Acute effects of angiotensin II on renal haemodynamics and excretion in conscious dogs

The effects of a 60-min intravenous infusion of angiotensin II (A II; 4 or 20 ng A II/min/kg body weight) on renal blood flow (RBF; electromagnetic flow transducer, control value 19-25 ml/min/kg), glomerular filtration rate (GFR; control value 4.2-5.0 ml/min/kg), mean arterial blood pressure, sodium excretion, water excretion, and plasma A II and plasma aldosterone concentrations were examined in 6 chronically instrumented female conscious beagle dogs kept on three different dietary sodium intakes (SI): SI 0.5 or SI 2.5 mmol Na/kg/day or SI 4.5 mmol Na/kg/day plus an oral saline load prior to the experiment SI 4.5(+) dogs. Four nanograms A II decreased RBF and GFR in SI 4.5(+) dogs without changing the filtration fraction (FF%); in SI 0.5 dogs the RBF decreased, and the FF% increased. Twenty nanograms A II decreased RBF and increased FF% in all dietary protocols, less in SI 4.5(+) dogs. The mean arterial blood pressure increased in all dietary protocols by 10-15 mm Hg (4 ng A II) and 32-37 mm Hg (20 ng A II). Sodium and water excretions decreased by 32 and 46%, respectively, in SI 4.5(+) dogs at both doses of A II. The plasma aldosterone concentration increased in all but one protocol: 4 ng A II, SI 4.5(+) dogs. It is concluded that when A II plasma concentrations are most likely borderline to pathophysiological conditions (up to an average of 370 pg/ml), the GFR is less decreased than the RBF. This phenomenon also can be observed at lower plasma A II concentrations (average 200 pg/ml), when the renin-angiotensin system had been previously moderately activated.     

Effect of aldosterone on vascular angiotensin II receptors in the rat

The effect of aldosterone on the density and affinity of binding sites for 125I-labelled angiotensin II was investigated in a particulate fraction prepared from the rat mesenteric arteriolar arcades. The infusion of aldosterone 6.6 micrograms/h intraperitoneally via Alzet osmotic minipumps for 6 d produced an increase in the density of binding sites for 125I-labelled angiotensin II without change in affinity. After sodium depletion, mesenteric artery angiotensin II receptors were down-regulated as expected. An increase in the number of binding sites could be found when aldosterone was infused into sodium-depleted rats with no change in the elevated plasma renin activity. The intraperitoneal infusion of angiotensin II (200 ng X kg-1 X min-1 for 6 d) simultaneously with aldosterone resulted in down-regulation of vascular angiotensin II receptors, whereas after intravenous angiotensin II infusion (at 60 ng X kg-1 X min-1) the density of angiotensin II binding sites rose with aldosterone infusion. Plasma renin activity (PRA) was reduced and plasma angiotensin II increased in a dose-dependent fashion after angiotensin II infusion. An aldosterone concentration of 3 ng/mL for 18 h produced an increase in the number of angiotensin II binding sites in rat mesenteric artery smooth muscle cells in culture. We conclude that increased plasma aldosterone may result in up-regulation of vascular angiotensin II receptors independently of changes in plasma renin activity, and may in certain physiological states effectively antagonize the down-regulating action of angiotensin II.     

Effects of different angiotensins during acute,double blockade of the renin system in conscious dogs

