Angiotensin tachyphylaxis and its reversal

Loss of Tachyphylaxis and Increased Sensitivity to Angiotensin II in Experimental Vein Grants

Intimal hyperplasia and atherosclerosis have been implicated in the pathophysiology of vein graft failure. Several recent studies have also reported alterations in the vasoreactivity of vein grafts. These alterations in vasoreactivity could contribute to vein graft spasm and lead to graft occlusion. This study examined the vasomotor responses of experimental vein grafts to angiotensin II, the most potent natural vasoconstrictor known. The right carotid artery was divided and bypassed in 12 rabbits with use of the right external jugular vein. The left external jugular vein was used as a control.

Eight vein grafts and jugular veins were harvested after fourteen days and 4 vein grafts after twenty-eight days. Segments of vein graft and control vein were mounted under isometric tension in an organ bath, and the dose response curves to angiotensin II obtained. On day 14, the response of the jugular veins was triphasic, while the respnse of the vein grafts was sigmoidal. The vein grafts were hypersensitive to angiotensin II. The ED50 was reduced from 8.4 ± 2.5 x 10-6 M in the jugular veins to 1.62 ± 0.24 x 10-8 M in the vein grafts (p < 0.005). The maximal response to angiotensin II was also increased from 342 ± 24 mg in the jugular veins to 558 ± 108 mg in the vein grafts on day 14 (p < 0.05). There was no significant difference in either the ED50 or the maximal response of the vein grafts on day 14 or 28. Tachyphylaxis (desensitization with repeated doses of agonist) was observed in the jugular veins but not in the vein grafts. The results show that experimental vein grafts are hypersensitive to angiotensin II, with either single or repeated exposure. This increased vasoreactivity to angiotensin II may have important clinical implications, particularly when vein grafts are used in patients with renovascular hypertension.

A fluorimetric binding assay for angiotensin II and kinin receptors

Angiotensin II (AngII) and kinins (bradykinin (BK) and des-Arg9-bradykinin (DBK)), are potent agents involved in the maintenance of blood pressure and several biological activities, and their better understanding is important to produce new drugs aimed to control arterial blood pressure. Previous studies on ligand-receptor binding have been based on radioactive methods, which led us to study a new method based on the fluorimetric method. A lanthanide attached to the N-terminal segment of the peptide (AngII, BK and DBK), which produces a time-resolved-fluorescent ligand, was used in a binding test with CHO cells expressing the AT1, AT2, B1 or B2 receptors in comparison with the same cell line tested with the radioactive ligand. Our findings indicated that the non-radioactive method provided a comparable result for the angiotensin receptors. On the other hand, the kinin receptors showed a slight reduction in the binding affinity, probably due to the linkage at the N-terminal segment and/or to the lower biological stability associated to the high temperature (37°C) used for the fluorimetric method, while the radioactive one was at 4°C. We can conclude that a time-resolved fluorescence assay would provide a sensitive method as an alternative tool for receptor studies.

Role of the second disulfide bridge (Cys(18)-Cys(274)) in stabilizing the inactive AT₁ receptor

Previous research showed that disruption of the Cys(18)-Cys(274) bond in the angiotensin II (AngII) AT₁ receptor mutant (C18S), expressed in CHO cells, causes an increase in the basal activity and attenuation of the maximum response to AngII. In addition, this mutant was mostly intracellularly distributed. Our aim was to investigate whether the intracellular presence of the mutant was due to a constitutive internalization or to a defective maturation of the receptor. The first hypothesis was assessed by pretreating the cells with losartan or [Sar¹Leu⁸]-AngII, specific AT₁ receptor antagonists, a maneuver to revert the receptor internalization. The second hypothesis was tested using calnexin, an endoplasmic reticulum marker. We found that treatment with AT₁ receptor antagonists causes an increase in the binding ability of the mutant to AngII. Furthermore, whereas the maximum effect is increased, it reduces the enhanced basal levels of IP₃. The hypothesis for a lack of maturation of the mutant receptor was ruled out because calnexin was poorly colocalized with the intracellular C18S receptor. Our results suggest that the mutation of the AT₁ receptor leads to a conformational structure similar to that of the active mode of the AT₁ receptor, favoring its internalization in the absence of the agonist.

The Angiotensin II AT1 Receptor Structure-Activity Correlations in the Light of Rhodopsin Structure

The most prevalent physiological effects of ANG II, the main product of the renin-angiotensin system, are mediated by the AT1 receptor, a rhodopsin-like AGPCR. Numerous studies of the cardiovascular effects of synthetic peptide analogs allowed a detailed mapping of ANG II's structural requirements for receptor binding and activation, which were complemented by site-directed mutagenesis studies on the AT1 receptor to investigate the role of its structure in ligand binding, signal transduction, phosphorylation, binding to arrestins, internalization, desensitization, tachyphylaxis, and other properties. The knowledge of the high-resolution structure of rhodopsin allowed homology modeling of the AT1 receptor. The models thus built and mutagenesis data indicate that physiological (agonist binding) or constitutive (mutated receptor) activation may involve different degrees of expansion of the receptor's central cavity. Residues in ANG II structure seem to control these conformational changes and to dictate the type of cytosolic event elicited during the activation. 1) Agonist aromatic residues (Phe8 and Tyr4) favor the coupling to G protein, and 2) absence of these residues can favor a mechanism leading directly to receptor internalization via phosphorylation by specific kinases of the receptor's COOH-terminal Ser and Thr residues, arrestin binding, and clathrin-dependent coated-pit vesicles. On the other hand, the NH2-terminal residues of the agonists ANG II and [Sar1]-ANG II were found to bind by two distinct modes to the AT1 receptor extracellular site flanked by the COOH-terminal segments of the EC-3 loop and the NH2-terminal domain. Since the [Sar1]-ligand is the most potent molecule to trigger tachyphylaxis in AT1 receptors, it was suggested that its corresponding binding mode might be associated with this special condition of receptors.

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.

