UNIPROT:P01185 - FACTA Search

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Query: UNIPROT:P01185 (vasopressin)
23,126 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In addition to increasing blood pressure, stimulating aldosterone and vasopressin secretion, and increasing water intake, angiotensin II affects the secretion of anterior pituitary hormones. Some of these effects are direct. There are angiotensin II receptors on lactotropes and corticotropes in rats, and there may be receptors on thyrotropes and other secretory cells. Circulating angiotensin II reaches these receptors, but angiotensin II is almost certainly generated locally by the pituitary renin-angiotensin system as well. There are also indirect effects produced by the effects of brain angiotensin II on the secretion of hypophyseotropic hormones. In the anterior pituitary of the rat, the gonadotropes contain renin, angiotensin II, and some angiotensin-converting enzyme. There is debate about whether these cells also contain small amounts of angiotensinogen, but most of the angiotensinogen is produced by a separate population of cells and appears to pass in a paracrine fashion to the gonadotropes. An analogous situation exists in the brain. Neurons contain angiotensin II and probably renin, but most angiotensin-converting enzyme is located elsewhere and angiotensinogen is primarily if not solely produced by astrocytes. Angiotensin II causes secretion of prolactin and adrenocorticotropic hormone (ACTH) when added to pituitary cells in vitro. Paracrine regulation of prolactin secretion by angiotensin II from the gonadotropes may occur in vitro under certain circumstances, but the effects of peripheral angiotensin II on ACTH secretion appear to be mediated via the brain and corticotropin-releasing hormone (CRH). In the brain, there is good evidence that locally generated angiotensin II causes release of norepinephrine that in turn stimulates gonadotropin-releasing hormone-secreting neurons, increasing circulating luteinizing hormone. In addition, there is evidence that angiotensin II acts in the arcuate nuclei to increase the secretion of dopamine into the portal-hypophyseal vessels, inhibiting prolactin secretion. Central as well as peripheral angiotensin II increases CRH secretion, but there is little if any evidence that angiotensin II mediates the ACTH responses to other stressful stimuli.
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PMID:Blood, pituitary, and brain renin-angiotensin systems and regulation of secretion of anterior pituitary gland. 834 4

In this article, we have discussed the localization of components of the renal renin-angiotensin system, as well as the existing information on the regulation of this axis and the effects of Ang II on renal function. All the components of the renin-angiotensin system are present in both fetal and adult kidney. In the adult kidney, renin is principally localized to jg cells of the distal afferent arteriole, where release is stimulated by increases in intracellular cAMP and inhibited by increases in cytosolic calcium. Four distinct stimuli mediating renin release are (1) NaCl sensed at the macula densa, (2) the sympathetic nervous system, (3) humoral factors, with Ang II, vasopressin, endothelin, and adenosine inhibiting renin release, and (4) changes in intrarenal blood pressure. Alterations in renal renin gene expression have been reported in pathophysiological states, such as salt depletion, diabetes mellitus, ureteral obstruction, Bartter's syndrome, and with high protein feeding. The highest renal concentrations of mRNA for the renin substrate angiotensinogen are found in the PT, where the protein is localized to subapical granules. Both salt depletion and androgens upregulate renal angiotensinogen mRNA. Of interest, renal angiotensinogen mRNA levels are lower in SHR than in normotensive WKY rats. As with angiotensinogen, renal ACE is mainly localized to the PT, with highest concentration on the brush border. The mechanisms of regulation of both renal angiotensinogen and ACE require further study. Using recently developed specific nonpeptide Ang II receptor antagonists, it appears that adult renal Ang II receptors are principally of the AT1 class, whereas fetal kidney Ang II receptors are of the AT2 subtype. By binding to AT1 receptors, Ang II exerts constrictive effects on both afferent and efferent arterioles, with increased effect reported on efferent arterioles. Glomerular Ang II receptors are localized to mesangial cells, mediating contractile responses resulting in changes in glomerular surface area and Kf, and potentially regulating mesangial sieving and phagocytosis. These receptors are reduced with salt restriction or in experimental diabetes. The highest concentrations of tubular Ang II receptors are found in PT, on both brush border and basolateral membranes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The intrarenal renin-angiotensin system. 843 83

