Studies of the renin-angiotensin-aldosterone system in patients with hypertension and in normal subjects

The response of renal plasma flow to angiotensin II infusion in a population-based sample and its association with the parental history of essential hypertension

BACKGROUND

Results from previous studies suggested that a blunted response of renal plasma flow (RPF) to angiotensin II infusion during a high-sodium diet (a phenotype associated with nonmodulation) is an intermediate phenotype for essential hypertension.

OBJECTIVE

To determine whether RPF traits used to investigate nonmodulation have the characteristics of intermediate traits when examined in a population-based sample of adults aged 20-49.9 years.

DESIGN AND METHODS

We examined the frequency distribution of baseline RPF and of its response to All infusion using maximum-likelihood commingling analysis in order to investigate the null hypothesis that the distributions of these traits are unimodal. We also examined the null hypothesis that there is no association between these candidate intermediate traits and the parental history of essential hypertension.

RESULTS

There was some evidence for the commingling of multiple distributions underlying these traits both for women and for men but the commingled distributions overlapped substantially and the inferences about the commingling of distributions were sensitive to the method of RPF measurement, exclusion of outliers, and the method of adjustment for concomitants. There was no statistically significant association between any of the RPF traits and a parental history of essential hypertension.

CONCLUSIONS

There is not sufficiently strong evidence to advocate the use of this set of intermediate traits to identify high-risk individuals or to relate genetic variation to the variation in risk of essential hypertension within this age range in the population at large.

Water loading and restriction in essential hypertension

Blood pressure, plasma arginine vasopressin (AVP), and renal excretory responses to short-term water loading (oral load of 20 ml/kg body weight over 30-45 minutes) were compared in 10 normotensive and 13 mild to moderately essential hypertensive subjects. In addition, we examined the renal concentrating ability of an additional group of 10 normotensive subjects and 12 hypertensive subjects in response to a 24-hour water restriction and intranasal administration of 10 micrograms of [1-deamino,8-D-arginine]vasopression. The hypertensive subjects exhibited both an exaggerated diuresis and natriuresis to the water load. At 20- and 60-minutes after water loading, hypertensive subjects had excreted 34 and 55% of the load, respectively, compared with 15 and 35% in normotensive subjects. Mean blood pressure rose significantly in both groups and hypertensive subjects exhibited a greater rise of systolic blood pressure (16 mm Hg) than normotensive subjects (8 mm Hg) 20 minutes after water loading. The maximum diuresis and natriuresis corresponded to the period in which the rise of blood pressure was greatest. The hypertensive subjects diluted and concentrated their urine as well as normotensive subjects did, indicating normal renal responsiveness to AVP. Plasma Na, osmolality, and AVP decreased similarly in both groups after water loading and rose similarly in the two groups after water restriction. This finding suggests that osmotic responsiveness of AVP is not altered in hypertensive subjects. In conclusion, the data suggest that the exaggerated renal response to water loading could be explained by the greater rise of blood pressure in hypertensive subjects rather than by altered AVP responses.

Converting-enzyme inhibition corrects the altered adrenal response to angiotensin II in essential hypertension

Of patients with essential hypertension, 30% to 50% do not modulate adrenal and renovascular responsiveness to angiotensin II (AII) with changes in sodium intake. To define the role of AII in mediating these altered responses, the adrenal and renal vascular responses to AII infusion (0.3, 1.0, 3.0 ng/kg/min) were assessed on a sodium-restricted intake in 31 patients with essential hypertension and 13 normotensive controls before and after 72 hours of converting-enzyme inhibition. Forty percent of the hypertensive patients had a subnormal adrenal response to AII. There were no differences between the normal and abnormal responding hypertensive patients in a number of clinical and biochemical factors except that the "abnormal responders" had a significantly (p less than 0.03) greater control AII level (37 +/- 3 vs 29 +/- 3 pg/ml) and lower control plasma aldosterone level (14 +/- 2 vs 22 +/- 3 ng/dl) than the "normal responders." When a converting-enzyme inhibitor was administered, no change in adrenal responsiveness to AII occurred in the normotensive controls or the hypertensive normal responders. In the hypertensive abnormal responders, both the threshold sensitivity and the entire dose response curve was significantly (p less than 0.01) enhanced following short-term converting-enzyme inhibition. This increased sensitivity could not be explained by differences in AII increment with AII infusions, in basal aldosterone levels, or in blood pressure or basal AII response to converting-enzyme inhibition. Since they occurred whether captopril or enalapril (MK 421) were used, this phenomenon is likely to be a specific effect of converting-enzyme inhibition.(ABSTRACT TRUNCATED AT 250 WORDS)

