Plasma renin activity in the emergency department and its independent association with acute myocardial infarction.

Elevated plasma renin activity (PRA) is associated with increased risk of future myocardial infarction (MI) in ambulatory hypertensive patients. The present study evaluated the relationship of PRA to the diagnosis of acute MI in patients presenting to an emergency department with suspected acute MI. PRA was measured upon entry to the emergency department, before any acute treatment, as part of the standard evaluation of 349 consecutive patients who were hospitalized for suspected MI. Diagnosis of acute MI was confirmed in 73 patients, and ruled out in 276. They did not differ in age (65.9 +/- 2 v 66.1 +/- 1 years), systolic (143 +/- 4 v 140 +/- 2 mm Hg), or diastolic (81 +/- 2 v 81 +/- 1 mm Hg) pressures. Median PRA was 2.7-fold higher in acute MI (0.89 v 0.33 ng/L/s; P < .001). In a multivariate analysis controlling for other cardiac risk factors and prior drug therapy, PRA as a continuous variable was the predominant independent factor associated with acute MI (P < .0001), followed by white race (P = .002) and history of hypertension (P = .047). The height of the PRA level upon entry to the emergency department was directly and independently associated with the diagnosis of acute MI. These new findings extend earlier reports because they encompass acute MI patients, include both hypertensive and normotensive patients, and control for potentially confounding variables. Based on these observations, a randomized clinical trial is warranted to determine whether measurement of PRA in acute MI could refine the process by which treatments are applied.

Delayed recovery of hypertension after single dose losartan in angiotensin II-infused conscious rats.

OBJECTIVE: In a conscious unrestrained rat model, it takes approximately 1 week for angiotensin II to increase blood pressure to maximum levels. We investigated the time required for hypertension to fully recover after acute angiotensin II receptor blockade in this angiotensin II dependent hypertensive model. DESIGN: Conscious unrestrained rats (n = 8) infused with 10 ng/kg per min angiotensin II for 21 days received losartan (10 mg/kg) on day 17 of angiotensin II infusion. Mean arterial pressure (MAP) and heart rate were monitored continuously. The acute pressor response to 50 ng/kg per min angiotensin II was monitored for 2 h on days 15, 17, 18, 19 and 20 of angiotensin II infusion. Plasma renin concentration (PRC) was measured daily. RESULTS: Angiotensin II increased MAP acutely by 26 +/- 2 mmHg and by a further 23 +/- 4 mmHg between days 4 and 8. Losartan acutely reduced MAP by 75 +/- 2 mmHg; 24 h later MAP had partially recovered but remained suppressed by 47 +/- 3 mmHg. MAP had not fully recovered 4 days later. Some 2 h after losartan, the acute pressor response to angiotensin II had fallen from 24 +/- 2 mmHg to zero. This recovered to 13 +/- 5 and 28 +/- 2 mmHg 24 and 48 h post losartan. After losartan PRC rose from 0.1 +/- 0.05 to above 1 ng/ml per h for less than 24 h. CONCLUSION: A single dose of losartan reverses both the fast and slow pressor effects of continuous angiotensin II infusions. While losartan is metabolized, the fast vasoconstrictor effect recovers quickly but the slow pressor effect takes almost a week to build up again to maximum levels. Since the slow pressor effect is mediated via the AT1 receptor, any means of blocking the renin-angiotensin system is likely to keep blood pressure below maximum hypertensive levels for several days after the drug has disappeared from the circulation.

Beta-adrenergic receptor blockade as a therapeutic approach for suppressing the renin-angiotensin-aldosterone system in normotensive and hypertensive subjects.

