UMLS:C0018801 - FACTA Search

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Query: UMLS:C0018801 (heart failure)
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The renin-angiotensin system is critical for regulating extracellular fluid volume and blood pressure. Angiotensin II, the active peptide hormone produced by the renin enzymatic cascade, sustains vascular volume and blood pressure by constricting vessels, stimulating adrenal aldosterone secretion, increasing renal tubular sodium absorption, activating the sympathetic nervous system, and increasing cardiac contractility. These actions are a disability in the pathophysiologic states of hypertension and congestive heart failure (CHF), however, since reactive increases in renal renin and angiotensin II stimulate sympathetic activity and renal sodium retention, leading consequently to circulatory volume over-load. The actions of angiotensin II are mediated by its interactions with specific cell-surface angiotensin II receptors, namely, AT1 and AT2; most cardiovascular actions of angiotensin II come from its interaction with the AT1 receptor. Angiotensin-converting enzyme (ACE) inhibitors and angiotensin-II-receptor blockers antagonize the actions of the renin-angiotensin axis, neutralizing its effects on hypertension and heart failure. Losartan is the first oral, nonpeptide, selective AT1-receptor blocker to be approved. Clinical trials show it to be effective and well tolerated as therapy for hypertension and CHF. Data obtained thus far suggest ACE inhibitors and AT1-receptor blockers have similar efficacy for treating these conditions, but the receptor blockers appear to produce fewer adverse effects. Whether the sustained increase in angiotensin II concentrations after AT1-receptor antagonism produces deleterious effects is not known. The concern is that these high levels may stimulate unblocked AT2 receptor; the effect of that stimulation may not be important, however.
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PMID:Angiotensin receptors: physiology and pharmacology. 763 61

Angiotensin II (Ang II) receptor heterogeneity is currently defined by the new subtype-selective agents, losartan (AT1) and PD123177 (AT2). Although both subtypes have been cloned and sequenced, only the AT1 receptor has been shown to have an important physiological or pathophysiological role. AT1 and AT2 receptors are found in both normal and failing cardiac tissue. They are found on myocytes, endothelial cells, fibroblasts, coronary arterial smooth muscle cells, and peripheral sympathetic nerves. The AT1 receptors mediate virtually all of the effects of Ang II in myocytes even though cardiac tissue may contain over 50% AT2 sites. In endothelial cells, functional responses are predominately AT1. In fibroblasts, preliminary data suggest that AT2 receptors may be involved in collagen synthesis. In isolated tissue, Ang II has a limited positive inotropic effect in atrial, but not in ventricular tissue, which is blocked by losartan. Ang II may also have a tonic effect on coronary artery resistance as angiotensin inhibitors can increase coronary flow. Both ACE (Ang II synthesis) inhibitors and Ang II receptor antagonists produce beneficial effects in experimental models of heart failure, suggesting Ang II is an important mediator of heart failure. Because ACE inhibitors also potentiate bradykinin and are non-specific inhibitors of Ang II synthesis (availability of Ang II to both receptor subtypes) some differences can be anticipated. At the present time, however, the beneficial role of bradykinin is controversial and the predominant functional Ang II receptor in the heart and other tissues is the AT1 subtype.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Angiotensin II receptor subtypes: selective antagonists and functional correlates. 771 19

With the development of subtype specific angiotensin II (Ang II) receptor antagonists and their introduction into the treatment of heart failure and hypertension, the regulation of the Ang II receptor with its subtypes AT1 and Ang T2 gains clinical importance. In cell cultures, the number of surface AT1 is clearly down-regulated by Ang II exposure. Down-regulation can be due to reversible internalization, to phosphorylation and to reduced synthesis and involves protein kinase C and phospholipase C mediated pathways. In this respect, the AT1 behaves as a typical G-protein coupled receptor. Aldosterone, cAMP, norepinephrine and extracellular glucose concentrations can contribute to AT1 regulation. There are very few data regarding the regulation of the subtype AT2, indicating modulation by a number of growth factors and by Ang II. In whole animal models receptor regulation deviates partially from cell cultures. In the rat, the two subtypes AT1A and AT1B are differentially regulated and the expression of subtypes is organ specific. In most experiments, including our own experiences, the AT1, in the adrenals was up-regulated by Ang II infusion and down-regulated by angiotensin converting enzyme inhibitors (ACEI) or Ang II receptor antagonists. Differing effects were observed in other organs. In humans, a number of studies seeking an association between Ang II levels, Ang II receptor regulation and physiological events have been conducted in platelets. In pregnant women, a negative correlation between plasma Ang II levels and Ang II binding and an association between receptor regulation and pregnancy-induced hypertension has been described.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Regulation of the angiotensin receptor subtypes in cell cultures, animal models and human diseases. 771 21

