Comparison of the pressor effects of angiotensin II and III in the rostral ventrolateral medulla

Microinjection of angiotensin II and III into the rostral ventrolateral medulla of anesthetized barodenervated rabbits elicited in both cases pressor responses, which were of similar magnitude and time course. The responses to angiotensin II and III were either unchanged or increased in the presence of compounds which inhibit their degradation to shorter length peptides. The results indicate that both angiotensin peptides are independently capable of eliciting pressor responses in the rostral ventrolateral medulla.     

Differential effects of endotoxaemia on pressor and vasoconstrictor actions of angiotensin II and arginine vasopressin in conscious rats

1. Regional haemodynamic responses to arginine vasopressin (AVP; 0.5, 1.0, 5.0 pmol i.v.) and angiotensin II (AII; 5.0, 10.0, 50.0 pmol i.v.) were measured in conscious Long Evans rats at various times (0, 2, 6 and 24 h) during infusion of lipopolysaccharide (LPS, 150 microg kg(-1) h(-1), i.v., n=9) or saline (n=9). Additional experiments were performed in vasopressin-deficient (Brattleboro) rats infused with LPS (n=7) or saline (n=8) to determine whether or not, in the absence of circulating vasopressin, responses to the exogenous peptides differed from those in Long Evans rats. 2. In the Long Evans rats, during the 24 h infusion of LPS, there was a changing haemodynamic profile with renal vasodilatation from 2 h onwards, additional mesenteric vasodilatation at 6 h, and a modest hypotension (reduction in mean arterial blood pressure (MAP) from 103+/-1 to 98+/-2 mmHg) associated with renal and hindquarters vasodilatation at 24 h. 3. In the Brattleboro rats, the changes in regional haemodynamics during LPS infusion were more profound than in the Long Evans rats. At 2 h and 6 h, there was a marked fall in MAP (from 103+/-3 mmHg; to 65+/-3 mmHg at 2 h, and to 82+/-4 mmHg at 6 h) associated with vasodilatation in all three vascular beds. After 24 h infusion of LPS, the hypotension was less although still significant (from 103+/-3 mmHg; to 93+/-4 mmHg, a change of 10+/-4 mmHg), and there was renal and hindquarters vasodilatation, but mesenteric vasoconstriction. 4. During infusion of LPS, at each time point studied, and in both strains of rat, pressor responses to AII and AVP were reduced, but the changes were less marked at 6 h than at 2 h or 24 h. The reduced pressor responses were not accompanied by generalized reductions in the regional vasoconstrictor responses. Thus, in the Long Evans rats, the renal vasoconstrictor responses to both peptides were enhanced (at 6 h and 24 h for AVP; at all times for AII), whereas the mesenteric vasoconstrictor response to AVP was unchanged at 2 h, enhanced at 6 h and reduced at 24 h. The mesenteric vasoconstrictor response to AII was reduced at 2 h, normal at 6 h and reduced at 24 h. The small hindquarters vasoconstrictor responses to both peptides were reduced at 2 h and 6 h, but normal at 24 h. 5. In the Brattleboro rats, the renal vasoconstrictor responses to both peptides were reduced at 2 h and enhanced at 6 h and 24 h, whereas the mesenteric vasoconstrictor response to AVP was normal at 2 h and 6 h, and reduced at 24 h. The response to AII was reduced at 2 h, normal at 6 h and reduced again at 24 h. There were no reproducible hindquarters vasoconstrictions to AVP in the Brattleboro rats. The small hindquarters vasoconstrictor responses to AII were unchanged at 2 h and enhanced at 6 h and 24 h. 6. In isolated perfused mesenteric vascular beds, removed after 24 h of LPS infusion in vivo, there was an increase in the potency of AVP in both strains (Long Evans, ED50 saline: 56.9+/-15.0 pmol, ED50 LPS: 20.4+/-4.8 pmol, Brattleboro, ED50 saline: 38.6+/-4.2, ED50 LPS: 19.6+/-2.9 pmol), but no change in the responses to AII. 7. These findings indicate that a reduced pressor response to a vasoconstrictor challenge during LPS infusion is not necessarily associated with a reduced regional vasoconstriction. The data obtained in the Brattleboro rats indicate a potentially important role for vasopressin in maintaining haemodynamic status during LPS infusion in Long Evans rats. However, it is unlikely that the responses to exogenous AVP (or AII) are influenced by changes in the background level of endogenous vasopressin, since the patterns of change were similar in Long Evans and Brattleboro rats. 8. The results obtained in isolated perfused mesenteric vascular beds differed from those in vivo, possibly due to the conditions pertaining with in vitro perfusion.     