Although beta-adrenergic-blocking drugs suppress the renin system (RAAS), plasma angiotensin II (Ang II) responses during beta-blockade have not been defined. This study quantifies the effects of beta-blockade on the RAAS and examines its impact on prorenin processing by measuring changes in the ratio of plasma renin activity (PRA) to total renin. In normotensive (N = 14) and hypertensive (N = 16) subjects, blood pressure (BP), heart rate, PRA, plasma prorenin, plasma total renin (prorenin + PRA), ratio of PRA to total renin (%PRA), plasma Ang II, and urinary aldosterone were measured before and after 1 week of beta-blockade. Plasma renin activity, Ang II, and urinary aldosterone levels were similar for normotensive and hypertensive subjects. Plasma renin activity correlated with Ang II. Total renin, which is proportional to (pro)renin gene expression, was lower in hypertensive subjects and was inversely related to BP. Beta-blockade decreased BP and heart rate in both groups, with medium- and high-renin hypertensive subjects responding more frequently than those with low renin. Beta-blockade consistently suppressed PRA, Ang II, and aldosterone. Total renin was unchanged, thus, %PRA fell. These results indicate that beta-blockers suppress plasma angiotensin II levels, in parallel with the marked reductions in PRA and urinary aldosterone levels in normotensive and hypertensive subjects. The suppression of Ang II levels was comparable to that produced during angiotensin converting enzyme (ACE) inhibition. However, by reducing prorenin processing to renin, beta-blockers do not stimulate renin secretion, unlike ACE inhibitors and Ang II receptor antagonists. This unique action of beta-blockers has important implications for the treatment of cardiovascular disease.

Appropriate regulation of renin and blood pressure in 45-kb human renin/human angiotensinogen transgenic mice.

The renin-angiotensin system is normally subject to servo control mechanisms that suppress plasma renin levels in response to increased blood pressure and increase plasma renin levels when blood pressure falls. In most species, renin is rate limiting, and angiotensinogen circulates at a concentration close to the Km, so varying the concentration of either can affect the rate of angiotensin formation. However, only the plasma renin level responds to changes in blood pressure and sodium balance to maintain blood pressure homeostasis. Therefore, the high plasma human renin levels and the hypertension of mice and rats containing both human renin and angiotensinogen transgenes indicate inappropriate regulation of renin and blood pressure. These anomalies led us to develop new lines of transgenic mice with a longer human renin gene fragment (45 kb) than earlier lines (13 to 15 kb). Unlike their predecessors, the 45-kb hREN mice secrete human renin only from the kidneys, and both the human and mouse renins respond appropriately to physiological stimuli. To determine whether blood pressure is also regulated appropriately, we crossed these new 45-kb hREN mice with mice containing the human angiotensinogen gene. All doubly transgenic mice were normotensive like their singly transgenic and nontransgenic littermates. Moreover, among doubly transgenic mice, both human and mouse plasma renin concentrations were suppressed relative to the singly transgenic 45-kb hREN mice. These findings demonstrate the importance of appropriate cell and tissue specificity of gene expression in constructing transgenic models and affirm the pivotal role played by renal renin secretion in blood pressure control.

Kidney is the only source of human plasma renin in 45-kb human renin transgenic mice.

Prorenin is expressed in certain extrarenal tissues, but normally only the kidneys process prorenin to renin and secrete renin into the circulation. Although transgenic animal lines containing the human renin (hREN) structural gene with either 0.9-kb or 3-kb 5'-flanking DNA express the transgene appropriately in renal juxtaglomerular cells and secrete hREN into the circulation, the source of the circulating renin is not known. In the present study, we observed that 13-kb hREN transgenic mice that contain the structural gene and 0.9-kb 5'-flanking DNA express hREN mRNA in many unusual tissues. We also observed that circulating hREN levels in 13-kb hREN mice increased after bilateral nephrectomy. These results suggested that the hREN gene is expressed at inappropriate locations where prorenin might be processed to renin. To determine if more distal sequences flanking the hREN gene might contribute to cell and tissue specificity, we used a 45-kb hREN genomic fragment that contained the structural gene and about 25-kb 5'- and 8-kb 3'-flanking DNA sequences to generate 3 separate transgenic lines that contained the intact transgene sequences. Ribonuclease protection assays revealed a much narrower tissue distribution of hREN expression than in the 13-kb hREN transgenic mice. In each 45-kb hREN line, hREN mRNA was present only in the kidney, adrenal, lung, eye, ovary, and brain. Moreover, 24 hours after nephrectomy, human plasma renin fell to very low levels, indistinguishable from those of nontransgenic littermates, indicating that their circulating hREN is of renal origin. These studies suggest that sequences flanking the structural gene, missing from previous hREN transgenic lines, suppress renin gene expression at inappropriate extrarenal sites where cellular proteases, to which prorenin is not normally exposed, could convert prorenin to renin, resulting in abnormal secretion of renin into the plasma.