Experimental myocardial infarction is a model of cardiac overload in which part of the cardiac muscle is removed. The resulting left ventricle insufficiency depends on the size of the infarct and time. The infarcted area remodels, due to proteolytic activity of inflammatory cells and collagenogenesis from fibroblast activity. The phenotype of the residual healthy cardiac muscle undergoes modification, and there are peripheral vascular changes which are partly dependent on the activation of pressor systems and/or inactivation of dilator systems. The changes are proportional to the infarct size at any given time after induction of the model. The degree of right ventricular hypertrophy and the drop in arterial pressure are upstream and downstream markers of the loss of left ventricular function and therefore indicate the extent of the remodelling. The increase of type V3isomyosin, the amount of subendocardial collagen, and the biosynthesis, storage and secretion of atrial natriuretic factor (ANF) are all proportional to the infarct size and the degree of cardiac overload. The level of urinary cGMP is also correlated with infarct size. These indices show ventricular remodelling, increased stress and energy restriction of the residual healthy cardiac muscle. The activation of peripheral pressor systems also depends on infarct size. They reflect the influence of defective cardiac pumping on the kidney, liver, brain and endothelium. Massive infarcts are accompanied by an increase in circulating renin and in renal renin content, by a decrease in angiotensinogen due to its consumption by renin, and to its insufficient hepatic synthesis, and by an increase in vasopressin secretion and biosynthesis in the hypothalamus. Converting enzyme inhibition has beneficial effect in this model by lowering cardiac load. It reduces arterial pressure, reverses bi-atrial and right ventricular hypertrophy, reduces the changes in the myosin isoenzyme patterns, and normalizes subendocardial fibrosis and the level of ANF. Although the effects of converting enzyme inhibition are beneficial in this model, they are restricted by their inability to normalize the load and stress when the initial loss of cardiac contractile material exceeds 40%.
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PMID:Left ventricular remodelling following experimental myocardial infarction. 882 57

The transgenic rat (TGR) (mRen-2)27 is said to have low circulating active renin values in plasma and little or no renin gene expression in the kidney. Nevertheless, intrarenal angiotensin II-related effects appear to be responsible for the rightward shift in pressure-natriuresis curves of TGR. To clarify the role of the intrarenal renin-angiotensin system in modulating TGR pressure-natriuresis, TGR were given lifelong lisinopril by treating TGR and their mothers before conception. Rat and mouse renin, AT1 receptor, and angiotensinogen gene expression in the kidneys were studied with in situ hybridization. Neural and endocrine regulatory differences between TGR and Sprague-Dawley Hannover (SDH) rats were eliminated by renal denervation and infusion of vasopressin, aldosterone, 17-OH corticosterone, and norepinephrine. TGR with lisinopril had blood pressures similar to SDH. In TGR with lisinopril, the pressure-natriuresis curve was shifted leftward but not quite to the values observed in SDH given lisinopril. The histology of lisinopril-treated TGR was indistinguishable from normal SDH. Lisinopril increased rat renin and angiotensinogen gene expression both in SDH and TGR, but it did not influence mouse renin gene expression in TGR. Discontinuing lisinopril increased blood pressure in TGR and shifted the pressure-natriuresis relationship rightward. Thus, the components of the endogenous renin-angiotensin system and the mouse renin transgene were present and expressed in kidneys of TGR. The rat gene components responded to lisinopril as expected, but the mouse renin transgene expression was not influenced. Lisinopril normalized TGR blood pressure; however, a detectable leftward shift in pressure-natriuresis remained. These studies underscore the role of angiotensin-mediated effects of the mouse renin transgene in terms of shifting pressure-natriuresis in TGR.
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PMID:Lifelong angiotensin-converting enzyme inhibition, pressure natriuresis, and renin-angiotensin system gene expression in transgenic (mRen-2)27 rats. 891 71