Evidence of biological activity of fragments of ANG II is accumulating. Fragments considered being inactive degradation products might mediate actions previously attributed to ANG II. The study aimed to determine whether angiotensin fragments exert biological activity when administered in amounts equimolar to physiological doses of ANG II. Cardiovascular, endocrine, and renal effects of ANG II, ANG III, ANG IV, and ANG-(1-7) (6 pmol.kg-1.min-1) were investigated in conscious dogs during acute inhibition of angiotensin I-converting enzyme (enalaprilate) and aldosterone (canrenoate). Furthermore, ANG III was investigated by step-up infusion (30 and 150 pmol.kg-1.min-1). Arterial plasma concentrations [ANG immunoreactivity (IR)] were determined by an ANG II antibody cross-reacting with ANG III and ANG IV. Metabolic clearance rates were higher for ANG III and ANG IV (391 +/- 19 and 274 +/- 13 ml.kg-1.min-1, respectively) than for ANG II (107 +/- 13 ml.kg-1.min-1). ANG II increased ANG IR by 60 +/- 7 pmol/ml, blood pressure by 30%, increased plasma aldosterone markedly (to 345 +/- 72 pg/ml), and plasma vasopressin transiently, while reducing glomerular filtration rate (40 +/- 2 to 33 +/- 2 ml/min), sodium excretion (50 +/- 7 to 16 +/- 4 micromol/min), and urine flow. Equimolar amounts of ANG III induced similar antinatriuresis (57 +/- 8 to 19 +/- 3 micromol/min) and aldosterone secretion (to 268 +/- 71 pg/ml) at much lower ANG IR increments ( approximately 1/7) without affecting blood pressure, vasopressin, or glomerular filtration rate. The effects of ANG III exhibited complex dose-response relations. ANG IV and ANG-(1-7) were ineffective. It is concluded that 1) plasma clearances of ANG III and ANG IV are higher than those of ANG II; 2) ANG III is more potent than ANG II in eliciting immediate sodium and potassium retention, as well as aldosterone secretion, particularly at low concentrations; and 3) the complexity of the ANG III dose-response relationships provides indirect evidence that several effector mechanisms are involved.     

Influence of insulin on plasma concentration and renal excretion of sodium and potassium in normal, electrolytes depleted and aldosterone treated dogs

Effects of insulin on plasma concentration and renal excretion of sodium and potassium were compared in conscious dogs 1) maintained in water and electrolytes balance (Series 1, 10 dogs), 2) depleted of electrolytes by repeated i.v. loading with 20% mannitol (Series 2, 10 dogs), and 3) aldosterone treated (0.8 micrograms.kg-1.h-1 i.v., Series 3, 10 dogs). In each Series intravenous infusion of insulin at a rate of 0.05 U.kg-1.h-1 elicited transient increase in plasma sodium concentration and prolonged hypokalemia. Repeated loading with mannitol in Series 2 elicited significant elevation of plasma sodium, ADH and aldosterone concentrations, as well as decrease in extracellular fluid volume. Infusion of insulin in this Series elicited smaller decrease in plasma potassium concentration and longer lasting hypernatremia than in dogs in water-electrolytes balance. Aldosterone infusion in Series 3 did not change hypokalemic effect of insulin but attenuated hypernatremia. Infusion of insulin in Series 1 elicited increase of sodium excretion and decrease in potassium excretion. These effects were absent in Series 2 and 3. The results indicate that depletion of electrolytes and blood aldosterone elevation modify the effects of insulin on plasma concentration and renal excretion of sodium and potassium.     

Aldosterone response to angiotensin II during hypoxemia

Exercise in humans causes increases in plasma renin activity (PRA) and plasma aldosterone concentrations (PAC) except when performed at high altitude or while the subjects breathe hypoxic gas. Under those conditions, PRA increases with exercise but PAC does not. We speculated that the PAC suppression during hypoxemic exercise was due to hypoxemia-induced release of a circulating inhibitor of angiotensin II-mediated aldosterone secretion. To test this hypothesis, we measured the PAC response to graded infusions of angiotensin II during hypoxemia and normoxemia. Eight normal volunteers were given increasing doses of angiotensin II (first 2 ng X kg-1 X min-1 and then 4, 8, and finally 12 ng X kg-1 X min-1, each for 20-min periods) on 2 separate days, once while breathing room air and the other day while breathing hypoxic gas adjusted to maintain the subjects' hemoglobin saturation at 90%. The PAC response to different doses of angiotensin II did not significantly differ during hypoxemia from normoxemia. We conclude that our model of hypoxemia does not cause release of an inhibitor of angiotensin II-mediated aldosterone release.     