Identical hemodynamic and hormonal responses to 14-day infusions of renin or angiotensin II in conscious rats.

OBJECTIVE: To investigate whether plasma angiotensin II (Ang II) determines the effects of the renin-angiotensin system or whether tissue uptake of renin and localized production of Ang II might account for any cardiovascular, renal, hormonal or drinking effect of circulating renin. DESIGN: Intravenous infusions of renin (0.6 ng/min; n = 10) and Ang II (3.5 ng/min; n = 10) that produce similar plasma Ang II levels were compared for 2 weeks with vehicle (n = 7) in conscious rats after a 1-week control period. Mean arterial pressure (MAP) and the heart rate were measured continuously. Hormones and renal function were measured twice weekly. Plasma Ang II and recovery data were measured in seven additional rats. RESULTS: In renin- and Ang II-infused rats, respectively, plasma Ang II increased similarly from 4.5 +/- 0.8 and 4.4 +/- 0.9 to 10.8 +/- 0.7 and 10.6 +/- 0.7 pg/ml and declined similarly in the second week to 7.0 +/- 1.1 and 7.0 +/- 1.5 pg/ml. Plasma renin increased from 4.2 +/- 0.7 to 21.7 +/- 1.3 and fell from 5.9 +/- 0.5 to 0.6 +/- 0.2 ng/ml per h respectively. Plasma prorenin fell similarly (> 70%); angiotensinogen was unchanged. MAP rose initially by 25.6 +/- 1.2 and 23.3 +/- 0.9 mmHg and by an additional 21.1 +/- 2.4 and 27.4 +/- 1.8 mmHg on days 5-8. The heart rate fell gradually but transiently by -11% in both. Although the initial MAP rise was slower in renin-infused rats (P< 0.05) MAP returned to baseline within 2 h after both infusions were stopped. Changes in renal vascular resistance, renal blood flow, glomerular filtration rate, urinary sodium, potassium and water excretion and water intake were not significantly different between renin- and Ang II-infused rats. CONCLUSIONS: Intravenous infusions of low doses of renin or Ang II into conscious rats increase MAP identically. MAP increases in two phases 5-8 days apart, in coordination with transient falls in the heart rate. Renin- and Ang II-induced chronic hypertension are identically sustained by very small increases in plasma Ang II. Blood pressure increases more slowly with renin infusions, consistent with tissue binding. Notwithstanding, no evidence was obtained for a physiological role of tissue-bound renin in causing the cardiovascular, renal, hormonal and drinking responses measured in this study.

Renin-aldosterone system can respond to furosemide in patients with hyperkalemic hyporeninism.

Thirty-four patients (65.3+/-3.3 years of age, mean+/-SEM) with hyperkalemia (serum potassium >5.0 mEq/L) had measurement of their renin-aldosterone system. Nineteen patients (56%) had plasma renin activity (PRA) >1.5 ng/mL/h, which was not low, while 15 (44%) had PRA <1.5. Twelve of the 15 hyporeninemic hyperkalemic patients were studied to determine whether their renin-aldosterone system responded to 2 weeks of furosemide, 20 mg daily. Four were nonresponders: PRA averaged 0.3+/-0.1 ng/mL/h, and it did not increase with furosemide or respond to captopril before or after furosemide. Eight patients were responders: PRA averaged 0.6+/-0.2 ng/mL/h and increased with furosemide to 5.5+/-3.4 ng/mL/h. Captopril failed to increase PRA before furosemide, but PRA increased to 15.3+/-8.4 ng/mL/h after furosemide. Plasma aldosterone was low in both nonresponders and responders (3.5+/-1.2 ng/dL vs 5.8+/-2.5 ng/dL) and did not increase significantly with furosemide (4.3+/-1.7 ng/dL vs 8.7+/-2.5 ng/dL). Serum potassium did not fall and therefore did not limit the rise in aldosterone. Renin responders had greater body weight, were predominantly female (6/8 vs 2/4) and were more likely to have diabetes mellitus (7/8 vs 0/4). Plasma atrial natriuretic peptide (ANP) fell with furosemide in 8 of 8 responders and in 1 of the 2 nonresponders in whom it was measured. Neither group had suppressed plasma prorenin levels, indicating no suppression of renin gene expression. These results indicate that many hyperkalemic patients do not have suppressed PRA. Further, a majority of patients with suppressed PRA have high levels of ANP and can respond to diuretic therapy with a rise in PRA and a fall in ANP, suggesting physiologic suppression of the renin system by volume expansion. A minority of hyperkalemic patients with suppressed PRA had PRA that did not increase under these study conditions.

