D. Jukic

Pharmacological characterization of a new highly potent B2 receptor antagonist (HOE 140: D-Arg-[Hyp3, Thi5, D-Tic7, Oic8]bradykinin)

HOE 140 (D-Arg-[Hyp3,Thi5,D-Tic7,Oic8]bradykinin), a new B2 antagonist, was compared to R-493 (D-Arg[Hyp3-D-Phe7,Leu8]bradykinin) with respect to inhibition of the responses of seven isolated smooth muscle preparations to bradykinin. R-493 was found to exert: (a) high antagonistic activity on the rabbit jugular vein (pA2 of 8.86), (b) moderate activity on the rabbit aorta, guinea-pig ileum, hamster urinary bladder and human urinary bladder (pA2 of 5.76, 6.77, 7.16 and 7.15, respectively) and (c) a stimulatory effect on the guinea-pig trachea. On the other hand, HOE 140 showed identical apparent affinities (8.36-9.12) on all preparations except the rabbit aorta where it was inactive and the guinea-pig trachea where the compound was an antagonist (pA2: 7.42) without agonistic effect. HOE 140 is specific and selective for B2 receptors since it was inactive against angiotensin II, substance P, neurokinin A, desArg9-bradykinin, noradrenaline or acetylcholine in the various preparations. R-493 inhibited the contractile effects of bradykinin competitively, while HOE 140 was not competitive even at low concentrations (7.7 x 10(-9) M). These results demonstrate that HOE 140 is a potent B2 antagonist with high affinity, specific for kinin receptors and selective for the B2 receptor type, but is non-competitive. HOE 140 is the first bradykinin receptor antagonist that acts as such on the guinea-pig trachea without showing any agonistic activity.

BRADYKININ RECEPTOR TYPES AND B2 SUBTYPES

Bradykinin, desArg9BK, some agonist analogues and several antagonists have been tested in isolated organs in order to identify bradykinin B2 receptor subtypes. The initial pharmacological characterization was made in the rabbit jugular vein and the guinea pig ileum, two widely used B2 preparations which have shown marked differences in their sensitivities to both agonists and antagonists. The study has then been extended to peripheral tissues (stomach, colon, urinary bladder) of four species (the rat, guinea pig, rabbit and man) and to isolated vessels (rabbit jugular vein, rabbit vena cava, guinea pig pulmonary artery, rat portal vein) in order to determine if pharmacologic receptor subtypes may be related to species. It has been shown that B2 receptors in rat and guinea pig tissues belong to a similar pharmacological entity, a receptor which is different from that mediating the responses of rabbit and human tissues. Agonists order of potency ([Hyp3]BK > BK > [Aib7]BK) obtained in the rabbit jugular vein is different from that found in the guinea pig ileum (BK < or = [Aib7]BK > [Hyp3]BK). Affinities of competitive antagonists (for instance DArg[Hyp3,DPhe7,Leu8]BK) in rabbit tissues are higher than in guinea pig and rat tissues by at least 2 log units, while the non peptidic compound WIN 64338 is more active (also by two log units) in guinea pig than in human and rabbit tissues. The non competitive long-acting antagonist HOE 140 is very potent and equally active in the four species. Some antagonists (peptides without unnatural residues, peptides with unnatural residues, non peptides) have been shown to be specific for kinin receptors and selective for the B2. Altogether, the present results a) confirm the existence of two B2 receptor subtypes, b) suggest that receptor subtypes may be species dependent and c) indicate that the B2 receptor subtype found in the rabbit is similar to that found in man.

Structure-activity studies of bradykinin and related peptides. B2-receptor antagonists.

Thirty-seven compounds were tested as antagonists of kinin B2- and B1-receptors to identify the chemical changes required to obtain antagonism, improve antagonist affinity, and eliminate residual agonistic activities. Apparent affinity of antagonists was evaluated in terms of pA2 on the rabbit jugular vein, the dog carotid and renal arteries, the hamster urinary bladder, the guinea pig ileum, the rat vas deferens, the guinea pig trachea, and the rabbit aorta, using bradykinin and desArg9-bradykinin as B2- and B1-receptor activators. Replacement of Pro7 of bradykinin with D-Phe leads to antagonism; substitution of Pro3 by Hyp and extension of the peptide chain at the N-terminal with a D-Arg residue improves the affinity of antagonists; acetylation of N-terminal amine function reduces residual agonistic activity; these changes, combined with the replacement of Phe8 by Leu as in Ac-D-Arg[Hyp3,D-Phe7,Leu8]-bradykinin, led to potent full B2-receptor antagonists. Affinity of antagonists differs markedly between highly sensitive (rabbit jugular vein, dog carotid and renal artery), moderately sensitive (hamster urinary bladder, guinea pig ileum, and rat vas deferens), and insensitive preparations (the guinea pig trachea) in which antagonists act as potent stimulants. High concentrations of antagonists block bradykinin completely in the rabbit jugular vein but not in the guinea pig ileum, suggesting that kinins stimulate the moderately sensitive tissues by two mechanisms, of which only one is blocked by antagonists. It thus appears that kinins act on various B2-receptor subtypes or by different action mechanisms.

