J E Sealey

We have previously shown that the natriuretic effect of rat atrial extract (AE) may be due, perhaps entirely, to its powerful renal hemodynamic actions. The present study was undertaken to test the hypothesis that mammalian atria contain a substance that behaves as a functional antagonist of endogenous vasoconstrictors, by examining the direct effects of AE and extensively purified atrial "natriuretic" factor on the contractile response of rabbit aortic rings to angiotensin II (AII), norepinephrine (NE), and K+-induced depolarization. Dose-response curves to AII and NE (i.e., change in tension vs log hormone concentration) were determined in the absence or presence of boiled AE or ventricular extracts (VE). Increasing concentrations of boiled AE caused a progressive right-ward shift of the AII and NE dose-response curves, whereas VE was without effect. A similar inhibitory effect was produced after extensive purification of atrial natriuretic factor by gel filtration and reversed-phase high performance liquid chromatography (HPLC). It appeared that this factor antagonized AII-induced contractility to a greater degree than that of NE. Moreover, the partially purified factor also inhibited the contraction induced by depolarization with 15 mM KCl in a concentration-dependent manner. These studies show that a substance present in the atria, but not ventricles, blocks both hormone- (receptor) and depolarization- (nonreceptor) induced vasoconstriction in aortic rings. Moreover, this antagonism is retained following extensive purification of an atrial factor that induces natriuresis in the intact rat and isolated rat kidney, suggesting that both the vasoactive and natriuretic properties of AE may reside in a single substance.(ABSTRACT TRUNCATED AT 250 WORDS)

Sensitivity and accuracy are essential features of an assay of plasma renin activity (PRA) because the normal concentration of PRA is only 1 pmol/L, and subnormal concentrations have diagnostic relevance. Conditions for blood collection need to be standardized but the conditions are not difficult for outpatients. For routine diagnostic purposes blood should be collected from ambulatory (ideally, untreated) patients on moderate sodium intake. To avoid irreversible cryoactivation of plasma prorenin (which is present in 10-fold greater concentrations than renin), samples should be processed at room temperature and stored completely frozen. Cryoactivation occurs when plasma is liquid at temperatures less than 6 degrees C. PRA is commonly measured with an enzyme kinetic assay in which angiotensin I (Ang I) is formed by the reaction of plasma renin with endogenous renin substrate (angiotensinogen). The Ang I so formed is measured by RIA; results are expressed as an hourly rate (micrograms/L formed per hour). This method, which is provided by most commercial kits, has the potential for unlimited sensitivity because the step for Ang I generation can be prolonged as long as necessary, so that enough Ang I forms to be measured accurately. Unfortunately, that sensitivity is not always exploited. Dilution of plasma during pH adjustment should be kept to a minimum. The Ang I generation step should last at least 3 h. The step should last 18 h for samples with PRA less than 1.0 micrograms/L per hour, to eliminate the errors inherent in the measurement and subtraction of immunoreactive Ang I in the untreated plasma (blank subtraction). These changes actually simplify PRA measurements because they eliminate the need for ice in the clinic and reduce by almost half the number of samples to be assayed by RIA. I also describe the method for measurement of plasma prorenin, which may be an important marker for patients with diabetes mellitus who subsequently develop vascular complications.

As the characteristics of sodium and water balance in heart failure remain undefined, we evaluated the hemodynamic, metabolic, and hormonal effects of balanced sodium intake in 10 patients with chronic congestive heart failure. We discontinued diuretics to avoid their confounding influence, and all patients received 1 wk of 10 meq and 100 meq balanced sodium intake and controlled free water. Comparing sodium intake of 10 with 100 meq, the following observations were made. There was weight gain (2.0 kg) and increased sodium excretion (11 +/- 3 to 63 +/- 15 meq/24 h), unaccompanied by increase of blood volume. Both renin-angiotensin system and sympathetic nervous system activity were greater during the 10 meq diet, and suppressed with the 100 meq sodium diet. For both diets, plasma renin and urinary aldosterone excretion were correlated with urinary sodium excretion (r = -0.768, r = -0.726, respectively; P less than 0.005). Systemic hemodynamics were minimally changed with increased sodium intake. However, reversal of vasoconstriction by captopril during the 10 meq diet, and its ineffectiveness during the 100 meq diet, indicated a renin-dependent mechanism in the former, and a renin-independent mechanism in the latter diet. There were two subgroups of response to the 100 meq diet: one group (n = 5) achieved neutral balance, while the second (n = 5) avidly retained sodium and water. Renin-angiotensin system activity was significantly higher in the latter group, and the mechanism for differences in sodium excretion for the subgroups could not be identified by blood volume or hemodynamic parameters. Orthostatic hypotension during tilt was greater during the 10 meq sodium diet, and in all cases, related to ineffective hemodynamic and hormonal compensatory responses.

