Synthesis and biological activity of modified peptide inhibitors of angiotensin-converting enzyme.

A series of non-sulfhydryl modified dipeptides related to CI-906, CI-907, and enalapril was prepared in which various isosteric moieties (O, S, SO, SO2) have been substituted for the amino group and in which the proline residue has been replaced with various hydrophobic amino acids. The compounds were evaluated in vitro for inhibition of angiotensin-converting enzyme and in vivo for antihypertensive activity. Compound 7c, the most potent member of this series, had an in vitro IC50 of 1.4 X 10(-8) M and showed modest oral antihypertensive activity at 30 mg/kg in conscious, two kidney, one clip Goldblatt hypertensive rats. Structure-activity relationships are discussed.

Angiotensin converting enzyme inhibitors: modifications of a tripeptide analogue.

Modified nonhydrolyzable tripeptide analogues of (S)-1-[5-(benzoylamino)-1,4-dioxo-6-phenylhexyl]-L-proline (1), designed to impart oral angiotensin converting enzyme (ACE) inhibitory activity, were made and evaluated in vivo and in vitro. The N-methyl and C5-methyl analogues of 1 were inactive. Insertion of heteroatoms (O, S, NH) into the C--C chain of 1 gave a series of compounds with high in vitro activity in the guinea pig serum ACE assay. The O-analogue was the most potent with an IC50 = 4.4 x 10(-9) M compared to 1 with an IC50 = 3.2 x 10(-9) M. The structure-activity relationships in this series of compounds lead one to speculate that the heteroatom provides an additional binding site to the surface of the enzyme; however, these compounds were inactive when tested for antihypertensive activity in the renal hypertensive rat at 30 mg/kg by the oral route (captopril is active at 1.0 mg/kg po).

Derivatives of the potent angiotensin converting enzyme inhibitor 5(S)-benzamido-4-oxo-6-phenylhexanoyl-L-proline: effect of changes at positions 2 and 5 of the hexanoic acid portion.

Several derivatives of the potent angiotensin converting enzyme inhibitor 5(S)-benzamido-4-oxo-6-phenylhexanoyl-L-proline (1) were synthesized and tested for converting enzyme inhibition activity and blood pressure lowering effects in rats. One compound, 5(S)-benzamido-2(R)-methyl-4-oxo-6-phenylhexanoyl-L-proline (2a), had and I50 against angiotensin converting enzyme of 1.0 x 10(-9) M and is the most potent inhibitor prepared thus far in this class of compounds. Testing of 2a orally at 30 mg/kg for inhibition of the angiotensin I induced blood pressure increase in conscious normotensive rats gave 100% inhibition that required 143 min before the angiotensin I blood pressure response returned to 70% of the pretreatment control response. In the conscious renal hypertensive rat, 2a given orally at a dose of 3 mg/kg caused a lowering of blood pressure that reached its maximum of 40 mmHg 8 h following drug administration.

Antihypertensive activity of 6-arylpyrido[2,3-d]pyrimidin-7-amine derivatives. 2. 7-Acyl amide analogues.

The effect of acylation with a variety of acids on the antihypertensive activity of 6-(2,6-dichlorophenyl)pyrido[2,3-d]pyrimidine-7-amine (1) is reported, and structure-activity relationships are discussed. Although several of the compounds show good oral antihypertensive activity in the conscious, spontaneously hypertensive rat (SHR), their activity profile appears to differ from 1 in that the onset of action is shortened at comparable blood pressure lowering doses, and the magnitude of effect is considerably greater at higher doses. A variety of urea, thiourea, guanidine, and amidine analogues also were prepared. Although many of these derivatives showed some antihypertensive effects when dosed orally to SHR, this activity was weaker and of shorter duration than that obtained with 1. Aqueous solubilities and hydrolytic stabilities for four of the more active compounds were measured and suggest that these do not function as prodrugs of 1.

Synthesis and angiotensin-converting enzyme inhibitory activity of 3-(Mercaptomethyl)-2-oxo-1-pyrrolidineacetic acids and 3-(Mercaptomethyl)-2-oxo-1-piperidineacetic acids.