Neurokinin receptor subtypes characterized by biological assays

Neurokinin receptors have been characterized by biological assays using naturally occurring and selective agonists as well as peptide and non peptide antagonists. Six preparations have been used: the rabbit vena cava and the rat urinary bladder, treated with a NK-2 receptor antagonist for the NK-1 receptor, the rabbit pulmonary artery and the hamster urinary bladder for the NK-2, the rat portal vein and the guinea pig ileum, treated with a NK-1 receptor antagonist, for the NK-3. Treatment with antagonists was required because of the presence (in some preparations) of two functional sites contributing to the biological effect. Differences in the order of potency of agonists between each couple of receptors have been demonstrated, especially with tachykinins and the selective agonists. Such differences are even more evident with antagonists, some of which show apparent affinity (pA2) values 1.5 to 3 log units higher in one than in the other member of each couple. Based on data obtained in pharmacological experiments, it is concluded that NK-1, NK-2 and NK-3 receptors show differences strong enough to justify the assumption that their coding and/or expression diverge among species.

Structure-activity studies on bradykinin and related peptides: agonists

1 Bradykinin, kallidin, T‐kinin, [Hyp3]‐bradykinin and several analogues were prepared by solid‐phase synthesis and purified by high performance liquid chromatography. 2 The various peptides were tested for their abilities to relax the dog carotid and renal arteries, or to contract the rabbit jugular vein and aorta, in order to measure their activities on BK2 (the first three preparations) or BK1 (the rabbit aorta) receptors. The dog renal artery without endothelium was also used as a BK1 receptor system. 3 T‐kinin was found to be less active than bradykinin, while the replacement of Pro3 with Hyp favoured BK2 receptor occupation. [Hyp3,Tyr(Me)8]‐BK was found to be a selective BK2 receptor agonist. 4 Amidation or methylation of the C‐terminal carboxyl decreased activity, while extension of the N‐terminal with Sar or d‐Arg increased affinity and selectivity for BK1 (Sar) and affinity for BK2 (d‐Arg) receptors. Acetylation of N‐terminal amide brought affinity down to 10% or less. 5 Replacement of the peptide bonds Phe8‐Arg9 to protect from kininase I and II, decreased affinities slightly, but was incompatible with additional changes at the N‐terminal or in the peptide bond Gly4‐Phe5. 6 Substitution of C‐terminal Phe in desArg9‐BK (the BK1 receptor stimulant) with d‐Phe increased potency and selectivity for BK1 receptors while protecting from carboxypeptidases. Sar[d‐Phe8]desArg9‐BK was found to be a potent and selective BK1 receptor agonist.

Structure-Activity Studies of B1 Receptor–Related Peptides: Antagonists

We tested several peptides related to des-Arg9-bradykinin as stimulants or inhibitors of B1 (rabbit aorta, human umbilical vein) and B2 (rabbit jugular vein, guinea pig ileum, human umbilical vein) receptors. We also incubated the compounds with purified angiotensin-converting enzyme from rabbit lung to test their resistance to degradation. We evaluated apparent affinities (in terms of the affinity constant pA2) of compounds and their potential residual agonistic activities (alpha E). Bradykinin and des-Arg9-bradykinin were used as agonists for the B2 and B1 receptors, respectively. Degradation of peptides by the angiotensin-converting enzyme was prevented in the presence of a D-residue in position 7 of des-Arg9-bradykinin. Replacement of Pro7 with D-Tic combined with Leu, Ile, Ala, or D-Tic in position 8 led to weak B1 receptor antagonists, some of which had strong residual agonistic activities on the B2 receptor preparations. The use of D-beta Nal in position 7, combined with Ile in position 8 and AcLys at the N-terminal (eg, AcLys[D-beta Nal7, Ile8]des-Arg9-bradykinin) gave the most active B1 receptor antagonist (pA2 of 8.5 on rabbit aorta and human umbilical vein), which is also partially resistant to enzymatic degradation. Extension of the N-terminal end by Sar-Tyr-epsilon Ahx (used for labeling purposes) and even cold-labeling of Tyr with iodine were compatible with high, selective, and specific antagonism of the B1 receptors. We compared some compounds with some already known B1 receptor antagonists to underline the novelty of new peptidic compounds.

