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: EC:3.4.23.15 (renin)
35,795 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Recovery from renal ischemia requires regeneration of damaged tubular epithelium. Previous studies have examined the expression of proto-oncogenes and growth factors after ischemia, but the response of genes coding for structural and functional genes has not been scrutinized. Rats were subjected to 40 minutes of renal artery occlusion and 60 minutes to 96 hours of reperfusion. Total RNA was isolated and mRNA for the structural protein actin, the enzymes superoxide dismutase and renin, the proto-oncogene c-fos, the nuclear protein histone H2b, and the putative marker for cell injury TRPM-2 was quantitated by Northern hybridization. Expression of the proto-oncogene c-fos was seen early but for only short duration. Histone gene expression was not markedly increased until 24 hours after ischemia, but remained increased for several days. Renin mRNA was undetectable one hour after ischemia, but was present in normal amounts at 24 and 48 hours. In contrast, superoxide dismutase mRNA was present in decreased amounts 24, 48, and 96 hours after ischemia. TRPM-2 gene expression was greatly increased 24 to 72 hours after ischemia and began decreasing at 96 hours. This selective sequence of gene expression or repression after renal ischemia might maximize the proliferative repair process. This information will be useful for designing therapies to further enhance recovery from acute renal injury.
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PMID:Differential gene expression in the recovery from ischemic renal injury. 191 Jan 24

Hemodynamic load is a primary regulator of cardiac mass. A potential proximal event in this regulatory pathway is thought to be the induction of immediate early genes, and markers of this process include the re-expression of genes for fetal sarcomeric proteins and the ventricular expression of atrial natriuretic factor (ANF). Previous in vivo models which have examined these questions have often neither quantified myocardial loading nor accounted for covariables which may affect gene expression such as the renin-angiotensin-aldosterone system, the sympathetic nervous system, or baroreceptors. Thus, whether load alone is sufficient to induce immediate early genes, which may ultimately result in cardiac hypertrophy, remains unknown. In the present study two models of right ventricular (RV) pressure overload were created by partially occluding the pulmonary artery (PA), either with a balloon catheter for 1 or 4 h, or with a surgically placed PA band for 12, 24, or 48 h. Serum catecholamine concentrations were determined in a subset of RV pressure overload cats at basal state, after 5 min of balloon inflation, and after 1 h of balloon inflation to examine the effects of this systemic trophic factor on IEG induction. Northern blot analysis for c-fos, egr-1, alpha-skeletal actin, and ANF from paired RV and left ventricular (LV) RNA allowed the effect of load (selectively increased in the RV) to be separated from other systemic variables (present in both ventricles). The relative signal intensities of the optical density of RV and LV mRNA autoradiograms were determined from northern blots, alternate lanes of which were loaded with 7.5 micrograms of total RNA from RV and LV tissue from the same cat. Partial PA occlusion caused RV systolic pressure to increase from a control value of 22 +/- 1 mmHg to 57 +/- 6 mmHg after 1 h, 59 +/- 5 mmHg after 4 h, and 58 +/- 5 mmHg after 48 h of RV pressure overload (RVPO). Serum norepinephrine and epinephrine levels at both 5 and 60 min of RVPO were not significantly different from basal levels. The RV/LV ratios of mRNA for both egr-1 and c-fos were equal in control and 48 h PA banded animals, but were increased in the 1 and 4 h balloon RVPO cats. The RV/LV ratio of mRNA for alpha-skeletal actin was equal in the basal state and did not increase after 12, 24, or 48 h of RVPO. After 48 h of RVPO, total RNA was increased in the RV compared with the LV (1.9 +/- 0.1 v 1.1 +/- 0.1 micrograms/g tissue, P < 0.05). ANF expression was present in the RV after 48 h of RVPO, but absent in same-animal LV and all control ventricles. Thus, while increased load alone did not alter the expression of alpha-skeletal actin, it was sufficient both to induce increased expression of two distinct classes of immediate early genes, as well as ANF, and to increase total RNA, indicating hypertrophic growth initiation.
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PMID:Load effects on gene expression during cardiac hypertrophy. 776 Mar 68