The effect of Ringer solution induced extracellular volume expansion on kidney function

The present study quantitated the effects of extracellular volume expansion on sodium and water excretion in 118 anesthetized dogs. The animals received a priming injection of 10 ml kg-1 Ringer solution i.v. which was followed by a constant Ringer solution infusion at a rate of 0.25 ml.min-1.kg-1 until the end of the experiment. Fifteen minutes after the start of the constant infusion the renal parameters were examined in 11 subsequent 15 min periods (the total time was 3 hours). Volume expansion produced no significant change in arterial blood pressure, glomerular filtration rate (GFR), plasma sodium and potassium concentration or, haematocrit, but did reduce the CPAH from 284 ml.min-1 to 218 ml.min-1 (the data were calculated for 100 gram wet kidney weight). There were constant significant increases in the urinary excretion rate from 0.84 ml.min-1 to 4.06 ml.min-1 and the 39% of the infused water was excreted during the experiment. Volume expansion also caused a significant increase in sodium excretion during the three first periods from 120 mumol.min-1 to 329 mumol.min-1 followed by a small but significant decrease. The sodium excretion at the end of the experiment was 221 mumol.min-1 and the 23% of the infused sodium was excreted in the course of the experiment. The increase of the water excretion during the volume expansion was associated with fall of the urine osmolality and the urine because hypoosmotic as compared to the plasma. We have provided evidence that vasopressin was not involved in the control of water excretion in our experiments. It is concluded that neither filtered sodium nor decreased aldosterone secretion can account for the increase in sodium excretion that occurs after Ringer solution loading in the dog. It has been proposed that a decrease in plasma protein concentration may decrease passive sodium reabsorption due to oncotic forces in the proximal tubule. The Ringer solution diuresis elicits a rise in medullary blood flow, thereby causing a washout of medullary sodium. This might dissipate the osmotic force for the back-diffusion of water from the collecting duct. Our studies indicate that the response of the diluting segments of the distal nephron to increased delivery of sodium depends upon the presence or absence of volume expansion. However the increase of the distal tubular loading activates the tubuloglomerular feedback which increases the proximal tubular reabsorption. Based on these assumptions our studies provide further evidence that the tubuloglomerular feedback regulates the blood pressure in the peritubular capillaries in the cortex around the proximal tubules.     

Interaction between the natriuretic effects of renal perfusion pressure and the antinatriuretic effects of angiotensin and aldosterone in control of sodium excretion

Aldosterone has been recognized as an important sodium retaining hormone for many years. Recently we have demonstrated that angiotensin II has a much more powerful antinatriuretic effect than that of aldosterone. The importance of angiotensin II in regulation of sodium excretion has been observed in experiments in which angiotensin II has been infused intravenously or into the renal artery in acute and chronic situations, and in studies involving blockade of angiotensin II formation. In other experiments we have studied the effects of changes in renal perfusion pressure on sodium excretion. While earlier work by others indicated that an acute 10 mm Hg increase in perfusion pressure would increase sodium excretion 60%-70% we observed that a chronic 10 mm Hg change in perfusion pressure would result in a 300% change in sodium excretion. In view of evidence suggesting that changes in the ability of the kidney to excrete sodium normally at normal arterial pressure is an important element in hypertension we studied the effects of aldosterone and angiotensin II on arterial pressure regulation in normal dogs. High physiological levels of each hormone were infused intravenously for several weeks. Both produced sustained hypertension. Aldosterone hypertension was a typical volume loading type with sodium retention, increased blood volume and extracellular fluid volume and a slow rise in arterial pressure. Angiotensin hypertension was a typical vasoconstrictor type with high peripheral resistance, normal or decreased blood volume, decreased cardiac output, a rapid rise in arterial pressure and only initial sodium retention.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of captopril and enalapril on sodium excretion and blood pressure in sodium-deficient dogs