Effect of angiotensin II and 5-hydroxytryptamine on the vessels of the human foetal cotyledon

1 The actions of angiotensin II (AT II) and 5-hydroxytryptamine (5-HT) on the vessels of the human isolated, perfused, cotyledon were examined in vitro. 1 The cotyledonary vessels were shown to respond to both AT II and 5-HT over the range 10(-8) to (10(-4) M. 3 The preparation was found to be more responsive to AT II than 5-HT. 4 The findings confirm that the responsiveness of the cotyledonary vessels differs from the vessels of the umbilical cord, and that this behaviour does not depend upon the integrity of the endothelium associated with these vessels.     

Intrarenal vascular effects of angiotensin I and angiotensin II

The effects of angiotensin I (250 pmol) and angiotensin II (7.5 pmol) on total renal blood flow and its cortical distribution were examined in 25 dogs anesthetized with pentobarbital. These peptides were administered as bolus injections directly into the left renal artery. Right and left renal blood flows were measured with noncannulating electromagnetic flow probes. The distribution of renal cortical blood flow was measured with 15-micrometers radioactive microspheres. Because angiotensin I is converted to angiotensin II extrarenally as well as intrarenally, the distribution of renal blood flow in response to the bolus injection of angiotensin agonists was measured before these peptides could have recirculated through the kidney. This maneuver precluded the possibility that blood flow changes were due to the extrarenal formation of vasoactive metabolites of angiotensin I or angiotensin II. Control total renal blood flow averaged 3.0 +/- 0.1 ml.min-1.g kidney wt-1 and was decreased 25% by both angiotensin I and angiotensin II. Outer renal cortical flow (zone I) was 5.1 +/- 0.3 ml.min-1.g-1 and was decreased to 3.9 +/- 0.3 ml.min-1.g-1 by both angiotensin I and angiotensin II. On the average, angiotensin I decreased inner cortical renal blood flow from a control of 1.8 +/- 0.2 to 1.2 +/- 0.2 ml.min-1.g-1; angiotensin II decreased inner cortical renal blood flow from a control of 1.9 +/- 0.2 to 1.4 +/- 0.2 ml.min-1.g-1. Analysis on a per-experiment basis revealed that angiotensin I, compared with angiotensin II, produced a proportionally greater decrease in inner cortical renal blood flow relative to its effects on outer cortical blood flow.     

Subfornical organ: forebrain site of pressor and dipsogenic action of angiotensin II

Intracranial injection of angiotensin II (AII) at three brain sites elicited near simultaneous dipsogenic and pressor effects in rats. Both effects were maximal, occurred with the shortest latencies, and at the lowest doses of AII when the cannula terminated precisely within the parenchyma of the subfornical organ (SFO). Pressor effects were produced by SFO injection of a dose of AII (0.1 pg) which approximates plasma AII concentrations at the high end of the physiological range. Both the drinking and pressor effects were blocked by saralasin. Injections of AII at sites immediately adjacent to SFO produced smaller effects with longer latencies. These results ruled out the possibility that SFO injections were effective via leakage to alternative sites. The pressor effect of AII at the SFO remained in animals under chloralose anesthesia, demonstrating that it is not an artifact of drinking behavior. These results indicate that the SFO is a site of AII pressor action, and confirm previous demonstrations that the structure is a site of AII drinking action.     