[Phe8Ψ(CH2-NH)Arg9]bradykinin, a B2 receptor selective agonist which is not broken down by either kininase I or kininase II

We report data obtained with a new compound, [Phe 8 ψ(CH 2 -NH)Arg 9 ]BK (BK=bradykinin) in which the Phe 8 -Arg 9 peptide bond was replaced by the isosteric CH 2 -NH bond, in order to protect BK from metabolic degradation. By preventing the action of kininase I, this chemical modification should give the compound good selectivity for B 2 receptors, since active stimulants of the B 1 receptors, such as desArg 9 -BK, will no longer be released. BK and [Phe 8 ψ(CH 2 -NH)Arg 9 ]BK were tested in four pharmacological preparations, the dog carotid artery the dog renal artery, the rabbit jugular vein and the rabbit aorta

Neurokinin A. A pharmacological study

Discovered in 1983, the decapeptide neurokinin A has been shown to occur in several peripheral organs and to exert a variety of biological effects. In this article, we review the most sensitive and selective in vivo and in vitro tests which have been used in various laboratories to evaluate naturally occurring or synthetic neurokinin A. A comparison of the effects of neurokinin A and those of its mammalian homologues, substance P and neurokinin B as well as those of tachykinins and related peptides is presented in the frame of a study directed toward characterization of neurokinin receptors. Indeed, neurokinin A has been shown to be particularly active on a neurokinin receptor subtype, the NK-2. Structure-activity studies performed with neurokinin A and its fragments as well as with several analogues of both the decapeptide and the heptapeptide NKA(4-10) have brought to the identification of the minimum structure required for activation of NK-2 receptors. Selective agonists for this receptor have been identified, in particular [Nle10]-NKA(4-10) and [beta-Ala8]-NKA(4-10).

Structure-activity study of neurokinins: antagonists for the neurokinin-2 receptor.

A series of 21 peptides were synthesized and tested in a variety of isolated organs in order to determine their potential as neurokinin-2 (NK-2) antagonists. The peptides have been tested in the three monoreceptor systems, the dog carotid artery (NK-1), the rabbit pulmonary artery (NK-2) and the rat portal vein (NK-3) as well as on other preparations containing NK-2 receptors, such as the rat vas deferens, the hamster urinary bladder, the guinea-pig trachea and the human urinary bladder. Some of the compounds have also been tested on the human isolated bronchus. Three compounds, of which two are linear peptides, Ac.Leu-Asp-Gln-Trp-Phe-Gly.NH2, Thr-Asp-Tyr-D-Trp-Val-D-Trp-D-Trp-Arg.NH2 and a cyclic one, cyclo[Gln-Trp-Phe-Gly-Leu-Met] have been shown to reduce or eliminate the effects of neurokinin A (NKA) in practically all the preparations containing NK-2 receptors. The first compound was found to be selective for the NK-2 receptor and showed only agonistic or no activity on the other receptor systems, while the second compound showed some antagonistic effects not only on the NK-2 but also on the other systems. The cyclic compound was found to be fairly selective for the NK-2 receptor. The first compound (Ac.Leu-Asp-Gln-Trp-Phe-Gly.NH2) was characterized with respect to its specificity for neurokinins (NK): it was found to be inactive on receptors for acetylcholine, noradrenaline, angiotensin and des Arg9-bradykinin in the rabbit pulmonary artery. Moreover, the compound exerted a competitive type of antagonism on the rabbit pulmonary artery and on the hamster urinary bladder. Although of moderate affinity, the NK-2 receptor antagonists described in this paper provide important tools for pharmacological studies on NK.

Structure-Activity Studies of B1 Receptor–Related Peptides

We tested several peptides related to des-Arg9-bradykinin as stimulants or inhibitors of B1 (rabbit aorta, human umbilical vein) and B2 (rabbit jugular vein, guinea pig ileum, human umbilical vein) receptors. We also incubated the compounds with purified angiotensin-converting enzyme from rabbit lung to test their resistance to degradation. We evaluated apparent affinities (in terms of the affinity constant pA2) of compounds and their potential residual agonistic activities (alpha E). Bradykinin and des-Arg9-bradykinin were used as agonists for the B2 and B1 receptors, respectively. Degradation of peptides by the angiotensin-converting enzyme was prevented in the presence of a D-residue in position 7 of des-Arg9-bradykinin. Replacement of Pro7 with D-Tic combined with Leu, Ile, Ala, or D-Tic in position 8 led to weak B1 receptor antagonists, some of which had strong residual agonistic activities on the B2 receptor preparations. The use of D-beta Nal in position 7, combined with Ile in position 8 and AcLys at the N-terminal (eg, AcLys[D-beta Nal7, Ile8]des-Arg9-bradykinin) gave the most active B1 receptor antagonist (pA2 of 8.5 on rabbit aorta and human umbilical vein), which is also partially resistant to enzymatic degradation. Extension of the N-terminal end by Sar-Tyr-epsilon Ahx (used for labeling purposes) and even cold-labeling of Tyr with iodine were compatible with high, selective, and specific antagonism of the B1 receptors. We compared some compounds with some already known B1 receptor antagonists to underline the novelty of new peptidic compounds.