Bombesin receptor antagonists. 5 new irreversible alkylating analogues.

New alkylating bombesin analogues were synthesized in order to increase their solubility and stability in aqueous solutions. The best compromise between these parameters and the biological properties (receptor binding and antagonistic activity) was achieved with 4-[bis(2-chloro-ethylamino)]benzoyl derivatives of the BN (7-14) octapeptide carrying a (13-14) reduced peptide bond independently of the presence of a His12 residue, either free or protected.     

Bombesin receptor antagonists. 4. Chloromethylketone and chloroethylnitrosourea derivatives.

Four alkylating bombesin (BN) analogues (two C-terminal and one N-terminal chloromethylketone derivatives, and one chloroethylnitrosourea derivative) were synthesized and tested in Swiss 3T3 fibroblasts for receptor binding and mitogenic activity. Although they bound to the BN receptor with no or very weak mitogenic activity, no one analogue inhibited BN-induced thymidine incorporation in the contemporaneous treatment; only one behaved as a weak receptor antagonist when given 24 h before BN stimulation.     

Bombesin receptor antagonists. 2. Analogues based on substance P antagonists.

Although bombesin (BN) and substance P share only the C-terminal dipeptide amide, some substance P receptor antagonists are also weak bombesin receptor antagonists. In order to increase the selectivity of the antagonism for the BN receptor, a series of hybrid peptides were synthesized by the solid-phase methodology, and screened on 3T3 fibroblasts for binding and mitogenic activity. The analogues inhibiting BN-induced thymidine incorporation were further tested for peripheral (amylase release and urinary bladder contraction) and central activity (grooming behaviour).     

5-HT3 receptor antagonists. 1. New quinoline derivatives.

A series of esters and amides of 1-alkyl-2-oxo-1,2-dihydroquinoline-4- carboxylic acid or 2-alkoxy-quinoline-4-carboxylic acid containing a basic azabicycloalkyl moiety has been synthesized and evaluated for affinity for the [3H]quipazine-labeled 5-HT3 receptors. Most of the esters exhibited 10-fold more potent activity than that of ondansetron (1; Ki = 7.6 nM). Lipophilic substituents at the 1- or 2-position of the quinoline ring enhanced affinity for the receptors. Compounds 21 and 37 showed the highest affinity (Ki = 0.32 and 0.31 nM, respectively) among them. On the other hand, most of the amides showed 100-fold lower affinity than that of the esters. Molecular modeling studies indicated that the carbonyl moiety in 19 (ester) or 31 (amide) was not coplanar to the plane of an aromatic ring (over 20 degrees deviation). Although some of the selected compounds exhibited potent activity in the Bezold-Jarisch (B-J) reflex test, good correlation was not observed between the affinity for the 5-HT3 receptors and the activity in the B-J reflex test (in vivo). From these data, it was suggested that our quinoline derivatives might interact with the 5-HT3 receptors in a different way from that of the reported 5-HT3 receptor antagonists presumably due to the presence of the heterogeneity of the 5-HT3 receptors between brain and heart.     

The alkaloid conessine and analogues as potent histamine H3 receptor antagonists

The naturally occurring alkaloid, conessine (6), was discovered to bind to histamine H3 receptors in a radioligand-based high-throughput screen. Conessine displayed high affinity at both rat and human H3 receptors (pKi = 7.61 and 8.27) and generally high selectivity against other sites, including histamine receptors H1, H2, and H4. Conessine was found to efficiently penetrate the CNS and reach very high brain concentrations. Although the very slow CNS clearance and strong binding to adrenergic receptors discouraged focus on conessine itself for further development, its potency and novel steroid-based skeleton motivated further chemical investigation. Modification based on introducing diversity at the 3-nitrogen position generated a new series of H3 antagonists with higher in vitro potency, improved target selectivity, and more favorable drug-like properties. One optimized analogue (13c) was examined in detail and was found to be efficacious in animal behavioral model of cognition.     

Fancy bioisosteres: novel paracyclophane derivatives as super-affinity dopamine D3 receptor antagonists

The exploration of the chemical diversity space depends on the discovery of novel bioisosteric elements. As a continuation of our project on bilayered arene surrogates, we herein report on [2.2]paracyclophane-derived dopamine D3 receptor antagonists of type 4 and 6. For the most promising test compound 6a, bearing a 2-methoxyphenyl substituent, a stereocontrolled preparation was performed when the planar chirality of enantiomers (R)-6a (FAUC 418) and (S)-6a caused a considerable differentiation of D3 binding, which is indicated by K(i) values of 0.19 and 3.0 nM, respectively. Functional experiments showed D3 antagonist properties for the paracyclophane derivatives of type 6. To elucidate putative bioactive low-energy conformations, DFT-based studies including the calculation of diagnostic magnetic shielding properties were performed. An 89% increase in volume for the [2.2]paracyclophane moiety compared to that of the monolayered benzofurane of lead compound 3b indicates higher plasticity of GPCR binding regions than usually expected.     