Endothelium-dependent desensitization to angiotensin II in rabbit aorta: the mechanisms involved

The aim of this study was to characterize the role of the endothelium in angiotensin II-desensitization and its mechanisms of action. Rabbit aortic rings were exposed to increasing doses of angiotensin II (Ang II, 10–9 to 2.5 × 10–6) to generate two cumulative dose-response curves (CDRC I and II). A 50-min interval separated CDRC I and II. Desensitization was observed at all doses in unrubbed aortic tissue and at lower doses in rubbed aortic tissue. Tachyphylaxis was greater in arteries with endothelium. Treatment of intact rings with L-NG-nitroarginine methyl ester (L-NAME, 10–4 M) did not prevent this phenomenon. However, indomethacin (10–5 M) and miconazol (10–6 M) attenuated Ang II-desensitization. Treatment of unrubbed rings with nifedipine (10–6 M) and cromakalim (10–6 M) inhibited the effect of indomethacin. To confirm the involvement of K+ channels, unrubbed and rubbed aortic rings were treated with the KCa2+ blockers apamin (10–7 M), tetraethylammonium (TEA, 10–3 M), and iberiotoxin (10–8 M), and the KATP blocker glibenclamide (10–5 M). In both arteries apamin, TEA, and glibenclamide abolished the tachyphylaxis without changes in the maximal response. Iberiotoxin diminished Ang II-desensitization in rubbed but not unrubbed arteries. Results from this study suggest that Ang II-desensitization involves endothelium-dependent and -independent mechanisms. Endothelium-dependent desensitization could be mediated by a cyclooxygenase-cytochrome P450 product, which could act by increasing KCa2+ channel activity.Key words: angiotensin II, rabbit aorta, desensitization, endothelium, cyclooxygenase products.

Enalapril and valsartan improve cyclosporine A-induced vascular dysfunction in spontaneously hypertensive rats

Cyclosporine A causes hypertension and nephrotoxicity in spontaneously hypertensive rats (SHR). In the present study, arterial function was investigated using in vitro vascular preparations after long-term treatment with cyclosporine A. SHR received cyclosporine A (5 mg kg(-1) day(-1) s.c.) and high-Na(+) diet for 6 weeks during the developmental phase of hypertension. Part of the rats were treated concomitantly either with the angiotensin converting enzyme inhibitor enalapril (30 mg kg(-1) day(-1) p.o.) or with an angiotensin AT(1) receptor antagonist valsartan (3 or 30 mg kg(-1) day(-1) p.o.). In renal arteries, contractile responses to noradrenaline and angiotensin II, as well as relaxation responses to acetylcholine (endothelium-dependent) and to sodium nitroprusside (endothelium-independent), were severely impaired by cyclosporine A-treatment. There was also a trend for the dysfunction of the mesenteric arteries, but the impairment did not reach statistical difference. Enalapril and valsartan improved the impaired renal arterial functions. Cyclosporine A-induced hypertension and nephrotoxicity seem to be associated with renal arterial dysfunction in SHR on high-Na(+) diet. Antagonism of the renin-angiotensin system protects from vascular toxicity of cyclosporine A.

Increased tail artery vascular responsiveness to angiotensin II in cold-treated rats

Chronic exposure of rats to cold for 1-3 weeks results in a mild form of hypertension. The renin-angiotensin system (RAS) has been implicated in this model of cold-induced hypertension. Previously we have characterized the vascular responsiveness in cold-acclimated animals, using aortic tissue, and recent studies have focused on the thermoregulatory responses of angiotensin II (AngII), utilizing the tail artery of the rat. Therefore in the current study we evaluated the vascular responsiveness of cold-treated rats to AngII in both aorta and tail artery at 2 and 4 weeks of cold exposure (5 ± 2°C). Systolic blood pressures were significantly elevated in cold-treated animals compared with control animals at both 2 and 4 weeks of cold exposure. At both of these time points body weights were reduced and ventricular weights were increased in cold-treated animals. After 2 weeks of cold exposure the vascular responsiveness of the aorta to AngII was significantly lower than that of controls. This vascular responsiveness to AngII was elevated and returned to control levels after 5 weeks of cold exposure. However, this pattern was not observed in the tail artery. The vascular responsiveness of tail artery rings from cold-treated rats to AngII was significantly greater than that of control animals during both 2 and 5 weeks of exposure to cold. The vascular contractile responses of both the aorta and tail artery to KCl in the cold-treated animals was not different from that of the control animals maintained at ambient room temperature, suggesting that the vascular smooth muscle contractile components were not altered by the cold exposure. Thus, the in vitro vascular reactivity to the receptor-mediated vasoconstrictor AngII was decreased in the sparsely innervated aorta and increased in the more densely innervated tail artery of the cold-treated animals when compared with controls. These results suggest that the increased responsiveness of AngII on the smooth muscle of the tail artery may play a role in adaptation to the cold and the maintenance of cold-induced hypertension.Key words: cold exposure, hypertension, renin-angiotensin system, vascular responsiveness, angiotensin II.

Role of AT1 and AT2 receptors in the plasma clearance of angiotensin II

This study assessed the role of angiotensin (Ang) AT1 and AT2 receptors as modulators of the plasma clearance of Ang II. Groups of male spontaneously hypertensive rats (SHRs; n = 25) were given an intravenous injection of either saline, losartan, PD123319, losartan in combination with PD123319, or Sar1-Thr8-Ang II. One hour later, Ang II (0.5 microg/kg) was infused for 15 min into a vein. Immediately thereafter, arterial blood samples were collected at regular intervals for the assay of plasma Ang II levels by radioimmunoassay. The infusion of Ang II significantly increased baseline mean arterial pressure (MAP) in rats pretreated with either saline or PD123319 but not in those receiving losartan, losartan combined with PD123319, or Sar1-Thr8-Ang II. The plasma clearance of Ang II was significantly greater in rats injected with either PD123319, losartan combined with PD123319, or Sar1-Thr8-Ang II compared to those injected either saline or losartan. Furthermore, the half-life of Ang II in rats pretreated with saline or losartan was significantly greater than that measured in the other three groups. These results suggest that plasma clearance of Ang II in the SHRs is independent of an AT1 receptor, but plasma levels of the peptide are unexpectedly protected by an AT2 receptor-dependent mechanism.

G protein-coupled receptor kinase 5 in cultured vascular smooth muscle cells and rat aorta. Regulation by angiotensin II and hypertension

GRK5, a recently cloned member of the G protein-coupled receptor kinase family, has been shown to phosphorylate and participate in the desensitization of angiotensin II (Ang II) type 1A (AT1A) receptors. In this study, the effect of angiotensin II on GRK5 expression was examined in cultured vascular smooth muscle cells and aortas of Ang II-infused hypertensive rats. In vascular smooth muscle cells, Ang II (100 nM) up-regulated GRK5 mRNA as early as 1 h, with a peak at 16 h. This up-regulation was dose- and calcium-dependent. The increase in GRK5 mRNA was reflected in a smaller increase in protein expression, which nonetheless had functional significance since AT1 receptor phosphorylation was increased and phospholipase C activation was decreased following prolonged incubation with Ang II. In aortas of Ang II-infused hypertensive rats, both GRK5 mRNA and protein levels increased approximately 3-fold compared with sham-operated rats at 5 and 7 days, respectively. This up-regulation was blocked either by losartan or by the nonspecific vasodilator hydralazine. Since a subpressor dose of Ang II did not increase GRK5 mRNA levels and norepinephrine infusion also increased GRK5 mRNA expression, we conclude that Ang II-induced GRK5 up-regulation in rat aortas may be due to hypertension per se. Hormone- and hemodynamic stress-induced GRK5 regulation may provide a novel molecular basis for long-term regulation of agonist sensitivity of vascular cells.

