Specific measurement of angiotensin metabolites and in vitro generated angiotensin II in plasma

Combining high-performance liquid chromatography with radioimmunoassay enabled the precise measurement of different angiotensins and their metabolites in plasma. Peptides were extracted from 2 ml of plasma by reversible adsorption to phenylsilyl-silica, separated by isocratic high-performance liquid chromatography, and quantitated by radioimmunoassay using a sensitive but suitably cross-reacting angiotensin II antiserum. For the C-terminal angiotensin II metabolites (2-8)heptapeptide, (3-8)hexapeptide, and (4-8)pentapeptide, overall recoveries of 10 fmol peptide added to 1 ml of plasma were (mean +/- SD), 74 +/- 6, 68 +/- 8, and 67 +/- 11%, respectively. The detection limit for these peptides in plasma was 0.2 fmol/ml. Blanks were below the detection limits. In eight seated normal subjects treated for 4 days with enalapril, 20 mg p.o., q.d., angiotensin II metabolites tended to decrease during the 4 postdrug hours. However, their cumulated concentration in relation to octapeptide increased from 54 to 163% on Day 1 and from 62 to 103% on Day 4. After 4 hours of converting enzyme inhibition with enalapril there was still a close correlation between plasma renin activity and angiotensin-(1-8)octapeptide level (r = 0.83, p less than 0.05) and between blood angiotensin I and angiotensin-(1-8)octapeptide levels (r = 0.86, p less than 0.01). Adding angiotensin I in vitro raised the angiotensin-(1-8)octapeptide levels after incubation at 4 degrees C for 4 hours. Thus, immunoreactive "angiotensin II" does not disappear after converting enzyme inhibition largely because of the cumulated contribution of cross-reacting metabolites and partly because of in vitro generation of true angiotensin II.     

Plasma Angiotensin I Determines the Rate of Angiotensin II Generation Even during ACE Inhibition

ABSTRACT

After single or multiple administration of an angiotensin converting enzyme(ACE) inhibitor, plasma angiotensin(ANG) II recovers more rapidly than plasma ACE-activity. To investigate the dynamics of the biochemical changes induced by ACE inhibition, 6 normal volunteers received in a randomized order one dose of enalapril (E, 20mg), an ACE-inhibitor with a 35 hour terminal half-life, or benazepril (B, 20 mg), an ACE-inhibitor with a 23 hour terminal half-life. Biochemical effects of the 2 agents were compared at 0-4 hours and 14-30 hours after drug intake. ACE-inhibition was estimated in vivc by the ratio between plasma ANG II and blood ANG I (ANG II/ANG I) and in vitro by a radioenzymatic assay. At peak inhibition (4 hours after E, 2 hours after B), plasma ACE-activity was inhibited with E by 94% in vivo and by 98% in vitro, compared to 98% and 97%, respectively, with B. Twenty-four hours post drug, plasma ACE-activity was inhibited with E by 84% in vivo and by 83% in vitro, compared to 64% and 94%, respectively, with B. Plasma ACE-inhibition largely exceeded 24 hours and was independent of terminal half-lives. ANG II levels were initially suppressed by 88% with E and by 95% with B, but they returned to their initial values within 24 hours. Active renin measured by IRMA was increased to 183% and 313% 4 and 24 hours after E, and to 342% and 337% after B. Corresponding ANG I levels were 240% and 319% for E, and 329% and 295% for B; they were highly correlated to active renin (r=0.82, n=252, p<0.001). Thus, 24 hours post-drug, ANG II/ANG I was still reduced but the biologically effective product of the renin-angiotensin system(RAS), ANG II, has returned to its initial level, as a consequence of the increase in renin secretion and ANG I production. The RAS is reset at a time when ACE-inhibition is still effective. Feed-back increase in renin release seems to be an important factor contributing to the reappearance of ANG II in plasma in the presence of ACE-inhibition.     

Blood pressure control by the renin-angiotensin system in normotensive subjects. Assessment by angiotensin converting enzyme and renin inhibition.