Inhibition of angiotensin I-converting enzyme (ACE) (kininase II) provides a powerful new method for evaluating the role of the renin-angiotensin-aldosterone and kallikrein-kinin systems in the control of aldosterone secretion, renal function, and arterial blood pressure. This study compares the effects of long-term administration of a sulfhydryl inhibitor, captopril, with a nonsulfhydryl inhibitor, enalapril (1-[N-[1-(ethoxycarbonyl-3-phenylpropyl]-L-alanyl]-L-proline), in conscious sodium-deficient dogs. Plasma aldosterone concentration (PAC), plasma renin activity (PRA), urinary sodium excretion (UNaV), arterial pressure (AP), blood kinins (BK), urinary kinins (UK), and urinary kallikrein activity (UKA) were determined during long-term inhibition of ACE in sodium-deficient dogs. In response to captopril administration (20 mg/(kg . day], PAC decreased from 38.9 +/- 6.7 to 14.3 +/- 2.3 ng/dl, PRA increased from 3.58 +/- 0.53 to 13.7 +/- 1.6 ng/(ml . h), UNaV increased from 0.65 +/- 0.27 to 6.4 +/- 1.2 meq/day, AP decreased from 102 +/- 3 to 65 +/- 2 mm Hg, BK increased from 0.17 +/- 0.02 to 0.41 +/- 0.04 ng/ml, UK increased from 7.2 +/- 1.5 to 31.4 +/- 3.2 micrograms/day, and UKA decreased from 23.6 +/- 3.1 to 5.3 +/- 1.2 EU/day. Quantitatively similar changes in AP, UNaV, and PAC were observed in sodium-deficient dogs in response to long-term enalapril administration (4 mg/(kg X day]. In sodium-deficient dogs maintained on captopril or enalapril for several days, angiotensin II (AngII) infusion (3 ng/(kg X min] restored PAC, UNaV, and AP to levels observed in untreated sodium-deficient dogs. These data indicate that the long-term hypotensive and natriuretic actions of inhibitors of ACE are mediated by inhibition of AngII formation and that the renin-angiotensin system plays an essential role in regulating aldosterone secretion, renal function, and AP during sodium deficiency.     

Modification of the renal response to endopeptidase inhibition and atrial natriuretic peptide infusion in normal dogs.

Inhibition of intrarenal neutral endopeptidase 24:11 (NEP) increases the natriuretic response to infused atrial natriuretic peptide (ANP). In various models of canine heart failure, angiotensin and kinins have been shown to modulate ANP and (or) NEP activity. In the present study, we examined possible modulators of NEP activity in normal dogs by infusing various agents into the left renal artery (or by denervating the left kidney) and comparing the response of this kidney with that of the contralateral one following the combined intravenous infusion of Squibb 28603 (a potent NEP inhibitor) and ANP (75 ng.kg-1.min-1). Four dogs received angiotensin (1.5 ng.kg-1.min-1) into the left renal artery, 8 dogs received saralasin (5 micrograms/min), 5 dogs received noradrenaline (2 micrograms/min), and 6 dogs received bradykinin (3 micrograms/min). Five dogs underwent left renal denervation. Angiotensin inhibited sodium excretion following the NEP inhibitor alone and after the NEP inhibitor plus ANP. Saralasin augmented the natriuretic response. None of the other protocols influenced sodium excretion. We conclude that angiotensin may modulate either the enzymatic degradation of ANP or influence its renal tubular effects.     