Agonist-antagonist interactions at angiotensin receptors: application of a two-state receptor model

Interactions between agonists and antagonists at angiotensin receptors are characterized by a number of features: variation of antagonist dynamics between apparent simple competition, insurmountable antagonism and, occasionally, augmentation; the tendency for insurmountable antagonism to be saturable; slow recovery of agonist responses following agonist-induced tachyphylaxis; and the ability of competitive antagonists to accelerate recovery from the latter intervention. Some of these phenomena have also been observed in studies of 5-HT2 receptors where they were attributed to the operation of a two-state model with an allosteric site. In this article, Mark Robertson and colleagues propose that the properties of angiotensin AT1 receptors may be explained by a similar model, but without the need to evoke an allosteric site.

In vivo study of angiotensin II tachyphylaxis in freely moving normo- and hypertensive rats

In vivo tachyphylaxis to the angiotensin II-induced increase in mean arterial blood pressure was studied in conscious freely moving rats by telemetry blood pressure monitoring. The animals studied were the normotensive Sprague Dawley rats (SD), the spontaneously hypertensive rats (SHR), and two models of experimentally-induced hypertensive rats, namely, the left renal artery stenosed SD hypertensive rat (LRAS) and the deoxycorticosterone acetate/salt SD hypertensive rat (DOCA). Two consecutive dose-response curves to angiotensin II in each rat were obtained. The increase in mean arterial pressure (MAP) at each bolus dose of the first dose-response curve was found not to be significantly different from the corresponding value of the second dose-response curve in the four models of rat studied (i.e. no significant difference in the intra-rat response to AII). In addition, the slope of the dose-response curve is similar for each model of rat indicating that there was no inter-model variation to the response of AII. The results show that the response to AII in the SD and the three models of hypertensive rats was remarkably similar and that they did not develop tachyphylaxis to the pressor response of AII at concentrations ranging from circulating level of 0.0005 nmoles/kg (10(-11) M) to 10 nmoles/kg (2 x 10(-7) M). This was despite the fact that the SD had normal blood pressure and the genesis of hypertension in each model of the hypertensive rats was different.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of tachyphylaxis to angiotensin II in rabbit isolated aorta by the angiotensin AT1 receptor antagonist, losartan

In rabbit aortic strip preparations, angiotensin II (AII) concentration-contractile response curves (0.3-100 nM) were highly reproducible. However, tachyphylaxis to the contractile response elicited by AII could be induced by repeated exposure to a supramaximal concentration (10 microM) of the peptide. In contrast, a correspondingly supramaximal concentration of the alpha 1-adrenoceptor agonist, phenylephrine (1 mM), did not cause the tissue to become tachyphylactic to phenylephrine. Furthermore, phenylephrine responses were unaffected in tissues previously made tachyphylactic to AII. When the non-peptide, competitive angiotensin AT1 receptor antagonist, losartan (300 nM), was administered before each supramaximal AII challenge, tachyphylaxis did not subsequently occur. Additionally, in tissues made tachyphylactic to AII, subsequent incubation with losartan (300 nM) reversed the AII tachyphylaxis. Thus, losartan may prevent the loss of contractility by preventing AII from interacting with its receptor in a manner which induces tachyphylaxis. However, since losartan can also completely reverse the loss of contractility, it appears capable of restoring the AT1 receptor to a state which allows subsequently administered AII to fully activate the contractile pathway.

Evidence that [Sar1]angiotensin II behaves differently from angiotensin II at angiotensin AT1 receptors in rabbit aorta

Three peptide analogues, [Sar1]angiotensin II, angiotensin II and [Asn1, Val5]angiotensin II, that act at angiotensin AT1 receptors were compared in an isolated rabbit aorta assay. Significant differences have been found among them in agonist profiles and agonist-antagonist interactions with losartan, a nonpeptide antagonist selective for AT1 receptors. Most significantly, underestimation of the antagonist potency for losartan with a flat Schild plot was obtained with [Sar1]angiotensin II. These findings were confirmed in further examinations with representative peptide antagonists including [Sar1,Ala8]angiotensin II. The failure of PD123177, a nonpeptide antagonist selective for AT2 binding sites, to induce any significant difference in the complex antagonism of [Sar1,Phe(Br5)8]angiotensin II to angiotensin II appeared to rule out significant involvement of AT2 binding sites in the differences observed among the agonists, as well as in the complex antagonism. On the basis of the present findings it is speculated that either a saturable agonist removal process or heterogeneous sub-populations of AT1 receptors may be involved.

Response of the human urinary bladder to angiotensins: a comparison between neurogenic and control bladders

The response of the human detrusor muscle to angiotensins was investigated and compared between neurogenic and control bladders. Both angiotensin I and II induced potent contraction of the human detrusor muscle. Saralasin completely inhibited the response to both angiotensins, while verapamil and indomethacin barely suppressed the contractility provoked by angiotensin II. Captopril completely blocked the response to angiotensin I. The contractile response of angiotensin II was abolished in Ca(++)-free Krebs' solution. The contractile strength of the neurogenic bladders induced by both angiotensin I and II was significantly weaker than that of the controls. However, there was no difference in ED50 value between the 2 groups. These results support the hypothesis that angiotensin I is converted to angiotensin II by angiotensin converting enzyme in the detrusor, and that angiotensin II subsequently contracts the detrusor muscle through angiotensin II receptors. The bladder contractility induced by the angiotensins was significantly less potent in the neurogenic bladders than in the control.

Prorenin in diabetes mellitus

A rise in plasma prorenin often precedes the onset of vascular injury in patients with diabetes mellitus. Plasma prorenin measurements may be useful for predicting which patients will develop vascular injury and for monitoring the progression of the disease. A hypothesis is presented that accounts for these relationships and for the cosecretion of prorenin and renin into the circulation.