BACKGROUND. The participation of the renin-angiotensin system in the control of blood pressure in normal, sodium-replete subjects is not clear. The use of a specific inhibitor of human renin should allow a better delineation of the importance of this system. METHODS AND RESULTS. Blood pressure responses were measured 1 hour after randomized, double-blind administration of the renin inhibitor Ro 42-5892 (600 mg p.o.) or the angiotensin converting enzyme inhibitor captopril (50 mg p.o.) in 20 healthy men on an ad libitum sodium diet. Effective inhibition of the renin-angiotensin system by either compound was indicated by increases of immunoreactive renin associated with an increase of angiotensin I production rate of 67.8 +/- 33.6% after captopril and a decrease of 79.5 +/- 16.4% after Ro 42-5892. Furthermore, Ro 42-5892 decreased plasma renin activity by 64%. Whereas intra-arterial diastolic (60 +/- 5.1 to 51.4 +/- 7.2 mm Hg, p less than 0.01) and mean arterial (77.7 +/- 6.0 to 71.4 +/- 8.5 mm Hg, p less than 0.001) pressures decreased after captopril, they remained unchanged after Ro 42-5892. Captopril, but not Ro 42-5892, increased forearm blood flow (2.4 +/- 0.8 versus 1.9 +/- 0.8 ml/min/100 ml, p less than 0.01) and significantly enhanced the increase of forearm blood flow to brachial artery infusions of bradykinin (0.15, 1.5, 5, 15, and 50 ng/min/100 ml; 5 minutes each) from 744 +/- 632% to 1,383 +/- 514% (p less than 0.01). Furthermore, repeat bradykinin infusions resulted in further decreases of blood pressure (from mean pressure of 71.4 +/- 8.5 to 63.2 +/- 7.6 mm Hg, p less than 0.01) only after captopril. Changes of blood pressure after captopril were unrelated to baseline plasma renin activity but correlated with captopril-induced enhancement of vasodilation to bradykinin (r = 0.68, p less than 0.05). CONCLUSIONS. The lack of blood pressure effects of renin inhibition in contrast to angiotensin converting enzyme inhibition suggests that the renin-angiotensin system does not contribute significantly to blood pressure control in normotensive, sodium-replete subjects. The hypotensive activity of angiotensin converting enzyme inhibitors may result from additional hormonal effects, for example, inhibition of bradykinin degradation and/or subsequent increases of vasodilating prostaglandins or endothelium-derived relaxing factor(s).     

Angiotensin formation in the isolated rat hindlimb

Local vascular generation of angiotensin was investigated in isolated perfused rat hindquarters. Extraction and combined high-performance liquid chromatography (HPLC)/radioimmunoassay analysis of hindlimb perfusate showed a spontaneous release of angiotensin I (Ang I; 5.0 +/- 3.4 fmol/h) and angiotensin II (Ang II; 31.8 +/- 7.9 fmol/h). Angiotensin converting enzyme (ACE) inhibition with captopril abolished Ang II release while Ang I levels increased more than 10-fold. Perfusion with purified hog renin caused a dose-dependent angiotensin release and vasoconstriction. The renin inhibitor H-142 abolished all effects of renin whereas ACE inhibition prevented Ang II formation and vasoconstriction but increased Ang I levels. Metabolism and pressor effects of synthetic tetradecapeptide renin substrate (TDP), Ang I and Ang II were studied using a recirculating rat hindlimb perfusion system. TDP-dependent formation of Ang I and II, and an increase in perfusion pressure was shown; ACE inhibition reduced but did not abolish Ang II formation and vasoconstriction. Ang I was converted to Ang II by about 50% during one pass through a hindlimb. This conversion was abolished by ACE inhibition. These data add support to the presence of a functional vascular renin-angiotensin system.     

Renal and endocrine responses to a renin inhibitor, enalkiren, in normal humans

Interpretation of renin-angiotensin blockade with angiotensin converting enzyme inhibitors is potentially confounded by their multiple effects. We used a selective renin inhibitor (enalkiren, A-64662) to explore the renal and endocrine effects of angiotensin II in healthy men. Each received 90-minute enalkiren infusions at 2-day intervals, on a low (10 mmol, 16 subjects) and high (200 mmol, 12 subjects) salt diet. Plasma renin activity, immunoreactive plasma angiotensin II and aldosterone concentrations, inulin, and p-aminohippurate clearance were measured by standard methods. Plasma renin activity fell at 0.1 micrograms/kg, but the threshold for biologic effect was 256 micrograms/kg, where plasma immunoreactive angiotensin II and aldosterone concentration fell, and renal plasma flow rose (p less than 0.01). The maximal renal vascular response (+152 +/- 23 ml/min/1.73 m2) occurred at 512 micrograms/kg (p less than 0.01). Diastolic and mean blood pressure fell modestly but significantly (p less than 0.05). Responses were limited on a high salt diet. We confirm that conventional plasma renin activity measurement is misleading in humans receiving a renin inhibitor. The renal vascular response to renin inhibition in this study appeared to substantially exceed reported responses to angiotensin converting enzyme inhibition, perhaps reflecting a crucial and relatively inaccessible intrarenal locus.     