1. Tsukuba hypertensive mice (THM) carry both human renin and angiotensinogen genes, and develop hypertension. The animal has high levels of renin activity and angiotensin II concentration in the plasma. 2. Urinary excretion in THM was greater than in the control animal, non-transgenic C57BL/6j. THM showed a greater amount of daily water intake. The osmolality of 24 h urine was lower than that of the control animal. 3. When water was deprived for 12 h and then loaded with 0.25 mL/10 g bodyweight, the osmolality of urine at the first 0-3 h period was the same in THM and control, but significantly lower in THM at the following 3-6 h period, indicating that the urine concentrating activity is insufficient in THM compared with the control animal. 4. Urinary excretion of vasopressin was significantly higher in THM. Plasma aldosterone concentration and urinary excretion of aldosterone were also higher in THM. Plasma potassium level was significantly low. 5. The mechanism underlying the pathophysiology of polyuria is not totally explained; however, hypokalaemia, which was probably the result of hyperaldosteronism, may be at least partially involved, since hypokalaemia is considered to be a factor hampering the action of vasopressin for concentration of urine at the site of the collecting duct of the kidney.
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PMID:Development of polyuria in Tsukuba hypertensive mice carrying human renin and angiotensinogen genes. 907 20

In the last decade, two types of genes participating in the etiology of hypertension have been identified. The primary genes or blood pressure regulators are those that codify enzymes (renin, kallikrein, kininase, aminopeptidase), hormones (angiotensins, vasopressin, aldosterone, prostaglandins, and atrial natriuretic peptide) and substrates (angiotensinogen and kininogen). They cause arteriolar vasodilation or vasoconstriction or sodium retention in the extravascular space. Allelic polymorphisms associated to essential hypertension have been described. The secondary genes are those that produce hereditary diseases of low prevalence, associated to hypertension in 20 to 80% of patients (polycystic kidney disease, pheochromocytoma, adrenal hyperplasia, hereditary nephritis). Forty genes located in all chromosomes, that are dominantly, recessively or X-linked transmitted, have thus far been identified. Chromosomal maps with all genic loci are presented.
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PMID:[The genes of human hypertension]. 946 Feb 75

Angiotensinogen gene-knockout (Atg-/-) mice lacking angiotensin II exhibit chronic hypotension. The present study was designed to investigate pathophysiology of Atg-/- mice from the renal functional view. Wild-type (Atg+/+) and Atg-/- mice at 10 weeks of age were housed in metabolic cages for 24-hour urine collection. When provided free access to water, Atg-/- mice showed an increased urine output and a decreased urine osmolality compared with Atg+/+ mice. Urinary excretion and plasma levels of vasopressin were significantly higher in mutant mice than in wild-type mice. On the other hand, urinary excretion of aldosterone in mutant mice was suppressed to the levels under the detection limit of the assay system. The mean plasma aldosterone level of Atg-/- mice was suppressed to 30% of that of Atg+/+ mice. Plasma levels of creatinine, endogenous creatinine clearance, and urinary electrolyte excretion were not different between these mice. In Atg+/+ mice, urine osmolality was markedly increased from 1929 +/- 21 to 3314 +/- 402 mOsm/kg during water deprivation, whereas this parameter in Atg-/- mice did not change significantly (from 1413 +/- 121 to 1590 +/- 92 mOsm/kg). Urinary vasopressin excretion increased during water deprivation from 0.24 +/- 0.04 and 0.70 +/- 0.08 to 0.42 +/- 0.06 and 2.31 +/- 0.35 ng/mg creatinine in wild-type and mutant mice, respectively. Histologic study revealed interstitial inflammation, and atrophic changes in the tubules and papilla in Atg-/- mice. In conclusion, a genetic deficiency of angiotensinogen produced an impaired urine concentrating ability and tubulointerstitial lesions, indicating the critical role of angiotensinogen in developing normal tubular function and construction.
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PMID:Genetic deficiency of angiotensinogen produces an impaired urine concentrating ability in mice. 950 98

