Measurement and characterization of angiotensin peptides in plasma

We report a method for the extraction of angiotensin peptides from plasma with a mixture of acetone, 1 mol/L HCl, and water (40/1/5 by vol). The method is highly reproducible for the measurement of angiotensin I and angiotensin II in small sample volumes, with analytical recoveries of about 80% for both peptides. We investigated the influence of sample handling and found a standard procedure for blood collection, plasma preparation, and extraction was essential. The method was used to measure angiotensin I and II in rat and human plasma. In rat plasma, the mean (+/- SEM) concentrations of angiotensin I and angiotensin II were determined to be 67 (+/- 8) and 14 (+/- 1) pmol/L (n = 10), respectively. Neither angiotensin I nor angiotensin II was detectable 24 h after bilateral nephrectomy. Acute oral administration of the converting-enzyme inhibitor ramipril caused a significant increase of angiotensin I from 85 (+/- 6) to 257 (+/- 33) pmol/L (n = 10; P less than 0.001) and a significant decrease of angiotensin II from 12 (+/- 1) to 7 (+/- 0.4) pmol/L in rat plasma (n = 9; P less than 0.001). In human plasma, angiotensin I and angiotensin II values of 21 (+/- 1) and 6.6 (+/- 0.5) pmol/L (n = 10) were found. A single oral dose of the diuretic furosemide increased angiotensin I significantly from 21 (+/- 1) to 32 (+/- 1.7) pmol/L (n = 5); P less than 0.001), whereas angiotensin II remained unchanged, 6.6 (+/- 0.5) vs 6.4 (+/- 0.4) pmol/L (n = 5). Extracted peptides could be identified as [IIe5]-angiotensin I and [IIe5]-angiotensin II by HPLC in combination with specific radioimmunoassays for angiotensin I and angiotensin II.     

Pathogenic factors involved in renovascular hypertension. State of the art.

The complex hormonal action of angiotensin II in the long-term control of blood pressure or sodium metabolism, or in renal hypertension, is not completely understood. Structure-activity relations with analogues of angiotensin II gave information about the functions responsible for pressor and myotropic response in the molecule that led to the synthesis of competitive antagonists of this hormone. These antagonists, however, show variable agonist/antagonist ratios in different species or different tissues of the same species. This fact necessitates further work to induce tissue specificity. Although des-Asp1-angiotensin II ("angiotensin III") has been recognized as a hormone, its exact role in the biosynthesis of aldosterone is yet to be discovered. The antagonists such as des-Asp1-[Ile8]-angiotensin II or des-Asp1-[Thr8]-angiotensin II have provided important leads in this direction. Many of the biologic effects of angiotensin I have been attributed to its conversion to angiotensin II by the converting enzyme. Recent investigations indicate that angiotensin I itself may play a direct role; however, most of these studies were carried out by inhibiting the converting enzyme activity with peptides obtained from the venom of Bothrops jararaca. Since these peptides also potentiate bradykinin action, the observed biologic activities could be caused by either angiotensin I or bradykinin. Bsides, converting enzyme is no longer thought to be a single enzyme and its nature varies from species to species and from tissue to tissue in the same species. Renin inhibitors related to renin substrate or pepstatin are not freely soluble in plasma and are not effective under physiologic conditions. This points to the importance of renin inhibitors isolated from kidney or other natural sources. Thus, although the renin-angiotensin system appears to be an integral part of the problem of hypertension, characterization of various converting enzymes, roles of extrarenal renin, isorenin, tonin, and brain-renin, and the involvement of other humoral, neurogenic, and immunogenic factors should be pieced together to get a clear picture of the hypertension problem.     

