Increased systemic and renal vascular sensitivity to angiotensin II in normotensive men with positive family histories of hypertension.

Normotensive young men (mean age 36 years) with positive (PFH) (n = 13) and negative (n = 29) family histories of hypertension were investigated in order to study systemic and renal hemodynamics at baseline conditions and during infusion of low doses (0.1 and 0.5 ng/min/kg) of angiotensin II (AII). The control group with negative family histories of hypertension was subdivided into one group matched for body mass index (n = 15) to subjects with PFH, and one lean control group (n = 14). Baseline blood pressure and sodium intake, measured as urinary excretion, were higher in PFH and in matched controls than in the lean control group. At baseline, renal blood flow (para-aminohippurate clearance) did not differ significantly among the three groups, while glomerular filtration rate (inulin clearance) was higher in PFH than in matched controls. Both doses of angiotensin II infusion increased the blood pressure significantly in PFH. In matched controls a small increase in blood pressure was seen with the highest dose only, while no change in blood pressure was observed in the lean control group. In PFH both doses of AII infusion caused diminished renal blood flow (P less than .01) and increased renal vascular resistance (P less than .001). The two control groups remained unchanged with both AII doses. These results could indicate that normotensive subjects with positive family histories of hypertension are characterized by an increased sensitivity to AII in the systemic and renal circulation as compared with subjects with negative family histories of hypertension.     

Vitamin D and the vascular sensitivity to angiotensin II in obese Caucasians with hypertension

Obesity and vitamin D deficiency have both been linked to augmented activity of the tissue renin-angiotensin system (RAS). We investigated whether obesity status influenced the relationship between 25-hydroxyvitamin D (25(OH)D) and vascular RAS activity. The levels of 25(OH)D were measured in hypertensive obese (n=39) and non-obese (n=58) Caucasian individuals. RAS activity was assessed by plasma renin activity, and evaluation of the vascular sensitivity to angiotensin II (AngII) using the mean arterial pressure (MAP) response to an infusion of AngII. Among obese subjects, 25(OH)D was an independent positive predictor of the MAP response to AngII (β=0.70, r=0.41, P<0.01); lower 25(OH)D concentrations were associated with a blunted MAP response to AngII. In contrast, 25(OH)D did not significantly predict the vascular sensitivity to AngII in non-obese subjects (β=0.10, r=0.07, P=0.62). A multivariable-adjusted interaction model confirmed that the positive relationship between 25(OH)D and the vascular sensitivity to AngII strengthened with obesity (P-interaction=0.03). These findings demonstrate a positive association between 25(OH)D and the vascular sensitivity to AngII in obese hypertensives, and further suggest that vascular RAS activity may progressively increase when 25(OH)D deficiency occurs in obesity. Future studies to evaluate the effect of vitamin D supplementation on vascular RAS activity in obesity are needed.     

Increased adrenal sensitivity to angiotensin II in idiopathic hyperaldosteronism.

Plasma aldosterone increases briskly during upright posture in patients with idiopathic hyperaldosteronism, despite only small increases in PRA and presumably small increases in angiotensin II. To examine the postulate that small increments in angiotensin II mediate these brisk increases in aldosterone, we infused graded doses of angiotensin II into normal subjects and patients with idiopathic hyperaldosteronism and compared the changes in levels of plasma aldosterone in the two groups. Supplemental sodium and dexamethasone were given before the infusion to minimize the influence of endogenous angiotensin II and ACTH. In response to the infusion of angiotensin II, increases in the levels of plasma aldosterone of patients with idiopathic hyperaldosteronism were significantly greater than those of normal subjects. In addition, levels of plasma aldosterone increased at a lower rate of infusion of angiotensin II in patients than in normal subjects. It is concluded that patients with idiopathic hyperaldosteronism have increased adrenal sensitivity to angiotensin II. This increased sensitivity may explain the brisk increases in aldosterone that occur during upright posture in these patients.     

Angiotensin sensitivity and prostaglandins in dogs with renal hypertension

During established two-kidney one clip hypertension in dogs blood pressure is elevated despite only slightly raised plasma renin activity. Dose dependent effects of exogenous angiotensin II on systemic and renal haemodynamics were examined before and after induction of this type of hypertension in conscious dogs. There was no difference in the response of blood pressure to angiotensin II in each group, suggesting that altered pressor sensitivity to angiotensin II is not the cause of the persisting hypertension. However sodium excretion, effective renal plasma flow and glomerular filtration rate were all decreased by angiotensin II in the normotensive group, but were unchanged or increased in the hypertensive group. Renal prostaglandin E excretion was also increased in the hypertensive animals, and further increased during infusion with angiotensin II. The altered renal response to angiotensin II in the hypertensive group may reflect changes in occupancy of angiotensin II receptors and/or enhanced renal release of vasodilator prostaglandins.     