Cardiac-specific overexpression of angiotensin II AT2 receptor causes attenuated response to AT1 receptor-mediated pressor and chronotropic effects

BACKGROUND & AIMS: The gastroduodenal epithelium is protected from acid-peptic damage, in part, by its ability to secrete bicarbonate. Patients with duodenal ulcer disease have impaired proximal duodenal mucosal bicarbonate secretion. We have shown in vitro that histamine inhibits prostaglandin-stimulated bicarbonate secretion in rabbit duodenal mucosa via histamine H2 receptors and enteric nerves. In this study we examined whether the proulcerogenic compounds aspirin or ethanol regulate duodenal bicarbonate secretion and the involvement of histamine. METHODS: Bicarbonate secretion by rabbit proximal duodenal mucosa was examined in vitro in Ussing chambers. RESULTS: Aspirin and ethanol decreased basal and prostaglandin-stimulated bicarbonate secretion; the latter effect was specific for prostaglandin. The inhibitory effects of the two ulcerogenic compounds were at least additive. Ranitidine and tetrodotoxin abolished the inhibitory effects on stimulated, but not basal, secretion. Aspirin and ethanol also induced release of duodenal histamine. CONCLUSIONS: Aspirin and ethanol act by two distinct pathways to impair duodenal bicarbonate secretion. Both agents inhibit basal secretion via a histamine-independent and neurally independent pathway while they inhibit prostaglandin E2-stimulated secretion via histamine release, likely from mast cells, and actions on enteric nerves. Our findings may be of relevance to the understanding and potential treatment of nonsteroidal anti-inflammatory drug-associated mucosal injury.     

Fetoplacental vascular tone during fetal circuit acidosis and acidosis with hypoxia in the ex vivo perfused human placental cotyledon

OBJECTIVES: Our purpose was to determine the effects of acidosis and acidosis-hypoxia on fetoplacental perfusion pressure and its response to angiotensin II. STUDY DESIGN: Perfused cotyledons from 14 placentas were studied with either an acidotic fetal circuit perfusate (n = 7) or an acidotic-hypoxic fetal circuit perfusate (n = 7). Each cotyledon's fetal vasculature was initially perfused under standard conditions and bolus injected with 1 x 10(-10) moles of angiotensin II. Fetoplacental perfusate was then replaced with either an acidotic medium (pH 6.90 to 7.00 and Po2 516 to 613 mm Hg) or an acidotic-hypoxic medium (pH 6.90 to 7.00 and Po2 20 to 25 mm Hg) followed by an angiotensin II injection. The vasculature was subsequently recovered with standard perfusate and again injected with angiotensin II. Perfusion pressures within each group were compared by one-way analysis of variance, and results were expressed as mean pressure +/- SEM. RESULTS: Resting fetoplacental perfusion pressure did not change when the fetal circuit perfusate was made acidotic (28 +/- 1 mm Hg vs 25 +/- 2 mm Hg) or acidotic-hypoxic (26 +/- 2 mm Hg vs 25 +/- 2 mm Hg). The maximal fetoplacental perfusion pressure achieved in response to angiotensin II did not differ with an acidotic perfusate (41 +/- 2 mm Hg vs 38 +/- 1 mm Hg) or with an acidotic-hypoxic perfusate (39 +/- 2 mm Hg vs 36 +/- 2 mm Hg). CONCLUSIONS: In the perfused placental cotyledon fetoplacental perfusion pressure and pressor response to angiotensin II are not affected by fetal circuit acidosis or acidosis-hypoxia. This suggests that neither fetal acidosis nor fetal acidosis combined with hypoxia has a direct effect on fetoplacental vascular tone.     

The deleterious effects of exogenous angiotensin I and angiotensin II on myocardial ischemia-reperfusion injury