Defect in the sodium-modulated tissue responsiveness to angiotensin II in essential hypertension

In normal subjects, dietary sodium intake modulates renovascular, adrenal, and pressor responses to infused angiotensin II (AII). To examine the hypothesis that this modulation is abnormal in some patients with essential hypertension, we studied 18 hypertensives and 9 normal subjects twice--during dietary sodium restriction and during loading. Paraaminohippurate (PAH) clearance was used to assess renal plasma flow. AII was infused in graded doses (0.3-3.0 ng/kg per min). Plasma aldosterone, cortisol, renin activity, AII, sodium, potassium, and PAH clearance were measured at the onset and end of each AII dose. During dietary sodium repletion, eight of the subjects with essential hypertension showed a normal renovascular response (greater than 125 ml/min per 1.73 m2) to AII infusion (3 ng/kg per min). The decrement in renal blood flow in these normal responders (NR) was 168 +/- 10, which was comparable to the range in normotensive subjects (206 +/- 25 ml/min per 1.73 m2). All of the remaining hypertensive patients, designated abnormal responders (AbR), had lower (less than 125) renal blood flow responses to the same dose of infused AII (mean decrement: 84 +/- 11 ml/min per 1.73 m2) compared with the NR and normotensive subjects. Renal blood flow responses to all AII doses were statistically greater on a high-vs.-low salt diet in the NR (P less than 0.001, chi-square) and normotensives (P = 0.004, chi-square) but sodium intake had no effect on this response in the AbR. Basal renal blood flow in NR increased significantly (P less than 0.001, paired t test) with dietary sodium repletion, from 491 +/- 36 (low salt) to 602 +/- 40 ml/min per 1.73 m2 (high salt), but was almost identical in the AbR on differing dietary sodium intakes (429 +/- 24 vs. 425 +/- 26 ml/min per 1.73 m2). The adrenal responses to sodium intake and infused AII also differed in the two subgroups. In the NR, the adrenal response to AII was significantly greater (P = 0.011, Wilcoxon signed rank test) after sodium restriction. In contrast, there was no significant difference in the aldosterone response to AII infusion between the low and high sodium diets in the AbR. Thus, a substantial subgroup of essential hypertensives has an abnormality in responsiveness to AII in two systems central to volume homeostasis: the kidney and adrenal. They fail to modulate their renal blood flow and aldosterone responses to AII with changes in dietary sodium intake. Moreover, basal renal blood flow does not increase appropriately with increased sodium intake. These abnormalities, which may be due to an increased local production of AII or a defect in the AII receptors in these three target tissues, could contribute to the elevated blood pressure.

Parallel adrenal and renal abnormalities in young patients with essential hypertension

To determine whether the previously described abnormalities in adrenal secretion and renal blood flow in essential hypertension are associated, we examined the responses to the relevant systems in 18 patients with essential hypertension. Young patients, under 30 years of age, were studied to minimize the likelihood that the phenomena were secondary to long-standing hypertension. To achieve a wide span of sodium balance, studies were performed during a high (200 mEq) sodium intake, a restricted (10 mEg) sodium intake and a restricted sodium intake supplemented by a further short-term diuretic-induced volume deficit (furosemide, 180 to 300 mg, to reduce body weight by 1 to 1.5 kg). The indexes measured included cardiac output (indocyanine green indicator dilution), plasma volume (125 I albumin space), renal blood flow (radioxenon transit), plasma renin activity and aldosterone levels and aldosterone secretory rate. All of these variables, with the exception of blood pressure and total peripheral resistance, were within the normal range during the two diets. However, the aldosterone secretory response to diuretic-induced volume depletion on a low-sodium diet was clearly blunted in nine subjects. These nine subjects (abnormal responders) had a virtually absent aldosterone increment (23 +/- 34 micrograms per 24 hours) compared with the normal responders (502 %/- 70 micrograms per 24 hours). In addition, renal blood flow was significantly higher in these same nine subjects during both a high sodium intake (434 +/- 19 versus 342 +/- 26 ml/100 g per minute) and a restricted sodium intake /446 +/- 11 versus 285 +/- 39 ml/100 g per minute). Yet, there were no significant differences between these two groups in sodium or potassium balance, blood pressure, plasma volume, cardiac index or plasma renin activity during a high or low sodium intake. Normally, control of both aldosterone release by the adrenal and renal perfusion is dominated by angiotensin; an apparently blunted response of both systems suggests that there may be a generalized abnormality in the way angiotensin interacts with its target tissues in many young patients with essential hypertension.