Cardiac and vascular hypertrophy in hypertension due to angiotensin II. Effect of losartan and bosentan

We assessed the role of angiotensin (Ang) II type 1 receptor (AT1) and endothelin type A and B (ETA & ETB) receptor in cardiovascular hypertrophy associated with angiotensin II-induced hypertension (200 ng/kg.min s.c. for 10 or 17 days). Antagonism of AT1 receptors was obtained by oral administration of losartan (10 or 30 mg/kg.day) and blockade of ETA and ETB receptors was obtained by oral administration of bosentan (30 mg/kg.day). Losartan and bosentan were administered 24 h before and during the 10 days of angiotensin II (prevention) or they were given after the development of hypertension i.e. from day 10 to 17 of angiotensin II (treatment). Tail-cuff pressure (TCP) was measured before and at the end of the period of administration of antagonists. At the end of experiments, cross sectional area (CSA, mm2) of the carotid was measured after perfusion and fixation at 100 mmHg and heart weight index (HWI, mg/g body weight) was determined. Results are mean +/- SEM. [table: see text] In addition to its blood pressure lowering effect, both doses of losartan prevented and reversed the cardiovascular hypertrophy induced by angiotensin II. Similarly, bosentan prevented and reversed the effect of angiotensin II on cardiovascular structure independently of arterial pressure. These results indicate that the effect of angiotensin II on blood pressure, heart and carotid structure is exclusively mediated by AT1 receptors. The influence of bosentan suggests that endothelin plays an important role in local action of angiotensin II independently of blood pressure level.     

Enhanced antinatriuresis in response to angiotensin II in essential hypertension

Angiotensin II regulates sodium homeostasis by modulating aldosterone secretion, renal vascular response, and tubular sodium reabsorption. We hypothesized that the antinatriuretic response to angiotensin II is enhanced in human essential hypertension. We therefore studied 48 white men with essential hypertension (defined by ambulatory blood pressure measurement) and 72 normotensive white control persons, and measured mean arterial pressure, sodium excretion, renal plasma flow, glomerular filtration rate, and aldosterone secretion in response to angiotensin II infusion (0.5 and 3.0 ng/kg/min). Hypertensive subjects exhibited a greater increase of mean arterial pressure (16.7+/-8.2 mm Hg v 13.4+/-7.1 mm Hg in normotensives, P < .05) and a greater decrease of renal plasma flow (-151.5+/-73.9 mL/ min v -112.6+/-68.0 mL/min in controls, P < .01) when 3.0 ng/kg/min angiotensin II was infused. The increase of glomerular filtration rate and serum aldosterone concentration was similar in both groups. Sodium excretion in response to 3.0 ng/kg/min angiotensin II was diminished in both groups (P < .01). However, the decrease in sodium excretion was more pronounced in hypertensives than in normotensives (-0.18+/-0.2 mmol/min v -0.09+/-0.2 mmol/min, P < .05), even if baseline mean arterial pressure and body mass index were taken into account (P < .05). We conclude that increased sodium retention in response to angiotensin II exists in subjects with essential hypertension, which is unrelated to changes in glomerular filtration rate and aldosterone concentration. Our data suggest a hyperresponsiveness to angiotensin II in essential hypertension that could lead to increased sodium retention.     

Altered adrenal sensitivity to angiotensin II in low-renin essential hypertension.