Immediate converting-enzyme inhibition with intravenous enalapril in chronic congestive heart failure

To test the hypothesis that intravenous enalapril is a useful pharmacologic probe of the renin angiotensin system, intravenous enalapril was administered to 9 patients with severe congestive heart failure (CHF). This produced abrupt and complete blockade of converting enzyme, with peak effect occurring at 30 minutes, as reflected by increases of plasma renin activity (from 16.8 +/- 6 to 86.6 +/- 23 ng/ml/hour) and decreases of plasma aldosterone levels (from 46 +/- 14 to 25 +/- 6 ng%) (both p less than 0.05). With reduction of angiotensin II--mediated vasoconstriction, systemic vascular resistance decreased markedly (from 1,974 +/- 233 to 1,400 +/- 136 dyne s cm-5) and cardiac index was improved (from 1.88 +/- 0.9 to 2.20 +/- 0.21 liters/min/m2) (both p less than 0.05). The time course of angiotensin II levels suggested that the lack of a cumulative effect from additive doses of intravenous enalapril was a reflection of complete inhibition of converting enzyme. One patient did not respond to enalapril; despite comparable hemodynamic severity of CHF, the renin-angiotensin system was not activated in this patient. Thus, intravenous enalapril is capable of rapid and complete inhibition of converting enzyme for the accurate assessment of angiotensin II--mediated vasoconstriction in patients with severe CHF.     

Evaluation of a long-acting converting enzyme inhibitor (enalapril) for the treatment of chronic congestive heart failure

Converting enzyme inhibition of the renin-angiotensin system has proved a valuable therapeutic approach in patients with severe chronic congestive heart failure. In the present study, a new long-acting converting enzyme inhibitor (enalapril) was evaluated with acute single dose testing (10, 20 or 40 mg) in nine patients with severe chronic congestive heart failure. Four hours after administration, there was a significant reduction of systemic vascular resistance (-19%) and pulmonary wedge pressure (-19%); in addition, there were related increases of cardiac index (+16%) and stroke index (+19%) (probability [p] less than or equal to 0.05 for all changes). This was associated with an increase of plasma renin activity (9 +/- 3 to 35 +/- 11 ng/ml per hour) and a decrease of plasma aldosterone (19 +/- 4 to 9 +/- 2 ng/100 ml) (p less than 0.02 for both). With long-term therapy (1 month), there was improvement of exercise tolerance time and lessening of symptoms based on the New York Heart Association classification. Hemodynamic improvement was maintained in most, but not all, patients. There was no orthostatic hypotension during head-up tilt and hemodynamic values in the upright position were associated with normalization of intracardiac pressures. Long-term converting enzyme inhibition was indicated by a persistent increase of plasma renin activity (16 +/- 2 ng/ml per hour) and a decrease of plasma aldosterone (8 +/- 3 ng/100 ml). In addition, relative angiotensin II receptor occupancy was decreased as judged by the pharmacodynamic response to infusion of the angiotensin II analog saralasin. In conclusion, the long-acting converting enzyme inhibitor, enalapril, was effective in patients with chronic congestive heart failure; however, additional studies will be necessary to further delineate the optimal dose range and identify those patients who are most likely to respond to the drug.     

Unrelated responses of brachial artery hemodynamics and renin-angiotensin system to acute converting enzyme inhibition by enalaprilat in essential hypertension

The simultaneous acute effects of converting enzyme inhibition by intravenous enalaprilat on the circulating renin-angiotensin system and on the brachial artery were studied in 12 hypertensive patients by a double-blind comparison with saline effects in 14 hypertensive patients. The brachial artery was investigated in terms of arterial section (measured by pulsed Doppler technique) and wall rigidity (assessed by pulse wave velocity). Arterial and biochemical parameters were measured in baseline before injection and at 20 to 40 minutes (t1) and 80 to 100 minutes (t2) after saline and drug injections. Compared with the saline vehicle, enalaprilat significantly decreased angiotensin enzyme converting activity (p less than 0.001), increased plasma renin activity (p less than 0.01) and decreased plasma aldosterone concentrations (p less than 0.01). The drug reduced blood pressure (p less than 0.01) and increased the brachial artery section (p less than 0.01), but did not change pulse wave velocity. In the enalaprilat group, significant postinjection relations were observed between: (1) enalaprilat concentration and plasma angiotensin converting enzyme activity (r = -0.72, p less than 0.001); (2) plasma renin activity and mean blood pressure (r = -0.46, p less than 0.02); (3) plasma enalaprilat concentration and pulse wave velocity (r = -0.50, p less than 0.01) and (4) pulse wave velocity and brachial artery section (r = 0.42, p less than 0.05). Thus, the brachial artery effects of enalaprilat were not directly related to the blockade of the renin-angiotensin system in plasma.(ABSTRACT TRUNCATED AT 250 WORDS)     