Effects of truncated angiotensins in humans after double blockade of the renin system

Angiotensins different from ANG II exhibit biological activities, possibly mediated via receptors other than ANG II receptors. We studied the effects of 3-h infusions of ANG III, ANG-(1-7), and ANG IV in doses equimolar to physiological amounts of ANG II (3 pmol. kg-1. min-1), in six men on low-sodium diet (30 mmol/day). The subjects were acutely pretreated with canrenoate and captopril to inhibit aldosterone actions and ANG II synthesis, respectively. ANG II infusion increased plasma angiotensin immunoreactivity to 53 +/- 6 pg/ml (+490%), plasma aldosterone to 342 +/- 38 pg/ml (+109%), and blood pressure by 27%. Glomerular filtration rate decreased by 16%. Concomitantly, clearance of endogenous lithium fell by 66%, and fractional proximal reabsorption of sodium increased from 77 to 92%; absolute proximal reabsorption rate of sodium remained constant. ANG II decreased sodium excretion by 70%, potassium excretion by 50%, and urine flow by 80%, whereas urine osmolality increased. ANG III also increased plasma aldosterone markedly (+45%), however, without measurable changes in angiotensin immunoreactivity, glomerular filtration rate, or renal excretion rates. During vehicle infusion, plasma renin activity decreased markedly ( approximately 700 to approximately 200 mIU/l); only ANG II enhanced this decrease. ANG-(1-7) and ANG IV did not change any of the measured variables persistently. It is concluded that 1) ANG III and ANG IV are cleared much faster from plasma than ANG II, 2) ANG II causes hypofiltration, urinary concentration, and sodium and potassium retention at constant plasma concentrations of vasopressin and atrial natriuretic peptide, and 3) a very small increase in the concentration of ANG III, undetectable by usual techniques, may increase aldosterone secretion substantially.     

Cardiorenal reflexes do not attenuate the renal effects of infused atriopeptin in conscious dogs.

Low-dose infusions of atriopeptin produce only a modest diuresis and natriuresis. However, these infusions also decrease atrial pressures, a change that has been postulated to elicit an antidiuretic and antinatriuretic reflex from cardiac receptors and thereby to attenuate the direct renal effects of atriopeptin. To determine whether the renal effects of intravenously administered atriopeptin might be attenuated by a cardiorenal reflex, we infused alpha-human atrial natriuretic peptide (alpha-hANP) into cardiac-denervated and sham-operated (normal) conscious dogs. Following a control period, alpha-hANP was infused into each dog at 12.5, 25, or 50 ng.kg-1.min-1 for 1 hr. Infusion of alpha-hANP at 50 ng.kg-1.min-1 produced similar decreases in left atrial pressure in both normal and cardiac-denervated dogs (peak changes, -1.6 +/- 0.8 vs -2.4 +/- 0.9 mm Hg, respectively). Increases in urine flow (peak changes, 0.13 +/- 0.05 vs 0.20 +/- 0.06 ml/min) and sodium excretion (peak changes, 56 +/- 22 vs 70 +/- 11 microEq/min) also were not different between groups. The lower doses of alpha-hANP also elicited renal and hemodynamic responses in the cardiac-denervated dogs that did not differ significantly from those in the normal dogs. These data indicate that the diuresis and natriuresis elicited by intravenously administered alpha-hANP are not attenuated by a cardiorenal reflex in conscious dogs.     

Serial natriuretic response to atrial peptide in preascitic bile duct ligated dogs

We determined if nine precirrhotic unanaesthetized dogs with chronic bile duct ligation (CBDL) responded uniformly to atrial natriuretic peptide (ANF) by infusing this peptide sequentially over 8-12 weeks at 175 ng.kg-1.min-1 and observing the natriuretic response. ANF was administered every 2 weeks post-CBDL until the 8th week and given again during the cirrhotic phase with ascites present (10-12 weeks post-CBDL). Sodium balance studies were conducted at similar time intervals. During the control period and at weeks, 2, 6, and 8 post-CBDL all dogs responded to ANF with a significant change in sodium excretion (delta UNaV, 50-240 mu equiv./min). At these times, all dogs were in sodium balance. At week 4 and during the ascitic period, heterogeneity of response to ANF was observed. In the former interval, five dogs responded (delta UNaV,75-230 mu equiv./min) and four did not, while in the latter interval, five dogs responded (delta UNaV, 50-240 mu equiv./min) and three did not (one dog died). In both time periods, there was severe urinary sodium retention (daily UNaV, 11 +/- 3 and 2 +/- 1 mequiv./day, respectively) while the dogs were ingesting 45 mequiv.Na+/day. The heterogeneity of natriuretic response was not correlated to plasma immunoreactive ANF, renin, or aldosterone levels. Plasma volume was significantly expanded from control during both intervals. We conclude that there is transient sodium retention during the 4th week post-CBDL, and that this period is associated with the heterogeneity of natriuretic response to ANF, despite the absence of ascites or edema.     