Alterations in aldosterone biosynthesis in essential hypertensives

We studied hypertensives with decreased adrenal responsiveness to infused angiotensin II (AII) to assess their responsiveness to other aldosterone secretagogues, ACTH and potassium, which are thought to stimulate aldosterone synthesis in sites different from one another and from AII. All subjects, following sodium restriction, received an infusion of AII in increasing doses (0.1-3 ng/kg per min). The increment in aldosterone between control and the highest infusion dose divided by the increment in plasma AII was used as the index of adrenal responsiveness. All normotensive controls (NC) had a ratio greater than 0.5. Hypertensives with a normal ratio were designated normal responders (NR) and those with a lower ratio were abnormal responders (AbR). The slope of the regression line between aldosterone and AII was significantly less for the AbR (0.02 +/- 0.04) than for the NR (1.20 +/- 0.02, P less than 0.001) and the NC (1.00 +/- 0.03, P less than 0.001) groups. During infusion of cosyntropin in increasing doses (0.05-1.5 mIU/kg per 30 min), the aldosterone response of the AbR was significantly less than that of the NR (P less than 0.016) or the NC (P less than 0.05) groups. Similarly, after infusion of potassium (0.33 mEq/min), the increment in aldosterone in the AbR group (7.6 +/- 2.2 ng/dl) was significantly less than that in the NR (14.2 +/- 2.5 ng/dl, P less than 0.05) and the NC (18 +/- 5 ng/dl, P less than 0.05) groups. Thus hypertensives with decreased aldosterone responsiveness to infused AII also had decreased responsiveness to infused ACTH and potassium, suggesting that their defect lies in the intracellular aldosterone biosynthetic pathway.

Aldosterone in primary hypertension relationship to plasma renin activity and urinary electrolytes and a comparison with normotensive subjects

Plasma aldosterone (PA) and urinary aldosterone (Aldo-U) concentrations were studied in 123 patients with primary (essential) hypertension during basal (1 h supine rest), upright and frusemide (80 mg orally) stimulated conditions, and were related to urinary sodium and potassium excretions, supine and sitting blood pressure (BP) and the relationship to plasma renin activity (PRA). As controls, 120 normotensive subjects, matched for age and sex, were investigated identically during strictly defined out-patient conditions. No differences regarding the different mean PA levels, urinary electrolyte excretion or the urinary sodium: potassium ratio were observed between the hypertensive and the normotensive populations. However, the hypertensive subjects had significantly higher mean Aldo-U excretions than the controls. Correlations between PA and the corresponding PRA were consistently significant in the normotensive control group but weak to non-existent in the hypertensive subjects. No relationships at all could be found between the different PRA and Aldo-U values in the hypertensive population but significant correlations were noted in the control group. These findings point to a disturbed function of the renin-angiotensin-aldosterone (RAA) system even in primary hypertension.

Extrarenal renin-secreting tumor associated with hypertension

Described herein is an autopsy case of a 16-year-old female with severe hypertension, hyperreninemia and secondary aldosteronism. She had had a progressively growing tumor of her right orbita from the age of 4. The tumor was partially excised 13 months before death. A high content of a renin-like material was detected in the excised tumor, which was histologically a hemangiopericytoma. Bowie stain revealed some granules in small number of tumor cells and electron microscopic study showed some cytoplasmic granules. Following the operation, hypertension was somewhat improved, but the levels of plasma renin activity and plasma aldosterone concentration remained elevated, because the tumor was partially resected. At autopsy, the tumor invaded into the cranial base and right frontal lobe, and metastasized to the lungs. In the present case, renal renin-secreting tumor, malignant hypertension and renovascular hypertension were ruled out by the clinical and pathological studies.