Appropriate regulation of human renin gene expression and secretion in 45-kb human renin transgenic mice.

To create physiological models of the human renin-angiotensin system in transgenic animals, the component genes should be expressed in the correct tissues and cells and respond appropriately to physiological stimuli. We recently showed that mice carrying a 45-kb human renin genomic fragment, containing approximately 25 kb 5'-flanking DNA and 6 kb 3'-flanking DNA, express the transgene in a highly cell- and tissue-specific pattern. More importantly, in contrast to previous models, human renin in the circulating plasma of these mice is derived exclusively from the kidneys. In the present study, we tested the responses of both human and mouse renal renin expression and secretion of the 45-kb hREN transgenic mice to a variety of physiological and pharmacological stimuli. A sodium-deficient diet, angiotensin-converting enzyme inhibition, and beta1-adrenergic stimulation each increased both human and mouse plasma renin concentration significantly, whereas elevated blood pressure and/or increased plasma angiotensin II levels suppressed them. Human and mouse renal renin mRNA levels changed similarly but to a lesser degree. These studies demonstrate that human renin synthesis and secretion respond appropriately in 45-kb hREN mice to physiological stimuli. This most likely results from appropriate cell-specific expression of the transgene conferred by the extended transgene flanking sequences.

Differential effects of angiotensin converting enzyme inhibition and diuretic therapy on reductions in ambulatory blood pressure, left ventricular mass, and vascular hypertrophy.

Diuretic-based therapy is less effective in reducing the cardiac complications of hypertension than the risk of stroke and may be less effective in reducing left ventricular (LV) mass than is therapy with angiotensin converting enzyme (ACE) inhibition. In view of the strong association of LV hypertrophy with cardiovascular risk, this study was designed to compare the impact of therapy with a diuretic and ACE inhibition on cardiac and vascular structure. Fifty essential hypertensives (74% male, 88% nonwhite) participated in a double-blind study for 6 months and were randomized to either ramipril or hydrochlorothiazide (HCTZ). Echocardiography, carotid ultrasonography, and ambulatory blood pressure (BP) monitoring were performed at baseline and 3 and 6 months after initiation of therapy. The 22 ramipril patients were comparable to the 28 HCTZ patients at baseline in age, race, and 24-h BP. Although HCTZ resulted in a greater reduction in 24-h BP, only treatment with ramipril resulted in a decrease in LV mass (193 to 179 g, P < .005, v 184 to 182 g, P = NS), attributable to a reduction in wall thicknesses but not in chamber diameter. In multivariate analysis, both change in BP and treatment group were independent predictors of change in LV mass. Importantly, although neither drug reduced carotid artery cross-sectional area, relative wall thickness increased due to a tendency for vessel diameter to decrease and wall thickness to increase, particularly in the diuretic group. Ramipril caused a sustained fall in plasma angiotensin II, whereas HCTZ increased angiotensin II levels. Although diuretic therapy was more effective in lowering ambulatory BP in this predominantly nonwhite population, only therapy with ACE inhibition was associated with regression of LV mass. Vascular geometry was altered consistent with the reduction in distending pressure resulting in vascular remodelling.

Effect of high-performance liquid chromatography on plasma angiotensin II measurements in treated and untreated normotensive and hypertensive patients.

