Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0004135 (ATM)
 13,001 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We had reported that in the ischemic heart, locally formed bradykinin (BK) and angiotensin II (Ang II) activate B2- and AT1-receptors on sympathetic nerve terminals (SNE), promoting reversal of the norepinephrine (NE) transporter in an outward direction (i.e., carrier-mediated NE release). Although both BK and Ang II contribute to ischemic NE release, Ang II is likely to play a more important role. Since BK is formed by ischemic SNE, we questioned whether cardiac SNE also contribute to local Ang II formation, in addition to being a target of Ang II. SNE were isolated from surgical specimens of human right atrium and incubated in ischemic conditions. These SNE released large amounts of endogenous NE via a carrier-mediated mechanism, as evidenced by the inhibitory effect of desipramine on this process. Moreover, two renin inhibitors, pepstatin-A and BILA 2157 BS, the ACE inhibitor enalaprilat and the AT1-receptor antagonist EXP3174 prevented ischemic NE release. Western blot analysis revealed the presence of renin in cardiac SNE. Renin abundance increased more than three-fold during ischemia. Thus, renin is present in cardiac SNE and is activated during ischemia, eventually culminating in Ang II formation, stimulation of AT1-receptors and carrier-mediated NE release. Our findings uncover a novel autocrine mechanism, by which Ang II, formed at SNE in myocardial ischemia, elicits carrier-mediated NE release by activating prejuntional AT1-receptors.
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PMID:Activation of a renin-angiotensin system in ischemic cardiac sympathetic nerve endings and its association with norepinephrine release. 1248 10

Renin-angiotensin system (RAS) overactivity has been implied in progressive renal function loss. We investigated whether changes in the renal expression of RAS components are specifically associated with the proteinuric kidney. Unilateral adriamycin-induced proteinuria was obtained by clamping the left renal artery before injection of adriamycin. In control animals, both left and right renal arteries were clamped. Twelve weeks later, mRNA expression of RAS components was determined in both kidneys. In the affected and non-affected kidney of the unilateral proteinuric rat, we demonstrate up-regulation of angiotensin- converting enzyme (ACE) mRNA (213%+22 and 188%+24 of controls, respectively), up-regulation of transforming growth factor beta (TGF-beta) mRNA (956%+229 and 418%+56) and down-regulation of angiotensin type 2 receptor (AT2-R) mRNA (24%+5 and 20%+5). The expression of angiotensin type 1 receptor (AT1-R) mRNA and inositol 1,4,5- trisphosphate receptor type I (IP3R-I) mRNA were unchanged. In conclusion, renal expression of ACE, AT2-R, and AT1-R mRNA is not mediated by protein leakage. Local intrarenal protein leakage did influence renal TGF-beta mRNA expression.
J Renin Angiotensin Aldosterone Syst 2003 Mar
PMID:Role of proteinuria in the regulation of renal renin-angiotensin system components in unilateral proteinuric rats. 1269 52

Arterial Hypertension (AH) is characterized by reduced nitric oxide (NO) biosynthesis, activation of the Renin-Angiotensin-Aldosteron-System (RAAS), vasoconstriction, and microvascular rarefaction. The latter contributes to target organ damage, especially in left ventricular hypertrophy, and may partially be due to impaired angiogenesis. Angiogenesis, the formation of new microvessels and microvascular networks from existing ones, is a highly regulated process that arises in response to hypoxia and other stimuli and that relieves tissue ischemia. In AH, angiogenesis seems impaired. However, blood pressure alone does not affect angiogenesis, and microvascular rarefaction is present in normotensive persons with a family history for AH. Normal or increased NO in several processes and diseases enables or enhances angiogenesis (e.g. in portal hypertension) and reduced NO biosynthesis (for example, in a rat model of AH, in other disease models in vivo, and in endothelial NO Synthase knock out mice) impairs angiogenesis. Angiogenic growth factors such as Vascular Endothelial Growth Factor (VEGF) and Fibroblast Growth Factor (FGF) induce NO and require NO to elicit an effect. Effector molecules and corresponding receptors of the RAAS either induce (Bradykinin, Angiotensin II) or perhaps inhibit angiogenesis. The pattern of Bradykinin- and Angiotensin II-receptor expression and the capacity to normalize NO biosynthesis may determine whether ACE-inhibitors, Angiotensin II-receptor antagonists and other substances affect angiogenesis. Reconstitution of a normally vascularized tissue by reversal of impaired angiogenesis with drugs such as ACE inhibitors and AT1 receptor antagonists may contribute to successful treatment of hypertension-associated target organ damage, e.g. left ventricular hypertrophy.
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PMID:Hypertension and angiogenesis. 1287 Dec 5