New benzimidazole derivatives: selective and orally active 5-HT3 receptor antagonists

The synthesis of new 5-HT(3) receptor antagonists is an interesting field of research because of their wide therapeutic use. The aim of this work is to functionally characterise a new series of benzimidazole derivatives previously described. These compounds bind to 5-HT(3) receptors and have been evaluated using in vitro (rat tunica muscularis mucosae) and in vivo tests (Bezold-Jarisch reflex in rat and gastrointestinal motility and spontaneous motility in mice). Ondansetron and 1-[4-amino-5-chloro-2-(3,5-dimethoxyphenil)methyloxy]-3-[1-[2-methylsulfonylamino]piperidin-4-yl]propan-1-one hydrochloride (RS 39604) were used as well known 5-HT(3) and 5-HT(4) receptor antagonists. These benzimidazole derivatives have proved to be 5-HT(3) receptor antagonists. Interestingly, they are as active as ondansetron when they are intraperitoneally (i.p.) or orally (p.o.) administered and, in mice, they seem to induce fewer behavioural changes at similar effective doses than does ondansetron. The present results confirm the usefulness of the previously proposed pharmacophore and justify the interest in these new benzimidazole derivatives.     

Xanthine derivatives as adenosine receptor antagonists

The potency of a series of xanthine derivatives as adenosine antagonists was studied in fat cells (A1-receptors) and hippocampal slices (A2-receptors) and on L-[3H]phenylisopropyladenosine (PIA) binding in membranes from rat cortex. The order of potency in all three tests systems was: diethyl-8-phenyl-theophylline greater than 8-phenyltheophylline greater than 8-p-sulfophenyltheophylline greater than verrophylline greater than isobutylmethylxanthine greater than theophylline caffeine greater than theobromine. Enprofylline was about 20 times more potent in the hippocampus system than in the other two systems.     

Para-substituted Phe3 deltorphin analogues: enhanced selectivity of halogenated derivatives for delta opioid receptor sites.

The delta-selective opioid peptide deltorphin C(H-Tyr-D-Ala-Phe-Asp-Val-Val-Gly-NH2) (DEL C) was modified by para-substitution of Phe3 with halogens (F, Cl, Br, I), amino, or nitro groups. The bioactive potencies in peripheral tissues and brain receptor selectivities of these analogues depended upon the particular substituent; peptides containing halogen substituents exhibited the least disruptive effect. In the mouse vas deferens (MVD) bioassay, [p-ClPhe3]DEL C displayed equivalent bioactivities to DEL C; in combination with the guinea pig ileum (GPI) bioassay, [p-ClPhe3]DEL C and [p-BrPhe3]DEL C exhibited marked preference for delta sites (IC50GPI/IC50MVD = 11,250 and 6,363, respectively), which are approximately 4- and 2-fold greater than DEL C. In a receptor binding assay, none of the halogenated analogues had delta affinities (Ki) exceeding that of DEL C; however, in terms of delta selectivity (Ki mu/Ki delta), [p-BrPhe3]DEL C was nearly twice as selective as DEL C, while [p-FPhe3]DEL C was equivalent, and [p-IPhe3]DEL C only 25% less selective. The only correlation evident with the halogenated derivatives occurred between IC50GPI and Ki mu (r = 0.814) rather than between delta receptor studies (MVD or Ki delta); interestingly, IC50GPI also correlated with K' (r = 0.982). The p-amino or p-nitro substituents of Phe3 in DEL C and DEL B (= [Glu4]DEL C) were deleterious for bioactivity (MVD) (losses ranged from 400- to approximately 8,000-fold) and in receptor binding assays, where delta affinities decreased 140- to 840-fold and delta selectivities by 34- to 380-fold. p-Nitro-Phe3 was the most detrimental substitution for all the parameters measured for both deltorphins: the loss in MVD activity, however, was less with DEL B than with DEL C, which was the opposite for delta receptor affinity.     

Piperidine-containing histamine H3 receptor antagonists of the carbamate series: the alkyl derivatives

A series of N-alkyl urethanes, potential histamine H3 receptor antagonists, was prepared. Carbamate derivatives were synthesized from appropriate isocyanates and N-piperidinoalkan-1-ols. The novel compounds were evaluated for histamine H3 receptor activity in vitro on the guinea pig ileum. Some selected compounds were tested in vivo after p.o. application to mice and in vitro for selectivity towards other histamine receptors (H1, H2) in functional assays in the guinea pig. The most potent H3 receptor antagonist in vitro was compound 14 (pA2 = 7.2). Compound 14 was equipotent at M3 receptors and lacked H3 receptor activity in vivo. Predictions of octanol-water partition coefficient (Pallas) and metabolic fate (MetabolExpert, METEOR) were used to explore potential reasons for this absence of in vivo activity.     