New mineralocorticoids and adrenocorticosteroids in hypertension

Alterations in steroidogenesis have been demonstrated in experimental and human hypertension. It is highly likely that increased secretion of the nonaldosterone mineralocorticoid deoxycorticosterone (DOC) and 18-hydroxy-11-deoxycorticosterone (18-OH-DOC) may initiate or perpetuate hypertension, or both. It is possible that 16 beta-hydroxydehydroeplandrosterone (16beta-OH-DHEA) directly induces the hypertensive process in animals. The significance of the findings of increased secretion of 16 alpha, 18-dihydroxy-11-deoxycorticosterone (16alpha, 18-diOH-DOC) and dehydroepiandrosterone sulfate (DHEA-S) cannot now be appreciated. Neither has been examined experimentally for its ability to induce hypertension, and the former compound is not a mineralocorticoid. It does possess the curious property of increasing mineralocorticoid activity of other steroids, by altering either their metabolism or mode of action. Variations in the mineralocorticoid hypertensive syndrome or, more aptly, the steroid hypertensive syndrome could account for the hypertension in a substantial portion of patients with reduced plasma renin activity.

Plasma renin activity in diabetic autonomic neuropathy

Postural changes in plasma renin activity were studied in three groups of age and duration-matched male diabetics (potent, impotent and with postural hypotension) and in non-diabetic control subjects. Those diabetic subjects with postural hypotension due to automatic neuropathy had no increase in plasma renin activity to the erect posture whereas both the potent and impotent groups had similar plasma renin activity responses to the control subjects. There was a significant inverse correlation between the rise in plasma renin activity on standing and the postural drop in blood pressure (r = 0.476, P less than 0.01) but no correlation with other tests of autonomic reflex function such as the Valsalva manoeuvre and blood pressure response to sustained handgrip. The results suggested that the lesion responsible for the postural hypotension is in the efferent sympathetic pathway. However, neuropathy per se did not wholly explain the decreased postural plasma renin activity response. Diabetic nephropathy, with involvement of cells of juxtaglomerular apparatus, may also be implicated.

[Plasma aldosterone and plasma renin activity in patients with essential and renal hypertension under acute stimulation with saline depletion and acute suppression with saline infusion]

Plasma aldosterone, plasma renin activity, sodium and potassium in the plasma and the urine were determinated under acute stimulation with saline-depletion (furosemide) and under acute suppression with saline infusion in 40 patients with primary hypertension stage I, 19 patients with primary hypertension stages II and III, and 11 patients with renal hypertension (chronic glomerulonephritis and chronic pyelonephritis). The majority of the patients with primary hypertension stage I showed a good stimulation of the plasma aldosterone and the plasma renin activity under acute salt depletion. Three out of the 40 patients with primary hypertension stage I, and 13 of the 19 patients with primary hypertension stages II and III did not show any stimulation of the renin secretion ("low renin hypertension"). In all these patients the plasma aldosterone stimulation remained intact. With infusion of saline all the groups showed suppression of the plasma aldosterone and the plasma renin activity. A good stimulation of the plasma renin activity, demonstrates that in our experiments the renin-angiotensin system cannot be responsible for the increase in aldosterone secretion under salt depletion. Most likely the increase of the plasma aldosterone, in spite of the fixed renin activity, is stimulated by the sodium depletion due to diuretics. In all patients with primary hypertension we did not find an inadequate reaction of the aldosterone secretion under saline infusion. The patients with renal hypertension showed a minimal stimulation and suppression of the plasma renin activity. The plasma aldosterone secretion increased only slightly under sodium depletion and the decrease under saline infusion was statistically not significant. Thus we conclude that these patients show an inadequate reaction of the plasma aldosterone and renin secretion under salt infusion and depletion.