Effects of alpha-adrenergic blockade on sodium excretion in normal and chronic salt retaining dogs.

The alpha-adrenergic blocking agent phenoxybenzamine (PBA) was administered intravenously (10 mug kg-1 min-1) during a steady state water diuresis under pentothal anesthesia to six normal dogs, six dogs with chronic throacic inferior vena cava constriction and ascites (caval dogs) and seven dogs chronically salt depleted by sodium restriction and furosemide administration. In normal dogs urinary sodium excretion increased significantly from 265+/56 (SEM) to 370+/65 muequiv./min, whereas no increase in sodium excretion was noted in either caval dogs or salt depleted animals after PBA. In all three groups urine volume, fractional free water clearance and distalsodium load did not change significantly. In normal dogs, tubular sodium reabsorption decreased significantly from 73.4+/2.8% to 63.1+/4.0%, whereas no change was noted in caval or salt depleted dogs. Blood pressure and renal hemodynamics were not significantly altered by PBA administration in any group. These data demonstrate a natriuretic effect of alpha-adrenergic blockade in normal dogs with the major effect in the water clearing segment of the nephron. The absence of any effect in chronic caval or salt depleted dogs suggests that increased alpha-adrenergic activity does not play a significant role in the sodium retention of these animals.     

Pulmonary vascular responses to angiotensin II and captopril in conscious dogs

Our objectives were to investigate the extent to which angiotensin II (ANG II) and converting-enzyme inhibition (CEI) exert a direct vasoactive influence on the pulmonary circulation of conscious dogs. Multipoint pulmonary vascular pressure-cardiac index (P/Q) plots were constructed during normoxia in conscious dogs by stepwise constriction of the thoracic inferior vena cava to reduce Q. The effects of ANG II infusion (60 ng X kg-1 X min-1, iv) and CEI with captopril (1 mg/kg plus 1 mg X kg-1 X h-1, iv) on pulmonary vascular P/Q plots were assessed first with the conscious dogs intact and again after combined administration of pharmacological antagonists to block sympathetic alpha- and beta-adrenergic, cholinergic, and arginine vasopressin receptors. In intact dogs, ANG II increased (P less than 0.01) the pulmonary vascular pressure gradient (pulmonary arterial pressure-pulmonary capillary wedge pressure, PAP-PCWP) over the entire range of Q studied (60-120 ml X min-1 X kg-1). Conversely, CEI decreased (P less than 0.05) PAP-PCWP at each level of Q. After administration of the autonomic nervous system and arginine vasopressin receptor antagonists, ANG II again increased (P less than 0.01) and CEI decreased (P less than 0.01) PAP-PCWP over the entire range of Q studied. Thus exogenous administration of ANG II results in active, nonflow-dependent constriction of the pulmonary circulation, and this effect is not dependent on the autonomic nervous system or increased circulating levels of arginine vasopressin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of chemical sympathectomy on renal hydroelectrolytic handling in dogs with chronic caval constriction