Low-renin essential hypertension (LREH) describes a widely recognized classification validated by clinical features, including salt-sensitive blood pressure and diuretic responsiveness. Classic physiological teaching has cited normal plasma aldosterone concentration despite suppressed renin as evidence for adrenal supersensitivity to angiotensin II (Ang II). We studied 94 patients with LREH, 242 normal-renin hypertensives, and 135 normal subjects as controls. Low-renin hypertensives did not differ significantly from the other groups in either basal or Ang II-stimulated aldosterone concentrations on a high-sodium diet. Stimulated with a low-sodium diet, LREH patients demonstrated the smallest rise in basal aldosterone secretion. Ang II responsiveness was also subnormal: the rise in aldosterone after Ang II infusion in LREH (613+/-39 pmol/L), although greater than in nonmodulators (180+/-17 pmol/L; P=0.001), was less than either the patients with intact modulation (940+/-53 pmol/L; P=0.001) or normotensives (804+/-50 pmol/L; P<0.05). Blacks with LREH demonstrated an even lower response than low-renin whites ((388+/-50 versus 610+/-47 pmol/L; P=0.0001). In contrast, the rise in systolic blood pressure with Ang II infusion on a low-salt diet was greatest among LREH patients (P=0. 001). Patients with LREH and nonmodulators were equally salt-sensitive. These results indicate that the adrenal response in LREH is normal on a high-salt diet but becomes progressively more abnormal as sodium control mechanisms are stressed. The factors that mediate enhanced adrenal response to Ang II with sodium restriction may be defective, suggesting the existence of alternative physiological mechanisms for sodium homeostasis in the low-renin state.     

Enhanced aldosterone response to angiotensin II in human hypertension.

Adrenal and vascular responsiveness to graded doses of angiotensin II (A II) were recorded for seven normal subjects and 12 patients with essential hypertension while in balance on an intake of 200 mEq sodium/100 mEq potassium. Patients with essential hypertension had been previously studied and known to have normal responses of plasma renin activity to sodium restriction and upright posture. A II was administered for 30 minutes at rates of 0.1, 0.3, 1, and 3 ng/kg per minute and plasma aldosterone responses were assessed 20 and 30 minutes later; blood pressure was monitored at intervals of 1 minute during infusion of A II at each rate. A significant increment in plasma aldosterone occurred at an infusion rate of 0.3 ng/kg per minute in patients with hypertension. This change was not seen until the infusion rate reached 1.0 ng/kg per minute in the normotensive control subjects. Even at an A II infusion rate of 1 ng/kg per minute, the increment in plasma aldosterone levels in normotensive subjects (4.2 +/- 0.6 ng/dl) was significantly less (P less than 0.001) than that in patients with essential hypertension (19 +/- 3 ng/dl). In both groups, a significant rise in mean arterial blood pressure occurred at an A II dose of 0.3 ng/kg per minute, but the pressor response of the hypertensive group was significantly greater at the highest infusion rate (3 ng/kg per minute) (P less than 0.05). Thus, enhanced adrenal and pressor responsiveness to infused A II was observed in the hypertensive subjects, suggesting a change in A II receptor affinity.     

Evidence for renal vascular remodeling in angiotensin II-induced hypertension

OBJECTIVES: To determine whether 'slow pressor' hypertension from systemic angiotensin (Ang II) infusion was associated with renal vascular structural remodeling of the renal resistance vessels and glomerulus. METHODS: Ang II (4.5-10 ng/kg per min) or vehicle was infused for 10 days. Renal resistance vascular lumen changes were assessed at 10 days as changes in renal pressure flow and pressure-glomerular filtration rate (GFR) and pressure-Na+ excretion in maximally dilated, isotonically perfused kidneys. RESULTS: Low-dose, initially subpressor Ang II infusion for 10 days increased conscious arterial pressure by 27 mmHg compared to vehicle-infused rats (140 +/- 7 and 113 +/- 2 mmHg, respectively). There was no change in the pressure-flow relationship but the slope of the pressure-GFR relationship was reduced in the rats treated with Ang II. These changes are consistent with equal and opposite pre-and post-glomerular effects (i.e., increased pre-glomerular vessel resistance and reduced post-glomerular vessel resistance) and reduced glomerular ultrafiltration coefficient. There was also a significant reduction in pressure-dependent Na+ excretion. CONCLUSIONS: Slow pressor Ang II-induced hypertension was associated with apparent pro-hypertensive changes in the kidney involving pre/post-glomerular vessel remodeling as indicated by an apparent reduction in pre-glomerular lumen dimensions, a reduced glomerular filtration capacity and a reduction in the pressure natriuresis relationship.     