Angiotensin-(1-7). A member of circulating angiotensin peptides.

We measured the concentrations of three principal products of the renin-angiotensin system and seven of their metabolites in the plasma of anesthetized normal dogs and in dogs 24 hours after bilateral nephrectomy. The levels of the angiotensin peptides were measured by high-performance liquid chromatography combined with radioimmunoassay using three specific antibodies that recognized different epitotes in the sequences of angiotensin I, angiotensin II, and angiotensin-(1-7). The analysis revealed that angiotensin-(1-7) is present in the plasma of intact (4.9 +/- 2.2 fmol/ml) and nephrectomized (0.5 +/- 0.5 fmol/ml) dogs. An intravenous injection of purified hog renin (0.01 Goldblatt unit/kg) increased plasma levels of angiotensin I, angiotensin II, and angiotensin-(1-7) both before and after nephrectomy. These changes were associated with parallel increases in the concentrations of fragments of the three parent peptides. Administration of MK-422 led to the disappearance of circulating angiotensin II and its fragments both before and after a second injection of the same dose of renin. In contrast, MK-422 augmented the plasma levels of both angiotensin I and angiotensin-(1-7). The concentrations of these two peptides, but not the blood pressure, were again augmented by a second injection of renin given after blockade of converting enzyme. These effects were observed both before and after bilateral nephrectomy. These findings show that angiotensin-(1-7) circulates in the blood of normal and nephrectomized dogs. In addition, we found that angiotensin-(1-7) is generated in the blood from the cleavage of angiotensin I through a pathway independent of converting enzyme (EC 3.4.15.1).     

Plasma angiotensin II, renin activity and serum angiotensin-converting enzyme activity in non-insulin dependent diabetes mellitus patients with diabetic nephropathy

The renin-angiotensin system (RAS) has been unequivocally implicated as a mediator of diabetic complications. The present study was designed to evaluate the RAS in non-insulin dependent diabetic patients with diabetic nephropathy. Plasma renin activity, plasma angiotensin II and serum angiotensin-converting enzyme (ACE) activity were measured in 45 non-insulin dependent diabetes mellitus (NIDDM) patients and 15 healthy non-diabetic controls. Diabetics were subdivided into 15 normoalbuminuric NIDDM subjects, 15 NIDDM patients with microalbuminuria and 15 diabetics with macroalbuminuria. Mean plasma renin activity for macroalbuminuric diabetics (0.65+/-0.10 ng/ml/hr) was significantly reduced than the controls (1.28+/-0.37 ng/ml/hr) (P<0.001), the diabetic group with microalbuminuria (1.08+/-0.48 ng/ml/hr) (P<0.05) and normoalbuminuric patients (1.56+/-0.82 ng/ml/hr) (P<0.001). A significant negative correlation was obtained between serum creatinine and plasma renin activity (r=-0.842, p<0.001) in macroalbuminuric NIDDM patients. Plasma angiotensin II was significantly decreased in non-complicated diabetics compared to healthy controls (4.36+/-1.49 pg/ml vs 14.87+/-3.48 pg/ml respectively, p<0.001). Non-insulin dependent diabetic patients with nephropathy had significantly higher plasma angiotensin II levels (28.99+/-5.88 pg/ml) than non-complicated diabetics (p<0.001). Serum ACE activity was increased in 53.3% of NIDDM patients. All diabetic groups showed increased serum ACE activity (normoalbuminuric NIDDM 114.9+/-28.3 nmol/min/ml, microalbuminuric NIDDM 127.9+/-31.2 nmol/min/ml and macroalbuminuric NIDDM 127.0+/-29.3 nmol/min/ml) when compared to the normal control group (76.3+/-16.5 nmol/min/ml) (p<0.001). No significant difference in serum ACE activity was obtained between normoalbuminuric and nephropathic diabetics or between diabetics with and without retinopathy. No significant correlation was obtained between serum ACE activity and blood pressure, blood glucose level and duration of diabetes. Thus plasma renin activity is decreased in diabetic nephropathy and negatively correlates with serum creatinine. Plasma angiotensin II is decreased in normoalbuminuric diabetics and elevated in diabetic nephropathy. Serum ACE activity is raised in NIDDM patients with no relation to albumin excretion rate. The role of increased ACE activity in NIDDM remains to be established.     