The effect of renal selective chemical sympathectomy by intrarenal infusion of 6-hydroxydopamine (6-OHDA, 5 mg/kg body weight) on the renal excretion of water and electrolytes was studied in 7 dogs in whom a syndrome of sodium and water retention and ascites formation was induced by partial constriction of thoracic inferior vena cava. Propranolol (1 mg) and phentolamine (3 mg) were also injected to obviate acute systemic hemodynamic changes. Sympathectomy was performed once in 4 dogs and three times in 3 dogs. Sympathectomy induced an abrupt and transient increase in urinary flow (from 170 +/- 30 to 890 +/- 60 ml/24 h) and sodium excretion (from 4.5 +/- 1.5 to 178 +/- 21 mEq/24 h). This was accompanied by an important fall in plasma renin activity (from 2.2 +/- 0.2 to 0.5 +/- 0.1 ng angiotensin I/ml/h) and aldosterone, and disappearance of ascites. It is concluded that chemical sympathectomy, by increasing renal sodium and water excretion, mobilizes the ascites induced by chronic caval constriction, a fact that highlights the role of the renal sympathetic system in the pathogenesis of sodium and water retention by the kidney.     

Actions of nicotine on renal function in dogs

Renal excretory and circulatory responses to nicotine were investigated in anesthetized dogs under three sets of conditions: (a) infusion of nicotine into the left renal artery (ia) at a dose of 0.5 microgram X min-1 X kg body wt-1 X 15 min; (b) ia nicotine after 1.0 mg/kg ia propranolol; and (c) ia nicotine after bilateral adrenalectomy. Measured and calculated left and right renal excretory variables included sodium, potassium, and chloride excretion rates (UNaV, UKV, and UClV, respectively), total solute excretion (UOsV), glomerular filtration rate (GFR), fractional sodium excretion (FENa), and urine flow rate. Systemic arterial pressure and left renal artery blood flow (RBF) were also measured. In seven intact dogs administered nicotine alone, there were significant increases in UNaV, UClV, UOsV, GFR, and urine flow rates from both kidneys. However, nicotine did not significantly affect UKV, FENa, arterial pressure, or RBF. The lack of circulatory effects of nicotine was also observed after either propranolol or adrenalectomy. However, when nicotine was administered after propranolol, the drug evoked significant decreases in UOsV, UNaV, UClV, and GFR, compared with prenicotine values. When nicotine was administered after bilateral adrenalectomy, the drug evoked decreases in the excretory parameters similar to those observed after propranolol. These findings seem to support several inferences: (a) nicotine stimulates renal excretory functions-the alkaloid is saluretic and diuretic; (b) the action of nicotine on the kidney is mediated mainly by the release of catecholamines from the adrenal medulla; (c) catecholamines released by nicotine act mainly on beta-adrenergic receptors; and (d) the saluresis prompted by the release of catecholamines in response to nicotine is due to a subsequent increase in GFR.     

Effects of angiotensin II on arterial pressure, renin and aldosterone during exercise

To evaluate the effect of isotonic exercise on the response to angiotensin II, angiotensin II in saline solution was infused intravenously (7.5 ng X kg-1 X min-1) in seven normal sodium replete male volunteers before, during and after a graded uninterrupted exercise test on the bicycle ergometer until exhaustion. The subjects performed a similar exercise test on another day under randomized conditions when saline solution only was infused. At rest in recumbency angiotensin II infusion increased plasma angiotensin II from 17 to 162 pg X ml-1 (P less than 0.001). When the tests with and without angiotensin II are compared, the difference in plasma angiotensin II throughout the experiment ranged from 86 to 145 pg X ml-1. The difference in mean intra-arterial pressure averaged 17 mmHg at recumbent rest, 12 mmHg in the sitting position, 9 mmHg at 10% of peak work rate and declined progressively throughout the exercise test to become non-significant at the higher levels of activity. Plasma renin activity rose with increasing levels of activity but angiotensin II significantly reduced the increase. Plasma aldosterone, only measured at rest and at peak exercise, was higher during angiotensin II infusion; the difference in plasma aldosterone was significant at rest, but not at peak exercise. In conclusion, the exercise-induced elevation of angiotensin II does not appear to be an important factor in the increase of blood pressure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of parathyroid hormone on renin secretion