Endothelium-dependent contractions induced by angiotensin I and angiotensin II in canine cerebral artery

Whether angiotensin I and angiotensin II caused endothelium-dependent contraction was examined in canine cerebral arteries. In endothelium-intact preparations, angiotensin I and angiotensin II at 10(-8) to 10(-6) M caused dose-dependent contractions, whereas both angiotensins caused much less contractions in endothelium-removed preparations. The contractions induced by angiotensin I and angiotensin II were strongly attenuated by aspirin (cyclooxygenase inhibitor) (5 x 10(-5) M), OKY-046 [thromboxane (TX) A2 synthetase inhibitor] (10(-5) M) and ONO-3708 (TX)A2 antagonist) (5 X 10(-9) M). Captopril (10(-6) M) significantly attenuated the contractions induced by angiotensin I but not those induced by angiotensin II. Angiotensin I- and angiotensin II- induced contractions were inhibited markedly by Sar1, Ala8-angiotensin II (10(-9) and 10(-8) M). The present experiments demonstrate that angiotensin I and angiotensin II produce endothelium-dependent contraction in canine cerebral artery via a factor which appears to be TXA2. Angiotensin I may be converted by endothelial cells to angiotensin II, which may activate the cells to produce TXA2 in canine cerebral artery.     

IMMUNOLOGIC PRODUCTION OF ANTIANGIOTENSIN : II. PRODUCTION AND DETECTION OF ANTIANGIOTENSIN

The parenteral administration of benzoylangiotensin II-azo-BGG to rabbits produced an antiserum with antiangiotensin activity. Antiangiotensin inhibited the biological action of p-aminobenzoylangiotensin II, valine⁵-angiotensin II (free acid form), isoleucine⁵-angiotensin II and valine⁵-angiotensin II (amide form), but it was totally inert towards angiotensin 1. Antiangiotensin activity was distinguished from that of serum angiotensinase by the following observations: (a) an angiotensinase-free γ-globulin fraction contained antiangiotensin, (b) angiotensinase inactivated angiotensin II (both the amide and free acid forms) and angiotensin I in contrast to the remarkable specificity for angiotensin II exhibited by antiangiotensin. Serological demonstration of antiangiotensin included: (a) a comparison of its precipitin reaction with the angiotensin BGG complex with the reaction with BGG alone, (b) the partial inhibition of the precipitin reaction with the angiotensin BGG complex by angiotensin II, (c) a precipitin reaction with a different angiotensin II protein complex (cat serum). Angiotensin II administered parenterally as the free polypeptide was not antigenic.     

Radioligand binding reveals chymase as the predominant enzyme for mediating tissue conversion of angiotensin I in the normal human heart.

We investigated the binding characteristics of angiotensin receptors and used this assay to determine the predominant enzyme capable of converting angiotensin I in the human left ventricle. In homogenates of human left ventricle, (125)I-[Sar(1),Ile(8)]angiotensin II bound with sub-nanomolar affinity, with a corresponding K(D) of 0.42+/-0.09 nM, a B(max) of 11.2+/-2.3 fmol.mg(-1) protein and a Hill slope of 1.04+/-0.04. The rank order of inhibitory potency of competing ligands for the (125)I-[Sar(1),Ile(8)]angiotensin II binding site was CGP42112>angiotensin II> or =angiotensin III=angiotensin I>losartan. The angiotensin type II (AT(2)) receptor predominated in the human left ventricle over the angiotensin type I (AT(1)) receptor, with an approximate AT(1)/AT(2) receptor ratio of 35:65. No specific (125)I-angiotensin IV binding sites could be detected in the human left ventricle. Using competitive radioligand binding assays, we were able to demonstrate that the chymase/cathepsin G enzyme inhibitor chymostatin was more potent than the angiotensin-converting enzyme (ACE) inhibitor captopril at inhibiting the conversion of angiotensin I in the human left ventricle. Aprotonin (an inhibitor of cathepsin G but of not chymase) had no effect on angiotensin I conversion, suggesting that the majority of the conversion was mediated by chymase. Thus, although the current therapies used for the renin-angiotensin system have focused on ACE inhibitors and AT(1) receptor antagonists, the left ventricle of the human heart expresses mainly AT(2) receptors and the tissue-specific conversion of angiotensin I occurs predominantly via chymase rather than ACE.     