Angiotensin II is well known to have a cardiotoxic effects. However, it is still unclear whether exogenous angiotensin I or angiotensin II has a deleterious effect on myocardial ischemia-reperfusion injury. To examine this deleterious effects, we administered angiotensin I and angiotensin II to perfused hearts before ischemia, and measured creatine kinase (CK) release and cardiac function during subsequent reperfusion. Wistar Kyoto rats were used and the hearts were perfused by the Langendorff technique at a constant flow (10 ml/min). Seven hearts were perfused for 20 min and then subjected to 15 min of global ischemia (Control). In the experimental groups, during the 5 min before ischemia, we administered 100 ng/ml angiotensin I (Ang I; n = 9), 1 microgram/ml enalaprilat (ACEI; n = 5), both agents (ACEI + Ang I) (n = 6), or 10 ng/ml angiotensin II (Ang II; n = 6). The perfusates were then sampled to measure angiotensin II. After 15 min of ischemia, the hearts were reperfused with control perfusate. Throughout the 20 min of reperfusion, the effluent was collected to measure cumulative CK release. Angiotensin I increased coronary perfusion pressure (CPP) by 32 +/- 4 mmHg, however, the angiotension converting enzyme inhibitor inhibited the increase of CPP by angiotension I (11 +/- 1 mmHg) (p < 0.01). The contents of angiotensin II in the effluent in Ang I and Ang I + ACEI were 11.5 +/- 1.9 ng/ml and 4.0 +/- 0.5 ng/ml (p < 0.01). After 20 min of reperfusion, the left ventricular developed pressure was unchanged in all of the groups. CPP was also unchanged by ischemia in all of the groups.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hemodynamic effects of angiotensin II and the influence of angiotensin receptor antagonists in pithed rabbits

We investigated the cardiovascular effects of angiotensin II (AII) and the influences of four angiotensin receptor antagonists: losartan, PD123177, BIBS 39, and BIBS 222 in the pithed rabbit preparation. AII (0.03-10 nmol/kg) elicited a dose-dependent increase in blood pressure (BP), left ventricular pressure (LVP), LV end-diastolic pressure (LVEDP), dP/dtmax, and heart rate (HR). The maximal hypertensive effect of AII is comparable to that of norepinephrine (NE), but its effects on LVEDP and HR are weaker than those of NE. On a molar base, AII is approximately 27 times more potent than NE. Propranolol (0.5 mg/kg i.v.) did not significantly influence the AII-induced increase in diastolic BP (DBP) and LVEDP, but it abolished AII-induced positive chronotropic effects over the entire dose range of angiotensin AII studied. Losartan, but not PD123177, shifted the dose-response curves for AII to the right in a parallel manner. BIBS 39 and BIBS 222 also caused rightward shifts of the AII dose-response curve. These experiments indicate that in propranolol-treated pithed rabbits AII causes vasoconstrictor effects in both resistance vessels and in the venous system, which are both mediated by AT1- but not by AT2-receptors. The AII-induced positive chronotropic effect is an indirect action mediated by the stimulation of postsynaptic beta 1-adrenoceptors. BIBS 39 and BIBS 222, two new nonpeptide angiotensin receptor blockers that have affinity for both AT1- and AT2-receptors are also potent antagonists of the cardiovascular effects of AII in pithed rabbits.     

Changes in angiotensin II metabolism contribute to the increased pressor response to angiotensin after chronic treatment with L-NAME in the spontaneously hypertensive rat

1. Administration of nitric oxide (NO) synthase inhibitors, such as L-NAME, is associated with an increase in blood pressure and an increase in pressor responsiveness to infused angiotensin II (AngII). The present study was designed to investigate the contribution of changes in the metabolism of AngII to the enhanced pressor response to AngII in the spontaneously hypertensive rat (SHR; 14 weeks old) chronically treated with L-NAME. 2. Group I rats received L-NAME for 7 days (5 mg/kg per day) in their drinking water. Group II rats received water only. On day 7, rats were anaesthetized and metabolic clearance studies were performed. AngII concentrations in plasma and infusate were measured by radioimmunoassay. 3. Urinary NO2 was unchanged after L-NAME treatment, while NO3 decreased compared with control. Mean arterial pressure (MAP) was higher in the L-NAME treated rats than in control. After 30 min infusion of AngII, MAP increased significantly in both groups, although the increase was larger in L-NAME-treated than control rats. The metabolic clearance rate of AngII was significantly lower in L-NAME-treated rats than in the control group. 4. We conclude that chronic NO synthase inhibitors, such as L-NAME, cause a decrease in the rate at which AngII is metabolized. This decrease, in combination with the increase in the number of vascular AngII receptors, may account for the reported increase in pressor responsiveness to infused AngII.     