Cardiac myocyte hypertrophy often occurs in response to both hemodynamic and neurohumoral factors. To study whether activation of the renin-angiotensin system by itself may induce a cardiac growth response, the acute effects of angiotensin II on cardiac protein synthesis were studied in isolated rat hearts. New protein synthesis in isolated buffer-perfused adult rat hearts was measured by incorporation of [3H]phenylalanine into cardiac proteins during a 3-hour perfusion protocol. Angiotensin II (1 x 10(-8) mol/L), administered alone or in combination with the alpha 1-blocker prazosin (1 x 10(-7) mol/L), stimulated protein synthesis in both ventricles. The rate of [3H]phenylalanine incorporation into cardiac proteins was 3.9-fold (P < .005) and 2.6-fold (P < .01) higher in angiotensin II-perfused (n = 6) than in vehicle-perfused (n = 6) left and right ventricles, respectively. The induction of new protein synthesis by angiotensin II was blocked by the angiotensin II type 1 (AT1) receptor antagonist losartan (1 x 10(-7) mol/L, n = 5). To study the pathways of angiotensin signal transduction, protein kinase C (PKC)-epsilon as well as cardiac c-fos and c-jun mRNA levels were analyzed. Angiotensin II (1 x 10(-8) mol/L, n = 20) resulted in a transient translocation of PKC-epsilon from the cytosol to the cellular membrane. However, compared with phorbol ester stimulation (phorbol 12-myristate 13-acetate [PMA], 1 x 10(-7) mol/L; n = 20), angiotensin II effects on PKC translocation were significantly less pronounced and required a more prolonged stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Angiotensin II-induced growth responses in isolated adult rat hearts. Evidence for load-independent induction of cardiac protein synthesis by angiotensin II. 785 94

Based upon literature the renin-angiotensin system involvement in the pathogenesis of atherosclerosis has been discussed. Angiotensin II leads to the increased production of growth factors such as PDGF, TGF-beta, FGF and extracellular matrix proteins. There are evidences that angiotensin II stimulates expression of egr-1, c-jun, c-fos and c-myc oncogenes in vascular smooth muscle cells. Proliferation of aortic smooth muscle cells in response to the injury can be reduced by inhibitors of renin-angiotensin system what supports the hypothesis that angiotensin II can contribute to the pathogenesis of atherosclerosis.
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PMID:[Renin-angiotensin system and atherosclerosis]. 820 30

The body defends against reduced extracellular fluid volume both by activation of autonomic and endocrine reflexes and by mobilization of behavioral mechanisms. The behaviors that are required to correct an extracellular fluid deficit involve the ingestion of both water and sodium. It is reasonable to hypothesize that afferent neural input from both arterial and cardiopulmonary high pressure and volume receptors, and afferent humoral input in the form of ANG II, are important systemically-generated signals acting as afferent mediators of extracellular depletion-induced thirst and sodium appetite. Neural information from these signals has been shown to converge on forebrain structures located along the lamina terminalis where processing and integration of this input is likely to take place. This paper describes an analysis of the mechanisms of afferent signaling that accompanies a form of rapidly induced sodium appetite. Because volume and pressure-related input in concert with elevated activity of the renin-angiotensin system is likely to be important for generating this form of induced hypertonic sodium chloride and water intake, we have focused on the structures of the lamina terminalis, specifically the SFO, MnPO, and OVLT. Investigations that employ immunocytochemical methods for the detection of the early oncogene, c-fos, indicate that neurons in the lamina terminalis, as well as the SON and PVN, are activated by the composite of systemically derived signals necessary for producing thirst and sodium appetite. So far, there is no thorough understanding of how these visceral signals activate the neural substrates for these motivated behaviors. However, these studies, combining both functional and neuroanatomical approaches, provide a strategy for investigating the neurobiological basis of the behavioral and physiological control systems that maintain fluid balance and cardiovascular homeostasis. This paper describes an analysis of the mechanisms of afferent signaling that accompanies a form of rapidly induced sodium appetite. Because volume and pressure-related input, in concert with elevated activity of the renin-angiotensin system, is likely to be important for generating this form of induced hypertonic sodium chloride and water intake, we have focused on the structures of the lamina terminalis, specifically the SFO, MnPO, and OVLT. Investigations that employ immunocytochemical methods for the detection of the early oncogene, c-fos, indicate that neurons in the lamina terminalis, as well as the SON and PVN, are activated by the composite of systemically derived signals necessary for producing thirst and sodium appetite. So far, there is no thorough understanding of how these visceral sensory-related signals activate the neural substrates for these motivated behaviors.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Afferent signaling and forebrain mechanisms in the behavioral control of extracellular fluid volume. 837 12