The effect of captopril on blood pressure and angiotensins I, II and III in sodium-depleted dogs: problems associated with the measurement of angiotensin II after inhibition of converting enzyme

1. Changes in arterial blood pressure, blood angiotensin I, plasma angiotensin II and plasma angiotensin III were measured in conscious sodium-depleted dogs after infusion of captopril, an orally active inhibitor of converting enzyme. 2. Angiotensins II and III were measured after chromatography to remove angiotensin I, which increased in concentration after inhibition of converting enzyme and which interfered in the direct assay for angiotensin II. 3. Infusion of captopril at 20, 200, 2000 and 6000 microgram h-1 kg-1, each for 3 h, produced a rapid fall in blood pressure and in concentration of angiotensin II. Angiotensin II was undetectable at 6000 microgram h-1 kg-1 (mean pre-infusion value for all samples was 39 +/- SD 15 pmol/1, n = 14). 4. The percentage fall in blood pressure correlated with the percentage fall in plasma angiotensin II (r = 0.65, P < 0.001). 5. These results suggest that the initial fall in blood pressure may be mediated in part by the suppression of angiotensin II. 6. Blood angiotensin I concentration rose with each rate of infusion of drug to a maximum 16-fold increase at 6000 microgram h-1 kg-1 (26-416 pmol/l). The rise in angiotensin I was inversely related to the fall in angiotensin II (r = 0.68, P < 0.001).     

Selective blockade of angiotensin responses in the rabbit isolated vas deferens by angiotensin receptor antagonists

We examined the effect of two angiotensin receptor antagonists on neuromodulatory and prostaglandin-producing effects of angiotensin II in the rabbit isolated vas deferens because prior studies have established that angiotensins selectively influence the two neural events, one being adrenergic and the other nonadrenergic. Angiotensin II increased adrenergic neurotransmission and prostaglandin E synthesis in a concentration-dependent manner while depressing nonadrenergic neurotransmission. The [1-Sarcosine, 8-Alanine]-angiotensin II preferentially antagonized adrenergic neuromodulatory effects of angiotensin II. In contrast, the nonadrenergic neuromodulatory and prostaglandin E-releasing effects of angiotensin II were suppressed by [1-Sarcosine, 8-Alanine]-angiotensin II to a lesser extent. The nonpeptide angiotensin receptor antagonist, Dupont 753 (2-n-butyl-4-chloro-5-hydroxymethyl-1-[2(1)-(1-H-tetrazol-5-yl) biphenyl-4-yl)methyl] imidazole, potassium salt, exhibited the opposite selectivity. It eliminated the depression of nonadrenergic neurotransmission without significantly altering the potentiation of adrenergic neurotransmission caused by angiotensin II. The angiotensin-induced stimulation of prostaglandin E synthesis was also eliminated by this antagonist. These data suggest that angiotensin effects in the vas deferens are mediated by at least two types of angiotensin receptors.     

Effect of angiotensin II infusion with and without angiotensin II type 1 receptor blockade on nitric oxide metabolism and endothelin in human beings: a placebo-controlled study in healthy volunteers