A number of gamma- and delta-lactam derivatives were synthesized and their in vitro angiotensin-converting enzyme (ACE) inhibitory activities were compared. The structures of these compounds were designed to include many of the important features of captopril. The synthesis involved the preparation of a variety of novel 3-methylene-2-pyrrolidinones (3-5 and 16) and 3-methylene-2-piperidinones (3a-5a, 10-12, and 17). The key intermediate 3-methylenelactams 3 and 3a were obtained from 3-(hydroxymethyl)lactams 2 and 2a by a direct dehydration with dicyclohexylcarbodiimide using cuprous iodide as a catalyst. Introduction of the sulfhydryl group was accomplished by a Michael addition of these alpha, beta-unsaturated lactams. The compound with the highest in vitro activity was 3-(mercaptomethyl)-2-oxo-1-piperidineacetic acid (7a). The activity of the 7a both in vitro and in vivo (dog) was shown to be less than that of captopril by a factor of about 100.

Novel synthesis of (S)-1-[5-(benzoylamino)-1,4-dioxo-6-phenylhexyl]-L-proline and analogues: potent angiotensin converting enzyme inhibitors.

A new approach was developed for the synthesis of (S)-1-[5-(benzoylamino)-1,4-dioxo-6-phenylhexyl]-L-proline (1) and 23 analogues. The delta-(acylamino)-gamma-keto acid intermediates were obtained by a modified Dakin--West reaction using 3-carbomethoxypropionyl chloride. Acylation of L-proline and recrystallization of the mixture of diastereomers gave the optically pure title compound in three reaction steps. The in vitro angiotensin converting enzyme (ACE) inhibitory activity of 1 was confirmed. Some of the novel analogues (6, 11, 13, and 17) were also found to be potent inhibitors of ACE in vitro with an IC50 of 1.4-8.8 x 10(-9) M (IC50 for captopril = 0.9 x 10(-8) M). In vivo these compounds (6, 11, 17, and 18) were much less active than captopril, especially by the oral route. Against angiotensin I (AI) challenge in normotensive conscious rats, 1 and 6 produced less than 50% inhibition at 30 mg/kg po but 57 to 82% inhibition at 3 mg/kg iv. Inhibition by both routes lasted less than 1 h. In renal hypertensive rats, 1 and 15 of its analogues failed to produce significant blood pressure lowering effects, in contrast to the marked effects of captopril. Near maximum inhibition of AI was achieved by continuous intravenous infusions of 1 and 20, suggesting that limited oral activity may by due to degradation and/or clearance.

Pharmacology of bevantolol hydrochloride.

Bevantolol is a cardioselective, beta-adrenoreceptor antagonist, devoid of intrinsic beta sympathomimetic activity and with weak membrane-stabilizing and local anesthetic properties. The 3,4-dimethoxyphenylethylamino moiety, substituted on the side chain amine function, confers cardioselectivity, which has been confirmed by a number of experiments. In vitro, bevantolol demonstrated greater antagonism of atrial than tracheal responses to isoproterenol. In vivo, bevantolol preferentially inhibited isoproterenol-induced tachycardias in conscious and anesthetized dogs, compared with the nonselective agent propranolol. Conversely, its effect on blood pressure after isoproterenol was minimal compared with propranolol, reflecting its muted effect on beta 2 peripheral receptors. A functional difference between bevantolol and propranolol was demonstrated in histamine-challenged guinea pigs. Bevantolol had little effect on the antiasthmatic effect of isoproterenol, whereas propranolol blocked it totally. Bevantolol's lack of intrinsic sympathomimetic activity was demonstrated in normal and reserpinized dogs, where it was devoid of intrinsic sympathomimetic activity at doses up to 10 mg/kg. Similarly, intravenous doses of 10 mg/kg had to be administered before direct myocardial depression occurred in the reserpinized animals. Metabolite 3, which is excreted in trace amounts in human urine, demonstrates intrinsic sympathomimetic activity when administered in pharmacologic doses to dogs; however, any clinical relevance remains to be established. Several laboratories have demonstrated that bevantolol interacts at alpha-adrenergic sites. These data require further investigation. The dose-related antihypertensive effect of bevantolol has been demonstrated in spontaneously hypertensive and 2 kidney, 1 clip renal hypertensive rats. Animal experiments also suggest that bevantolol may be useful in angina: It caused a favorable redistribution of blood flow in dogs in which the left circumflex artery had been stenosed.(ABSTRACT TRUNCATED AT 250 WORDS)

Preclinical pharmacology of pirmenol.