Organ specificity of angiotensin II and Des-aspartyl angiotensin II in the conscious rat

Des-Asp angiotensin II (des-Asp AII) is a naturally occurring heptapeptide metabolite of angiotensin II (AII) which is formed by the enzymatic action of aminopeptidase A. Angiotensin II and des-Asp AII were infused into unanesthetized rats while direct mean arterial pressure, serum aldosterone and serum corticosterone were measured. Both AII and des-Asp AII caused a dose-related increase in serum aldosterone with a significant increase occurring with a dose as low as 1 ng/min. This effect was blocked by pretreatment with 1-Sar-8-Ala-angiotensin II, a competitive inhibitor of AII; however, the inhibitor was more effective in blocking the effects of AII (101%) than of des-Asp AII (82%). Both angiotensins induced a dose-related increase in serum corticosterone and mean arterial pressure. Des-Asp AII was however only 1/10 as potent as AII in elevating mean arterial pressure. 1-Sar-8-Ala-AII was also effective in inhibiting the pressor effects of AII and des-Asp AII. These data illustrate a high degree of organ specificity or selectivity for des-Asp AII and a low specificity for AII. Aminopeptidase A and leucine aminopeptidase were identified in the adrenal cortex and medulla in large amounts. Des-Asp AII may thus be formed from AII locally in the adrenal gland prior to exerting its action at that site.     

Dietary (n-3) and (n-6) polyunsaturates and acetylsalicylic acid alter ex vivo PGE2 biosynthesis, tissue IGF-I levels, and bone morphometry in chicks

This study examined the effects of dietary (n-6) and (n-3) polyunsaturated fatty acids (PUFA) and acetylsalicylic acid (ASA) on bone ash content, morphometry, fatty acid composition, ex vivo PGE2 biosynthesis, tissue IGF-I concentration, and serum alkaline phosphatase (ALPase) activity in chicks. Newly hatched chicks were fed a semipurified diet containing soybean oil (S) or menhaden oil / safflower oil (M) at 90 g/kg. At 4 days of age, chicks were divided into four equal treatment groups receiving 0 mg [symbol: see text] or 500 mg [symbol: see text] of ASA/kg of diet: S[symbol: see text]ASA, M[symbol: see text]ASA, S[symbol: see text]ASA, and M[symbol: see text]ASA. Lipid and ASA treatments did not affect bone length, bone ash, or bone mineral content in chicks. Chicks fed M had increased fractional labeled trabecular surface and tissue level bone formation rates, independent of ASA treatment, compared with those given S. A significant fat x ASA interaction effect was found for trabecular bone volume, thickness, separation, and number. Chicks fed S had higher 20:4(n-6) but lower 20:5(n-3) concentrations in liver and bone compared with those given M. Ex vivo PGE2 biosynthesis was higher in liver homogenates and bone organ cultures of chicks fed S compared with the values for those given M at 17 days. ASA treatment decreased ex vivo PGE2 production in liver homogenates and bone organ cultures of chicks, independent of the dietary lipids. Chicks fed ASA had a lower concentration of IGF-I in tibiotarsal bone compared with those not given ASA at 19 days. Serum ALPase activity was higher in chicks given M compared with those fed S, but the values were reversed with ASA feeding. This study demonstrated that both dietary fat and ASA modulated bone PGE2 biosynthesis, and that (n-3) PUFA and fat x ASA interactions altered bone morphometry.     

Chronic intrarenal infusion of low-dose angiotensin II in dogs increases arterial pressure without impairment of renal function

In an effort to be a good manager, it is easy to lose sight of the fact that knowledge workers require a unique approach from their manager. Because nurses are independent and capable individuals that prosper in an environment that recognizes them as knowledge workers, nurse managers often find that traditional management techniques are not sufficient. Trying to manage all of the nurses on a unit as a single group is much like trying to herd cats. It might be less frustrating for the nurse manager to lead gently rather than manage with a firm hand. Warren Bennis suggests that this approach may provide a valuable key to successfully managing in a world of constant change.     