We compared the phenotype of two common mouse models, C-57BL/6J (C57), which carries only the Ren-1c gene, and 129/SvJ (Sv-129), with both Ren 1d and Ren-2. We hypothesized two renin gene Sv-129 would have increased blood pressure and the renin-angiotensin system would be more influential in regulating renal function compared with one renin gene mice. Sv-129 consistently had higher blood pressure than C-57, whether conscious (128 versus 108 mm Hg, P<0.001) or anesthetized (102 versus 88 mm Hg, P<0.001). Plasma renin concentration in both conscious and anesthetized C-57 mice was 3- to 4-fold higher than in Sv-129 (P<0.05), whereas renal cortical renin content was 2.5-fold higher (P<0.005). Renal blood flow and renal vascular resistance were the same in C-57 and Sv-129. Exogenous angiotensinogen produced identical pressor and renal vasoconstrictor responses in both strains. Blocking AT1 receptors with losartan reduced blood pressure by 19 mm Hg in both strains. Nitric oxide synthase inhibition by l-NAME increased blood pressure by 29 mm Hg in C-57 and 35 mm Hg in Sv-129 mice, but the decrease in renal blood flow was 30% less in C-57 (P<0.025). We conclude that Sv-129 mice with two renin genes have higher blood pressure but lower plasma and renal renin than C-57 mice with one renin gene. Renin substrate may limit angiotensin II production in the mouse. In Sv-129, the influence of nitric oxide on renal but not systemic resistance may be exaggerated. Renin from Ren-2 may act independently of normal renin control mechanisms.
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PMID:Cardiovascular and renal phenotype in mice with one or two renin genes. 1466 50

Angiotensin II was initially described as a hormone of peripheral origin, the active end product of the Renin-Angiotensin System. The subsequent discovery that Angiotensin II was locally formed and selectively regulated in most organs indicated that tissue Angiotensin II systems might play additional important roles. After initial controversy, the presence of an Angiotensin II system in the brain is now universally accepted. Brain Angiotensin II is probably involved in the regulation of many brain functions. Angiotensin II AT1 receptors are localized not only in areas related to the regulation of autonomic and endocrine control, but also in many other areas of the brain involved in emotional, sensory and motor functions. Angiotensin II AT2 receptors are more abundant in brain areas related to sensory and motor control. The roles of brain Angiotensin II appear to be multiple and complex. In addition to a regulatory role in the control of the autonomic and hormone systems, the peptide participates in brain development, sensory processes, cognition and in the regulation of cerebrovascular flow. Recent developments indicate that blockade of the brain Angiotensin II AT1 receptors not only contributes to a significant blood pressure decrease in hypertension, but that simultaneous antagonism of peripheral and brain AT1 receptors reduces the sympathoadrenal and hormonal responses to stress and prevents stress-induced gastric injury. A novel role emerges for the use of peripheral and centrally acting AT1 receptor antagonists as therapeutically advantageous for the treatment of stress-related disorders.
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PMID:Stress and angiotensin II: novel therapeutic opportunities. 1468 69