BACKGROUND: Angiotensin II (Ang II) levels are normally very low in human plasma, approximately 5 pg/ml. They are usually measured by radioimmunoassay after extraction and concentration. An additional high-performance liquid chromatography (HPLC) step is reportedly necessary for accurate measurement but it is laborious and time-consuming, severely limiting the number of samples that can be assayed. OBJECTIVE: To investigate whether the HPLC step was necessary for measuring Ang II in human plasma samples in our laboratory using our own Ang II antiserum. DESIGN: Human plasma Ang II levels, measured with and without the HPLC step, were compared in two different studies. Since the action of renin is the rate-limiting step in the production of Ang II in plasma, the relationships of plasma renin activity (PRA) to Ang II levels measured with and without HPLC were also evaluated. In the first study, 108 blood samples were collected from 29 hypertensive patients during placebo or treatment with the Ang II antagonist BMS-186295. In the second study blood samples were collected from 12 normal subjects before and during beta-adrenergic blockade. RESULTS: In samples collected during angiotensin II antagonism, which predictably increased plasma Ang II levels, a highly significant relationship between the Ang II measurements with and without HPLC was found (y = 0.99x + 1.7; r = 0.97, P < 0.001). The y intercept of 1.7 pg/ml suggested that the nonspecific immunoreactivity was close to 2 pg/ml in samples assayed without the HPLC step. During beta-adrenergic blockade, which predictably suppressed plasma renin levels, highly significantly linear relationships between HPLC and non-HPLC Ang II measurements (y = 1.3x + 1.6; r = 0.93. P < 0.001, n = 16) and between non HPLC Ang II and PRA (y = 1.9x + 1.7; r = 0.73, P < 0.001, n = 108) were again found. The relationship between PRA and HPLC Ang II was also highly significant (y = 1.4x + 0.04; r = 0.92, P < 0.001, n = 16), but the y intercept was significantly lower (P < 0.001), approaching zero, indicating the removal of nonspecific immunoreactivity during the HPLC step. CONCLUSIONS: These results demonstrate once more that, when using polyclonal antibody 182, the accuracy of the Ang II measurement in human plasma is improved by the inclusion of a HPLC step, especially for samples with Ang II levels in the normal-to-low range. They also show that plasma Ang II and PRA increase or decrease proportionally during treatment with Ang II antagonists or beta-adrenergic blockade, respectively.

Ovarian origin of plasma and peritoneal fluid prorenin in early pregnancy and in patients with ovarian hyperstimulation syndrome.

Prorenin is the major product of renin gene expression in the ovary. Plasma levels of prorenin are elevated in ovarian-stimulated patients and during early pregnancy. To further elucidate the source of the elevated plasma levels of prorenin, we measured prorenin, renin activity, angiotensinogen, and steroid hormone levels in the plasma, luteal fluids (luteal cysts), ascitic fluid, and in ovarian venous samples collected from a patient with severe ovarian hyperstimulation syndrome (OHSS) and ectopic pregnancy. Prorenin/renin was also measured in plasma and in peritoneal fluid obtained during, therapeutic paracentesis from four patients with OHSS. Several corpora luteal fluids were obtained that were rich in estradiol (E2) and progesterone (P). Ovarian venous E2 and P were 20-fold higher than in arterial blood and as high or higher than the levels detected in the luteal fluids. The ratios of the hormonal levels in ascitic fluid and plasma were 1.9 for P and 1.4 for E2. A wide range of prorenin concentrations [1279 +/- 918 SD ng/mL/hr, n = 6] were found in corpora luteal fluids, but in each the prorenin concentration was higher than in plasma (494 ng/mL/hr). Prorenin but not renin was higher (+23%) in ovarian venous than arterial blood. Prorenin in the 7 liters of ascitic fluid aspirated (2686 ng/mL/hr) was 5-fold higher than in plasma and similar to the levels measured in the corpora lutea with the highest prorenin concentrations. Renin in luteal cysts and ascitic fluid constituted 3% and 6% of the total renin (renin+prorenin), respectively. Total renin was also higher in peritoneal fluid (1538 +/- 925 ng/mL/hr) than in plasma (375 +/- 237 ng/mL/hr) of the 4 additional patients with severe OHSS. These findings indicate that the ovary secretes prorenin during early pregnancy and that its secretion is directed preferentially from the luteal cysts into the peritoneal cavity. In light of recent evidence of an effect of prorenin on the vascular system, the presence of a huge reservoir of prorenin in the peritoneal cavity of patients with OHSS suggests a potential role for prorenin in the pathogenesis of this syndrome.

