE inhibitor in vivo. In separate experiments, the pressor response of anesthetized rats to angiotensin I showed more rapid decay in ACE inhibition by S 21402-1 than by captopril. These studies indicated that in vivo modification of S 21402-1 caused a much greater decrease in potency of ACE inhibition than NEP inhibition. Consequently, effective ACE inhibition by S 21402-1 required doses much higher than those required for NEP inhibition.
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PMID:Marked difference between angiotensin-converting enzyme and neutral endopeptidase inhibition in vivo by a dual inhibitor of both enzymes. 949 36

Available information from 1980 to 1997 on angiotensin converting enzyme (ACE) inhibitor-induced angioedema and its underlying mechanisms are summarised and discussed. The incidence of angioedema is low (0.1 to 0.2%) but can be considered as a potentially life-threatening adverse effect of ACE inhibitor therapy. This adverse effect of ACE inhibitors, irrespective of the chemical structure, can occur early in treatment as well as after prolonged exposure for up to several years. The estimate incidence is quite underestimated. The actual incidence can be far higher because of poorly recognised presentation of angioedema as a consequence of its late onset in combination with usually long term therapy. Also, a spontaneous reporting bias can contribute to an actual higher incidence of this phenomenon. The incidence can be even higher (up to 3-fold) in certain risk groups, for instance Black Americans. Treatment includes immediate withdrawal of the ACE inhibitor and acute symptomatic supportive therapy followed by immediate (and long term) alternative therapy with other classes of drugs to manage hypertension and/or heart failure. Preclinical and clinical studies for the elucidation of the underlying mechanism(s) of ACE inhibitor-associated angioedema have not generated definite conclusions. It is suggested that immunological processes and several mediator systems (bradykinin, histamine, substance P and prostaglandins) are involved in the pathogenesis of angioedema. A great part of all reviewed reports suggest a relationship between ACE inhibitor-induced angioedema and increased levels of (tissue) bradykinin. However, no conclusive evidence of the role of bradykinin in angioedema has been found and an exclusive role of bradykinin seems unlikely. So far, no clear-cut evidence for an immune-mediated pathogenesis has been found. In addition, ACE gene polymorphism and some enzyme deficiencies are proposed to be involved in ACE inhibitor-induced angioedema. Progress in pharmacogenetic and molecular biological research should throw more light on a possible genetic component in the pathogenesis of ACE inhibitor-associated angioedema.
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PMID:ACE inhibitor-induced angioedema. Incidence, prevention and management. 953 May 37

The endothelium controls vascular smooth muscle tone by secreting relaxing and contracting factors. There is a constant release of endothelium-derived relaxing factors(s) (EDRF) under basal conditions. In addition, the endothelium can increase the release of EDRF in response to humoral stimulation by vasoactive substances such as acetylcholine or bradykinin. Under physiological conditions the most important stimulus to the release of EDRF is an increase in blood flow, leading to increased shear stress on endothelial cells. Recent experimental studies have raised the possibility that bradykinin plays an important role in the regulation of vascular tone at rest and during flow-stimulated conditions. Bradykinin is a very potent vasodilator that exerts its vasodilatory actions by causing endothelial release of nitric oxide, prostacyclin and/or endothelium-derived hyperpolarizing factor. Recent studies in humans have demonstrated that bradykinin contributes to the regulation of coronary vascular tone under resting and flow-stimulated conditions. This mechanism has been shown to be important in humans in both peripheral and coronary arteries. Angiotensin-converting enzyme (ACE) inhibitors not only decrease angiotensin II but also increase bradykinin levels, since ACE is identical to kininase II, which degrades bradykinin. The beneficial vascular effects of ACE inhibitors may therefore be related to increased availability of bradykinin. Indeed, we have recently shown that ACE inhibition improves flow-dependent, endothelium-mediated vasodilation and that this beneficial effect is bradykinin-dependent. Our preliminary data also indicate that ACE inhibition improves endothelium-mediated vasodilation in patients with heart failure and coronary artery disease due to an enhanced availability of nitric oxide. These findings suggest that the beneficial vascular effects of ACE inhibition in heart failure may be due in part to improved endothelial function.
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PMID:Effect of ACE inhibition on endothelial dysfunction in patients with chronic heart failure. 971 56

I have shown that cardiac sympathetic afferent stimulation by epicardial application of bradykinin (BK) was significantly enhanced in pacing-induced heart failure (HF) dogs. This enhancement appeared to be mediated by prostaglandins. The present study was to determine whether nitric oxide is involved in this enhancement. Under alpha-chloralose (100 mg/kg iv) anesthesia, the renal sympathetic nerve activity (RSNA) response to BK was determined in 15 HF and 15 sham dogs in the sinoaortic-denervated and vagotomized state. The RSNA response to BK was significantly enhanced in HF. This enhanced RSNA response to BK was significantly reduced in the HF dogs after administration of the cycloxygenase inhibitor indomethacin (5 mg/kg iv), but no significant change was found in the sham group. In contrast, RSNA responses to BK were significantly reduced in the sham dogs after administration of the nitric oxide synthase inhibitor NG-nitro-L-arginine methyl ester (L-NAME, 30 mg/kg iv), but no significant change was found in the HF group. These data suggest that the RSNA response to BK is mediated by nitric oxide to a large degree in the normal state but is primarily mediated by prostaglandins in the HF state.
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PMID:Cardiac sympathetic afferent stimulation by bradykinin in heart failure: role of NO and prostaglandins. 972 80