Congestive heart failure (CHF) is characterised by activation of the renin-angiotensin-aldosterone system (RAAS) and the sympathetic nervous system (SNS). Both systems are known to interact and to potentiate each other s activities. We recently demonstrated that angiotensin II (Ang II) enhances sympathetic nerve traffic via prejunctionally-located AT1-receptors. At present, little is known about the effects of Ang II at the level of the sympathetic neurones in CHF. Accordingly, we investigated the effect of Ang II in the presence and absence of the AT1-receptor antagonist, eprosartan, on stimulation-induced nerve traffic in isolated thoracic aorta preparations obtained from rabbits suffering from experimentally-induced CHF. Control-preparations were obtained from age-matched animals. Sympathetic activity was assessed by a [3H]noradrenaline spill-over model. Additionally, Ang II constrictor responses were compared between CHF and control vessels in the presence and absence of eprosartan. Additionally, to study postjunctional facilitation, the effects of Ang II on postsynaptic a-adrenoceptor-mediated responses were studied using noradrenaline. Stimulation-evoked SNS-neurotransmission was similar in both groups (CHF versus control). Ang II (0.1 nM 0.1 M) caused a concentration-dependent increase of the stimulation-evoked sympathetic outflow in both groups, with a maximum at 10 nM (control [n=7], FR2/FR1 2.03+0.11 and CHF- preparations [n=7], FR2/FR1 1.71+0.07). The enhancement by Ang II was decreased in CHF- preparations compared with controls (p<0.05). Eprosartan concentration-dependently attenuated the Ang II-enhanced (10 nM) sympathetic outflow in both CHF- and control preparations. The sympatho-inhibitory potency of eprosartan was similar in both groups (control pIC50 8.81 0.31; CHF 8.65+0.42). Ang II (1 nM 0.3 M) concentration-dependently increased the contractile force in control preparations (Emax 21.64+3.86 mN, pD2 7.63+0.02, n=7). Eprosartan (1 nM 0.1 M) influenced the Ang II- contractions via a mixed form of antagonism. In CHF-preparations, Ang II caused impaired vascular contraction. The KCl-induced contraction was decreased in the CHF- compared with control preparations (13.02+0.64 mN versus 30.40+0.89 mN). The relative Ang II contraction (% of KCl) was also decreased (2.3% vs. 58.0%). Concentration-response curves to noradrenaline (%KCl) were similar (control pD2 6.93+0.05, Emax 131.0+2.7; CHF pD2 7.00+0.05, Emax 136.7+2.6) (p>0.05) and were not affected by Ang II. We conclude that Ang II-enhanced sympathetic neurotransmission is mediated by the prejunctional AT1-receptor in both control and CHF-preparations. The decreased facilitation of SNS effects by Ang II may be explained by down-regulation or desensitisation of the neuronal AT1-receptor. Additionally, the aortic contractile capacity in heart failure rabbits appears to be decreased, probably as a result of heart failure-associated neuroendocrine and functional changes.
J Renin Angiotensin Aldosterone Syst 2003 Dec
PMID:Impaired neuronal and vascular responses to angiotensin II in a rabbit congestive heart failure model. 1468 69

The renin-angiotensin system (RAS) is compartmented between circulating blood and tissue pericellular space. Whereas renin and its substrate diffuse easily from one compartment to another, the angiotensin peptides act in the compartment where there are generated: blood or pericellular space. Renin is trapped in tissues by low and high affinity receptors. In the target cells, angiotensin II/AT1 receptor interaction generates different signals including an immediate functional calcium-dependent response, secondary hypertrophy and a late proinflammatory and procoagulant response. These late pathological effects are mediated by NADPH oxydase-generated free oxygen radicals and NFkappaB activation. In vivo, the tissue binding of renin and the induction of converting enzyme are the main determinants of the involvement of the RAS in vascular remodeling. The target cells of interstitial angiotensin II are mainly the vascular smooth muscle cells and fibroblasts, whereas the endothelial cells and circulating leukocytes are the main targets of circulating angiotensin II. In vivo, angiotensin II participates in the vascular wall hypertrophy associated with hypertension. In diabetes, as in other localized fibrotic cardiovascular diseases, the tissue effects of angiotensin II are mainly dependent on its ability to induce TGF-beta expression. In experimental atherosclerosis, angiotensin II infusion induces aneurysm formation mediated by activation of circulating leucocytes. In these models, the administration of angiotensin II antagonists has beneficial effects on pathological remodeling. Such beneficial effects of angiotensin II antagonists in localized pathological remodeling have not yet been demonstrated in humans.
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PMID:[Renin-angiotensin system and vascular remodelling]. 1512 12