Plasma renin activity: a risk factor for myocardial infarction in hypertensive patients.

To determine whether pretreatment plasma renin activity (PRA), without accompanying 24-h urine sodium, can predict myocardial infarction (MI), the PRA levels of 2,902 hypertensive patients [white (38%), male (65%), median age 55 years], with mean entry blood pressure (BP) of 150/97 mm Hg were examined. During an average 3.6 years follow-up (87% > or = 9 months), there were 55 MIs, 21 strokes, and 16 other cardiovascular disease (CVD) deaths. Classification of PRA levels into 3 renin strata [high (H) PRA > or = 4.5 (n = 354), normal (N) 0.75 to 4.49 (n = 1,622), and low (L) < 0.75 (n = 926) ng/mL/h] yielded subgroups that did not differ in LVH (9% v 11%) or smoking prevalence (26% v 25%) but high versus low PRA subjects included more aged < 55 years (64% v 53%); white (49% v 25%); men (79% v 52%); cholesterol > or = 6.3 mmol/L (33% v 25%); all P values < .01. MI rates per 1,000/year were H: 9.3, N: 5.5, L: 2.5 (H v L, RR = 3.8, 95% CI: 1.7 to 8.4). A similar relationship was seen with total CVD (H: 12.5, N: 9.3, L: 5.2; RR = 2.4, 95% CI: 1.3 to 4.5) and all-cause mortality (H: 7.0, N: 6.2, L: 2.5; RR = 2.8, 95% CI: 1.2 to 6.8) but not CVA (H: 1.6, N: 2.0, L: 1.9). In a Cox survival analysis only renin, age, sex, smoking, LVH, and cholesterol were significantly (P < .02) related to MI occurrence. There was, for every 2 unit increase in PRA, an overall 25% increase in MI incidence. Among hypertensive subjects, PRA level (without urine sodium), is independently and directly associated with the incidence of MI.

Chronic carvedilol reduces mortality and renal damage in hypertensive stroke-prone rats.

The effects of carvedilol, a novel vasodilating beta-blocker and antioxidant, and propranolol on survival, neurobehavioral deficits, cardiovascular parameters, plasma renin, plasma aldosterone levels and renal pathology were determined in stroke-prone spontaneously hypertensive rats. Stroke-prone spontaneously hypertensive rats were allowed access to 1% NaCl as the drinking solution and a high fat diet supplemented with carvedilol (1200 or 2400 ppm) or propranolol (2400 ppm). The control group consisted of stroke-prone spontaneously hypertensive rats placed on the same diet with no drug supplement. Animals fed propranolol had a blood level of 864 +/- 68 ng/ml, whereas carvedilol-fed animals had blood levels of 24 +/- 4 ng/ml at 1200 ppm and 471 +/- 145 ng/ml at 2400 ppm. Carvedilol and propranolol treatment resulted in significant beta adrenoceptor blockade. Both compounds reduced heart rate, but had no significant effects on systolic arterial blood pressure. Carvedilol- and propranolol-treated animals also exhibited significant, prolonged protection from neurobehavioral deficits and mortality (P < .01). Elevated plasma renin activity and aldosterone levels seen in untreated controls were significantly decreased by propranolol (P < .05), and to a considerably greater extent by the same dose of carvedilol (P < .01). Carvedilol decreased renal histopathological damage and cardiac hypertrophy to a greater extent (P < .01) than propranolol (at equal doses). Both carvedilol (P < .01)- and propranolol (P < .01)-treated animals had considerably reduced renal damage at 18 weeks of treatment. Carvedilol reduced renal damage more than propranolol (P < .05). In addition, the lower (1200 ppm) dose of carvedilol, which decreased neurobehavioral deficits and mortality, had no significant effects on organ mass or renal function, but significantly (P < .01) reduced renal damage. These data indicate that both beta adrenoceptor blockers, especially carvedilol to a considerably greater degree, convey significant protection in a genetic model of severe hypertension that results in renal and cardiovascular organ pathology, neurobehavioral deficits and premature death.