The ability of parathyroid hormone (PTH) to increase renin secretion was investigated in pentobarbital-anesthetized dogs. An intravenous infusion of bovine PTH 1-34, at the dose of 0.028 microgram/kg-1 min-1 increased renin secretion by 149% (501 +/- 105 to 1249 +/- 309 ng hr-1 min-1); renin secretion returned to control values during the recovery period. In order to determine whether PTH acted directly on the kidney to increase renin secretion, PTH was infused into the right renal artery at doses of 0.0014 to 0.0028 microgram/kg-1 min-1 and renin secretion from the right kidney was compared to that from the left (control) kidney. Renin secretion from the right (PTH-infused) kidney was not greater than control values for that kidney or different from the renin secretory rate of the left (control) kidney. In contrast, the excretion rates of both phosphate and sodium from the right kidney were greater than control values and from the excretion rates of the left kidney. These data suggest that PTH, while acting directly on the kidney to increase phosphate and sodium excretion, does not elevate renin secretion by a direct renal action.     

Effects of dipyridamole and furosemide on renal function during adenine dinucleotide infusion in rats

In anaesthetized rats kept on normal diet an i.v. infusion of NAD (200 nmole X kg-1 X X min-1) induced a decrease in renal plasma flow (CPAH), glomerular filtration rate (GFR) and electrolyte excretion accompanied by an increase in plasma adenosine concentration. Separate infusions of a small dose of NAD (50 nmole X kg-1 X min-1) or dipyridamole (25 micrograms X kg-1 X min-1) did not affect renal function or plasma adenosine concentration. However, when the above small doses of both agents were given simultaneously, GFR, CPAH and electrolyte excretion fell significantly, indicating potentiation of NAD action by dipyridamole, associated with increased plasma adenosine level. An i.v. infusion of furosemide failed to abolish the depression of renal function in response to NAD. The data suggest that the causal factor of this depression was adenosine and not NAD itself.     

ACE inhibition facilitates sodium and water excretion during PEEP in conscious volume-expanded dogs.

Increased activity of the renin-angiotensin system may be involved in sodium and water retention during controlled mechanical ventilation (CMV) with positive end-expiratory pressure (PEEP). We therefore evaluated renal, hemodynamic, and hormonal effects of an acute angiotensin-converting enzyme inhibition (ACEI) during PEEP and extracellular volume expansion in five trained chronically tracheotomized dogs. Three protocols were performed: control, 4 h spontaneous breathing with continuous positive mean airway pressure (Paw) of 4 cmH2O (CPAP 4); CMV 20, CPAP for 1st h, CMV with 20 cmH2O Paw for 2 h (2nd and 3rd h), and 1 h of CPAP (4th h); and CMV20-ACEI, ACEI (Ramipril, 2 mg/kg body wt) followed by the same protocol as in CMV 20. During control, sodium excretion (UNaV) and urine volume (V) increased continuously to 56.2 +/- 2.7 (SE) mumol.min-1.kg body wt-1 and 482 +/- 23 microliters.min-1.kg body wt-1, respectively. UNaV and V increased less during PEEP in CMV 20 and CMV 20-ACEI. However, significantly more sodium and water were retained in CMV 20 than in CMV 20-ACEI (2.3 +/- 0.3 vs. 1.0 +/- 0.3 mmol/kg body wt, and 20 +/- 3 vs. 11 +/- 2 ml/kg body wt) because of a decrease of glomerular filtration rate and fractional UNaV in CMV 20. Heart rate did not change in control, CMV 20, or CMV 20-ACEI. Mean arterial pressure increased during control by 13 mmHg, did not change during CMV 20, and was decreased by 7 mmHg in CMV 20-ACEI.(ABSTRACT TRUNCATED AT 250 WORDS)