Coronary vasodilatation and improved myocardial lactate metabolism after angiotensin converting enzyme inhibition with cilazapril in patients with congestive heart failure.

The effects of angiotensin converting enzyme inhibition on systemic and coronary hemodynamics and on myocardial lactate metabolism were investigated before and 2 and 6 hours after cilazapril at rest and during supine submaximal exercise in 10 patients with New York Heart Association class II or III chronic congestive heart failure. Angiotensin converting enzyme inhibition, indicated by a significant increase in plasma renin activity, resulted in significant reductions in blood pressure and systemic vascular resistance. Myocardial oxygen demand decreased (resting double product 10.9 +/- 3.7 vs 12.2 +/- 3.8 mm Hg beats/min 10(-3); p less than 0.05), but coronary sinus blood flow remained unchanged and calculated coronary resistance decreased (0.45 vs 0.5 units, rest 6 hours; p less than 0.05) suggesting coronary vasodilatation. Changes in coronary vascular resistance were directly related to changes in systemic vascular resistance (r = 0.75, p less than 0.5). Myocardial lactate extraction increased at rest (47 +/- 60 vs 134 +/- 132 mumol/min; p less than 0.5) and during exercise (27 +/- 54 vs 491 +/- 317 mumol/min; p less than 0.05) both in patients with coronary artery disease (n = 5) and idiopathic dilated cardiomyopathy (n = 5). Resting lactate production was converted to lactate extraction in two patients with coronary artery disease. Neither plasma catecholamine nor atrial natriuretic peptide concentrations changed significantly. The results suggest coronary vasodilation and improved aerobic myocardial metabolism by angiotensin converting enzyme inhibition in patients with congestive heart failure.     

Role of the adrenal renin-angiotensin system on adrenocorticotropic hormone- and potassium-stimulated aldosterone production by rat adrenal glomerulosa cells in monolayer culture

The rat zona glomerulosa has a renin-angiotensin system that appears to function as an autocrine or paracrine system in the regulation of aldosterone production. To further investigate dynamic changes of production of renin and aldosterone in vitro we developed a primary monolayer culture of rat adrenal glomerulosa cells in serum-free medium. Collagenase-dispersed glomerulosa cells were incubated in PFMR-4 medium containing 10% fetal calf serum for 48 hours; the medium was then replaced with serum-free PFMR-4 medium. The cell viability and the aldosterone secretion were stable over the additional 48 hours in the serum-free control medium. After incubation for 24 hours in the serum-free medium, the cells were exposed to high K+ or adrenocorticotropic hormone (ACTH) for another 24 hours. ACTH stimulated aldosterone secretion, and this increased secretion was associated with an increase in renin activity (cell active renin, from 15.56 +/- 0.71 to 45.75 +/- 5.69; cell inactive renin, from 0.67 +/- 0.54 to 8.75 +/- 3.40; medium inactive renin, from 5.58 +/- 1.16 to 106.20 +/- 14.01 pg angiotensin I (Ang I)/micrograms protein/3 hr). Aldosterone was also stimulated by high K+. This increase was also associated with an increase in active renin in the cells (from 15.08 +/- 1.80 to 23.26 +/- 2.15 pg Ang I/micrograms protein/3 hr) and an increase in inactive renin in the medium (from 10.87 +/- 1.62 to 21.37 +/- 3.20 pg Ang I/micrograms protein/3 hr). Addition of the angiotensin converting enzyme inhibitor lisinopril attenuated both ACTH- and high K(+)-stimulated aldosterone secretion significantly.(ABSTRACT TRUNCATED AT 250 WORDS)     

Need for plasma angiotensin measurements to investigate converting-enzyme inhibition in humans

Since only a minute proportion of total angiotensin-converting enzyme (ACE) is present in plasma, the reliability of conventional in vitro measurements of ACE activity has been questioned. Data presented here demonstrate that the definition of ACE inhibition depends on the methodology used, with different results obtained with different substrates. We have developed a method that provides accurate and precise determinations of "true" angiotensin levels and in vivo ACE activity was estimated by measuring the plasma angiotensin II/angiotensin I ratio. Since the initial interruption of angiotensin II production by an ACE inhibitor stimulates renal renin release, the response can be quantitated by measuring changes in plasma levels of angiotensin I. The actual state of the renin-angiotensin system during ACE inhibition is represented by the plasma angiotensin II level. When ACE inhibition is no longer complete, increased angiotensin I levels bring the system back toward initial angiotensin II concentrations.     