BACKGROUND: Angiotensin II has been shown to induce the synthesis of endothelium-derived relaxing factor nitric oxide (NO) and endothelin in vitro. In human beings, to our knowledge, no data on NO release in response to angiotensin II and on the influence of angiotensin II type 1 receptor blockade have been published. METHODS: In a placebo-controlled study in nine healthy volunteers, angiotensin II was administered intravenously for 6 hours with and without pretreatment with valsartan, a specific angiotensin II type 1 receptor antagonist. NO (NO2 + NO3) and endothelin plasma concentrations, clearance values for inulin and paraaminohippuric acid and NO (NO2 + NO3) excretion in urine were determined. RESULTS: During angiotensin II infusion NO plasma concentrations remained unaltered compared with placebo after 3 hours: 6.66 +/- 5.49 versus 5.56 +/- 3.09 micromol/L (P = ns) but increased after 6 hours: 18.36 +/- 20.02 versus 7.13 +/- 3.87 micromol/L (P < .04). The same was noted after pretreatment with valsartan: 7.61 +/- 5.69 versus 5.56 +/- 3.09 micromol/L (P= ns) after 3 hours, and 21.70 +/- 11.51 versus 7.13 +/- 3.87 micromol/L (P = .02) after 6 hours. In urine fractional NO excretion decreased after angiotensin II infusion: 0.87 +/- 0.72 versus 0.95 +/- 0.71 (P = .5) during the first 3 hours, and 0.44 +/- 0.39 versus 0.78 +/- 0.43 (P = .01) during the following 3 hours. After valsartan pretreatment the decrease in fractional urinary NO excretion began earlier: 0.40 +/- 0.15 versus 0.95 +/- 0.71 (P = .04) during the first 3 hours, and 0.17 +/- 0.11 versus 0.78 +/- 0.43 (P = .01) during the following 3 hours. Endothelin plasma concentrations showed no difference after angiotensin II infusion with or without valsartan. CONCLUSIONS: Our observations demonstrate for the first time that angiotensin II increases NO plasma concentrations in human beings and that this response is not mediated by angiotensin II type 1 receptor. In spite of increased NO plasma levels, urinary NO excretion decreased. Endothelin plasma levels remained unchanged during angiotensin II infusion.     

Effects of treatment with angiotensin-converting enzyme inhibitor (ACEI) or angiotensin II receptor antagonist (AIIRA) on renal function and glomerular injury in subtotal nephrectomized rats

The aim of this study was to determine if treatment with angiotensin-converting enzyme inhibitors (ACEI) or angiotensin II receptor antagonists (AIIRA) might decrease urinary albumin excretion and prevent glomerular enlargement and glomerulosclerosis in subtotal (5/6) nephrectomized rats. Morphometric image analysis of glomeruli was also performed in the subtotal nephrectomized rats. The nephrectomized rats were treated with ACEI (enalapril 100mg/l), AIIRA (L-158,809 10 mg/l) or TRX (reserpine 5 mg/l, hydralazine 80 mg/l, and hydrochlorothiazide 25 mg/l) and euthanized at 16 weeks after renal ablation. Treatments were started at 2 weeks (early treatment: Group I) or 8 weeks (later treatment: Group II) after the ablation. ACEI and AIIRA treatments were equally and significantly effective in limiting albuminuria and progression of glomerular sclerosis. TRX was also as effective in decreasing urinary albumin excretion and preserving the renal function as ACEI or AIIRA in Group I. The improvement of albuminuria, glomerular enlargement and sclerosis after these treatments in Group II was significantly less than that in Group I. It appears that the early treatment with angiotensin converting enzyme inhibitor, angiotensin II receptor antagonist or reserpine, hydralazine and hydrochlorothiazide (TRX) may prevent glomerular injury in human patients with renal hypertension. J. Clin. Lab. Anal. 11:53–62. © 1997 Wiley-Liss, Inc.     

The excretion of carbonic anhydrase isozymes CA I and CA II in the urine of apparently healthy subjects and in patients with kidney disease

Carbonic anhydrase isozymes CA I and CA II were assayed by a radio-immunosorbent technique in the plasma and urine of apparently healthy subjects and of patients with renal disease. The concentrations (mean +/- SD, n = 8) of CA I and CA II in the plasma of healthy subjects were 2.3 +/- 2.3 and 0.8 +/- 0.5 mg/l, respectively. The urinary excretion values were 3.8 +/- 2.0 and 3.5 +/- 1.9 micrograms/24 h, and the apparent renal clearances were 21 +/- 17 and 52 +/- 44 microliters/min, respectively, values that are similar to those of other low molecular weight proteins. CA I and CA II have mol. wt of 28,850 and 29,300, respectively, they are globular in shape and have a Stoke-Einstein radius of 25 A. They could, therefore, be expected to be filtered at the glomeruli and thereafter reabsorbed by the proximal tubules. CA II is also present in the cytoplasm of renal proximal and distal tubular cells. A study of the pattern of urinary excretion of CA I and CA II could permit detection of damage to renal tubular cells in two ways--either from defective reabsorption of filtered CA I and CA II by the proximal tubular cells, or from leakage of CA II from the proximal or distal tubules into the urine. Some patients with hypercalcuria and renal tubular acidosis showed increased excretion of these enzyme proteins and of beta 2-microglobulin (BMG) into the urine, but the prevalence was rather low (27%). Further studies of patients with more severely damaged kidneys are required.     

