Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01185 (vasopressin)
 23,126 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Idiopathic edema is characterized by impaired water excretion, particularly in the upright posture. Indirect evidence has shown that antidiuretic hormone is involved in this disease. For this reason, we measured urinary arginine vasopressin by radioimmunoassay before and during water loading (15 ml/kg) in 10 normal women and in 10 subjects with idiopathic edema in both the supine and upright postures. Daily sodium intake was 100 meq. Renin and aldosterone were concomitantly investigated, and abnormally high values were observed both in the recumbent and upright postures. Basal values for urinary arginine vasopressin were identical in control subjects and in patients with idiopathic edema. The water load significantly reduced urinary arginine vasopressin in normal women in both positions, but in those with idiopathic edema only in the supine position. In those with idiopathic edema, assumption of the upright posture was accompanied by a transient decrease in glomerular filtration, a major decrease in osmolar clearance and no decrease in urinary arginine vasopressin after water loading. Significant correlations were established between urinary arginine vasopressin and osmolar or volemic parameters in normal women, but these correlations were not found in those with idiopathic edema in either position. Arginine vasopressin regulation was abnormal in idiopathic edema, and this hormone was believed to play a part in the pathogenesis of this disease.
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PMID:Abnormal regulation of antidiuretic hormone in idiopathic edema. 46 18

Unanesthetized dogs were infused with heterologous (hog) renin at 0.33 Goldblatt U/kg per h for 2 h, once normally hydrated and once after 48 h of dehydration. Dehydration increased the average plasma osmolality from 306 to 322 mosmol/kg, the plasma renin activity (PRA) from 0.5 to 1.4 ng/ml per h, and the plasma antidiuretic hormone (ADH) concentration from 1.7 to 3.7 muU/ml, although the latter was not statistically significant. Renin infusion resulted in approximately the same average PRA, about 10 ng/ml per h, in both states of hydration. Mean arterial blood pressure increased during renin infusion in both states of hydration, although the increase was greater when the dogs were normally hydrated. There was no apparent effect of renin infusion on plasma ADH concentration when the dogs were normally hydrated, but in the dehydrated state renin infusion was accompanied by an increase from 3.7 to 6.3 muU/ml in plasma ADH concentrations after 80 min of infusion. There were no apparent changes in plasma osmolality or sodium or potassium concentrations due to the renin infusions; however, plasma osmolality and potassium concentration decreased during the course of the experiment. The results suggest a possible role for the renin-angiotensin system of renin released by the kidney in the control of ADH during dehydration. The metabolic clearance rate of the hog renin was 37 ml/min-kg.
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PMID:Effect of dehydration on stimulation of ADH release by heterologous renin infusions in conscious dogs. 97 Apr 47

1. Isolated rat kidneys were perfused at a constant pressure of 90 mmHg in a single-pass system with either a cell-free medium or a suspension of washed bovine red blood cells, free of the components of the renin-angiotensin system. In red blood cell perfused kidneys renal haemodynamics and sodium reabsorption corresponded closer to values observed in the intact rat than in cell-free perfused kidneys. 2. In red blood cell-perfused kidneys in the absence of plasma renin substrate autoregulation of renal blood flow was almost complete at pressures above 90 mmHg, provided that perfusion pressure was changed rapidly. 3. Renin release varied inversely with perfusion pressure within a pressure range from 50 to 150 mmHg; the greatest changes of renin release occurred, when perfusion pressure was reduced from 90 to 70 mmHg; maximal stimulation of renin release was observed at 50 mmHg. After reduction of perfusion pressure, renin release immediately started to rise and reached a new level within 5 min. Local reduction of perfusion pressure in small arteries and arterioles by the injection of microspheres induced a short-lasting decrease in renal plasma flow and a transient stimulation of renin release. 4. High concentrations of furosemide stimulated renin release by a direct intrarenal mechanism. 5. Isoproterenol stimulated renin release in low concentrations without a concomitant vasodilation, whereas high concentrations induced an increase in both renal plasma flow and renin release. The effects of isoproterenol were completely blocked by propranolol. 6. Sodium nitroprusside induced similar increases in renal plasma flow, as did high concentrations of isoproterenol, but only a small and slow increase in renin release was observed. 7. Angiotensin II (AII) suppressed renin release in concentrations corresponding to plasma levels measured in the intact rat independently of its vasoconstrictor effects, whereas vasopressin in antidiuretic concentrations did not affect renin release. 8. AII, AI, synthetic tetradecapeptide renin substrate (TDP), crude and purified rat plasma renin substrate induced a dose-dependent reduction in renal plasma flow. SQ 20 881, a competitive inhibitor of converting enzyme, and low doses of 1-Sar-8-Ala-AII (saralasin), a competitive antagonist of AII, did not change renal plasma flow, whereas high concentrations of saralasin had a vasoconstrictor effect on their own. 9. Saralasin inhibited the vasoconstrictor effects of AII and TDP to a similar degree. SQ 20 881 inhibited the vasoconstrictor effects of AI and purified renin substrate, but did not influence the actions of TDP and the crude renin substrate preparation. 10. From these data it is concluded, that AI is converted into AII within the kidney at a rate of 1-2%. The vasoconstriction induced by the crude renin substrate probably does not involve the AII receptors. TDP may act by itself on the AII receptors or via the direct intrarenal formation of AII...
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PMID:Regulation of renin release and intrarenal formation of angiotensin. Studies in the isolated perfused rat kidney. 98 7