Cardiovascular, renal, and endocrine response to atrial natriuretic peptide in angiotensin II mediated hypertension

Studies done in vitro have demonstrated that atrial natriuretic peptide (ANP) antagonizes angiotensin II-mediated contraction of vascular smooth muscle. The present studies were designed to examine the in vivo actions of ANP in acute angiotensin II-mediated hypertension. The cardiovascular, renal, and hormonal effects of intravenous ANP were evaluated in anesthetized normotensive (n = 6) and hypertensive (n = 6) dogs. In both groups, ANP (3.0 micrograms/kg bolus, 0.3 micrograms/kg/min continuous infusion) reduced arterial pressure and cardiac output without changing systemic vascular resistance. ANP specifically reduced renal vascular resistance and increased sodium excretion. The natriuresis observed was greater in hypertensive than in normotensive dogs. This occurred without a significant change in glomerular filtration rate or aldosterone. The ANP-mediated reduction in arterial pressure was associated with an increase in circulating arginine vasopressin and catecholamines but not in renin. These studies demonstrate that ANP-mediated hypotension results from a reduction in cardiac output without changing systemic vascular resistance, ANP acts as a specific renal vasodilator, ANP-mediated natriuresis can occur without alteration in glomerular filtration rate or aldosterone, and ANP specifically inhibits the release of renin without inhibiting the release of other circulating vasoconstrictors.     

Increased renovascular response to angiotensin II in persons genetically predisposed to arterial hypertension disappears after chronic angiotensin-converting enzyme inhibition

OBJECTIVE AND METHODS: Functional changes in the kidneys of healthy men with (FH+) (n = 15) and without (FH-) (n = 15) family history of primary arterial hypertension were examined during administration of low-dose exogenous angiotensin II (A2) (1 ng/kg per min) before and after acute (1 mg intravenous enalaprilat) and chronic (7 days oral enalapril, 30 mg/day) angiotensin-converting enzyme (ACE) inhibition. RESULTS: Before chronic ACE inhibition, A2 increased mean arterial blood pressure (FH+, 8.7 +/- 0.8 mmHg; FH-, 8.9 +/- 0.9 mmHg), plasma immunoreactive A2 (FH+, 21 +/- 2 pg/ml; FH-, 18 +/- 3 pg/ml) and plasma aldosterone (FH+, 64 +/- 7 pg/ml; FH-, 56 +/- 6 pg/ml) to a similar degree in both groups. Chronic ACE inhibition had no impact on A2 blood pressure, plasma A2, or plasma aldosterone effects. A2 significantly increased renal vascular resistance in both groups (FH+, 3956 +/- 462 dyne s cm(-5); FH-, 2219 +/- 550 dyne s cm(-5)), but the effect was more pronounced in FH+ (P = 0.02). Glomerular hemodynamics, estimated by a modified Gomez model, revealed increased afferent and efferent responsiveness to A2 in FH+ subjects. These differences disappeared after chronic ACE inhibition when total, afferent and efferent sensitivities to A2 were similar in both groups. CONCLUSIONS: Systemic blood pressure and plasma aldosterone responses to A2 were similar in men with or without a genetic disposition to primary arterial hypertension. However, our data demonstrate that men with a family history of hypertension have increased renovascular sensitivity to A2, and that chronic ACE inhibition normalizes their sensitivity.     

Increased platelet angiotensin II receptor number in pregnancy-induced hypertension.

Women with pregnancy-induced hypertension (PIH) are characterized by relatively greater blood pressure sensitivity to exogenous angiotensin II (Ang II) than normotensive pregnant women. Evidence suggests that this is due to an alteration in Ang II receptor sites. However, the question of whether this represents an increase in receptor number or affinity remains unanswered. To answer this question Ang II receptors on platelets from normotensive women during each trimester of pregnancy and the postpartum period were studied and compared with platelet Ang II binding in third trimester women with PIH and in postpartum women who had had a recent pregnancy complicated by PIH. We also measured plasma renin activity, Ang II, and aldosterone in blood samples from these women and sodium and creatinine in 24-hour urine collections. Normotensive pregnant women had significantly less platelet Ang II binding than nonpregnant, postpartum women (0.85 +/- 0.19 versus 2.87 +/- 0.83%, p = 0.003), reflecting a reduction in receptor number but not affinity. This probably reflects the significant increase in Ang II during pregnancy. Urinary sodium excretion was equivalent and could not explain these changes. Comparisons of third trimester women with PIH against those without PIH documented a significantly higher Ang II binding in the women with PIH (2.23 +/- 0.42 versus 0.85 +/- 0.19%) that was caused by an increase in receptor number (6.0 +/- 1.3 versus 3.0 +/- 0.8 fmol Ang II per 5.6 x 10(8) platelets, p = 0.047) but similar Ang II binding affinity. This reflected significantly lower Ang II levels.(ABSTRACT TRUNCATED AT 250 WORDS)     