A-II exerts its activity on various target tissues by binding to its receptors. The discovery of local RASs and A-II receptors within various tissues has generated interest in the clinical usefulness of RAS inhibition by directly blocking the action of A-II at the receptor level. Different A-II receptor subtypes have been identified and subsequently termed AT1 and AT2. AT1-receptor subtypes are the predominant receptor subtypes existing in most organs and, by coupling to a transmembrane G protein, seem to be the main subtypes participating in the vasoactive responses of A-II. Saralasin, a peptide with specific A-II receptor-antagonistic activity, had limited practical long-term usefulness as a result of its short half-life, significant agonistic properties, and lack of oral bioavailability. The discovery of simple benzyl-substituted imidazoles, which possess weak but highly selective A-II receptor antagonistic properties, led to the development of losartan (DuP 753). Losartan is a potent, orally active, specific, competitive nonpeptide A-II receptor antagonist that appears to be an effective antihypertensive agent both in animal studies and in preliminary clinical trials. The therapeutic usefulness of losartan, however, is not limited to its antihypertensive effects. The potential benefits of A-II receptor antagonists include roles in postmyocardial infarction therapy, slowing A-II-induced cardiac hypertrophy, 154, 155 slowing the progression of heart failure, preventing postangioplasty restenosis, and in slowing the progression of renal disease. Furthermore, losartan, a selective A-II type 1 (AT1) receptor antagonist, has also been a valuable pharmacologic probe for studying the mechanism of A-II stimulation of its receptors. A-II receptor antagonism appears to be as effective as ACE inhibition in the treatment of hypertension and other pathologic processes that involve the RAS and may offer an alternative to those patients who cannot tolerate ACE inhibitors because of their side effects.
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PMID:Angiotensin II receptor antagonists: a new approach to blockade of the renin-angiotensin system. 817 70

The 'angiotensin system' is expressed at the whole body, organ/tissue and cellular levels through the action of angiotensin II at specific receptors. An appreciation of the full scope of the actions of angiotensin II (endocrine, paracrine and autocrine) has been made possible by the discovery of the non-peptide angiotensin II receptor antagonists, losartan (DuP 753/MK954)(AT1-selective) and PD123177 (AT2-selective). Virtually all of the known effects of angiotensin II are blocked by losartan and designated AT1. Selective AT1 receptor blockade with losartan lowers BP in angiotensin II-dependent models of hypertension, reduces cardiac hypertrophy, improves haemodynamics in models of cardiac failure and reduces the intimal response to vascular injury. AT2 sites have been localised in distinct parts of the brain and in foetal tissue. The functional role of the AT2 sites remains controversial, but possible roles in neuronal ion channel function and collagen metabolism in fibroblasts have been reported. AT1 (losartan-sensitive) receptor subtypes have now been cloned from several rat tissues, suggesting that selective agents of the future may be even more specifically targeted. New perspectives in the control of the angiotensin system continue to evolve rapidly as the new receptor antagonists and molecular biology techniques expand our understanding of angiotensin II.
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PMID:New perspectives in angiotensin system control. 823 85