Activity of [des-Aspartyl1]-Angiotensin II in Primary Aldosteronism

This study describes the effects of [des-Aspartyl(1)]-angiotensin II ([des-Asp]-AII) on blood pressure and aldosterone production in patients with primary aldosteronism due to aldosterone-producing adrenal adenoma (APA) and idiopathic adrenal hyperplasia (IHA), and in normotensive control subjects. 10 patients with primary aldosteronism, 7 with APA and 3 with IHA, and 6 normotensive control subjects were placed on a constant 150-meq sodium diet for 4 days. [des-Asp]-AII was infused for 30 min at 6, 12, and 18 pmol/kg per min. Three groups of patients were identified on the basis of aldosterone response to [des-Asp]-AII. Group I, composed of normotensive control subjects, showed incremental increases in plasma aldosterone concentration from 6+/-1 to 14+/-3 ng/100 ml (P < 0.01) with [des-Asp]-AII infusion. Group II, composed of patients with primary aldosteronism, showed incremental increases in plasma aldosterone concentration from 33+/-8 to 65+/-13 ng/100 ml (P < 0.05) with 12 pmol/kg per min of [des-Asp]-AII. Group III, also composed of patients with primary aldosteronism, showed no increase of plasma aldosterone concentration with [des-Asp]-AII. Groups I and II showed similar percentage increases in plasma aldosterone concentration (P = NS). Group III showed significantly lower aldosterone responses than group I (P < 0.01). Group II included all patients with IHA and two patients with APA. Group III included only patients with APA. The blood pressure responses to [des-Asp]-AII of subjects in group I did not differ significantly from those of groups II or III.Thus, patients with IHA and a subgroup of patients with APA showed responsiveness to [des-Asp]-AII which was limited to adrenal cortical stimulation of aldosterone biosynthesis. This suggests that adrenal responsiveness to angiotensin is a major control mechanism in some forms of primary aldosteronism. The differential adrenal responsiveness to [des-Asp]-AII in patients with APA indicates either that there are two distinct subpopulations of APA, or that alteration in tumor response to angiotensin occurs during the natural progression of the disease history.     

Effect of the converting enzyme inhibitor SQ-20881 on urinary excretion of prostaglandin E2 in the rat: influence of pretreatment with deoxycorticosterone

The effect of SQ-20881, an inhibitor of the peptidyl dipeptidase that degrades kinins and converts angiotensin I to angiotensin II, on the urinary excretion of immunoreactive prostaglandin E2 (iPGE2) was studied in rats receiving either deoxycorticosterone (DOCA, 5 mg/day s.c.) or sesame oil vehicle for 10 days before and then during the study, DOCA-treated animals had higher urinary excretion of iPHE2 and kallikrein, and lower plasma renin, than did animals injected with oil only. In rats pretreated with DOCA, infusion of SQ-20881 (1.2 mg/day s.c.) for 6 days increased iPGE2 excretion from 87.3 +/- 1.9 to 150.9 +/- 14.5 ng/day (P < .05). In contrast, in rats pretreated with vehicle, SQ-20881 had no significant effect on urine iPGE2. The enzyme inhibitor did not affect the intake of fluid, the volume of urine or the urinary excretion of kallikrein and electrolytes in either DOCA- or vehicle-treated animals. The blood pressure reduction elicited by a bolus injection of bradykinin (1.0 microgram i.v.) was greater in rats receiving SQ-20881 than in vehicle-infused controls, both in the DOCA- and in the sesame oil-treated groups, suggesting inhibition of kinin degradation by the converting enzyme inhibitor. These results indicate that DOCA or the consequences of its administration are required for SQ-20881 to increase iPHE2 excretion in the rat. Such an effect of the inhibitor probably relates to stimulation of renal prostaglandin synthesis consequent to elevation of kinin levels.     