Survival in patients with heart failure remains very poor, and is worse than that for most common cancers, including bowel cancer in men and breast cancer in women. The renin-angiotensin-aldosterone system (RAAS) is not completely blocked by angiotensin-converting enzyme (ACE) inhibition. Blockade of the RAAS at the AT1-receptor has the theoretical benefit of more effective blockade of the actions of angiotensin II. ACE inhibitors (ACE-Is) prevent the breakdown of bradykinin: this has been blamed for some of the unwanted effects of ACE-Is although bradykinin may have advantageous effects in heart failure. Consequently, ACE-Is and ARBs might be complementary or even additive treatments; recent trials have tested these hypotheses. The Candesartan in Heart failure Assessment of Reduction in Mortality and morbidity (CHARM) programme compared the angiotensin receptor blocker (ARB) candesartan (target dose 32 mg once daily) to placebo in three distinct but complementary populations of patients with symptomatic heart failure. These were: patients with reduced left ventricular ejection fraction (LVEF) who were ACE-I-intolerant (CHARM-Alternative); patients with reduced LVEF who were being treated with ACE-Is (CHARM-Added); and patients with preserved left ventricular systolic function (CHARM-Preserved). There were substantial and statistically significant reductions in the primary composite end point (risk of cardiovascular death or hospital admission for heart failure) in CHARM-Alternative. This was also the case in CHARM-Added, supporting and extending the findings of Val-HeFT. In CHARM-Preserved, the effect of candesartan on the primary end point did not reach conventional statistical significance though hospital admission for heart failure was reduced significantly with candesartan. In the CHARM-Overall programme there was a statistically borderline reduction in all-cause mortality with a clear reduction in cardiovascular mortality. All-cause mortality was reduced by 12% in the two CHARM trials in patients with low LVEF. CHARM succeeded in answering a number of questions about the safety and efficacy of ARB use in heart failure. It showed evidence for a clinical benefit of candesartan both additive to and independent of ACE-I use. The benefits in terms of clinical outcomes were seen irrespective of beta-blocker usage. Benefits in patients with preserved LVEF were shown in the proportion of patients hospitalised with worsening heart failure and in overall number of admissions for heart failure. Candesartan had expected effects on blood pressure and renal function, emphasising the need for careful patient monitoring.
J Renin Angiotensin Aldosterone Syst 2004 Sep
PMID:Angiotensin inhibition in heart failure. 1552 37

Activity of the renin-angiotensin-aldosterone system (RAAS) is increased in patients with heart failure, and its maladaptive mechanisms may lead to adverse effects such as cardiac remodelling and sympathetic activation. Elevated renin activity has been demonstrated in patients with dilated cardiomyopathy. (Third- generation synthetic non-peptide renin inhibitors, with more favourable properties than earlier renin inhibitors, lower ambulatory blood pressure and may have a role to play in other cardiovascular disease.) Chymase, a protease inhibitor stored in mast cells that generates angiotensin II (Ang II) (in addition to angiotensin-converting enzyme [ACE]), has been linked to extracellular matrix remodelling in heart failure. Again, chymase inhibitors have been developed to investigate its functions in vitro and in vivo . Bradykinin is thought to contribute to the cardioprotective effect of ACE inhibition through modification of nitric oxide release, calcium handling and collagen accumulation. Ang II is believed to influence a number of molecular and structural changes in the heart, mostly mediated through the AT1-receptor. The importance of the RAAS in heart failure is shown by the survival benefit conferred by treatment with ACE inhibitors.
J Renin Angiotensin Aldosterone Syst 2004 Sep
PMID:The role of the renin-angiotensin-aldosterone system in heart failure. 1552 42

The renin-angiotensin system (RAS) is compartmented between the circulating blood and pericellular spaces. Whereas renin and its substrate diffuse easily from one compartment to another, angiotensin peptides act in the compartment where there are generated. Renin is trapped in tissues by low- and high-affinity receptors. In target cells, angiotensin II/AT1 receptor interaction generates various signals, including an immediate functional calcium-dependent response, secondary hypertrophy, and a late proinflammatory and procoagulant response. These late pathological effects are mediated by NADPH oxidase-generated oxygen free radicals and NF-k-B activation. In vivo, renin tissue binding and converting-enzyme induction are the main determinants of RAS involvement in vascular remodeling. The main target cells of interstitial angiotensin II are vascular smooth muscle cells and fibroblasts, whereas endothelial cells and circulating leukocytes are the main targets of circulating angiotensin II. In vivo, angiotensin II participates in the vascular wall hypertrophy associated with hypertension. In diabetes, as in other localized fibrotic cardiovascular diseases, the tissular effects of angiotensin II are mainly dependent on its ability to induce TGF-beta expression. In experimental atherosclerosis, angiotensin II infusion induces aneurysm formation mediated by activation of circulating leucocytes. Angiotensin II antagonist therapy has beneficial effects on pathological remodeling in animal models, but it remains to be determined whether this is also the case in humans.
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PMID:[Tissue consequence of renin-angiotensin system activation]. 1558 80


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