Pathophysiology of intense physical conditioning in a hot climate. I. Mechanisms of potassium depletion

Serial estimations of exchangeable (42)K showed that six volunteer subjects undergoing intensive physical conditioning in a hot climate sustained a mean deficit of 517 mEq. This deficit occurred despite a daily potassium intake of 100 mEq. Simultaneous values for lean body mass rose suggesting that potassium deficiency was not the result of catabolism. Although sweating was the major avenue by which the deficit occurred, daily excretion of potassium into the urine when each subject was maximally deficient ranged from 46 to 75 mEq and thus was inappropriately high for potassium-depleted subjects. Despite high intakes of sodium and excretion of corresponding quantities into the urine, Na/K ratios in sweat were low thus indicating unsuppressed activity of aldosterone on sweat glands. Moreover, excretion and secretion of aldosterone and in many instances, plasma renin activity, appeared to be high with respect to sodium intake. These findings suggest that intense physical work in the heat stimulates higher production of aldosterone than would occur in nonexercising subjects on similar sodium intakes. Similar to the phenomenon of mineralocorticoid escape, such overproduction of aldosterone in the presence of conditions permitting excretion of sodium into the urine could facilitate continued excretion of potassium by the kidney despite serious potassium depletion. As a consequence, the kidney played a role in the genesis of potassium depletion in these subjects. In contrast to subjects undergoing conditioning in the summer months, potassium depletion did not occur in 16 subjects during identical training under cooler environmental conditions.

A decreased metabolic clearance rate of aldosterone in benign essential hypertension

Aldosterone secretion rate, metabolic clearance rate, and/or plasma concentration were determined in 16 patients with benign, uncomplicated essential hypertension and compared with those of control subjects. The mean metabolic clearance rate of aldosterone in 10 patients was significantly (P < 0.001) lower (mean 867 liters of plasma/day per m(2) +/-270 SD) than in a group of 7 healthy subjects (mean 1480 liters/day per m(2) +/-265 SD). Secretion rates in 13 patients (including the 10 already mentioned) tended to be low (83 +/-43 vs. 109 +/-54 mug/day) and plasma concentrations tended to be high (13.6 +/-4.6 vs. 7.5 +/-4.8 ng/100 ml), but neither of these differences was statistically significant. The lower metabolic clearance rate could account for elevated plasma concentrations of aldosterone even when the secretion rate is normal or low. Measurement of secretion rate or urinary excretion only is therefore insufficient to establish the presence and/or mode of evolution of hyperaldosteronism. Failure of the aldosterone secretion to adapt fully to a decreased aldosterone metabolic clearance rate (MCR) could explain the state of relative hyperaldosteronism in patients with benign essential hypertension, even when the secretion rate and the urinary excretion rate are in the normal range.

Abnormally sustained aldosterone secretion during salt loading in patients with various forms of benign hypertension; relation to plasma renin activity

Among 25 patients with benign, essential hypertension, and an equal number with other benign forms of hypertension, without serious cardiac, renal, or cerebrovascular impairment, 41 cases failed to reduce aldosterone excretion rates into the normal range (less than 5 mug/day) on a daily intake of 300 mEq of sodium. The hypertensive patients excreted slightly less than the normal fraction of labeled aldosterone as acid-hydrolyzable conjugate. Secretion rates were significantly higher in the hypertensive patients than in normotensive controls taking the high-sodium intake. On a 10 mEq sodium intake, the increase in excretion and secretion rates of aldosterone in the hypertensive patients could be correlated with plasma renin activity (PRA). The patients with the least increase in PRA had subnormal increase in aldosterone secretion and excretion, while unusually large rises in aldosterone secretion accompanied high PRA, especially in the cases with increased plasma angiotensinogen induced by oral contraceptives. The persistence of inappropriately high aldosterone secretion in most hypertensive patients during sodium loading could be related to a higher PRA than that found in normotensive controls under comparable conditions. In other hypertensives, whose PRA was unresponsive to sodium depletion, there was no significant correlation between PRA and aldosterone output, and no known stimulus to aldosterone production was detected. Five obvious cases of hyperaldosteronism were found among the 16 low-renin patients. The cause of the nonsuppressible aldosterone production in the other low-renin cases remains to be determined.