Increased intracellular free calcium and sensitivity to angiotensin II in platelets of preeclamptic women

Preeclampsia is characterized by a generalized vasoconstriction and increased vascular sensitivity to angiotensin II. Intracellular free calcium, implicated in vascular smooth muscle contraction, has been found to be elevated in platelets of other hypertensive disorders. We therefore measured intracellular free calcium concentrations by using the fluorescent probe quin-2 in platelets of six patients with preeclampsia and compared them to measurements in ten normotensive pregnant women and ten age-matched nonpregnant women. Intracellular free calcium was also determined in the preeclamptic women after delivery. We found that intracellular free calcium was slightly elevated in normal pregnancy (102 +/- 13 nmol/L v 87 +/- 17 nmol/L) but was markedly increased in preeclampsia (138 +/- 13 nmol/L, P less than .05). This increase disappeared six weeks after delivery (84 + 10 nmol/L, P less than .01). To investigate whether the increased intracellular free calcium was related to angiotensin II, the platelets were exposed to thrombin and angiotensin II in vitro. Exposure to thrombin and angiotensin II caused a dose-dependent increase in intracellular free calcium. The intracellular response to thrombin was not significantly different in the three groups. However, stimulation with angiotensin II revealed an increased response in intracellular free calcium in preeclampsia (P less than .05) that disappeared after delivery. Our findings show a sustained increase in platelet intracellular free calcium in preeclampsia and suggest a functional alteration of the angiotensin II receptor in this disease.     

Afferent arteriolar reactivity to angiotensin II is enhanced during the early phase of angiotensin II hypertension

Increased renal microvascular reactivity may contribute to the blunted pressure natriuretic response and increase in blood pressure during the development of angiotensin II hypertension. The current studies were performed to determine renal microvascular reactivity during the early phases of angiotensin II-infused hypertension. Male-Sprague Dawley rats received angiotensin II (60 ng/min) or vehicle via an osmotic minipump. Normotensive and angiotensin II hypertensive rats were studied 1 and 2 weeks after implantation of the minipump. Systolic blood pressure averaged 117 +/- 4 mm Hg (n = 31) before pump implantation. Angiotensin II infusion increased systolic blood pressure to 149 +/- 3 and 187 +/- 5 mm Hg on infusion days 6 and 12, respectively. Renal microvascular responses to angiotensin II and norepinephrine at renal perfusion pressures of 100 and 150 mm Hg were observed using the in vitro juxtamedullary nephron preparation. Afferent arteriolar diameters of 1-week normotensive animals averaged 22 +/- 1 microm and after 2 weeks of vehicle infusion averaged 21 +/- 1 microm at a perfusion pressure of 100 mm Hg. In animals infused with angiotensin II for 1 or 2 weeks, diameters of the afferent arterioles perfused at a pressure of 100 mm Hg were 20% and 9% smaller, respectively. Additionally, 1- and 2-week hypertensive animals had an enhanced responsiveness of the renal microvasculature to angiotensin II. At a perfusion pressure of 100 mm Hg, angiotensin II (10 nmol/L) decreased afferent arteriolar diameter by 26 +/- 5% and 22 +/- 3% in the 1- and 2-week angiotensin II hypertensive rats, respectively. In 1- and 2-week normotensive animals, angiotensin II (10 nmol/L) decreased afferent arteriolar diameter by 18 +/- 2% and 15 +/- 2%, respectively, at a perfusion pressure of 100 mm Hg. In contrast, the afferent arteriolar response to norepinephrine was not altered in angiotensin II hypertensive rats. These data demonstrate an elevated renal microvascular resistance and enhanced vascular reactivity that is selective for angiotensin II in the early phases of hypertension development after infusion of angiotensin II. Thus, an alteration in renal microvascular function contributes to the blunted pressure natriuretic response and progressive development of hypertension.     