Studies on the renin-angiotensin system in a kininogen-deficient individual

The physiological responses of the renin-angiotensin system were studied in an individual with kininogen deficiency (patient 1) with absent plasma bradykinin and markedly impaired pre-kallikrein conversion into kallikrein. After sodium depletion, patient 1 had a low plasma renin activity (1.4 pmol of ANG I h-1 ml-1) and a low angiotensin II concentration (36 pg/ml) compared with values in 11 normal individuals (4.0 +/- 0.94 pmol of ANG I h-1 ml-1) and 63 +/- 6 pg/ml respectively). Unlike normal individuals, in the kininogen-deficient subject there was no significant fall of renin activity or angiotensin II after dietary sodium repletion. Intravenous sodium repletion also failed to further decrease plasma renin activity or angiotensin II. The usual two- to three-fold rise in plasma renin activity and angiotensin II observed in normal subjects on assumption of the upright posture after ingestion of 200 mg of sodium/day failed to occur in the kininogen-deficient individual. These data in vivo are in agreement with observations in vitro that once plasma kallikrein forms it may be important in converting prorenin into renin. In the absence of kininogen, activation of prekallikrein to kallikrein is grossly defective, which may in part account for the diminished response of the renin-angiotensin system to changes in sodium balance and posture.     

Post-renal-transplant hypertension. Urine volume, free water clearance and plasma concentrations of arginine vasopressin, angiotensin II and aldosterone before and after oral water loading in hypertensive and normotensive renal transplant recipients

Urine volume (V), free water clearance (CH2O) and plasma concentrations of arginine vasopressin (AVP), angiotensin II (A II) and aldosterone (Aldo) were determined before and three times during the first 5 h after an oral water load of 20 ml/kg body wt in 19 patients with post-renal-transplant hypertension (group I), in 13 normotensive renal transplant recipients (group II) and in 20 control subjects (group III). Both V and CH2O increased significantly in all groups, but considerably less in groups I and II than in group III. When CH2O was related to glomerular filtration rate no differences existed between patients and control subjects. Basal AVP was the same in groups I (3.3 pmol/l, median) and II (3.0 pmol/l), but significantly (p less than 0.01) higher than in group III (1.9 pmol/l). Basal A II was significantly (p less than 0.01) elevated in group I (18 pmol/l) when compared to both groups II (10 pmol/l) and III (11 pmol/l), and the level was independent of the presence of native kidneys. Basal Aldo was the same in all groups. During loading, AVP was reduced in all groups, A II was almost unchanged, and Aldo was increased in groups I and II and reduced in group III depending on alterations in serum potassium. Thus urinary diluting ability is reduced in renal transplant recipients due to a reduced glomerular filtration rate. The enhanced A II in hypertensive renal transplant recipients gives further evidence for the point of view that hypertension is angiotensin-dependent in most of these patients.     

Expression of AT2 receptors in the developing rat fetus.