Pirmenol, a novel pyridinemethanol derivative, is active in a variety of experimental arrhythmic models of diverse etiology and has a favorable therapeutic index compared with other class I agents. Animal pharmacology studies showed that pirmenol is highly efficacious whether the arrhythmias were atrial or ventricular in origin, chemically, mechanically or electrically induced or of the automaticity or reentrant types. The conscious coronary artery-ligated (Harris) dog model best allowed simulation of a variety of clinical situations in which pirmenol could be used either alone or in combination. Pirmenol was highly effective by both the intravenous and oral routes, causing immediate suppression, prevention or termination of cardiac arrhythmias. Preclinical studies in the dog showed an excellent correlation between the dose of pirmenol, plasma levels and antiarrhythmic efficacy. Administration of pirmenol in the dog at intentionally accelerated infusion rates suggested a relatively wide margin of safety for pirmenol compared with other class I agents. Analysis of the pharmacokinetic data led to the modeling of a rapid infusion-slow infusion bolus for sustained intravenous administration, thereby optimizing therapeutic utility. In vitro electrophysiologic studies in dog Purkinje fibers revealed possibly unique differences of pirmenol from other antiarrhythmic agents. It depresses fast and slow response automaticity and its electrophysiologic effects were less variable than other class I drugs over a spectrum of potassium levels. To test the relevance of the in vitro electrophysiologic results, pirmenol's antiarrhythmic efficacy was assessed in several in vivo dog models in which serum potassium was either increased or decreased.(ABSTRACT TRUNCATED AT 250 WORDS)

l-Bunolol and propranolol: oral and intravenous beta-adrenoceptor blocking activity in rats compared to dogs and humans.

To determine the pharmacological significance of reported differences between species in l-bunolol metabolism, oral and intravenous beta-adrenoceptor blocking activity against an isoproterenol-induced tachycardia was compared in dogs, rats, and humans. Propranolol was similarly studied in rats and dogs. Species differences in intravenous potency were minimal for both compounds in contrast to oral dose studies. Oral to intravenous ratios of doses causing a comparable degree of beta-adrenoceptor blockade after l-bunolol were: rat, 212; dog 4; and human, 5. For propranolol, the oral to intravenous dose ratios were 210 and 32 for the rat and dog, respectively. These pharmacological findings show major differences in the rat compared to dogs and humans and may be explained in part by differences in the urinary excretion patterns of l-bunolol in the various species.

Quinapril: overview of preclinical data.

Quinapril hydrochloride, a new, orally active, nonpeptide, nonsulfhydryl angiotensin-converting enzyme (ACE) inhibitor, has been studied extensively in a variety of in vitro and in vivo animal models. Quinapril inhibits the contractile and pressor effects of angiotensin I in rabbit aorta and in rats, respectively, and lowers blood pressure in both high- and normal-renin rodent and diuretic-treated dog models of hypertension. No tolerance to the antihypertensive effects of quinapril was noted in spontaneously hypertensive rats treated with quinapril for up to 14 consecutive days. As with other ACE inhibitors, quinapril had virtually no effect on the development of hypertension in the renin-independent one-kidney deoxycorticosterone (DOCA)-salt hypertensive rat. Antihypertensive activity best correlates with the inhibition of tissue (vascular) ACE, and thus the reduction in peripheral vascular resistance associated with plasma and tissue ACE most likely accounts for the therapeutic benefit of quinapril. Preliminary data from a trial of quinapril in cardiomyopathic hamsters show that the drug prevents the anticipated decline in left ventricular contractile function and retards the temporal progression of left ventricular failure. ACE inhibitors have been found to have a lipid-neutral profile, unlike some other classes of antihypertensives. Quinapril is rapidly absorbed and extensively distributed to all tissues except brain. It is rapidly hydrolyzed to quinaprilat, its pharmacologically active diacid form. Metabolism to other compounds is not extensive. Quinapril's preclinical toxicologic profile is similar to that of other ACE inhibitors. Long-term toxicology studies show that quinapril is not teratogenic, carcinogenic, or mutagenic.

Bevantolol hydrochloride--preclinical pharmacologic profile.