Role of the renin-angiotensin system in the systemic vasoconstriction of chronic congestive heart failure

In 15 patients with severe chronic left ventricular failure, plasma renin activity (PRA) ranged widely, from 0.2--39 ng/ml/hr. The level of PRA was unrelated to cardiac output (CO) or pulmonary artery wedge pressure (PWP), but was slightly negatively correlated with mean arterial pressure (MAP) (r = -0.45) and systemic vascular resistance (SVR) (r = -0.40). After infusion of the angiotensin converting enzyme inhibitor teprotide (SQ 20,881) PWP fell from 26.3 +/- 1.3 (SEM) to 20.3 +/- 1.4 mm Hg (P less than 0.001), CO rose from 3.94 +/- 0.23 to 4.75 +/- 0.31 l/min (P less than 0.001), MAP fell from 87.5 +/- 3.8 to 77.9 +/- 4.1 mm Hg (P less than 0.001) and SVR from 1619 +/- 148 to 1252 +/- 137 dyne-sec-cm-5 (P less than 0.001). The fall in MAP and in SVR was significantly correlated with control PRA (r = 0.68 and r = 0.58, respectively). When subjects were divided on the basis of control PRA the hemodynamic response to teprotide was greatest in the high renin group. PRA rose after teprotide (8.7 +/- 3.4 to 37.9 +/- 7.7 ng/ml/hr, P less than 0.05) but plasma norepinephrine fell (619.1 +/- 103.6 to 449.7 +/- 75.7, P less than 0.05). The renin-angiotensin system thus appears to have an important role in the elevated SVR in some patients with heart failure. Chronic inhibition of converting enzyme should be explored as a possible therapeutic approach.     

Cardiac angiotensinogen and its local activation in the isolated perfused beating heart

Increasing evidence suggests that the renin-angiotensin system modulates cardiovascular homeostasis both via its circulating, plasma-borne components and through locally present, tissue-resident systems with site-specific activity. The existence of such a system in the heart has been proposed, based on biochemical studies as well as on the demonstration of renin and angiotensinogen messenger RNA in cardiac tissue. We conducted the present study to determine whether biologically active angiotensin peptides may be cleaved within the heart from locally present angiotensinogen. Isolated, perfused rat hearts were exposed to infusions of purified hog renin; the coronary sinus effluent was collected and subsequently assayed for angiotensin I (Ang I) and angiotensin II (Ang II) by high-pressure liquid chromatography and specific radioimmunoassay. Both Ang I and II were undetectable under control conditions but appeared promptly after the addition of renin. Dose-dependent peak values for Ang I release ranged from 2.42 +/- 0.65 fmol/min to 1.38 +/- 0.18 pmol/min during renin infusions at concentrations between 10 microunits/ml and 5 milliunits/ml. Ang II levels measured in the perfusate reflected a mean fractional intracardiac conversion of Ang I to Ang II of 7.18 +/- 1.09%. Generation of Ang I and Ang II was inhibited in the presence of specific inhibitors of renin and converting enzyme, respectively. To investigate the source of angiotensinogen, we measured spontaneous angiotensinogen release from isolated perfused hearts. In the absence of renin in the perfusate, angiotensinogen was initially released in high, but rapidly declining, concentrations and subsequently at a low, but stable, rate. Prior perfusion with angiotensinogen-rich plasma resulted in enhanced early angiotensinogen release but did not alter the second, delayed phase, suggesting that, in addition to plasma-derived substrate, locally produced angiotensinogen may also participate in the intracardiac formation of angiotensin. Supporting this interpretation, hearts from animals pretreated with dexamethasone showed increased angiotensinogen messenger RNA concentrations as well as increased rates of angiotensinogen release not only during the early but also during the late phase. Our study newly demonstrates that Ang I and II may be formed within the isolated heart from locally present substrate, which appears to be derived in part from the circulating pool and in part from endogenous synthesis. These findings add support to the concept of a functionally active and locally integrated cardiac renin-angiotensin system and emphasize its potential physiological and pathological relevance.     