Angiotensin II is known primarily for its effects on blood pressure and electrolyte homeostasis, but recent studies suggest that angiotensin II may play a role in the regulation of cellular growth. This study was undertaken to identify the angiotensin II receptor subtypes expressed during fetal and neonatal development and to characterize their cellular localization. Using an in situ receptor binding assay on sagittal frozen sections of fetal and neonatal rats, bound 125I-[Sar1,Ile8]-angiotensin II was visualized by film and emulsion autoradiography. Bound radioligand was detected by E11 (embryonic day 11) and maximal binding occurred by E19-21. Radioligand binding remained unaltered 30 min after birth, whereas a noticeable and stable decrease was observed 12 h postparturition. The highly abundant angiotensin II receptors were shown to be AT2 by the marked reduction in radioligand binding achieved with PD123177 (10(-7)M), a specific AT2 receptor antagonist, whereas DuP 753 (10(-5)M), an AT1 receptor antagonist, had little effect. Emulsion autoradiography showed radioligand binding in the undifferentiated mesenchyme of the submucosal layers of the intestine and stomach, connective tissue and choroid surrounding the retina, subdermal mesenchyme adjacent to developing cartilage, diaphragm, and tongue. Residual AT2 receptors were found on the dorsal subdermal region of the tongue 72 h after birth. AT1 receptors were detected in the placenta at E13 and in the aorta, kidney, lung, liver, and adrenal gland at E19-21, consistent with an adult distribution. The transient expression of AT2 receptors in the mesenchyme of the fetus suggests a role of angiotensin II in fetal development.     

Peptide-binding macromolecules in the blood of seriously ill or mentally retarded patients.

This report describes macromolecules that bind (des-aspartic acid1)-angiotensin II, the des aspartic acid1 derivative of angiotensin I, and several biologically active and inactive analogues of these polypeptides. The macromolecules were found in the plasma of approximately 2 per cent of ambulatory adults and hospitalized children and 32 per cent of the patients at two institutions for the mentally retarded. The binding properties of these macromolecules were studied by incubating with peptides labeled with 125iodine, and separating bound from free labeled peptide using small gel filtration columns. The peptide-binding macromolecules from several patients were compared. They showed very similar specificity for a group of arginyl peptides of the des-aspartyl1-angiotensin sequence. The plasma binders differed from one another in their optimum pH and their mobility in electrophoretic fields. Those with more acid pH optima displayed more rapid electrophoretic mobility. The binders fell into two classes based on apparent molecular weight, approximately 140,000 and 250,000. Those with the higher apparent molecular weight contained a large proportion of binder that could be precipitated with antiserum to human IgA. Kinetic measurements showed that the plasma binders were somewhat heterogeneous with respect to affinity for (des-asp1)-angiotensin, with apparent association constants ranging from 10(7) to 10(8) M-1. Binding activity was labile to heat, and to treatment with pepsin or trypsin. It was inhibited by calcium, protamine, streptomycin, and some other cationic compounds. The plasma peptide binder differed in specificity and molecular weight from soluble angiotensin-binding molecules extracted from tissues, and from properties expected of a receptor for angiotensin. These macromolecules may be useful reagents for measuring (des-asp1)-angiotensins. Their presence in plasma samples may interfere with angiotensin assays in some circumstances.     

Vasoactive intestinal peptide down-regulates the intrahepatic renin-angiotensin system in the anaesthetized rat.

Gastric sodium loading results in an increase in the portal venous concentration of vasoactive intestinal peptide (VIP) and down-regulation of both the intrahepatic and circulating renin-angiotensin systems. In the present study we sought to determine whether an increase in the concentration of VIP in the portal circulation might act to down-regulate the intrahepatic and/or circulating renin-angiotensin systems. Male Sprague-Dawley rats were infused intraportally with haemaccel vehicle or VIP in haemaccel for 60 min. Livers were harvested and blood was sampled. Angiotensin-converting enzyme (ACE) activity and angiotensinogen, angiotensin I, angiotensin II and renin concentrations were measured. VIP infusion decreased hepatic ACE activity (P < 0.05), the hepatic angiotensinogen concentration (P < 0.001) and the hepatic angiotensin I concentration (P < 0.05). The plasma angiotensinogen concentration and serum ACE activity were also decreased by intraportal VIP infusion (P < 0.05 for each). Plasma renin, angiotensin I and angiotensin II concentrations were unchanged by VIP infusion. We conclude that an increase in the portal venous VIP concentration down-regulates the intrahepatic renin-angiotensin system. These changes are similar to those reported after gastric sodium loading, and we suggest, therefore, that the increase in portal venous VIP that occurs after gastric sodium is the means by which the gastric sodium sensor signals the liver to effect these changes in the renin-angiotensin system.     