5-Hydroxytryptamine (5-HT3) receptor antagonists. 1. Indazole and indolizine-3-carboxylic acid derivatives

Metoclopramide (1) is a gastric motility stimulant and a weak dopamine and 5-HT3 receptor antagonist. Conformational restriction of the (diethylamino)ethyl side chain of 1 in the form of the azabicyclic tropane gave 3, a very potent gastric motility stimulant and 5-HT3 receptor antagonist but devoid of significant dopamine receptor antagonist properties. Subsequent alteration of the aromatic nucleus led to the identification of indazoles 6a-h, and 1- and 3-indolizines 7b-d and 8, and imidazo[1,5-alpha]pyridines 9 and 10, as potent 5-HT3 receptor antagonists devoid of either dopamine antagonist or gastric motility stimulatory properties. Further conformational restriction of the side chain identified quinuclidine 11 and isoquinuclidine 12 as potent 5-HT3 receptor antagonists which mimic the distorted chair conformation of the tropane with, in the case of 11, the N-methyl group axial. From these series, 6g (BRL 43694) was found to be both potent and selective and has been shown to be a very effective antiemetic agent against cytotoxic drug induced emesis both in the ferret and in man.     

Bombesin receptor antagonists [corrected]. 1. Analogues with deleted, inverted or substituted amino acid residues

Bombesin is a 14-residue peptide hormone which serves a variety of biological functions, including cell growth control in Swiss 3T3 cultured fibroblasts. It has been also involved in an autocrine system regulating the growth of small cell lung carcinoma. A series of bombesin analogues were developed by amino acid deletion, inversion or substitution in the carboxy-terminal region, identified by the target cell receptor. Their properties were examined for: i) competitive binding assays; ii) mitogenic induction and inhibition assays; iii) effects on early cellular events (inositol phosphates production and protein tyrosine phosphorylation). Inversion of the Trp residue, or deletion of the C-terminal tripeptide amide, induced complete loss of receptor affinity and biological effects. Deletion of the His residue, or its derivatization as His (Dnp) in conjunction with Met deletion or modification, gave rise to compounds with reduced receptor affinity and weak antagonistic properties. Other modifications in the C-terminal tripeptide affected the potency but not the biological profile of the parent peptide. These results indicate the basis for the eventual design of improved, specific bombesin receptor antagonists and stimulate further studies on their possible application in the therapy of human small cell lung cancer.     

Zwitterionic analogues of cimetidine as H2 receptor antagonists

A series of analogues of the H2 receptor histamine antagonist cimetidine have been synthesized in which the dipolar cyanoguanidine group has been replaced by a number of zwitterionic moieties. Although none of the compounds is more effective than cimetidine in blocking histamine-stimulated tachycardia on the isolated guinea pig atrium, the activities of most of the compounds possessing rigid dipoles can be accounted for on the basis of dipole orientation relative to the common side chain and by considering the active species in each case to be the zwitterion. These findings are in general agreement with those found for analogues having conjugated groups as dipoles.     

Somatostatin receptor 1 selective analogues: 3. Dicyclic peptides

The binding affinity of short chain somatostatin (SRIF) analogues at the five human SRIF receptors (sst) was determined to identify sterically constrained somatostatin receptor subtype 1 (sst(1)) selective scaffolds. Des-AA(1,2,4,13)-[d-Trp(8)]SRIF (2) retained high binding affinity at all receptors but sst(1), Des-AA(1,2,4,5)-[d-Trp(8)]SRIF (3) at sst(4) and sst(5), and Des-AA(1,2,4,5,13)-[d-Trp(8)]SRIF (4) at sst(2) and sst(4) (AA = amino acid). Des-AA(1,2,4,12,13)-[d-Trp(8)]SRIF (6) was potent and sst(4)-selective (>25-fold); Des-AA(1,2,5,12,13)-[d-Trp(8)]SRIF (7) and Des-AA(1,2,4,5,12,13)-[d-Trp(8)]-SRIF (9, ODT-8) were most potent at sst(4) and moderately potent at all other receptors. Dicyclic SRIF agonists of the sst(1)-selective Des-AA(1,5)-[Tyr(2),d-Trp(8),IAmp(9)]SRIF, (14, sst(1) IC(50) = 14 nM) were prepared in which a lactam bridge introduced additional conformational constraint (IAmp = 4-(N-isopropyl)-aminomethylphenylalanine). Cyclo(7-12)Des-AA(1,5)-[Tyr(2),Glu(7),d-Trp(8),IAmp(9),hhLys(12)]SRIF (31) (sst(1) IC(50) = 16 nM) and cyclo(7-12) Des-AA(1,2,5)-[Glu(7),d-Trp(8),IAmp(9),m-I-Tyr(11),hhLys(12)]SRIF (45) (sst(1) IC(50) = 6.1 nM) had equal or improved affinities over that of the parent 14. Binding affinity was decreased in all other cases with alternate bridging constraints such as cyclo (6-11), cyclo (6-12), and cyclo (7-11). Compound 45 is an agonist (EC(50) = 8.8 nM) in the adenylate cyclase assay.     