Plasma renin activity and plasma prorenin are not suppressed in hypertensives surviving to old age.

An age related decline in plasma renin activity (PRA) has been described in normotensive and hypertensive subjects. Moreover, hypertensive patients are reported to have lower plasma prorenin levels. We therefore investigated whether that pattern of renin and prorenin suppression was apparent in white hypertensives and normotensives surviving to an older age. The study population consisted of 65 untreated hypertensives (office blood pressure > or = 160/95 mm Hg; mean age 79 +/- 6 SD; range 69 to 94 years) and 26 normotensives (mean age 77 +/- 8; range 66 to 99 years). The PRA in this population of older hypertensives (1.7 +/- 1.6 ng/mL/h) was not significantly different from normotensives of similar age (1.5 +/- 0.8 ng/mL/h). PRA was not correlated to age in either normotensives and hypertensives, but was inversely correlated to office blood pressure in the hypertensives (r = -0.25; P = .05). Plasma prorenin was also not significantly lower in older hypertensives (14.6 +/- 8.6 ng/mL/h) than in the normotensive controls (15.1 +/- 7.0 ng/mL/h). In normal subjects, but not in hypertensive patients, there was a positive relationship between plasma prorenin and age (r = 0.82; P < .001). However, elderly normotensive men had lower plasma prorenin levels (11.6 +/- 4.1 ng/mL/h) than normotensive women (18.6 +/- 7.4 ng/mL/h; P < .05). "Total renin" (PRA + plasma prorenin) was also lower in elderly normotensive men compared to women (13.2 +/- 3.9 ng/mL/h v 20.0 +/- 7.5 ng/mL/h; P < .05). In conclusion, neither PRA nor plasma prorenin are suppressed in normotensive or hypertensive subjects who survive to an old age. However, since an inverse relationship between PRA and age has been reported, it remains to be determined whether the renin/prorenin parameters were suppressed at any time or if normal renin and normal prorenin patients preferentially survive to an old age. The wide spectrum of plasma renin levels in the elderly indicates that treatment of these patients too can profitably be guided by pretreatment plasma renin levels.

Specific prorenin/renin binding (ProBP). Identification and characterization of a novel membrane site.

Renin can be detected in cardiovascular and other tissues but it disappears after bilateral nephrectomy indicating that tissues can take up or bind renal renin from the circulation. If renin uptake is the result of specific binding, plasma prorenin may be a natural antagonist of tissue directed renin-angiotensin systems. To investigate if specific prorenin/renin uptake occurs in rat tissues, binding studies were performed, with rat microsomal membrane preparations using recombinant rat prorenin metabolically labeled with 35S-methionine as a probe. A high affinity binding site for both renin and prorenin was identified. Affinities for prorenin and renin were approximately 200 and 900 pmol/L, respectively. Binding was reversible, saturable, and pH and temperature dependent. The relative binding capacities of membranes from various rat tissues were as follows (fmol/mg): renal cortex (55), liver (54), testis (63), lung (31), brain (18), renal medulla (15), adrenal (17), aorta (7), heart (4), and skeletal muscle (1). Bound prorenin was displaced by rat and human renin or prorenin but not by the prosequence of rat prorenin, angiotensin I or II, rat or human angiotensinogen, the renin inhibitor SQ30697, atrial natriuretic factor, amylase, insulin, bovine serum albumin, hemoglobin, heparin, lysozyme, ovalbumin, cytochrome C, pepsin, pepsinogen, ribonuclease A, mannose-6-phosphate, alpha-methyl mannoside, gonadotropin releasing hormone, or an antibody to hog renin binding protein. these results demonstrate specific binding of prorenin to a site in rat tissues, herein named ProBP, that also binds renin. It is possible that differences in prorenin/renin binding capacity determine the activity of tissue-directed renin-angiotensin systems and that prorenin is a natural antagonist. Alternatively, a prorenin/renin receptor may have been identified that may function by transducing an intracellular signal.