Effects of noradrenaline and prostaglandin F2 alpha on angiotensin-induced contraction and tachyphylaxis in rat aortic rings

The aim of this study was to examine the effects of noradrenaline (NA) and prostaglandin F2 alpha (PGF2 alpha) on angiotensin II (AII)-induced contraction and tachyphylaxis in aortic rings of the rat. Neither NA (10(-9) M) nor PGF2 alpha (10(-7) M) had significant effect on the response of the rings to the spasmogenic concentrations (10(-10) to 10(-7) M) of AII, but lowered significantly the threshold response of the aortic rings to AII (from 10(-9) to 10(-12) M). In rings that were tachyphylatic to AII, both NA and PGF2 alpha attenuated significantly the tachyphylaxis of the rings to AII at the concentrations of 10(-10) and 10(-7) of the octapeptide; and also lowered the threshold of the tachyphylatic rings to AII (from 10(-9) to 10(-11) M for NA, and from 10(-9) to 10(-10) M for PGF2 alpha). The specific properties of noradrenaline and PGF2 alpha were not shared by the non-specific potassium chloride. Because the lowering of threshold and attenuation of tachyphylaxis occurred at the physiological levels of AII and NA, it is possible that the in vivo actions of AII are under constant modulation by circulating and localised (higher than circulating) levels (e.g. of PGF2 alpha) of spasmogens. The results also call into question the physiological significance of angiotensin tachyphylaxis and may suggest that it is only an in vitro phenomenon occurring in the absence of endogeneous spasmogens.

Modulation of angiotensin II-induced vasoconstriction by endothelium-derived relaxing factor in the isolated microperfused rabbit afferent arteriole

Although endothelium-derived relaxing factor (EDRF) has been studied extensively in large vessels, little is known about its role in the preglomerular afferent arteriole (Af-Art). We tested the hypothesis that EDRF, which is produced locally in the Af-Art, modulates arteriolar responses to angiotensin II (AII). A single rabbit Af-Art with its glomerulus intact was microperfused in vitro at 60 mmHg. When 0.1 microM AII was first applied, luminal diameter decreased by 49 +/- 7.0% (n = 9; P less than 0.0001); however, constriction waned, with the decrease becoming 15 +/- 3.5% at 1 min. After washing the Af-Art, repeated AII caused less constriction (13 +/- 4.0%; P less than 0.0002 vs. first application), showing tachyphylaxis. Pretreatment with Nw-nitro-L-arginine (N-Arg), which inhibits synthesis of nitric oxide (an EDRF), decreased basal diameter by 18 +/- 3.0% (n = 14; P less than 0.0001). N-Arg also augmented AII-induced constriction (86 +/- 6.8%; P less than 0.02 vs. nontreated Af-Art) and rendered it persistent (82 +/- 6.9% at 1 min). Even after pretreatment with N-Arg, repeated AII caused a weaker response, which was restored by washing with kidney homogenate rich in angiotensinase. In conclusion, this study provides evidence that local production of EDRF is an important determinant of the tone of the Af-Art. Our results suggest that the transient nature of AII-induced constriction of the Af-Art may be due to production of EDRF, while tachyphylaxis may be the result of long lasting receptor occupancy.

Arteriovenous ratios of angiotensin II during acute infusion experiments: a model-based analysis

The hormone angiotensin II (AII) is a vasoconstrictor known to participate in the natural regulation of blood pressure via the renin-angiotensin system. A third-order model was developed which describes the dynamics of venous and arterial plasma AII concentrations (PAC) and mean arterial blood pressure (BP) during acute constant rate AII infusion experiments. The model is calibrated using approximate blood circulation rates and steady-state PAC and BP data for published experiments in sheep. Analysis of the dynamic model demonstrates that local changes in PAC during the first several minutes of acute infusion are characterized by the comparatively rapid distribution of exogenous AII making its forward passage across the blood circulation, combined with the more gradual elevation of exogenous AII recycled through the circulation. This analysis explains the observed divergence in physiological levels of venous and arterial PAC at steady state in terms of the monotonic net clearance of elevated levels of circulating AII along the circulatory path between the point of infusion and the two sites at which the PAC measurements are taken. The model suggests that the differing arteriovenous AII concentration ratios and differing PAC and BP relationships reported for different dose-response experiments may be explained in part by differences in the specific infusion and measurement sites employed in those experiments.

Effect of age on contractile response to angiotensin II in rat aorta

The effects of aging on contractile response to angiotensin II and tachyphylaxis to it were investigated using aortic strips from rats aged 1.5, 4 and 22 months. Whether the endothelium was present or not, the contractile response to angiotensin II was greater and tachyphylaxis to it was less in 1.5-month-old rats than in 4- and 22-month-old rats. The differences between 4- and 22-month-old rats were not significant. Removal of the endothelium enhanced angiotensin II-induced maximal contraction and depressed the tachyphylaxis, these endothelial effects being greater in 4- rather than in 1.5-month-old rats. When the contractile force of angiotensin II was adjusted to a similar level for 1.5- and 4-month-old rats, the endothelial effect on the tachyphylaxis was greater in the 4-month-old rats, but no significant difference was noted in the endothelial effect on the contractile force. These results suggest that during growth, the contractile response of rat aorta to angiotensin II decreases while the endothelial effect on it increases.

Evidence for a regulatory site in the angiotensin II receptor of smooth muscle

The homologous desensitization induced by angiotensin II analogues in the guinea-pig isolated ileum was studied. Desensitization assessed by the loss of response on repeated treatment showed [Sar1]angiotensin II to be a strong desensitizer whereas no desensitization to [Lys2]angiotensin II was detected. However, prolonged treatment with either analogue desensitized the tissue, indicating that [Lys2]angiotensin II-induced desensitization was reversed faster. A correlation was found between the degree of desensitization caused by repeated treatment and the time for half-relaxation after washout of the first treatment, but the relaxation after washout became faster in the desensitized state. In experiments designed to study competition between the agonistic and desensitizing properties of angiotensin II analogues, high concentrations of [Lys2]angiotensin II blocked the agonistic but not the desensitizing effect of lower concentrations of [Sar1]angiotensin II. It is concluded that desensitization is due to the interaction of angiotensin II with a regulatory site on the receptor.

A dynamic model of angiotensin II infusion experiments

Applications of control theory in studies of biological system dynamics have come to be called compartmental modelling. A second order, nonlinear, compartmental model is developed which describes the dynamics of the hormone angiotensin II (AII) and arterial blood pressure (BP) during AII infusion experiments. The model is partially identified using dose response data for constant infusion rates between 0.01 and 0.10 microgram/kg/min over a period of several minutes. This study represents a first step in understanding the dynamics of regulation of arterial blood pressure by the renin-angiotensin system. AII is a vasoconstrictor and is known to participate in the natural regulation of BP. AII is also believed to be an agent in the development of hypertension and atherosclerosis. The model is used to identify causal mechanisms which are consistent both with the established correlation between plasma AII concentration and arterial BP and with current physiological knowledge. The study demonstrates how a simple state variable model can be used to provide guidance concerning the design of future infusion experiments.