Arterial tone and water-electrolyte homeostasis are regulated by several peptides, including angiotensin II (AII), bradykinin (BK), atrial natriuretic peptide (ANP) and endothelins (ETs). Changing the concentrations of these peptides in the plasma, tissue, or urine by decreasing the levels of angiotensin II and endothelins and increasing BK and ANP concentrations, is one way of modulating the hemodynamic load. The metabolism of these peptides in essentially controlled by three enzymes, angiotensin-converting enzyme (ACE), neutral endopeptidase (NEP), and endothelin converting enzyme (ECE), which all belong to the group of zinc metallopeptidases. Inhibition of these peptidases by a single compound (a dual inhibitor) that inhibits at once angiotensin II formation and BK and ANP inactivation, causes vasodilatation with reduction in blood pressure with reduction in blood pressure and increases natriuresis. The design of these inhibitors has often be relied on structure-activity studies, based on active-site models derived from structural data on thermolysin (TLN). The results of a large number of pharmacological experiments and those issued from some clinical studies using selective or mixed inhibitors show that in spontaneously hypertensive rats, dual ACE/NEP inhibitors such as S21,402 produce dose-related decreases (-15 to -40 mmHg) in mean arterial pressure and reductions in left ventricular hypertrophy and cardiac size. These compounds produce also an increase in urinary levels of BK, ANP and cGMP associated with enhanced urine output and sodium excretion. Moreover inhibition of NEP appears to improve the cardio- and reno-protective effects resulting from ACE inhibition and could also reduce hypertrophy of vascular walls. Inhibition of ECE seems to result in a weak reduction in blood pressure, an effect which could be emphasized by using dual ECE/ACE or ECE/NEP inhibitors. According to these results mixed dual inhibitors could be of great interest for the treatment of severe hypertension and chronic heart failure. Potent triple inhibitors blocking ACE, NEP and ECE could also be developed.
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PMID:Cell surface metallopeptidases involved in blood pressure regulation: structure, inhibition and clinical perspectives. 976 15

The natriuretic peptide (NP) system is one of the most important systems regulating blood pressure and body-fluid homeostasis. The biological activities of the system are determined by the NPs and the receptors, which are comprised of three subtypes: NP-AR and NP-BR related to biological activities and NP-CR related to the clearance of NP. We focused our studies on the receptor subtypes. In hypertensive rats (SHR-SP/Izm, DOCA/salt), NP-AR was upregulated and NP-CR was downregulated. The ACE inhibitor derapril, but not the Ca2+ blocker manidipine, normalized the upregulated NP-AR, but the effect was completely abolished by the bradykinin beta 2-receptor antagonist, suggesting that bradykinin regulates the vascular NP-AR. The AT1 antagonist TCV-116, but not manidipine, reversed the downregulated NP-CR. Ang II decreased NP-CR in cultured aortic smooth muscle cells. These results suggest that upregulation of NP-AR and downregulation of NP-CR with the increased plasma NPs counteract hypertension by enhancing the action of NP. A beta-blocker (carvedilol) potentiated the hypotensive action of NPs by increasing plasma NPs and enhancing the vascular response to NPs via downregulation of the vascular and lung NP-CR. The newly found mode of actions could be related to its anti-heart failure effect. In genetically hyperglycemic Wistar fatty rats, vascular NP-BR and NP-AR were upregulated. Since plasma ANP and vascular CNP were significantly increased, the local CNP/NP-BR system as well as the systemic ANP/NP-AR system may play an important role in counteracting vascular remodeling in diabetes mellitus. All these observations provide in vivo evidence for the pathophysiological significance of the receptor subtype of the NPs.
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PMID:[Pathophysiological significance of the natriuretic peptide system: receptor subtype as another key factor]. 979 68

During ischaemia, both the circulating renin-angiotensin system and the local angiontensin converting enzyme are activated. The circulating renin-angiotensin system has a short-term role in the regulation of the cardiovascular system. Its aim is to restore blood pressure and cardiac homeostasis. Activation of the local system causes long-term regulation of cardiovascular homeostasis via sustained activation of local angiotensin and the gradation of bradykinin. This results in the secondary permanent structural changes that underline many aspects of coronary artery disease. Recently it has been shown that ACE inhibition is useful in the early and late phase of myocardial infarction. ACE inhibitors have been shown to reduce in vitro vascular hypertrophy and attenuate arteriolosclerosis and to maintain endothelial function. Interestingly, unexpected data from trials on heart failure have shown that patients receiving ACE inhibitors have a reduced incidence of infarction, hospitalization for cardiovascular disease and the need for coronary artery bypass surgery or angioplasty. As a consequence, several trials have been designed to assess the effect of ACE inhibition on the progression of coronary artery disease, as well as on its morbidity and mortality. The EUropean trial on Reduction Of cardiac events with Perindopril in stable coronary Artery disease (EUROPA) is one of these. This article summarised a number of independent and complementary mechanisms and points to the role played by ACE and ACE inhibition in coronary artery disease. In particular it considers the possibility that ACE inhibition improves endothelial function, exerts anti-atherogenic and anti-proliferation activity and modulates sympathetic activity.
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PMID:Effect of ACE inhibition on myocardial ischaemia. 979 38


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