angiotensin-i and perindoprilat

We used mass spectrometry to quantitate production of angiotensinogen metabolites in renal artery of 3- and 7-month-old Wistar-Kyoto (WKY) and Spontaneously Hypertensive Rats (SHR). Tissue fragments were incubated for 15 min in oxygenated buffer, with added angiotensin I. Concentrations of angiotensins I (ANG I), II (ANG II), III (ANG III), IV (ANG IV), angiotensin (1-9) [ANG (1-9)], angiotensin (1-7) [ANG (1-7)], and angiotensin (1-5) [ANG (1-5)], excreted into the buffer during experiment, were measured using liquid chromatography-mass spectrometry (LC/MS) and expressed per mg of dry tissue. Effects of pretreatment with 10 microM perindoprilat on the production of ANG I metabolites were quantitated. Background production of any of ANG I metabolites differed neither between WKY and SHR rats nor between 3- and 7-month-old rats. Perindoprilat pretreatment of renal arteries resulted, as expected, in decrease of ANG II production. However, renal arteries of 7-month-old SHR rats were resistant to ACE inhibitor and did not change ANG II production in response to perindoprilat. In renal arteries, taken from 3-month-old rats, pretreated with perindoprilat, incubation with ANG I, resulted in the level of ANG (1-9) significantly higher in SHR than WKY rats. Our conclusion is that in SHR rats, sensitivity of renal artery ACE to perindoprilat inhibition changes with age.

Topics: Aging; Angiotensin I; Animals; Hypertension; In Vitro Techniques; Indoles; Male; Peptide Fragments; Rats, Inbred SHR; Rats, Inbred WKY; Renal Artery

Our view of renin-angiotensin system (RAS) has changed over the past two decades: new metabolites and pathways have been described; also the importance of local renin-angiotensin systems became more clearly understood. However, there is relatively scarce information about formation and action of angiotensin peptides in gastrointestinal tract, especially in the stomach. Here, using LC-ESI-MS method we assessed the metabolism of Ang I in organ bath of rat stomach wall. Additionally we compared the expression of mRNA of angiotensin converting enzymes (ACE, ACE2) and neprilysin (NEP) in the stomach, aorta and renal artery in rats. Despite, similar levels of expression of ACE and ACE2 mRNA in stomach wall, aorta and renal artery, the absolute amounts of main Ang I metabolites produced by stomach wall (in ng/mg of dry tissue) were much lower than that produced by aorta and renal artery. Also, the pattern of angiotensin I metabolites was different: opposite to aorta and renal artery, incubation of Ang I with stomach wall fragments resulted in predominant formation of Ang-(1-7) and relatively lower production of Ang II. In stomach wall both, perindoprilat and tiorphan decreased production of Ang II, but did not influence generation of Ang-(1-7). In conclusion, we identified Ang-(1-7) as the main product of Ang I conversion in rat stomach wall. The biological role of prevalence of Ang-(1-7) formation in stomach require further investigation.

Topics: Angiotensin I; Angiotensin-Converting Enzyme 2; Angiotensin-Converting Enzyme Inhibitors; Animals; Aorta; Chromatography, Liquid; Gastric Mucosa; Gene Expression Regulation; Indoles; Male; Neprilysin; Peptide Fragments; Peptidyl-Dipeptidase A; Rats; Rats, Inbred WKY; Renal Artery; Renin-Angiotensin System; RNA, Messenger; Spectrometry, Mass, Electrospray Ionization; Thiorphan

