N. Rouissi

Selective agonists for substance P and neurokinin receptors

A series of neurokinin analogues and fragments have been prepared in an attempt to identify selective agonists for NK-P, NK-A and NK-B receptors. The compounds have been tested on the dog carotid artery (NK-P receptor system), the rabbit pulmonary artery (NK-A) and the rat portal vein (NK-B). C-terminal substituted analogues of the three neurokinins have provided indication that NK-P receptor selectivity is improved by the oxidation of methionine to Met(O2), while selectivity for NK-A is favoured by replacing Met with NIe. Selectivity for NK-P receptors is further improved by the replacement of Gly9 with Sar. Selectivity and affinity for NK-B receptors is markedly increased when Val7 is replaced with MePhe in both the fragment NKB (4-10) and NKB. The results of the present study indicate that a) [Sar9,Met(O2)11]SP is a potent and selective agonist for the NK-P receptors of the dog carotid artery; b) [MePhe7]NKB is a very potent and selective stimulant of receptors for neurokinin B and c) [Nle10]NKA (4-10) is a promising compound, showing some selectivity for NK-A receptor; further modifications are however needed to improve its affinity.

Characterization of neurokinin receptors in various isolated organs by the use of selective agonists

The three mammalian neurokinins, substance P, neurokinin A and neurokinin B, as well as some agonists selective for their respective receptors, NK-P, NK-A and NK-B, were tested in a variety of pharmacological preparations in order to evaluate if the biological responses of the various tissues were mediated by single or multiple receptor types. Previous observations that the dog carotid artery, the rabbit pulmonary artery and the rat portal vein are selective preparations respectively for SP, NKA and NKB were confirmed in the present study by showing that only the respective selective agonists were active on these tissues. Multiple functional sites were demonstrated in intestinal tissues (guinea pig ileum, rat duodenum), which apparently contain the three neurokinin receptors. A large number of NK-P, together with some NK-A receptor sites were found in the guinea pig and rat urinary bladder. Similarly, the guinea pig trachea and the rabbit mesenteric vein contain NK-A and NK-P functional sites. Rat and rabbit vas deferens stimulated electrically respond as typical NK-A preparations, since they are almost insensitive to SP or NKB selective agonists. A mixture of NK-A and NK-B receptor sites has been shown to be present in the hamster urinary bladder: dog and human urinary bladder definitely contain NK-A receptors and the dog bladder also some NK-P functional sites.

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.

Structure-activity studies of neurokinin A

A structure-activity study on neurokinin A and its C-terminal fragment NKA (4-10) has been performed in order to find selective agonists for the NK-2 receptor and identify chemical modifications suitable for protecting the peptides from degradation, while maintaining activity. Five series of compounds have been prepared and tested: 1. the complete series of the L-Ala monosubstituted analogues of NKA; 2. a series of NKA fragments from the C- or N-terminal; 3. the complete series of NKA (4-10) analogues monosubstituted with beta-Ala; 4. a series of NKA (4-10) analogues with monosubstitutions in pos. 4, 8, 10 or multisubstitutions in two or more of the same positions; and 5. a series of 6 NKA (4-10) analogues monosubstituted with 1-amino,1-cyclohexane carboxylic acid residue. It has been found that the most selective agonists for the NK-2 receptor system are [beta Ala8]NKA (4-10) and [Nle10]NKA (4-10). Protection from aminopeptidase may be obtained by acetylation of the N-terminal amide of NKA (4-10), while partial protection from endopeptidases should be expected from the presence of beta-Ala in position 8. Conformational constraints induced with 1,amino,1-cyclohexane carboxylic acid residue gave weakly active compounds. Multiple substitutions reduce rather than potentiating the favorable effects of the corresponding monosubstituted compounds.

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.