The 'discovery' of losartan represents three separate discoveries: (1) losartan as the unique biphenyltetrazole molecule and the first of a new chemical class; (2) losartan as a tool to identify AT1-subtype receptors; and (3) losartan as a specific probe for exploring the multiple roles of angiotensin II (Ang II) in normal physiology and pathologic states. Losartan is the first nonpeptide orally active Ang II receptor antagonist to reach clinical trials. Losartan was selected for its affinity for Ang II receptors, functional antagonism of Ang II, lack of agonist properties, and oral anti-hypertensive effects. Losartan has been widely used to define the distribution and function of AT receptor subtypes. Although possible roles of the AT2 subtype have been reported, virtually all of the known effects of Ang II are blocked by losartan. Specific AT1 receptor blockade has been broadly compared with ACE inhibition. Possible differences on the basis of AT1 selectivity, bradykinin potentiating effects and Ang II formed by non-ACE pathways are discussed. Losartan blocks the vascular constrictor effect of Ang II, the Ang II-induced aldosterone synthesis and/or release, and the Ang II-induced cardiovascular 'growth' in vitro and in vivo. In various models of experimental hypertension, losartan prevents or reverses the elevated blood pressure and the associated cardiovascular hypertrophy similar to ACE inhibitors. Likewise, in models of renal failure (for example reduced renal mass, puromycin, ochratoxin), losartan, like ACE inhibition, markedly reduced the elevation in blood pressure, proteinuria or sclerosis. In aortocaval shunt, coronary ligation and ventricular pacing models of heart failure, losartan demonstrated a pathological role for Ang II by reversing the associated haemodynamic findings. In SHR-stroke prone, losartan dramatically increased survival while having a limited effect on blood pressure, suggesting a non-pressure dependent effect of Ang II. These collective data show that Ang II exerts complex pathological effects in experimental models of vascular, cardiac, renal and cerebral disease. The effectiveness of losartan in experimental models of heart failure supports its evaluation in clinical trials with patients with heart failure.
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PMID:Discovery of losartan, the first angiotensin II receptor antagonist. 858 79

So far, two angiotensin receptor subtypes, called AT1 and AT2, have been described in an animal model and in human. AT1 mediates almost all known effects of angiotensin II and its gene sequence and regulation is well studied. In contrast, only few data on function and regulation of AT2 are available. The complete mRNA sequence of AT2 has only recently been cloned and sequenced. The angiotensin receptors' receptor density and subtype distribution is organ specific. In the rat, lowest densities are found in the myocardium, followed by kidney, liver, adrenal medulla and cortex. The percentage of AT1 in the different organs amounts to 80, 85, 90, 57 and 10%. Angiotensin receptor subtypes have also been quantitated in human myocardium. There, the relatively unknown subtype AT2 dominates (67%). Myocardial receptor density is low, amounting to about 11 fmol/mg protein corresponding to 1/20-1/50 of the density of beta-adrenergic receptors. Angiotensin receptors in the human heart are present on cardiac fibroblasts and induce proliferation of these cells. Blockade of the renin angiotensin system by ACEI and AT1 antagonists in the rat downregulates angiotensin receptors in liver, kidney and adrenals to about 50% in an organ- and subtype specific manner, whereas cyclosporin A upregulates receptors twice. In end-stage human heart failure, but not in early stages, angiotensin receptors are downregulated to 1/3 of control values. Regulator mechanisms at transcriptional level have been elucidated by reporter gene assays; PMA, an activator of proteinkinase C, stimulates the transcription of the AT1 gene. The organ- and subtypespecific regulation of angiotensin receptors by pharmacological agents and/or cardiovascular diseases can contribute to the understanding of these drugs and of the pathophysiology of the corresponding diseases.
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PMID:[Angiotensin receptors--organ and subtype specific regulation in cardiovascular diseases by modulation of the renin-angiotensin system. Studies of the rat model and in human myocardium]. 858 75