To determine the short-term effects of angiotensin-converting enzyme (ACE) inhibition on hemodynamics and circulating levels of norepinephrine, angiotensin, and bradykinin, responses to enalaprilat and perindoprilat were examined at doses of 0.03, 0.3, and 1 mg/kg in permanently instrumented conscious dogs with pacing-induced heart failure (right ventricular pacing, 240-250 beats/min, 3 weeks). All doses of the two inhibitors produced similar decrease in mean aortic pressure and increase in cardiac output. Neither inhibitor affected plasma norepinephrine level. Both compounds induced a similar 60-80% decrease in blood angiotensin II level, a similar two- to eightfold increase in blood angiotensin I level, and a 80-95% decrease in the angiotensin II/angiotensin I ratio. There were also a fourfold to 10-fold increase in blood bradykinin-(1-9) level, a twofold increase in blood bradykinin-(1-7) level, and a 70-85% decrease in bradykinin-(1-7)/bradykinin-(1-9) ratio. In addition, the changes in total peripheral resistance induced by the two ACE inhibitors were weakly but significantly correlated with the changes in blood angiotensin II or blood bradykinin-(1-9). Thus whatever the specificity of enalaprilat and perindoprilat, both inhibitors produced similar acute hemodynamic effects in dogs with heart failure, which was associated with marked decrease in circulating angiotensin II level and increase in bradykinin-(1-9) level. This study, which measures for the first time in heart failure the blood bradykinin level after ACE inhibitors, indicates, in concert with angiotensin II reduction, a role for increased bradykinin-(1-9) level in mediating short-term hemodynamic effects of ACE inhibition in this model of heart failure.

Topics: Angiotensin I; Angiotensin II; Angiotensin-Converting Enzyme Inhibitors; Animals; Blood Pressure; Bradykinin; Cardiac Output; Cardiac Pacing, Artificial; Disease Models, Animal; Dogs; Enalaprilat; Heart Failure; Indoles; Norepinephrine; Peptide Fragments; Ventricular Function, Left

1. The pharmacokinetics of perindopril and perindoprilat and the hormonal and haemodynamic responses following a single oral dose were studied in 12 Chinese and 10 Caucasian healthy, normotensive volunteers on two occasions. Perindopril was given on the first occasion as a 4 mg dose and then after at least 10 days as a weight-adjusted dose of 4 mg/70 kg. Plasma was sampled for assay of perindopril, perindoprilat, plasma renin activity (PRA), aldosterone, angiotensin I (AI) and ACE activity. Urine was collected for perindopril and perindoprilat assay. A radioimmunoassay technique was used to measure the prodrug and its active metabolite. 2. The time to maximum concentration (tmax) for perindopril was shorter for the Chinese group after the 4 mg dose (median 0.5, range 0.5-1.5 h vs median 1.0, 0.5-1.5 h P < 0.05) and also tended to be shorter after the weight-adjusted dose (median 0.5, range 0.5-1.0 h vs median 1.0, range 0.5-3.0 h). Cmax and AUC tended to be higher after the 4 mg dose in the Chinese group who had a lower body weight than the Caucasians. 3. The tmax of perindoprilat tended to be shorter for both doses and there was a tendency towards a higher Cmax after the 4 mg dose in the Chinese group but there was no statistically significant difference between the two groups. 4. There were no differences in the levels of PRA, plasma AI, plasma aldosterone or the degree of ACE-inhibition for either dose in the two ethnic groups. 5. Blood pressure was measured at intervals up to 24 h post-dose in both the supine and standing positions. Perindopril reduced blood pressure acutely with respect to the pre-dose level with good tolerability in both groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Administration, Oral; Aldosterone; Analysis of Variance; Angiotensin I; Angiotensin-Converting Enzyme Inhibitors; Asian People; Blood Pressure; Blood Proteins; Female; Heart Rate; Humans; Indoles; Male; Peptidyl-Dipeptidase A; Perindopril; Protein Binding; Renin; White People

The aims were: (1) to study the acute effects of captopril on the action potential characteristics of ventricular fibres from the normal rat, (2) to compare the effects of captopril with those of perindoprilat, a non-thiol angiotensin I converting enzyme (ACE) inhibitor, (3) to determine the electrophysiological properties of the peptide substrates of converting enzyme, bradykinin and angiotensin I, and (4) to investigate whether the effects of captopril occurring in the healthy heart also occur in two models of ventricular hypertrophy.. Action potentials were recorded with the standard glass microelectrode technique in right ventricular preparations excised from rat hearts and superfused under baseline conditions and with drug containing or peptide containing Tyrode solution. Ventricular hypertrophy was induced in response to hypertension (unilaterally nephrectomised, DOCA-salt model) or 4 week old left ventricular infarction.. In preparations from normal rat hearts, captopril increased action potential duration in a concentration dependent fashion [EC50 = 3.5 x 10(-8) M; maximum effect = 44(SEM 5.1)% prolongation at 10(-5) M for action potential duration at 90% repolarisation, APD90]. Perindoprilat similarly caused a dose dependent increase in action potential duration, but with 100 times greater potency [EC50 = 3.1 x 10(-10) M; maximum effect = 71(11)% prolongation at 10(-5) M for APD90]. SQ 14,534, a stereoisomer of captopril with one hundredth the ACE inhibitor potency, had no significant effect on action potential duration at 10(-5) M. Angiotensin I and bradykinin caused concentration dependent prolongation of action potential, but angiotensin II (10(-6) M) had no effect. Captopril (10(-5) M) had no significant effect in the hypertrophied right ventricle from DOCA-salt hypertensive rats, but significantly increased APD90 [39(4.9)%] in right ventricular preparations from rats with 4 week old anterior left ventricular infarction.. In the rat, captopril prolongs action potential duration, an effect possibly due to local accumulation of bradykinin and angiotensin I.