Arteriolar vasoconstriction and tachyphylaxis with intraarterial angiotensin II

Several aspects of the differences between the responses of the second- to fifth-order arterioles (A2 to A5) to intraarterial administration of angiotensin II (AII) were studied by intravital microscopy on an original preparation of rat cremaster muscle. Dose-response curves displayed a leftward shift when the arteriolar order increased. Doses inducing 50% vasoconstriction were 15.1, 0.51, and 0.08 micrograms for A3, A4, and A5, respectively. For A2, very small vasoconstriction was found even at the highest dose of angiotensin II. The dynamics of the response were also dependent on the arteriolar order. The duration of the peak of vasoconstriction increased from A3 to A5, and the interval between the contact of vascular wall with drug and the response was smaller in A4 and A5 than in A3. To understand the effect of diameter as a determinant of heterogeneity in the degree of arteriolar vasoconstriction, norepinephrine was administered under the same conditions as angiotensin II, and responses were measured on arterioles with the same morphological characteristics as those examined after angiotensin II. When comparing the regression curves for the percentage of vasoconstriction vs diameter, we found that this relationship was drug dependent. The significantly steeper slope for angiotensin II than for norepinephrine excluded the possibility that heterogeneity of the degree of vasoconstriction is solely due to differences between the morphological characteristics of the arterioles. Since tachyphylaxis to AII is considered to be a reflection of the drug-receptor interaction, we also studied the magnitude of this phenomenon from proximal to distal parts of the arteriolar network. We showed that the degree of partial tachyphylaxis after 1 microgram AII was dependent on the arteriolar order and a decreasing tachyphylaxis gradient was evidenced from A3 to A5 arterioles.

Angiotensin tachyphylaxis in normal and everted rings of rabbit aorta

The development of tachyphylaxis to angiotensin II and to [1-sarcosine]angiotensin II ([Sar1]angiotensin II) was studied in rabbit aorta helical strips, normal rings and everted rings, with and without a functional endothelium. Normal rings developed tachyphylaxis to both angiotensin II and [Sar1]angiotensin II, helical strips only to [Sar1]angiotensin II and everted rings did not show tachyphylaxis. The presence or absence of a functional endothelium had no effect on the development of tachyphylaxis in any of the preparations. Measurement of the intraluminal pH of the normal rings with an antimony minielectrode showed that under steady state conditions there was a pH gradient between the intima side of the vessel wall and the outside bath medium. This could be responsible for the greater susceptibility of the normal rings to tachyphylaxis.

Effect of acute and chronic ethanol on the agonist responses of vascular smooth muscle

We studied the effect of ethanol in vitro on the response of isolated rat aortas to phenylephrine and angiotensin II. We also examined the effect of chronic ethanol consumption on the phenylephrine response and the effect of ethanol in vitro on that response during the development of ethanol-induced hypertension. In acute experiments the depression of the phenylephrine dose-response produced by ethanol in vitro was greater than that for angiotensin II. Comparing the depression of these agonist dose-responses by ethanol to the depression by the receptor blockers, verapamil, prazosin and saralasin, suggests that ethanol may act like an alpha 1-adrenoceptor blocker. During chronic ethanol consumption two opposing changes occurred: (1) desensitization to phenylephrine during weeks 6-18 and, (2) tolerance to depression by ethanol in vitro during weeks 4-10. These opposing changes may cancel each other which suggests that the hypertension due to chronic ethanol consumption is probably not due to an action of ethanol on the vasculature.

Endothelium enhances tachyphylaxis to angiotensins II and III in rat aorta

Development of tachyphylaxis to angiotensin-induced contraction was compared in rings of rat aorta with and without functional endothelium. Rat aorta with functional endothelium rapidly developed marked tachyphylaxis to contraction induced by angiotensin II or angiotensin III. Destruction of endothelium significantly depressed, but did not prevent, development of tachyphylaxis to contractile responses induced by repeated exposure to angiotensin II or angiotensin III. The findings suggest that two mechanisms are involved in the development of tachyphylaxis to angiotensin in rat aorta, an endothelium-dependent mechanism and an endothelium-independent mechanism.

Redistribution of blood flow in experimental hepatic tumours with noradrenaline and propranolol

Noradrenaline induced changes in the distribution of blood flow in implanted tumour and normal liver tissue was measured using blood flow tracer microspheres. The ratio of embolised microspheres in tumour compared to normal tissue was determined before and after the intravenous infusion of noradrenaline, propranolol and a combination of the two drugs. The ratio was significantly decreased by noradrenaline alone but significantly increased when propranolol was added to the infusate. Propranolol had no effect on the ratio. The drug combination increased the tumour to normal ratio by approximately 69% and also doubled the proportion of microspheres entering the internal tumour circulation. This represents an enhanced relative blood supply to tumour and would provide a means of preferential carriage of blood borne cytotoxic agents to tumour tissue rather than normal tissue.

Somatostatin: peripheral venoconstrictive activity and interaction with monoamines in man

The mechanism of somatostatin venoconstriction and tachyphylaxis in the human hand vein in vivo has been investigated. No cross-tachyphylaxis was observed between somatostatin and 5-hydroxytryptamine, noradrenaline, adrenaline, dopamine or tyramine-induced venoconstriction. Somatostatin potentiates the venoconstrictive activity of noradrenaline, adrenaline and dopamine, but not that of 5-hydroxytryptamine and tyramine. Phentolamine antagonizes the somatostatin-induced venoconstriction, whereas methysergide, haloperidol and morphine do not. It is suggested that somatostatin could act on specific receptors in the hand vein, but the mechanism of somatostatin venoconstriction and interaction with vasoactive monoamines remains to be defined.