Neuronal cells in primary culture from the hypothalamus-brain stem areas of normotensive [Wistar-Kyoto (WKY)] and spontaneously hypertensive (SH) rat brains have been used in the present study to investigate an interaction between the brain renin-angiotensin II system and the plasminogen activator system. This is an attempt to further our understanding of the role of brain Ang II in the control of neuronal development and differentiation through its regulation of the extracellular matrix. Ang II caused a 10-fold stimulation of plasminogen activator inhibitor-1 (PAI-1) messenger RNA (mRNA) in WKY rat brain neuronal cultures. The stimulation was mediated by the AT1 receptor subtype and was accompanied by an increase in PAI-1 gene transcription and the synthesis of cellular PAI-1 protein. The stimulation involved activation of protein kinase C, and alterations in the intracellular Ca2+ pool caused a significant inhibition of Ang II stimulation of PAI mRNA. Ang II stimulation of PAI-1 mRNA succeeded its action on c-fos mRNA and was attenuated by c-fos antisense oligonucleotide. Although PAI-1 gene expression was also stimulated by Ang II in neuronal cultures of SH rat brain, two differences between WKY and SH rat brain neurons were observed: 1) the level of Ang II stimulation in SH rat neurons was 50% of that in WKY rat neurons; and 2) Ang II stimulation of c-fos was 2.4-fold higher in SH neurons than in WKY neurons, but c-fos antisense oligonucleotide did not attenuate the stimulatory action of Ang II on PAI-1 mRNA in SH neurons. These observations suggest that the changes in the Ang II-mediated signaling pathways and/or the regulatory region(s) of the PAI-1 gene may contribute to the differential actions of Ang II in WKY and SH rat brain neurons.
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PMID:Angiotensin II regulation of plasminogen activator inhibitor-1 gene expression in neurons of normotensive and spontaneously hypertensive rat brains. 864 Dec 4

Although rapid growth of the heart during early postnatal development ceases with maturation of the organism, the potential for cardiomyocyte growth is not lost and may be observed even in senescent hearts. Rapid developmental heart growth is accompanied by a proportional growth of capillaries but not always of larger vessels, and thus coronary vascular resistance gradually increases. Growth of adult hearts can be enhanced by thyroid hormones, catecholamines and the renin-angiotensin system hormones, but these do not always stimulate growth of coronary vessels. Likewise, chronic exposure to hypoxia leads to growth, mainly of the right ventricle and its vessels but without vascular growth elsewhere in the heart. On the other hand, ischaemia is a potent stimulus for the release of various growth factors involved in the development of collateral circulation. Heart hypertrophy develops in response to training, pressure or volume overload. Training usually leads to growth of larger coronary vessels but little growth of capillaries, except in young animals. However, growth of the capillary bed, but not the resistance vasculature capacity, can be induced by either increased coronary blood flow, bradycardia (electrically or pharmacologically induced) or increased inotropism, all of which are involved in the training stimulus. Thus, what actually promotes growth of larger vessels as opposed to capillaries in training is unclear. Pressure overload hypertrophy is mediated by both the renin-angiotensin system and the response of cardiomyocytes to stretch; both lead to activation of early oncogenes (c-fos, c-jun, c-myc) and angiotensin II activates several protein kinases involved in cell growth. In this condition, growth of larger vessels is inadequate, although some capillary growth may occur. Volume overload leads to cardiomyocyte hypertrophy and hyperplasia and some increase in vascular supply. Deficits in capillary supply in pressure or volume overload hypertrophy can be reversed by chronic administration of ACE inhibitors, dipyridamole, the bradycardic drug alinidine or pacing-induced bradycardia respectively, but in neither case is training effective. Mechanical and humoral factors are involved in growth of cardiomyocytes and vessels. For cardiomyocytes, stretch is most important, activating oncogenes, protein kinases and possibly the inositol phosphate pathway, but not ion channels, with regulation by the balance of angiotensin II, TGF-beta 1 and IGF-1, but not FGFs. For vessels, growth is stimulated by stretch and shear stress, possibly with involvement of VEGF. Increased shear stress disrupts the glycocalyx on the luminal side of vessels and releases plasminogen activator and metalloproteinases which disrupt the basement membrane and enable endothelial cell migration and proliferation. It also causes rearrangement of the endothelial cytoskeleton and transmission of mechanical signals to the abluminal side disturbing extracellular matrix and causing distortion of capillary basement membrane. Stretch acting from the abluminal side has a similar effect resulting also in basement membrane disruption and endothelial cell proliferation.
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PMID:Postnatal growth of the heart and its blood vessels. 869 52