Racial differences in renal vascular response to angiotensin blockade with captopril or candesartan

OBJECTIVE: We compared the renal vascular response to captopril and candesartan among nondiabetic, normotensive black and white participants to explore angiotensin-converting enzyme-independent generation of angiotensin II. METHODS: Thirteen black individuals and 10 white individuals in low-salt balance were given captopril and candesartan on sequential study days, and the renal plasma flow responses to these agents were measured. RESULTS: Consistent with our prior observations, white individuals demonstrated a strong, significant correlation between responses to these drugs (r = 0.78, P = 0.008) and a significantly greater increase in the renal plasma flow in response to candesartan compared with captopril (104.2 +/- 26.8 versus 52.4 +/- 24.3 ml/min per 1.73 m; P = 0.03). In black participants, however, no correlation between responses to captopril and to candesartan was observed (r = 0.22, P = 0.47) and there was no difference in the renal plasma flow response between the two drugs (90.4 +/- 13.0 versus 80.4 +/- 15.3 ml/min per 1.73 m; P = 0.59). The difference in the response to the two drugs was significantly higher among white participants compared with black participants (P = 0.03). CONCLUSION: We confirmed the contribution of an angiotensin-converting enzyme-independent pathway for angiotensin II generation in the kidneys of nondiabetic, normotensive white, but not black, individuals.     

Renal response to angiotensin II is blunted in sodium-sensitive normotensive men

BACKGROUND: In hypertension, sodium sensitivity (SS) of blood pressure is associated with renal hemodynamic abnormalities related to increased activity of the renal renin-angiotensin aldosterone system (RAAS). The renal mechanisms of SS in normotensives are unknown. Therefore, we studied whether SS is related to renal hemodynamics and renal responsiveness to angiotensin II (AngII) in young healthy adults. METHODS: Blood pressure (mean arterial pressure (MAP)) and renal function were measured in 34 healthy men after 1-week low-sodium diet (LS; 50 mmol Na(+)/24 h), 1-week high-sodium diet (HS; 200 mmol Na(+)/24h), and 1-week HS-ACEi (enalapril 20 mg/day). The responses of effective renal plasma flow (ERPF; (131)I-Hippuran clearance) to graded infusion of AngII were assessed during each condition. RESULTS: The sodium-induced change in MAP ranged from -7 to +14 mm Hg. SS (a sodium-induced increase in MAP >3 mm Hg) was present in 13 subjects. ERPF was lower in SS subjects during LS and during HS-ACEi. The AngII-induced decrease in ERPF was blunted in SS on LS (-25 +/- 6 vs. -29 +/- 7% in sodium-resistant (SR) subjects, P < 0.05) and on HS (-30 +/- 5 vs. -35 +/- 6%, P < 0.05). The blunting was corrected by angiotensin-converting enzyme inhibitors (ACEi) (-36 +/- 6 vs. -37 +/- 7%). CONCLUSION: SS normotensive subjects have a blunted renal response to exogenous AngII. This is ameliorated by ACEi, supporting a role for inappropriately high intrarenal RAAS activity. As these findings cannot be attributed to subclinical renal hypertensive damage, high intrarenal RAAS activity and altered renal hemodynamics may be primary phenomena underlying SS.     

Adrenal response to angiotensin II in black hypertension: lack of sexual dimorphism

Adrenal responsiveness to angiotensin (Ang) II is markedly blunted in black hypertensive patients compared with white hypertensive patients. One characteristic of this blunted adrenal response in whites is a powerful sexual dimorphism: premenopausal white women rarely show blunted responses. This abnormality, most evident when the system is activated by a low-salt diet, is a cardinal feature of the syndrome of nonmodulation, affecting a large percentage of white hypertensive patients. Nonmodulation is also marked by an increase in cardiovascular risk beyond that from hypertension itself. This study investigated whether young black women are likewise spared its expression or whether the adrenal unresponsiveness common among black hypertensive patients is unaccompanied by a gender bias. We compared the adrenal response to Ang II in 382 hypertensive patients (313 white, 69 black; 238 male, 144 female). Ang II was infused when subjects were in balance on a 10-mmol Na(+) intake. As anticipated, white hypertensive patients showed a very strong sexual dimorphism, with women having twice the aldosterone response of men (P=0.0001). Blacks, on the other hand, showed no gender difference (P=0.9). Increasing age had the dramatic effect of reducing responsiveness in white women but not in blacks. Young black women demonstrated the same blunting of adrenal responsiveness as older black women and black men of all ages. Mechanisms protecting against a blunted adrenal response to Ang II in young white women are absent in blacks. These differences may contribute to the markedly increased prevalence of hypertension in young black women.