Hypoxia does not alter angiotensin converting enzyme activity in hamster pulmonary microvessels

Studies were initiated to investigate the effects of hypoxia on the conversion of angiotensin I (AI) to angiotensin II (AII) in microvessels of the lung. Using the technique of allografting neonatal lung tissue into the cheek pouch of normal hamsters, the microvessels of the lung, pulmonary arterioles, and venules could be visualized and manipulated by direct in vivo microscopy. The microvessels of the lung were studied 7-10 days after allografting by anesthetizing the hamster with pentobarbital (6.0 mg/100 g body weight i.p.) and then preparing the lung tissue for observation. The tissue was suffused with a Ringer's bicarbonate solution bubbled with a normal (20% O2-5% CO2-75% N2) or a low (95% N2-5% CO2) oxygen mixture. After equilibration, a pulmonary arteriole or venule was selected for observation, and the vessel geometry was recorded. Then, a micropipette containing either AI or AII was positioned alongside the vessel, and the agent was delivered continuously for 2 minutes. Lumen diameter was recorded continually for 8-10 minutes. This procedure was repeated until both angiotensins were tested on pulmonary arterioles and venules under conditions of a normal and low oxygen environment. This protocol was repeated on cheek pouch microvessels that did not contain pulmonary allografts. Both AI and AII produced rapid decreases in the lumen diameters of all microvessels tested. This vasoconstriction was greater for AII, and the oxygen environment did not alter the response. Conversion of AI to AII was not altered by the oxygen environment, and the relative conversion was similar in the microvessels of the lung and cheek pouch.(ABSTRACT TRUNCATED AT 250 WORDS)

The fundamental hemodynamic mechanism underlying gastric "stress ulceration" in cardiogenic shock

Acute hemorrhagic ulceration of the gastric mucosa is seen frequently in patients with hypovolemic or cardiogenic shock. Although such lesions clearly are related to regional gastric ischemia, little attention has been directed at the underlying mechanism(s) mediating the ischemia itself. To this end, anesthetized pigs were subjected to sustained cardiogenic shock (mild hemorrhage and pericardial tamponade) such that cardiac output was reduced to 38 +/- 1% of the baseline level for 4 hours, followed by release of the tamponade, reinfusion of the shed blood, and resuscitation for 2 hours. During the period of shock, there was profound regional gastric ischemia, resulting from severe and disproportionate gastric vasoconstriction. "Blinded" gross and microscopic evaluation of the stomachs removed after the experiment revealed severe mucosal ischemic necrosis, hemorrhage, and ulceration, whereas sham-operated pigs showed no lesions. The characteristics of this model therefore mimic the essential features of the gastric "stress ulceration" syndrome. Prior confirmed total alpha-adrenergic blockade with phenoxybenzamine failed to alter these features significantly. In contrast, prior ablation of the renin-angiotensin axis, whether by angiotensin-converting enzyme inhibition with teprotide or by bilateral nephrectomy, significantly and substantially ameliorated the ischemia, vasospasm, and mucosal injury. In this model of cardiogenic shock, acute gastric mucosal "stress ulceration" is caused by a disproportionately severe regional gastric ischemia resulting from selective splanchnic vasospasm that is unaffected by sympathetic blockade but abolished by prior ablation of the renin-angiotensin axis. Like nonocclusive small bowel ischemia, ischemic colitis, and the "shock liver" syndrome, gastric "stress ulceration" is yet another component of the multiple splanchnic organ failure syndrome that appears to be mediated primarily by the remarkable sensitivity of the splanchnic vascular bed to the renin-angiotensin axis.

Responses of femoral resistance vessels to angiotensin in vitro

The effect of angiotensin II and angiotensin I on isolated rat resistance vessels (inner diameter ca. 200 micron) was investigated. Angiotensin II caused a contraction (ED50 = 0.58 +/- 0.17 X 10(-8) M) of rat femoral and cerebral arteries and to a lesser extent of mesenteric and renal arteries. However, all vessels showed strong tachyphylaxis on repeated stimulation with angiotensin II. Tachyphylaxis was avoided by inducing submaximal tone in the vessels with either K, noradrenaline or serotonin. The response to angiotensin II was inhibited by saralasin but not by captopril. Angiotensin I also caused contraction of the femoral arteries (ED50 = 2.68 +/- 0.32 X 10(-8) M). These responses were inhibited by captopril and saralasin. Functional removal of the endothelium had little effect on the contractile responses to either angiotensin I or II. These results indicate that there are functional receptors to angiotensin II in the resistance vessels of the rat and that, in the presence of tone (a more physiological condition), the vessels contract to angiotensin II without tachyphylaxis. In addition, angiotensin II may be formed from angiotensin I by the angiotensin converting enzyme which may be situated in the vessel wall as well as in the endothelium.

Protection of the small intestine from nonocclusive mesenteric ischemic injury due to cardiogenic shock

In a pericardial tamponade model of cardiogenic shock in pigs, we had previously shown that acute reductions in cardiac output produce severe mesenteric ischemia due to disproportionate splanchnic vasoconstriction. In this study, we extended the period of cardiogenic shock in order to investigate the pathogenesis of ischemic injury to the small intestinal wall. Four hours of tamponade produced sustained changes in splanchnic hemodynamics, similar to those observed in the prior short-term experiments. The resultant mesenteric ischemia caused necrotic lesions of the small intestine which were characteristic of those seen in nonocclusive mesenteric ischemia in human subjects. Prior alpha-adrenergic blockade failed to prevent either sustained mesenteric vasospasm or ischemic injury. In contrast, prior blockade of the renin-angiotensin axis, whether by nephrectomy or angiotensin-converting enzyme inhibition, blocked the splanchnic vasoconstriction, and thereby protected the small intestine from ischemic injury. The primary hemodynamic and pathologic features of this model of nonocclusive mesenteric ischemia appear to be mediated by the renin-angiotensin axis.

Antidepressant tachyphylaxis

We report eleven patients in whom tachyphylaxis to antidepressants, lithium or ECT occurred. These cases are a small sample of patients we have encountered in whom an initial good response to mood regulating drugs was not sustained. We suspect that systematic studies would reveal that tachyphylaxis is a common phenomenon with antidepressant therapies.

Role of the two N-terminal residues of angiotensin II in the production of tachyphylaxis

The structural requirements for the production of angiotensin tachyphylaxis in the guinea-pig ileum were studied by analyzing the tachyphylactic properties of the following synthetic analogues of angiotensin II (AII): [1-sarcosine]AII, [1-betaine]AII; [1-guanidinoacetic]AII; betainyl-AII; [2-lysine]AII; [2-ornithine]AII. In the non-atropinized ileum, no tachyphylaxis was observed with any of the following analogues: [2-lysine]AII, [2-ornithine]AII, [2-ornithine]AII, [1-betaine]AII and betainyl-AII. [1-Guanidinoacetic]AII induced tachyphylaxis, but to a smaller degree than AII, while [1-sarcosine]AII was significantly more tachyphylactic than AII. Similar results were obtained in the atropinized ileum, except that moderate tachyphylaxis was also observed with betainyl-AII and [1-betaine]AII. The analogues with lysine or ornithine residues in position 2 did not induce tachyphylaxis under any of the conditions studied. It is concluded that, besides the protonated N-terminal amino group, the guanidino group of the Arg2 side-chain is essential for the manifestation of angiotensin tachyphylaxis in the guinea-pig ileum.