Injection of posterior pituitary powder induces an intense mitotic stimulation in the zona glomerulosa of the adrenal gland of young rats. This effect is much more pronounced in females than in males. It is maximal at two days treatment. Longer periods result in a hypertrophied zona glomerulosa and lower mitotic activity. A search for the hormone responsible for the stimulation shows that vasopressin, and to a lesser extent oxytocin, are mitogenic. ACTH, alpha-MSH, beta-MSH and the pineal hormones have no effect. Renin (but not angiotensin) induces a significant stimulation. It is concluded that vasopressin exerts a potent influence on the glomerulosa. This is in contrast with the prevalent view that the glomerulosa is little affected by the hypophysis.
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PMID:Adrenal glomerulosa mitotic stimulation by posterior pituitary hormones. 99 Dec 6

Overall 210 patients aged 60-74 years suffering from coronary heart disease associated with chronic circulatory failure, stages I, IIA and IIB, 53 patients aged 45-59 years and 20 healthy persons aged 45-74 years were examined for the renin-angiotensin-aldosterone system and antidiuretic hormone. Renin activity, the concentration of aldosterone and vasopressin in blood plasma were investigated by radioimmunoassay. In the initial stage of heart failure, the elderly persons showed up more marked renin activation in blood plasma, followed by its lowering as decompensation progressed as well as an increase in the concentration of aldosterone and vasopressin, which resulted in the progress of circulatory failure.
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PMID:[The renin-angiotensin-aldosterone system and antidiuretic hormone in chronic circulatory failure in elderly subjects]. 144 Feb 54

Echocardiographically determined left ventricular function and cardiovascular hormone balance were assessed before and after hemodialysis in 10 patients who had been on hemodialysis for 4 months to 15 years. Plasma levels of atrial natriuretic peptide (ANP), antidiuretic hormone (ADH), renin activity and aldosterone were determined. All patients had vector- and echocardiographic evidences of slight to moderate left ventricular hypertrophy. The body weight decreased 2.0 kg (3.3 +/- 0.5%) with dialysis. Nine out of ten patients showed a slightly reduced ejection fraction that normalized after dialysis (p less than 0.05). Left atrial and ventricular systolic dimensions were around the upper reference limit before dialysis with a decrease after dialysis (p less than 0.05 and p less than 0.02, respectively). The levels of ANP decreased with dialysis from 2-17 times to 1 to 15 times the upper reference value in nine out of the ten patients. In the whole group the decrease was 117 +/- 35% (p less than 0.005). A significant regression was obtained between percentage decrease of body weight and percentage change of ANP (r = 0.67; p less than 0.05). The plasma concentration of ADH did not change following dialysis but the mean value was significantly higher than the mean value of the reference group of the laboratory (p less than 0.05 before and p less than 0.005 after dialysis). Renin activity and aldosterone levels were low and did not change during dialysis. In conclusion, the slight left ventricular hypertrophy may partly be a response to volume overload with hyperdynamic circulation and partly to metabolically depressed myocardial function.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Cardiac function and cardiovascular hormone balance during hemodialysis with special reference to atrial natriuretic peptide. 297 8

The physical properties and chemical composition of urine are highly variable and are determined in large measure by the quantity and the type of food consumed. The specific gravity is the ratio of the density to that of water, and it is dependent on the number and weight of solute particles and on the temperature of the sample. The weight of solute particles is constituted mainly of urea (73%), chloride (5.4%), sodium (5.1%), potassium (2.4%), phosphate (2.0%), uric acid (1.7%), and sulfate (1.3%). Nevertheless, urine osmolality depends only on the number of solute particles. The renal production of maximally concentrated urine and formation of dilute urine may be reduced to two basic elements: (1) generation and maintenance of a renal medullary solute concentration hypertonic to plasma and (2) a mechanism for osmotic equilibration between the inner medulla and the collecting duct fluid. The interaction of the renal medullary countercurrent system, circulating levels of antidiuretic hormone, and thirst regulates water metabolism. Renin, aldosterone, prostaglandins, and kinins also play a role. Clinical estimation of the concentrating and diluting capacity can be performed by relatively simple provocative tests. However, urinary specific gravity after taking no fluids for 12 h overnight should be 1.025 or more, so that the second urine in the morning is a useful sample for screening purposes. Many preservation procedures affect specific gravity measurements. The concentration of solids (or water) in urine can be measured by weighing, hydrometer, refractometry, surface tension, osmolality, a reagent strip, or oscillations of a capillary tube. These measurements are interrelated, not identical. Urinary density measurement is useful to assess the disorders of water balance and to discriminate between prerenal azotemia and acute tubular necrosis. The water balance regulates the serum sodium concentration, therefore disorders are revealed by hypo- and hypernatremia. The disturbances are due to renal and nonrenal diseases, mainly liver, cardiovascular, intestinal, endocrine, and iatrogenic. Fluid management is an important topic of intensive care medicine. Moreover, the usefulness of specific gravity measurement of urine lies in interpreting other findings of urinalysis, both chemical and microscopical.
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PMID:Relative density of urine: methods and clinical significance. 307 30