Effect of chronic hypokalaemia on renal concentrating ability and secretion of arginine vasopressin

Two patients with a Bartter-like syndrome, who had been hypokalaemic for 129 and 55 months, and 13 normokalaemic control subjects were investigated during 24 h of water deprivation. The hypokalaemic patients had urine volumes, urine osmolalities, osmolar clearances and tubular capacities for water reabsorption within the normal range. During thirst, plasma-arginine vasopressin increased much more markedly in the patients (3.4 to 11.1 pmol/l and 3.0 to 17.7 pmol/l) than in the control subjects (2.1 pmol/l (median), range 1.0-3.1, to 3.7 pmol/l, range 1.7-6.4). Plasma angiotensin II increased during water deprivation in the patients (33 to 53 pmol/l and 147 to 208 pmol/l) but not in the control subjects (9 pmol/l (median), range 3-15, to 11 pmol/l, range 3-15). Plasma aldosterone was the same in patients and control subjects and did not change in response to thirst. It is suggested that renal concentrating ability can be preserved in patients with chronic potassium depletion by means of a compensatory increase in the secretion of antidiuretic hormone.     

Studies directed toward labeling analysis of angiotensin II in plasma

We assay a 1-mL plasma sample containing angiotensin II (103 pg by radioimmunoassay) for the hormone by the following sequence of steps: add 125I-labeled val5-angiotensin II as an internal standard, extract on a C18 Sep Pak column, extract on an antibody affinity column, label the extract with an 125I Bolton-Hunter reagent, separate on a Bio Gel P2 column, and repetitively separate on a reversed-phase "high-performance" liquid-chromatographic column, detecting the eluting compounds by counting radioactivity. The fact that we measured 46 pg of angiotensin II-like substance per milliliter in a sample of pooled plasma is encouraging for the further development of this methodology. In particular, replacing the radioisotope with a more suitable chemical label such as an electrophoric (electron-capturing) release tag should be useful.     

Antihypertensive effect of captopril and enalapril in endothelin-infused rats

Comparative effects of angiotensin converting enzyme inhibitors and calcium channel blockers were assessed in rats infused chronically with synthetic endothelin. When 50 mg/kg/day of captopril orally or 6 mg/kg/day of enalapril intraperitoneally was administered simultaneously with 60 micrograms/kg/day of endothelin, the systolic blood pressure was on Day 1 142.7 +/- 5.9 mmHg (p less than 0.05) or 128.7 +/- 6.7 mmHg (p less than 0.05), respectively, compared to the rise to 163.8 +/- 4.7 mmHg when endothelin alone was infused. The antihypertensive effect of captopril or enalapril was sustained for the entire experimental period and was not associated with a significant change in urinary sodium excretion, whereas both drugs induced a significant increase in urine volume. Chronic infusion of angiotensin II intraperitoneally at a subpressor dose (400 micrograms/kg/day) reversed the antihypertensive effect of captopril in endothelin-infused rats. When 6 mg/kg/day of benidipine or 10 mg/kg/day of nilvadipine orally was administered simultaneously with 60 micrograms/kg/day of endothelin, the systolic blood pressure was on Day 1 137.0 +/- 2.4 mmHg (p less than 0.05) or 119.7 +/- 5.9 mmHg (p less than 0.05), respectively, compared to the rise when endothelin alone was infused. The antihypertensive effect of benidipine or nilvadipine was sustained for the entire experimental period and was not associated with any significant changes in urine volume and urinary sodium excretion. These results indicate that the reduced sensitivity of the peripheral arteries to endothelin may be involved in the mechanism of the hypotensive action of angiotensin converting enzyme inhibitors, dependent on the suppressed angiotensin II formation.