Renal vascular tachyphylaxis to angiotensin II: specificity of the response for angiotensin

Hypotheses concerning angiotensin's role in states characterized by severe and sustained renal vasoconstriction, must account for the poorly sustained renal response to this agent in healthy animals and man. To assess the specificity of renal vascular tachyphylaxis to angiotensin II (AII), renal blood flow was measured with an electromagnetic flowmeter in eight anesthetized dogs. Bolus injections of AII and norepinephrine into the renal artery were adjusted to produce at least a 50% reduction in renal blood flow, and were followed by a continuous infusion of AII sufficient to reduce renal blood flow acutely by 60 +/- 10%. The response to the continuous infusion was poorly sustained, blood flow returning to near baseline within 10 minutes: At this time the response to bolus administration of AII was lost, but the response to norepinephrine was sustained. At 30 minutes the response to norepinephrine was also reduced, and there was no response in three of the eight dogs. After stopping the AII infusion, renal vascular responsiveness to norepinephrine returned almost immediately, but 30-60 minutes were required before responsiveness to AII was restored. We conclude that there is true, specific renal vascular tachyphylaxis to AII--which may well reflect receptor modulation or occupation--and that with time an additional, non-specific vasodilator mechanism can come into play.

Angiotensin increases Na+ entry and Na+/K+ pump activity in cultures of smooth muscle from rat aorta

Angiotensin markedly altered the Na+ permeability of smooth muscle cells cultured from explants of rat aorta. The rate of net Na+ uptake was followed in the presence of ouabain in order to block Na+ efflux via the Na+/K+ pump. Angiotensin II (AII) or angiotensin III (AIII) increased net Na+ uptake by about 3-fold. Maximal stimulation of Na+ uptake was produced by about 10 nM AII. Bradykinin and the angiotensin antagonist [Sar1, Ileu5, Ala8]AII had no significant effect on net Na+ uptake. Angiotensin also enhanced the activity of the Na+/K+ pump, which was assayed by following the rate of ouabain-sensitive 86Rb+ uptake by the cells. AII and AIII nearly doubled ouabain-sensitive 86Rb+ uptake, but bradykinin, norepinephrine, and [Sar1, Ileu5, Ala8]AII had no effect. In the presence of ouabain, 86Rb+ uptake was not significantly affected by AII or AIII, indicating that angiotensin did not alter passive permeability to Rb+. Loading the cells with Na+, either by incubation in K+-free medium or exposure to the Na+-selective ionophore monensin, markedly increased ouabain-sensitive 86RB+ uptake. This result indicates that the activity of the Na+/K+ pump is limited by the low level of Na+ that is normally in the cells. AII had no effect on the activity of the Na+/K+ pump in Na+-loaded cells. These results suggest that AII or AIII stimulates the Na+/K+ pump in cultured aortic muscle cells by increasing its Na+ supply.

Angiotensin I, II, and II tachyphylaxis in the mesenteric vascular circuit of the rat

Angiotensin tachyphylaxis is rapidly induced in the mesenteric vascular circuit of the rat perfused with a saline solution. there is crossed tachyphylaxis among angiotensins (AI, AII, and AIII). The angiotensin antagonist Sar 1-Ileu 8-AII is ineffective when the vascular preparation is previously rendered tachyphylactic to AII, showing that the AII receptors are not available during tachyphylaxis. This finding supports the theory that angiotensin tachyphylaxis is caused by receptor occupancy by the agonist. By perfusing the vascular preparation with aII solutions that were too diluted to produce vasoconstriction, tachyphylaxis to AII was induced. Therefore, AII receptors can be slowly saturated without producing vasoconstriction. The recoveries of the vasoconstrictor effect of AII and AIII at 30 and 60 minutes after tachyphylaxis are similar; thus, the dissociation constants of the AII- and AIII-receptor complexes should be alike. After three bolus injections of AI, the vascular preparation is completely refractory to AI, AII, and AIII. When the conversion of AI to AII is inhibited with captopril, AI no longer induces tachyphylaxis to AII and AIII. Thus, tachyphylaxis to AII and AIII induced by AI seems to be due not to the occupancy of AII receptors by AI but to the AII formation from AI "in situ."

Synthesis and pharmacology of a noncompetitive antagonist of angiotensin-induced contractions of vascular smooth muscle. [Sarcosyl]1-[cysteinyl (s-methyl)]8-angiotensin II

The synthesis of an angiotensin II (A II) antagonist, sarcosyl1-cysteinyl(S-methyl)8-angiotensin II [Sar1-Cys(Me)8-A II], showing partial organ selectivity and properties of a noncompetitive antagonist, is described. The compound was found to be an extremely potent antagonist on vascular smooth muscle both in vitro (pA2 for rabbit aorta approximately equal to 9.2) and in vivo on rat blood pressure (dose ratio of 103 for ED25 mm Hg during 1 microgram/kg per min infusion of antagonist). It was without effect on norepinephrine responses in both assay systems. In contrast, it was a considerably weaker antagonist on visceral smooth muscle (pA2 for guinea pig ileum = 8.5; pA2 for rat uterus = 7.9). Interestingly, in the vascular smooth muscle preparations, the compound also exhibited elements of a noncompetitive antagonist in that both the slope and maximum of the A II dose-response curves were reduced markedly. Qualitatively similar results were obtained with sarcosyl1-alanyl8-angiotensin II (Saralasin) on rabbit aorta. Moderate depression of maximum response was seen in guinea pig ileum but not in rat uterus. These effects on vascular smooth muscle were reversible in vitro but only partially reversible in vivo.