Body sodium works together with the plasma renin-angiotensin system to ensure adequate blood flow to the tissues. Body sodium content determines the extracellular fluid (ECF) volume ensuring that, with each heart beat, a sufficient volume of fluid is delivered into the arterial space. At the same time the kidneys monitor ECF volume and blood pressure (BP), so that the juxtaglomerular cells can adjust their net secretion rate of renin to maintain an appropriate plasma renin activity (PRA) level. Plasma renin produces angiotensin II (Ang II) to constrict the arterioles and thereby ensure sufficient BP to deliver an appropriate rate of flow for cardiovascular homeostasis. The low renin, sodium-volume dependent (V) form of essential hypertension occurs whenever body sodium content increases beyond the point where plasma renin-angiotensin vasoconstrictor activity is turned off. In contrast, medium to high renin (R) hypertension occurs when too much renin is secreted relative to the body sodium content. Thus, BP = V × R. This volume-vasoconstriction dual support of long-term hypertension is validated by the fact that all effective long-term antihypertensive drug types are either (i) natriuretic to reduce body salt and volume content (anti-V), or (ii) antirenin to reduce or block the activity of the circulating renin-angiotensin system (anti-R). The PRA test defines the relative participation of the concurrent volume and vasoconstrictor factors. In the hypertensive patient PRA testing can guide initiation, addition or subtraction of anti-V or anti-R antihypertensive drug types to thereby improve BP control and prognosis while reducing drug type usage and cost.

To investigate the degree to which endogenous increases in estradiol (E2) and progesterone (P4) are associated with changes in the renin system, we studied eight patients undergoing ovarian stimulation for in vitro fertilization (FSH/human menopausal gonadotropin or clomiphene citrate for 5-11 days, followed by hCG). Three conceived and were followed for up to 62 days after hCG treatment. The others were followed until the end of the luteal phase. During the follicular phase, E2 increased 10-fold, PRA increased 2-fold, and absolute levels of E2 and P4 were positively correlated (r = 0.63; P < 0.05). After ovulation, which was induced by hCG, E2 fell by 50% (day 7), but there was a 50-fold increase in P4 and a further 5-fold increase in PRA. By day 14, E2 increased again in the women who conceived, to levels even higher than those in the follicular phase, and both P4 and PRA increased 2- to 3-fold between days 7 and 14. In contrast, E2, P4, and PRA returned toward baseline levels in the nonpregnant women. On day 21, E2, P4, and PRA remained very high in the pregnant women [E2, 2297 +/- 255 pg/mL (8430 pmol/L); P4, 103 +/- 22 pg/mL (328 pmol/L); PRA, 33 +/- 8 ng/mL.h (9.17 ng/L.s)]. During the luteal phase and early pregnancy, there was a positive relationship between PRA and P4 (r = 0.68; P < 0.05). There was also a positive relationship between PRA and E2 (r = 0.54; P < 0.05); compared to the follicular phase level, PRA was 4-fold higher in the luteal phase at any E2 level. Like renin, urinary aldosterone excretion (UA) increased 5-fold during the luteal phase (day 7) and by a further 3-fold between days 7 and 21 in the pregnant women, reaching very high levels [135 +/- 28 micrograms/day (375 nmol/day); n = 3]. PRA and UA positively correlated (r = 0.59; P < 0.08). Plasma angiotensinogen increased from 2146 +/- 283 ng angiotensin-I/mL (n = 8) to 3682 +/- 607 (n = 8) on day 7 and to 5353 +/- 799 (n = 3) on day 21. Urinary sodium excretion did not fall, and urinary potassium did not increase in coordination with the changes in renin and aldosterone. There was no hypokalemia. These results demonstrate marked increases in plasma renin and UA in coordination with increases in plasma E2 and P4 during ovarian stimulation and early pregnancy, and coordinated falls during luteolysis.(ABSTRACT TRUNCATED AT 400 WORDS)