Neurokinin-3 receptor antagonists

Until late 1994, research on the neurokinin-3 (NK3) receptor, compared with that on neurokinin-1 (NK1) and neurokinin-2 (NK2) receptors, received little attention, due, to a large extent, to the absence of potent and selective non-peptide NK3 receptor antagonists. During 1995 and 1996, the disclosure of non-peptide antagonists led to a marked increase in research activities aimed at clarifying the physiological and pathophysiological role of the NK3 receptor. This review addresses the recent highlights and developments in this area, with particular emphasis on non-peptide NK3 receptor antagonists. Focus has been given to the various strategies utilised by several pharmaceutical companies to identify NK3 receptor antagonist prototypes and on the chemical optimisation processes which led to the potent and selective peptide-derived PD 161182 (8), the dichlorophenylalkylpiperidine SR 142,801 (9) and the quinoline derivative SB 223412 (27), which are representative compounds of the three distinct chemical classes of non-peptide NK3 receptor antagonists disclosed to date. The human NK3 (hNK3) receptor was cloned and stably expressed in 1992, and studies on the distribution in rodents and humans revealed that it is present in the central nervous system (CNS) and periphery. Based on receptor distribution and on the pharmacological effects of selective NK3 receptor agonists, a number of potential therapeutic indications for NK3 receptor antagonists are suggested, including CNS disturbances, pain and inflammation, pulmonary and skin diseases. Overall, although evidence indicates a noticeable increase in interest and research on NK3 receptors in the last few years, extensive additional medicinal chemistry and pharmacology studies, including preclinical and clinical evaluation of appropriate compounds from distinct structural classes, are required to delineate the pathophysiological role of NK3 receptors and to establish more firmly potential therapeutic utilities of potent and selective NK3 receptor antagonists.     

5HT6 receptor antagonists: a patent update. Part 1. Sulfonyl derivatives

Introduction: Among a variety of proteins included in a relatively wide GPCR family, serotonin 5HT receptors (5HT₆Rs) are highly attractive as important biological targets with enormous clinical importance. Among this subclass, 5HT₆R is the most recently discovered group. Available biological data clearly indicate that 5HT₆R antagonists can be used as effective regulators in a variety of contexts, including memory formation, age-related cognitive impairments and memory deficits associated with conditions such as schizophrenia, Parkinson's disease and Alzheimer's disease. Therefore, this receptor has already attracted a considerable attention within the scientific community, due to its versatile therapeutic potential.

Areas covered: The current paper is an update to the comprehensive review article published previously in Expert Opinion on Therapeutic Patents (see issue 20(7), 2010). Here, the main focus is on small-molecule compounds – 5HT₆ antagonists – which have been described in recent patent literature, since the end of 2009. To obtain a clear understanding of the situation and dynamic within the field of 5HT₆ ligands, having an obvious pharmaceutical potential in terms of related patents, a comprehensive search through several key patent collections have been provided. The authors describe the reported chemical classes and scaffolds in sufficient detail to provide a valuable insight in the 5HT₆R chemistry and pharmacology. The review consists of two core parts with separate sections arranged in accordance with the main structural features of 5HT₆R ligands.

Expert opinion: Recent progress in the understanding of the 5HT₆ receptor function and structure includes a suggested constitutive activity for the receptor, development of a number of multimodal small molecule ligands and re-classification of many selective antagonists as pseudo-selective agents. Heterocycles with sulfonyl group and without any basic center provide sufficient supramolecular interactions and show high antagonistic activity against 5HT₆R.     

Malonamic acid derivatives as M1 selective muscarinic receptor antagonists.

A series of malonamic acid esters with suitable amino alcohols, typical of antimuscarinic compounds, was synthesized and the affinities for the three pharmacologically defined muscarinic receptor subtypes, namely M1, M2 and M3, were evaluated by radioligand displacement experiments. It was found that the esters with 3-quinuclidinol 7b, 7f-g, 8 and 9 are ligands with intermediate to high affinity for the M1 receptors, for which they show a preferential binding. Unexpectedly, the ester 7a with tropine bound with negligible affinity to all the receptors investigated. The introduction of a phenyl group on the carboxamido moiety of 7b gave compound 9, which showed an affinity for the M1 receptor comparable with that of the reference drug Pirenzepine 1.