Effects of angiotensin II and 1-sar., 8-isoleu. angiotensin II on electrical and mechanical properties of the portal vein from rats of different ages

The effects of angiotensin II (Ag-11) and 1-sar., 8-isoleu. angiotensin 11 (anti-Ag-11) on the membrane and mechanical properties of smooth muscle cells of the rat portal vein were investigated in three different age groups (6--8 weeks, immature rat; 3--5 months old, young rat and 13--15 months old, adult rat). Application of Ag-11 (10(-10) g/ml) did not depolarize the membrane, but did increase the spike frequency and potentiated the frequency and amplitude of twitch contraction. In a concentration of more than 10(-9) g/ml Ag-II, the membrane was depolarized and a phasic contracture was developed in three age groups. Depolarization of the membrane produced by Ag-II could be classified into two components, i.e. phasic and tonic depolarizations. In adult rats, Ag-II produced the highest amplitude of the depolarization in three age groups but tonic depolarization showed nearly the same amplitude of smooth muscle cell membrane to Ag-II increases with age up to 3--5 months and that an increased sensitivity is accompanied by a generation of desensitization. Tachyphylaxis to Ag-II was also observed by repetitive applications, but the appearance depended on the stimulus conditions. Anti-Ag-II, itself slightly increased the spike frequency and the amplitude of twitch contraction. However, under pretreatment with anti-Ag-II (10(-9) or 10(-7) g/ml), the actions of Ag-II on the electrical and mechanical activities were markedly suppressed in the three age groups. When the dose-response curve was obtained from the mechanical response produced by Ag-II, the relation shifted to the right in the presence of anti-Ag-II in all age groups. In the presence of 10(-7) g/ml anti-Ag-II, no contracture was evoked by application of 10(-6) g/ml Ag-II in three age groups. Anti-Ag-II seems to possess a higher affinity to the angiotensin receptor than does Ag-II.

Angiotensin-induced steroidogenesis in rabbit adrenal: effects of pH and calcium

The effect of variations in pH and Ca2+ on angiotensin II (A-II)-induced steroidogenesis was tested on isolated adrenal glomerulosa cell suspensions. The results show that a reduction in pH from 7.4 to 6.5 produces both a shift to the left of the A-II dose-response curve as well as an increase in maximum steroid production. In contrast, removal of Ca2+ from the incubation medium virtually abolished steroidogenesis to A-II (5 X 10(-9)M(, KCl(10mM) and ACTH (250 microU/ml). The Ca2+ antagonist D-600, however, was less effective than simple removal of Ca2+ as 10(-4) M was required to block the steroidogenic response to these same agonists. The results indicate that the response characteristics of this system to A-II resemble most closely those seen with isolated arterial smooth muscle - especially rabbit aortic strips.

Change of the activities of angiotensins I and II on the vascular smooth muscle by crude kallikrein

Incubation in vitro of angiotensin I (A I) with crude kallikrein induced a potentiation in the response to decapeptide of the isolated continuously superfused rabbit aorta. Crude kallikrein when incubated with angiotensin II (A II) caused a decrease in response to octapeptide of the same assay tissue. Converting enzyme inhibitor, SQ 20881, produced a competitive inhibition in the response to A I preincubated with crude kallikrein but did not alter the inhibitory effect of the enzyme on A II response. Pure kallikrein did not induce any change in the responses to both peptides when used at the same concentrations. The competitive inhibitor of A II (N,N-dimethyl) Gly1-Ile5-Ile8-angiotensin II (DMGIA II), abolished the effects of both A II- and A I-preincubated with crude kallikrein. From these results it was concluded that crude kallikrein-induced potentiation in the response to A I of the aorta is probably due to the conversion of decapeptide to octapeptide by an enzyme fraction in crude kallikrein preparation. These results also indicate that crude kallikrein (Padutin) is not a pure enzyme preparation and probably contains some other enzyme fractions which are responsible from the changes of the vascular activities of angiotensin-peptides.

Role of prostaglandins in the mediation of systemic tachyphylaxis to angiotensin II

Angiotensin-induced prostaglandin release has been implicated in the deveolpment of tachyphylaxis to angiotensin in vitro. Based on these findings and evidence that prostaglandins modulate the angiotensin reposne locally, experiments were done to investigate the role of prostaglandins in the systemic tachyphylaxis to angiotensin. Rats were given intravenous infusions of 1-asparaginyl-5-valyl and 1-aspartyl-5-isoleucyl andiotensin II at two different doses. Using systemic blood pressure as a parameter, varying degrees of tachyphylaxis were produced and the aspartyl analog was found to be more tachyphylactic. When rats were given indomethacin, a prostaglading synthesis inhibitors, the response to intravenous infusion of aspartyl angiotensin was not significantly altered.

Potentiation by crude kallikrein of the myotropic effect of angiotensin I in the isolated rabbit aortic strip

Crude kallikrein (Padutin), but not pure kallikrein, when preincubated with angiotensin I caused a potentiation of the myotropic effect of decapeptide on the isolated continuously superfused rabbit aortic strip. Addition of converting enzyme inhibitor, SQ 20881, to the medium inhibited this potentiation. The potentiation by crude kallikrein of the myotropic effect of angiotensin I is probably due to the conversion of decapeptide to octapeptide angiotensin II. This study indicates that Padutin is not a pure kallikrein preparation and probably contains a kininase fraction which causes the conversion of angiotensin I.

The effects of intraportal injections of noradrenaline, adrenaline, vasopressin and angiotensin on the hepatic portal vascular bed of the dog: marked tachyphylaxis to angiotensin

1 The hepatic portal vein of the anesthetized dog was cannulated and perfused with blood derived from the cannulated superior mesenteric vein. 2 The portal vein was perfused at constant flow, the hepatic portal venous pressure being monitored continuously together with the inferior vena caval pressure. From these measurements, the hepatic portal venous vascular resistance was calculated. 3 Noradrenaline and adrenaline were injected intraportally in graded doses which caused dose-dependent increases in the hepatic portal vascular resistance. At all doses, adrenaline was significantly (P less than 0.05) more potent than noradrenaline. 4 Intraportal injections of vasopressin caused reductions in calculated hepatic portal venous vascular resistance in most experiments; three effects were dose-dependent. 5 No tachyphylaxis to the effects of noradrenaline, adrenaline or vasopressin was observed. 6 Intraportal injections of angiotensin caused dose-dependent increases in calculated hepatic portal vascular resistance up to 5 mug; therafter larger doses caused smaller increases in portal resistance. 7. Repeated intraportal injections of angiotensin revealed the existence of tachyphylaxis in the hapatic portal vascular bed. 8 Intraportal infusions of anagiotensin caused rises in calculated hepatic portal vascular resistance from which there was almost complete 'escape' despite the continued infusions. Infusions of noradrenaline which caused similar rises in calculated portal vascular resistance did not exhibit equivalent degrees of 'escape'. 9 The development of tachyphylaxisx explains the fact that doses of 10 and 20 mug of angiotensin injected after 5 mug doses produced smaller effects. If a much longer time interval was allowed between injections (30 min), the dose-response curve to angiotensin had a sigmoid shape. 10 These findings are discussed with respect to their possible importance in the functional status of the hepatic portal vascular bed in this species.