Myocardial stretch and the renin-angiotensin system have been implicated in the development of cardiac hypertrophy through the activation of specific target genes. However, the relative importance of these putative hypertrophic stimuli has not been established in vivo. We used an isolated isovolumic heart preparation in which coronary perfusion pressure (CPP), left ventricular end-diastolic pressure, and pharmacological therapy can be independently manipulated to study this relationship. High CPP (140 cmH2O), which increased coronary flow (8.99 vs. 17.6 ml/min) and left ventricular systolic pressure (50 vs. 91 mmHg), increased steady state c-fos mRNA expression 2.3-fold (all P < 0.01 vs. low CPP). In contrast, increased left ventricular end-diastolic pressure (25 mmHg) and/or infusion of angiotensin II in the absence of increased CPP was not associated with an increase in c-fos mRNA expression. The change in c-fos gene expression seen with increased CPP was largely reversed by treatment with an angiotensin type 1 (AT1) receptor blocker. Hearts perfused at high CPP demonstrated increased translocation/activation of protein kinase C-epsilon relative to controls. None of the hearts studied were ischemic during perfusion. Thus, in the perfused adult rat heart, dynamic, but not static, stretch activates the early response gene, c-fos, and may involve the endogenous reninangiotensin system and protein kinase C.
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PMID:Role of endogenous renin-angiotensin system in c-fos activation and PKC-epsilon translocation in adult rat hearts. 876 71

Although it is well known that mechanical load to cardiac muscles causes cardiac hypertrophy, little is known about how mechanical load is transduced into the activation of intracellular signals which are linked to cell growth. We investigated whether the cardiac renin-angiotensin system was involved in stretch-induced hypertrophy of cultured neonatal rat heart myocytes. Myocytes were cultured with serum-free medium in a deformable silicon dish. Stretch of cardiac myocytes significantly increased the protein/DNA ratio at culture days 6 and 7, and the RNA/DNA ratio at culture days 4 and 5. Stretch significantly accelerated rates of protein synthesis by 15%. c-fos mRNA expression was significantly increased after stretch. The stimulatory effects of cell stretch on these parameters were significantly inhibited by the angiotensin converting enzyme inhibitor, captopril, or the type 1 angiotensin II receptor antagonist, losartan. The concentrations of angiotensin I and angiotensin II in culture media were significantly increased by stretch. Stretch did not change the angiotensin converting enzyme activity. These studies demonstrate that mechanical stretch activates the cardiac renin-angiotensin system in a autocrine and paracrine system which acts as an initial mediator of the stretch-induced hypertrophic growth.
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PMID:Renin-angiotensin system in stretch-induced hypertrophy of cultured neonatal rat heart cells. 883 Nov 8

The renin-angiotensin system seems to play an important role in the pathogenesis of renal interstitial fibrosis. However, the potential direct effects of angiotensin II (Ang II) on cultured renal fibroblasts have been little studied. We have observed that rat renal interstitial fibroblasts (NRK 49F cell line) possess AT1 receptors coupled to intracellular calcium mobilization. Exposure of these cells to Ang II induced several short and long growth-related metabolic events mediated by the AT1 receptor, including c-fos gene expression, changes in cell cycle and cell proliferation. Activation of interstitial fibroblasts by Ang II could also contribute to extracellular matrix accumulation. Stimulation with Ang II increased mRNA expression of TGF-beta 1, fibronectin and type I collagen. In fact, Ang II enhanced fibronectin production via AT1 receptors by a process depending on autocrine TGF-beta secretion. The mechanism of some Ang II actions (calcium mobilization and fibronectin production) depended on protein kinase C and tyrosine kinase activation. We further investigated whether renal fibroblasts could express some components of the renin-angiotensin system. These cells constitutively expressed the angiotensinogen gene that was up-regulated by Ang II. Collectively, these results indicate that in renal interstitial fibroblasts Ang II causes hyperplasia and extracellular matrix production via the AT1 receptor. Ang II may initiate a positive feedback regulation of fibroblasts growth, inducing the expression of TGF-beta 1 and angiotensinogen genes. Ang II, acting directly on interstitial fibroblasts, may be implicated in the pathogenesis of renal fibrosis.
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PMID:Angiotensin II modulates cell growth-related events and synthesis of matrix proteins in renal interstitial fibroblasts. 940 95


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