In addition to inhibition of the circulating renin-angiotensin system, specific inhibition of the cardiac effects of angiotensin II (Ang II) represents an important therapeutic goal in the treatment of clinical heart failure. Subtype 1-specific Ang II receptor (AT1) antagonists have been developed to overcome potential limitations of angiotensin converting enzyme inhibitors, e.g. insufficient control of tissue Ang II production and bradykinin-related side effects. Clinical studies have demonstrated beneficial effects of AT1 antagonists. In a single-dose study, the AT1 antagonist losartan decreased the mean arterial pressure and pulmonary arterial pressure while increasing the cardiac index. Effects were dose dependent. Haemodynamic effects were greater with higher doses, but neurohormonal counter-regulation probably also increased, leading to relatively high levels of circulating Ang II with the 150-mg dose, A decrease in plasma levels of noradrenaline, atrial natriuretic factor, and aldosterone reached partial significance. Administration of multiple doses of losartan for 12 weeks also led to favourable haemodynamic and clinical results. Arterial blood pressure, pulmonary capillary wedge pressure, and systemic vascular resistance decreased. The neurohormonal effects of 12 weeks' administration of AT1 antagonists consisted in a decrease in plasma aldosterone concentrations. Whereas AT1 antagonists may counteract the effects of Ang II on the vasculature, and therefore are effective vasodilators, their direct myocardial effects are less clear. The subtype AT2, which represents the dominant, receptor in both healthy and failing human myocardium, is not blocked by AT1 inhibition. Angiotensin receptors on isolated human cardiac fibroblasts stimulate cellular proliferation via a yet undertermined receptor subtype. AT1 antagonists exert beneficial haemodynamic and neurohormonal effects in human heart failure. Their direct myocardial effects require further investigation.
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PMID:Effects of angiotensin receptor antagonists in heart failure: clinical and experimental aspects. 868 68

Angiotensin II is a multifunctional hormone that exerts its effects by interacting will cell surface receptors. Two major subtypes of receptors (AT1 and AT2) have been distinguished by pharmacological and molecular biological techniques. AT1 receptors have been further subdivided into AT1A and AT1B receptors. Several other isoforms have been found, notably in nonmammalian systems, but further information is necessary before definitive classification can be made. AT1 receptors mediate most known functions of angiotensin II, while AT2 receptors may be important developmentally. The molecular, structural, and biochemical characteristics of these receptors have been described, as well as the factors that regulate their expression. This receptor system has been implicated in several cardiovascular diseases, including hypertension, restenosis after angioplasty, cardiac hypertrophy, heart failure, myocardial infarction, and ventricular remodeling. Structural analysis of AT receptors may provide the basis for the development of new therapeutic agents with enhanced specificity for the treatment of these diseases.
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PMID:Angiotensin receptors and their therapeutic implications. 872 91

The actions of angiotensin II in the cardiovascular system are transmitted by two known and possibly some unknown angiotensin receptor types. AT1 and AT2 both correspond to G-protein-coupled receptors with seven hydrophobic transmembrane domains, several N-glycosylation sites and a potential G-protein binding site. Cloning of coding regions and promoter sequences contributed to the understanding of receptor protein function and regulation. Angiotensin receptors with atypical binding properties for the known AT1- and AT2-specific ligands are expressed on human cardiac fibroblasts and in the human ulcrus. In several animal models, receptors with high affinity for angiotensin (1-7) have been described. AT1 stimulation is mediated by the generation of phospholipid-derived second messengers, activation of protein kinase C, the MAPkinase pathway and of immediate early genes. Recently, phosphorylation and dephosphorylation of tyrosine kinases have been associated with AT1- and AT2-mediated signal transduction. ATR are regulated by phosphorylation, internalization, modification of transcription rate and mRNA stability. Regulation is highly cell and organ specific and includes upregulation of ATR in some pathophysiological situations where the renin angiotensin system is activated. Whereas the function of AT1 in the cardiovascular system is relatively well established, there is little information regarding the role of AT2. Recent hypotheses suggest an antagonism between AT1 and AT2 at the signal transduction and the functional level. Transgenic animal models, particularly with targeted disruption of the AT1 and AT2 genes, suggest the contribution of both genes to blood pressure regulation. Genetic polymorphisms have been described in the AT1 and AT2 gene or neighbored regions and are used to analyze the association between gene defects and cardiovascular diseases. AT1 antagonists are now being introduced into the treatment of hypertension and potentially heart failure, and more interesting pharmacological developments are expected from the ongoing basic studies.
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PMID:Molecular biology of angiotensin receptors and their role in human cardiovascular disease. 877 61

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