Differential regulation of angiotensin peptide levels in plasma and kidney of the rat.

We compared the effects of the converting enzyme inhibitor perindopril on components of the renin-angiotensin system in plasma and kidney of male Sprague-Dawley rats administered perindopril in their drinking water at two doses (1.4 and 4.2 mg/kg) over 7 days. Eight angiotensin peptides were measured in plasma and kidney: angiotensin-(1-7), angiotensin II, angiotensin-(1-9), angiotensin I, angiotensin-(2-7), angiotensin III, angiotensin-(2-9), and angiotensin-(2-10). In addition, angiotensin converting enzyme activity, renin, and angiotensinogen were measured in plasma, and renin, angiotensinogen, and their respective messenger RNAs were measured in kidney; angiotensinogen messenger RNA was also measured in liver. In plasma, the highest dose of perindopril reduced angiotensin converting enzyme activity to 11% of control, increased renin 200-fold, reduced angiotensinogen to 11% of control, increased angiotensin-(1-7), angiotensin I, angiotensin-(2-7), and angiotensin-(2-10) levels 25-, 9-, 10-, and 13-fold, respectively; angiotensin II levels were not significantly different from control. By contrast, for the kidney, angiotensin-(1-7), angiotensin I, angiotensin-(2-7), and angiotensin-(2-10) levels did not increase; angiotensin II levels fell to 14% of control, and angiotensinogen fell to 12% of control. Kidney renin messenger RNA levels increased 12-fold, but renal renin content and angiotensinogen messenger RNA levels in kidney and liver were not influenced by perindopril treatment. These results demonstrate a differential regulation of angiotensin peptides in plasma and kidney and provide direct support for the proposal that the cardiovascular effects of converting enzyme inhibitors depend on modulation of tissue angiotensin systems. Moreover, the failure of kidney angiotensin I levels to increase with perindopril treatment, taken together with the fall in kidney angiotensinogen levels, suggests that angiotensinogen may be a major rate-limiting determinant of angiotensin peptide levels in the kidney.     

Renin and aldosterone secretion under converting enzyme inhibition

The converting enzyme inhibitor (CEI) is known to inhibit the conversion of angiotensin I to angiotensin II. In order to analyse the regulatory mechanisms involved in aldosterone secretion independent of renin-angiotensin system, one of the CEIs, SQ 14,225 was infused to the dogs in association with several pharmacological agents. To the mongrel dogs under pentobarbital anesthesia, SQ 14,225 was administered intravenously as a bolus injection (0.5 mg/kg), followed by two hour infusion (0.5 mg/kg/hr). The effects of several pharmacological agents on plasma renin activity (PRA) and aldosterone concentration (PA) were examined in the condition in which endogenous angiotensin II production was blocked by CEI. PRA was increased significantly from the basal level (6.4 +/- 1.2; mean +/- SEM) to 14.1 +/- 2.6 ng/ml/hr 60 min after the administration of SQ 14,225. PA, on the other hand, was decreased from 12.2 +/- 3.6 to 7.6 +/- 2.2 ng/dl. The CEI-induced increase in PRA was completely blocked by infusion of angiotensin II (40 ng/kg/min), physiological saline (0.25 approximately 0.44 ml/kg/min), pretreatment of propranolol (0.5 mg/kg) or norepinephrine (200 ng/kg/min). Both pindolol and indomethacin had no significant effect on the CEI-induced increase in PRA. Increase in PRA was also observed by the infusion of furosemide, prostaglandin 1 or E1. PA was increased by KCl infusion (1.0 mEq/kg/hr), but was not affected significantly by the administration of furosemide, pindolol, prostaglandin A1 or E1, during the SQ 14,225 infusion. An elevation of PRA observed under the converting enzyme inhibition, was considered to be due to decreased feedback inhibition as a result of reduction of angiotensin II formation. It was suggested from the present results, that the CEI-induced increase in PRA might be mediated by beta-receptor and baroreceptor in addition to the direct negative feedback by angiotensin II. The present data also suggested that both furosemide and prostaglandins stimulated aldosterone secretion via the renin-angiotensin system, rather than by acting directly on the adrenal cortex.     