Plasma and renal prorenin/renin, renin mRNA, and blood pressure in Dahl salt-sensitive and salt-resistant rats.

We measured plasma prorenin and renin levels, renal renin mRNA, renal anti-renin and anti-prorenin-prosequence immunoreactivity, and blood pressure in maturing Brookhaven Dahl salt-sensitive (Dahl S) and salt-resistant (Dahl R) rats during 14 days of low (0%), medium (0.4%), or high 4%) NaCl diets. Blood pressure was higher in Dahl S rats and did not increase with high NaCl. Seven-week-old Dahl R rats had twofold and sixfold higher levels of plasma prorenin and renal prosequence immunoreactivity, respectively, which by 9 weeks were the same as in Dahl S rats. The anti-renin antiserum, BR1-5, was found to detect prorenin better than renin; Dahl S rats had suppressed renal anti-renin immunoreactivity relative to Dahl-R rats. Dahl R rats were unresponsive to high NaCl, whereas in Dahl S rats, plasma renin and renal prosequence immunoreactivity fell by 90% (P < .01), renal anti-renin immunoreactivity and renal renin MRNA fell by 35% (P < .05 for both), and plasma prorenin fell by 30% (P = NS). NaCl depletion increased prorenin/renin parameters similarly in both strains. There were direct relationships among all of the prorenin/renin parameters. Between low and high salt diets in Dahl S rats, plasma renin increased 20-fold, plasma total renin (renin plus prorenin) and renal renin mRNA both increased threefold, and plasma prorenin increased twofold. The results indicate that under steady-state conditions, plasma and renal renin/prorenin parameters change concordantly and that plasma total renin (renin plus prorenin) reflects changes in renal renin mRNA. The lower blood pressure of Dahl R rats is associated with later maturation-related declines in plasma and renal prorenin. Suppression of plasma renin may delay the salt-induced blood pressure rise in Dahl S rats. Finally, the renin system and blood pressure of Dahl R rats have remarkable disregard for a high salt diet.

Reduction of development of left ventricular hypertrophy in salt-loaded Dahl salt-sensitive rats by angiotensin II receptor inhibition.

To determine the effect of the angiotensin II AT1 receptor antagonist losartan (DuP753) on echocardiographic left ventricular (LV) anatomy in Dahl rats on high sodium diet, 27 Dahl salt-sensitive (Dahl-S, 13 on drug and 14 receiving tap water) and 27 Dahl salt-resistant rats (Dahl-R, 13 on drug and 14 receiving tap water) were studied by M-mode echocardiography during 8 weeks of 8% NaCl diet. At the endpoint (after 8 weeks or the last echocardiogram for animals who died earlier), Dahl-S receiving losartan had lower LV mass (1.6 +/- 0.4 g/kg 0.59) than Dahl-S receiving tap water (2.2 +/- 0.7 g/kg 0.59; P < .005), although blood pressure was only partially reduced (167 +/- 29 v 195 +/- 52; P = .05). This difference was mainly due to lower LV wall thickness (P < .02), with a less consistent decrease in LV chamber size in Dahl-S receiving losartan. Blood pressure was normal in Dahl-R (tap water group = 116 +/- 11 mm Hg; losartan group = 115 +/- 13 mm Hg) and losartan had no effect on LV mass (1.6 +/- 0.4 g/kg 0.59) in both groups). In the majority of rats, echocardiographic measurements were compared between the end of second or third week and the last available study: LV mass increased in salt-loaded Dahl-S receiving tap water (1.6+/- 0.6 to 2.1 +/- 0.7 g/kg 0.59, P < .04) and was stable in Dahl-S receiving losartan (1.5 +/- 0.1 to 1.5 +/- 0.3 g/kg 0.59), paralleling changes in LV chamber dimension. Thus, a high salt diet leads to hypertension and eccentric LV hypertrophy in Dahl-S but not in Dahl-R. Inhibition of angiotensin II AT1 receptors reduces the development of LV hypertrophy in Dahl-S rats despite lack of efficient control of blood pressure.