Bevantolol hydrochloride, a beta adrenoceptor antagonist, can be categorized using conventional schemes as being cardioselective, devoid of intrinsic sympathomimetic activity and having weak membrane-stabilizing and local anesthetic properties. The cardioselectivity of bevantolol was conferred by the incorporation of a 3,4-dimethoxyphenyl moiety into the terminal amino portion of the molecule. This portion of the molecule also appears to account for bevantolol's in vitro binding affinity at alpha-adrenoceptor sites; the in vivo significance of which remains unclear. In the various cardiovascular disease-state models, bevantolol's profile differed from that of propranolol, i.e., there was no initial pressor response in spontaneously hypertensive or renal hypertensive rats. In a myocardial ischemia model, bevantolol, unlike propranolol, increased contractile function in the ischemic myocardium. A ring hydroxylated urinary metabolite, which occurred only in trace amounts in human urine, had an interesting profile when studied in animals at pharmacologic doses. It ranked high in cardioselectivity (like bevantolol), but unlike bevantolol showed significant intrinsic beta sympathomimetic activity. The clinical significance of this metabolite, if any, remains to be established. Collectively the preclinical profile of bevantolol showed it to have an interesting profile for a beta adrenoceptor antagonist in a variety of pharmacologic test systems.

Pirmenol: preclinical pharmacology.

Pirmenol, a novel pyridinemethanol derivative, is active in a variety of experimental arrhythmic models of diverse etiology. Animal pharmacology studies showed that pirmenol is highly efficacious whether the arrhythmias were atrial or ventricular in origin; chemically, mechanically, or electrically induced; or of the automaticity or reentrant types. The conscious coronary artery-ligated (Harris) dog model best allowed simulation of a variety of clinical situations in which pirmenol could be used either alone or in combination. Pirmenol was highly effective by both the intravenous and oral routes, causing immediate suppression, prevention, or termination of cardiac arrhythmias. Preclinical studies in the dog showed an excellent correlation between the dose of pirmenol, plasma levels, and antiarrhythmic efficacy. Administration of pirmenol in the dog at intentionally accelerated infusion rates suggested a relatively wide margin of safety for pirmenol compared with other class I agents. In vitro electrophysiologic studies in dog Purkinje fibers revealed possibly unique differences of pirmenol from other antiarrhythmic agents. It depresses fast and slow response automaticity and its electrophysiologic effects were less variable than other class I drugs over a spectrum of potassium levels. To test the relevance of the in vitro electrophysiologic results, pirmenol's antiarrhythmic efficacy was assessed in several in vivo dog models in which serum potassium was either increased or decreased. Studies comparing pirmenol and disopyramide clearly showed a relative lack of serum potassium dependence for pirmenol, suggesting a potential clinical advantage over disopyramide and other antiarrhythmics in variable potassium settings. The clinical relevance of these observations will have to be established in patients with variable potassium levels. Overall, pirmenol compared favorably with other reference agents in efficacy and safety in extensive preclinical investigations.

Quinapril--a preclinical review of the pharmacology, pharmacokinetics, and toxicology.

Quinapril is an orally active, non-peptide, nonsulfhydryl angiotensin-converting enzyme (ACE) inhibitor that acts potently and specifically to interrupt the conversion of angiotensin I to angiotensin II in both plasma and tissue. Quinapril is enzymatically hydrolyzed to a pharmacologically active diacid form quinaprilat. Quinapril is efficacious in hypertensive models exhibiting both high (renal hypertensive rats, diuretic-treated dogs) and normal (spontaneously hypertensive rats) plasma renin activity. Quinapril does not prevent the development of hypertension when plasma renin activity (PRA) is markedly suppressed as in the deoxycorticosterone-saline treated rat. Hemodynamic studies in dogs indicate that quinapril decreases total peripheral and renal vascular resistance. Quinaprilat produces natriuresis and mild diuresis at doses that do not alter mean arterial blood pressure. Quinapril has the potential to affect plasma lipids beneficially or at least be "lipid neutral." Oral absorption of quinapril is rapid in rats, dogs, and monkeys. There is rapid and extensive distribution of radiolabel to most tissues except brain. Plasma radiolabel concentration-time profiles exhibit polyexponential decay with a prolonged terminal phase at low concentrations in all species. Metabolism to compounds other than quinaprilat is not extensive. Quinapril is excreted primarily as quinaprilat and to a lesser degree as quinapril. Quinapril is well tolerated in a variety of pharmacologic safety screens and its toxicity profile is similar to that of other ACE inhibitors. Quinapril does not adversely affect reproduction; it is not teratogenic, carcinogenic, or mutagenic.(ABSTRACT TRUNCATED AT 250 WORDS)