Renin release regulation during acute renin inhibition in normal volunteers

Blockade of the renin-angiotensin system by an angiotensin converting enzyme (ACE) inhibitor or an angiotensin II (Ang II) antagonist is accompanied by a reactive rise in renin release. This rise is generally attributed to interruption of the short feedback loop between Ang II and renin release. Similarly, after the administration of a renin inhibitor, the plasma concentrations of active and total renin are increased and plasma renin activity is suppressed. The aim of the present study was to investigate if a fall in the plasma Ang II level is the unique determinant of the rise in the active renin (AR) level that follows renin inhibition. Six normal male volunteers participated in three successive 240-minute experiments at weekly intervals according to a single-blind randomized Latin square design. For experiment 1, Ang II was infused at 2 ng/kg/min from 0 to 60 minutes and at 4 ng/kg/min from 60 to 120 minutes. For experiment 2, 0.3 mg/kg of the new potent renin inhibitor Ro 42-5892 was injected at 30 minutes followed by infusion at 0.1 mg/kg/hr from 30 to 240 minutes. For experiment 3, Ang II and Ro 42-5892 were administered simultaneously at the same doses as described above. The mean +/- SEM Ang II concentration increased from 10.2 +/- 1.6 to 33.7 +/- 11.2 pg/ml after infusion of exogenous peptide. It decreased from 9.5 +/- 0.9 to 1.4 +/- 0.3 pg/ml after the injection of Ro 42-5892 and increased from 15.6 +/- 2.9 to 37.1 +/- 11.8 pg/ml after the simultaneous infusion of both compounds.(ABSTRACT TRUNCATED AT 250 WORDS)     

Vascular renin-angiotensin system in two-kidney, one clip hypertensive rats

The possible role of the renin-angiotensin system in the maintenance of hypertension in two-kidney, one clip hypertensive rats was studied. Plasma renin activity rose rapidly and markedly in association with the elevation of blood pressure and then decreased gradually, although blood pressure remained high. Renin activity in the lung, aorta, and mesenteric artery also increased with the development of hypertension and then decreased in a way similar to that of plasma renin activity at the chronic stage of hypertension. Plasma angiotensin converting enzyme activity did not change significantly until 16 weeks after unilateral renal artery clipping, whereas vascular angiotensin converting enzyme activity significantly increased at the chronic, but not the acute, stage of hypertension. In chronically renal hypertensive rats, 1-sarcosine, 8-isoleucine angiotensin II or enalapril, an angiotensin converting enzyme inhibitor, lowered the blood pressure and enalapril also lowered the angiotensin converting enzyme activity of vascular tissues. The constrictor effect of angiotensin I was greater in isolated arteries from chronically hypertensive rats than in those from age-matched normotensive rats. These results suggest that the vascular renin-angiotensin system plays an important role in the maintenance of two-kidney, one clip hypertension. Elevated vascular angiotensin converting enzyme activity appears to increase local production of angiotensin II, which results in vasoconstriction by acting directly and indirectly through adrenergic nerves on vascular smooth muscle.     

Simultaneous radioimmunoassay of six angiotensin peptides in arterial and venous plasma of man

Using antibodies raised against angiotensin I and II, and high-performance liquid chromatography (HPLC) of plasma extracts, we have quantified six angiotensin peptides in venous (cubital vein) and arterial (brachial) plasma of normal male subjects. The concentrations of venous plasma (fmol/ml, mean +/- s.d., n = 29) for these six peptides were: pentapeptide-(4-8): 1.5 +/- 1.1; hexapeptide-(3-8): 1.0 +/- 0.8; heptapeptide-(2-8): 2.4 +/- 2.6; octapeptide-(1-8): 10.7 +/- 6.6; nonapeptide-(2-10): 3.7 +/- 2.1; and decapeptide-(1-10): 18.7 +/- 10.7. No significant differences in the levels of each peptide were found for arterial and venous plasma; thus the rate of production of these peptides in the forearm is equivalent to their rate of clearance by the forearm. Both angiotensin I and II were significantly correlated with plasma renin, and there was a highly significant correlation between angiotensin I and II. With respect to the mechanism of local production of angiotensin, the close correlations between renin and angiotensin I and II in venous blood provide evidence that, for the forearm, plasma renin is a major determinant of local production of angiotensin. The ratio of angiotensin I:II, 1.83: 1, was similar for arterial and venous plasma, and indicates that despite the ubiquitous distribution of the angiotensin converting enzyme, the conversion of angiotensin I to angiotensin II is a significant rate-limiting step in angiotensin II formation.