Chronic volume depletion by dietary salt restriction causes marked decrease in glomerular filtration rate (GFR) with little increase in urine osmolality in angiotensinogen gene null mutant (Agt-/-) mice. Moreover, urine osmolality is insensitive to both water and vasopressin challenge. In contrast, in normal wild-type (Agt+/+) mice, GFR remains remarkably constant and urine osmolality is adjusted promptly. Changes in volume status also cause striking divergence in renal structure between Agt-/- and Agt+/+ mice. Thus, in contrast to the remarkably stable glomerular size of Agt+/+ mice, glomeruli of Agt-/- mice are atrophied during a low salt and hypertrophied during a high salt diet. Moreover, the renal papilla, a structure unique to mammals and essential for urine diluting and concentrating mechanisms, is hypoplastic in Agt-/- mice. Thus, angiotensin is essential for the two fundamental homeostatic functions of the mammalian kidney, namely stable GFR and high urine diluting and concentrating capacity during alteration in extracellular fluid (ECF) volume. This is not only accompanied by angiotensin's tonic effects on renal vasomotor tone and tubule transporters, but also accomplished through its capacity to affect the structure of both the glomerulus and the papilla directly or indirectly.
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PMID:Angiotensinogen gene null-mutant mice lack homeostatic regulation of glomerular filtration and tubular reabsorption. 950 6

The hypertensive double transgenic rat harboring both the human renin and human angiotensinogen genes (dTGR) offers a unique opportunity to study the human renin-angiotensin system in an experimental animal model. Since nothing is known about the control of sodium and water excretion in these rats, this study was performed to compare pressure-natriuresis relationships in hypertensive dTGR and normotensive control rats harboring only the human renin gene (hREN), in order to determine how the pressure-natriuresis relationship is reset in hypertensive dTGR. To differentiate between extrinsic and intrinsic renal mechanisms, experiments were performed with and without renal denervation, and with and without infusions of vasopressin, norepinephrine, 17-OH-corticosterone, and aldosterone. Human and rat angiotensinogen and renin mRNA expression were also determined. In hREN without controlled renal function, urine flow and sodium excretion increased from 13 to 169 microl/min per g kidney wet weight (kwt) and from 1 to 30 micromol/min per g kwt, respectively, as renal perfusion pressure was increased from 67 to 135 mmHg. Renal blood flow (RBF) and GFR ranged between 3 to 7 and 0.9 to 1.5 ml/min per g kwt. In dTGR, pressure-natriuresis-diuresis relationships were shifted approximately 40 mmHg rightward. RBF was lower in dTGR than in hREN; GFR was not different. In dTGR with neurohormonal factors controlled, RBF was decreased and pressure-natriuresis-diuresis curves were not different compared to dTGR curves without these interventions. By light microscopy, the kidneys of these 6-wk-old dTGR and hREN rats were normal and indistinguishable. Both human and rat renin and angiotensinogen mRNA were expressed in the kidneys of dTGR. The two renin mRNA were decreased in dTGR, indicating a physiologic downregulation of renin gene expression by high BP. It is concluded that the renal pressure-natriuresis mechanism is reset toward higher pressure levels in dTGR and participates in the maintenance of hypertension. The reduced excretory function in dTGR depends on hREN and human angiotensinogen gene expression and is intrinsic to the kidney as opposed to extrarenal regulators.
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PMID:Pressure-natriuresis and -diuresis in transgenic rats harboring both human renin and human angiotensinogen genes. 984 75

Angiotensin produced systemically or locally in tissues such as the brain plays an important role in the regulation of blood pressure and in the development of hypertension. We have established transgenic rats [TGR(ASrAOGEN)] expressing an antisense RNA against angiotensinogen mRNA specifically in the brain. In these animals, the brain angiotensinogen level is reduced by more than 90% and the drinking response to intracerebroventricular renin infusions is decreased markedly compared with control rats. Blood pressure of transgenic rats is lowered by 8 mmHg (1 mmHg = 133 Pa) compared with control rats. Crossbreeding of TGR(ASrAOGEN) with a hypertensive transgenic rat strain exhibiting elevated angiotensin II levels in tissues results in a marked attenuation of the hypertensive phenotype. Moreover, TGR(ASrAOGEN) exhibit a diabetes insipidus-like syndrome producing an increased amount of urine with decreased osmolarity. The observed reduction in plasma vasopressin by 35% may mediate these phenotypes of TGR(ASrAOGEN). This new animal model presenting long-term and tissue-specific down-regulation of angiotensinogen corroborates the functional significance of local angiotensin production in the brain for the central regulation of blood pressure and for the pathogenesis of hypertension.
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PMID:Blood pressure reduction and diabetes insipidus in transgenic rats deficient in brain angiotensinogen. 1009 48

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