Antagonists for the neurokinin NK-3 receptor evaluated in selective receptor systems

Four isolated vessels that are monoreceptor systems for neurokinins, the dog carotid artery and rabbit jugular vein (NK-1), the rabbit pulmonary artery (NK-2) and the rat portal vein (NK-3), were used to compare the activities of selective neurokinin agonists and evaluate the affinities of new NK-3 antagonists. Chemical modifications in the partial sequences NKA (4-10) and NKB (4-10), particularly the replacement of Val7 with an aromatic residue (Tyr, MePhe or Trp) and the extension of the peptide backbone in position 8, obtained with beta-Ala, led to compounds that maintain weak agonistic activities on the NK-1 and NK-2, and some of them also on NK-3 receptors but exert potent antagonism against NKB on the NK-3 receptor of the rat portal vein. Antagonistic affinity is the highest when Trp is used in position 7 of [beta-Ala8]-NKA (4-10) and MePhe in position 7 of [beta-Ala8]-NKB (4-10). Antagonism is selective for NKB or [MePhe7]-NKB, and appears to be specific, since the most active compound [Trp7, beta-Ala8]-NKA (4-10) is inactive against bradykinin on the rabbit jugular vein (B2 receptor), against SP on the rabbit jugular vein (NK-1 receptor), against desArg9-bradykinin on the rabbit aorta (B1 receptor), and against angiotensin II and histamine (AT and H receptors, respectively) in the rabbit aorta. The new NK-3 receptor antagonists described in the present study provide useful tools for neurokinin receptor characterization and for determining the roles of neurokinins in physiopathology.

Receptors for neurokinins in human bronchus and urinary bladder are of the NK-2 type.

Human tissues such as the isolated bronchus and urinary bladder respond to neurokinins with concentration-dependent contractions, which appear to be due to the activation of receptors. We characterized these receptors in the present study using agonists (the naturally occurring neurokinins and some selective agonists) as well as newly identified antagonists. The order of potency of the agonists in the two preparations was as follows: neurokinin A (NKA) greater than substance P (SP) greater than neurokinin B (NKB) (bronchus) and NKA greater than NKB greater than SP (bladder), which suggests the presence of NK-2 receptors. This was confirmed by data obtained with two antagonists, one of which was shown to be competitive and selective for NK-2 type receptors. It thus appears that receptors of the NK-2 type are present in humans along the tracheo-bronchial tree and in the urinary system.

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.

[Leu9ψ(CH2NH)Leu10]-Neurokinin A(4–10) (MDL 28, 564) distinguishes tissue tachykinin peptide NK2 receptors

The neurokinin A analogue, MDL 28,564 (Asp-Ser-Phe-Val-Gly-Leu-CH2NH-Leu-NH2), inhibited 125I-NKA binding to hamster urinary bladder NK2 receptors with a KI of 130 nM. For rat submaxillary gland NK1 receptors and cerebral cortical NK3 receptors, the KIs for MDL 28,564 were greater than 250 microM and greater than 500 microM, respectively. MDL 28,564 did not relax dog carotid artery (NK1 tissue) or contract rat portal vein (NK3 tissue). In guinea-pig trachea tissues, MDL 28,564 stimulated phosphatidylinositol turnover and induced contraction with maximum effects similar to those of neurokinin A. In hamster urinary bladder tissue, MDL 28,564 stimulated phosphatidylinositol turnover with maximum effect only 10% of that of neurokinin A, did not produce sustained contraction itself and antagonized NKA-induced contraction. MDL 28,564 also produced full contraction in rabbit pulmonary artery (NK2 tissue) but was inactive in rat vas deferens (NK2 tissue). These data with MDL 28,564 are consistent with the NK2 receptors in guinea-pig trachea and rabbit pulmonary artery being different from those in hamster urinary bladder and rat vas deferens.

The rabbit jugular vein is a contractile NK-1 receptor system

Rabbit isolated jugular veins respond to substance P and related neurokinins with concentration-dependent contractions which appears to be due to the activation of a single neurokinin receptor of the NK-1 type. This is demonstrated by the order of potency of neurokinins and some of their fragments as well as by the strong activity of NK-1-selective agonists and the weakness of NK-2- and NK-3-selective agonists. The present results indicate that the rabbit jugular vein provides a sensitive, specific and selective NK-1 preparation which responds directly to neurokinins with contractions and therefore can be useful for characterization of NK-1 agonists and antagonists.