Topics: Action Potentials; Angiotensin I; Angiotensin-Converting Enzyme Inhibitors; Animals; Bradykinin; Captopril; Cardiomegaly; Dose-Response Relationship, Drug; Heart; Hypertension; Indoles; Myocardial Infarction; Rats; Rats, Sprague-Dawley; Rats, Wistar

Perindopril, a powerful ACE inhibitor contains 5 chiral carbons, thus there is the possibility of 2(5) = 32 stereoisomers for the general structure 1. These 32 stereoisomers were synthesized by cross-coupling the 8 stereoisomers of perhydroindole 2-carboxylic acid benzylester with the 4 stereoisomers of 2-(1-carbethoxybutylamino) propionic acid 4, then hydrogenating the resulting benzylesters. Each stereoisomer of perindopril furnished by saponification the corresponding diacid stereoisomer 2 of perindoprilate which is the active form of perindopril. For each of the 32 stereoisomers 2 the in vitro ACE inhibitory potency (IC50) was determined. Four of them, including perindoprilate, had activities in the nanomolar range, and four more were ca. 10 x less active. The four acid esters 1 corresponding respectively to the four most active diacids 2 in vitro were studied (1 mg/kg via the oral route) for their in vivo activity in dogs. It could be concluded that p.o. absorption of the active acid esters 1 and their activation to the active diacid 2 depended only on the chiralities of the two ring junction carbons of the perhydroindole ring.

Topics: Administration, Oral; Angiotensin I; Angiotensin-Converting Enzyme Inhibitors; Animals; Dogs; In Vitro Techniques; Indoles; Injections, Intravenous; Magnetic Resonance Spectroscopy; Mass Spectrometry; Perindopril; Stereoisomerism; Substrate Specificity

The pattern of inhibition of tissue angiotensin converting enzyme (ACE) was studied in rats after acute and chronic (14 days) oral administration of perindopril. Free and total tissue ACE were measured by quantitative in vitro autoradiography using [125I]-351A as a radioligand and compared with plasma ACE and pressor responses to angiotensin I. Following oral perindopril, plasma perindoprilic acid and the pattern of inhibition of plasma ACE activity were maximal at 1 to 2 h, but recovered over 24 h. However, inhibition of the pressor response to angiotensin I was more prolonged, being 95% at 4 h, but had not fully recovered by 24 h. Acutely, ACE was markedly inhibited in renal proximal tubules, lung parenchyma, and aortic wall. At 24 h, ACE in these tissues had only partially recovered. Angiotensin converting enzyme in vascular endothelium of other organs showed a similar pattern of inhibition. In contrast, ACE in testicular seminiferous tubules was unaffected by perindopril. After chronic (14 days) administration of perindopril, total plasma ACE increased 3-fold, of which 49% was occupied by the inhibitor. Total tissue ACE in kidney and aorta did not change, and the pattern of inhibition observed acutely was maintained during chronic treatment. These results demonstrate a prolonged effect of ACE inhibitors on tissue ACE that may better explain the time course of these drugs than the changes in plasma ACE or plasma levels of the drugs.

Topics: Angiotensin I; Angiotensin-Converting Enzyme Inhibitors; Animals; Blood Pressure; Indoles; Male; Peptidyl-Dipeptidase A; Perindopril; Rats; Rats, Inbred Strains; Tissue Distribution