We have suggested that the renal tubular signal for renin release is related to alterations of sodium chloride cotransport in the TALH. Renin release is inhibited by increased sodium chloride transport and stimulated by interrupted sodium chloride transport. Because of the different affinities of the carriers for sodium and chloride, chloride rather than sodium is rate limiting for this cotransport process. Consequently, renin release is related to alterations of chloride delivery rather than sodium delivery to the TALH. The reduction of PRA by selective chloride loading and by short-term infusion of chloride salts is related to increased chloride delivery to the loop and hence increased chloride transport. Alternatively, chlorpropamide and antidiuretic hormone may inhibit renin release by increasing chloride delivery to the loop. Stimulation of renin release may likewise be related either to decreased chloride delivery and hence decreased transport in the loop (hypochloremia related to selective chloride deprivation) or to an intrinsic alteration in the transporting capacity of the loop (loop diuretics, potassium depletion, glucocorticoid deficiency, Bartter's syndrome). The intermediate steps between alterations of sodium chloride transport in the TALH and renin release remain to be defined.
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PMID:Renal tubular chloride and renin release. 331 41

Renin secretion from the juxtaglomerular cell is controlled by numerous receptors, humoral agents, and ions. Recently, a stretch receptor hypothesis has been advanced to suggest that all of these diverse factors control renin secretion by a mechanism initiated by a fall in cytoplasmic Ca2+. This fall in Ca2+ may be achieved by lowering Ca2+ influx, raising Ca2+ efflux, or sequestering Ca2+ into cellular organelles and binding sites. The increased renin secretion observed with low arterial pressure, beta-adrenergic agonists, parathyroid hormone, glucagon, cyclic AMP, prostaglandins, low Ca2+ and Ca2+ ionophore, high Mg2+, and Na+ and Cl- may be explained in this context. On the other hand, the decreased renin secretion observed with high pressure, alpha-adrenergic agonists, some prostaglandins, angiotensin, vasopressin, and high K+ may be explained by a rise in cytoplasmic Ca2+ mediated by an opposite sequence of events. Recent observations suggest that the fall in cytoplasmic Ca2+ sets in motion the transport of renin from its site of storage (granules) or synthesis into the cytoplasmic space and finally across the plasma membrane. Thus although renin is stored in granules, its secretion occurs by a process quite different from exocytosis.
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PMID:Cellular mechanisms of renin secretion. 635 57

The most primitive components of the RAS appeared early in the phylogenetic history of vertebrate animals. It is probable that renin granules were present in the kidneys of ancestral chordates before divergence in the evolution of actinopterygian fish and tetrapods occurred. Granulated juxtaglomerular cells similar to the renin-containing cells of the mammalian nephron are found in most extant vertebrate species although not in agnathan and elasmobranch fish. A macula densa occurs in amphibians, birds and mammals; and an extraglomerular mesangium, only in birds and mammals. Renin-like activity and angiotensin-like pressor material have been demonstrated in all classes of vertebrates. The amino acid sequences of native ANG I have been determined for representative species of teleost fish, amphibian, reptile and bird. These peptides differ from mammalian angiotensins at positions 1, 5 and 9. The RAS appears to be involved in osmoregulation, ionoregulation and the control of blood circulation. Prolonged hypovolemic hypotension or sodium depletion increases renin levels. Angiotensins elicit drinking and stimulate transepithelial ion transport. However, direct steroidogenic and antidiuretic hormone-releasing activities, which would promote mineral and fluid conservation, have not been demonstrated unambiguously in nonmammalian vertebrates. ANG II raises blood pressure by direct vasoconstrictor action on arteriolar muscles in some animals, but perhaps more generally by acting on the nervous system and adrenal paraneurons. In birds the hormone also has a hypotensive effect. ANG II stimulates the SNS in agnathans, elasmobranchs, teleosts, amphibians, reptiles, birds and mammals. Thus, modulation of sympathetic activity may be one of the most primitive and conservative functions of the RAS. For this reason, nonmammalian vertebrates are valuable models for studying the neurogenic actions of angiotensin II relevant to hypertensive disease.
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PMID:The renin-angiotensin system in nonmammalian vertebrates. 636 15


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