Salt-dependent renal effects of an angiotensin II antagonist in healthy subjects

This study was designed to evaluate in healthy volunteers the renal hemodynamic and tubular effects of the orally active angiotensin II receptor antagonist losartan (DuP 753 or MK 954). Losartan or a placebo was administered to 23 subjects maintained on a high-sodium (200 mmol/d) or a low-sodium (50 mmol/d) diet in a randomized, double-blind, crossover study. The two 6-day diet periods were separated by a 5-day washout period. On day 6, the subjects were water loaded, and blood pressure, renal hemodynamics, and urinary electrolyte excretion were measured for 6 hours after a single 100-mg oral dose of losartan (n = 16) or placebo (n = 7). Losartan induced no significant changes in blood pressure, glomerular filtration rate, or renal blood flow in these water-loaded subjects, whatever the sodium diet. In subjects on a low-salt diet, losartan markedly increased urinary sodium excretion from 115 +/- 9 to 207 +/- 21 mumol/min (P < .05). The fractional excretion of endogenous lithium was unchanged, suggesting no effect of losartan on the early proximal tubule in our experimental conditions. Losartan also increased urine flow rate (from 10.5 +/- 0.4 to 13.1 +/- 0.6 mL/min, P < .05); urinary potassium excretion (from 117 +/- 6.9 to 155 +/- 11 mumol/min); and the excretion of chloride, magnesium, calcium, and phosphate. In subjects on a high-salt diet, similar effects of losartan were observed, but the changes induced by the angiotensin II antagonist did not reach statistical significance. In addition, losartan demonstrated significant uricosuric properties with both sodium diets.(ABSTRACT TRUNCATED AT 250 WORDS)     

The intact isolated (ex vivo) retina as a model system for the study of excitotoxicity

Excitotoxicity is defined as a mode of neural cell death triggered by overactivation of receptors for the amino acid transmitter glutamate. There is considerable evidence that excitotoxicity is responsible for cell death in several neuropathological states, including some retinal diseases. The isolated retina, particularly from chick embryos, has been used extensively as an experimental system to characterize this process. This paper summarizes the use of isolated retina as a model system for studies of excitotoxicity from a theoretical and methodological point of view, and reviews results obtained from studies utilizing this system.     

Prolonged systemic and regional haemodynamic effects of intracerebroventricular angiotensin II in conscious sheep

1. The haemodynamic mechanisms by which infusion of angiotensin II (AngII), either into the lateral cerebral ventricles (i.c.v.) or intravenously (i.v.), increased arterial pressure were studied in conscious sheep. 2. Sheep were previously fitted with flow probes for measurement of cardiac output and coronary, mesenteric, renal and iliac blood flows. 3. Intracerebroventricular AngII (10 nmol/h for 1 h) increased arterial pressure by 11 +/- 4 mmHg (P < 0.001) due to vasoconstriction, predominantly in the mesentric vasculature. These effects developed over 30 min and took 2 h to return to control. Following the infusion renal conductance increased continuously for 3 h, resulting in a parallel increase in renal blood flow (to 75 +/- 18 mL/min above control, P < 0.001). 4. Intracerebroventricular AngII increased plasma vasopressin from 0.8 +/- 0.3 to 7.2 +/- 1.8 pg/mL (P, 0.01), and reduced plasma renin concentration from 0.9 +/- 0.3 to < 0.4 nmol/L/h. 5. The pressor effect of i.v. AngII (5, 10, 25, 50 nmol/h) also depended on peripheral vasoconstriction, but the pattern of responses was different. The greatest degree of vasoconstriction occurred in the renal, followed by the mesentric and iliac vascular beds; these effects were rapid in onset and offset. 6. In conclusion, the pressor responses to both i.c.v. and i.v. angiotensin depended on peripheral vasoconstriction, but there were contrasting regional haemodynamic changes. ICV AngII caused a prolonged pressor response, mainly due to mesentric vasoconstriction possibly partly due to vasopressin release, and following the infusion there was a pronounced, long-lasting renal vasodilatation. In contrast, i.v. AngII caused vasoconstriction preferentially in the renal vascular bed and its effects were short lasting.