Affinity of muscarinic receptor antagonists for three putative muscarinic receptor binding sites

1. A range of muscarinic receptor antagonists were examined for affinity at the M1 muscarinic binding site, present in rat cerebrocortical membranes and the M2 muscarinic binding sites of rat cardiac and submaxillary gland membranes. 2. The results obtained were consistent with the presence of three classes of muscarinic binding site. 3. Both the M1 binding site, labelled by [3H]-pirenzepine ([3H]-Pir) in rat cerebrocortical membranes, and the M2 gland binding site, labelled by [3H]-N-methyl scopolamine ([3H]-NMS) in rat submaxillary gland membranes, displayed higher affinity for pirenzepine, dicyclomine, 4-diphenylacetoxy-N-methylpiperidine methiodide (4-DAMP) and cyclohexylphenyl (2-piperidinoethyl) silanol (CPPS) than did the M2 binding sites of cardiac membranes labelled by [3H]-NMS. 4. The M2 cardiac sites displayed higher affinity for methoctramine, himbacine and AF-DX 116 than did either the M1 binding site of cerebrocortical membranes or the M2 gland binding site present in rat submaxillary gland membranes. 5. The M1 and M2 gland binding sites could only be distinguished by considering the absolute affinity of compounds for these two sites. Thus, all compounds, with the exception of 4-DAMP, displayed between a 2 and 8 fold higher affinity for the M1 than for the M2 gland binding site. There were no antagonists with higher M2 gland than M1 affinity.     

Design of nonpeptidal ligands for a peptide receptor: cholecystokinin antagonists

A series of 3-substituted 5-phenyl-1,4-benzodiazepines, nonpeptidal antagonists of the peptide hormone cholecystokinin (CCK), have been synthesized. Designed on the basis of facts regarding CCK, its natural-product antagonist asperlicin (3), and the antianxiety agent diazepam (4), these compounds represent a significant departure from existing CCK antagonists. They also constitute perhaps the first examples of simple, nonpeptidal ligands for a peptide receptor to arise by design rather than by screening. These compounds serve to illuminate the distinction between central and peripheral CCK receptors, as well as to provide orally effective CCK antagonists of potential pharmacological or therapeutic utility. One rationale for their receptor affinity has possible applications in the design of nonpeptidal ligands for other receptors, peptidal as well as nonpeptidal.     

Inhibition of the preferential binding of actin to the N-terminal hydratase domain of the 78-kDa gastrin-binding protein by non-steroidal anti-inflammatory drugs and gastrin receptor antagonists

The 78 kDa gastrin-binding protein (GBP) is a likely target for the antiproliferative effects of gastrin receptor antagonists and non-steroidal anti-inflammatory drugs (NSAIDs) on colorectal carcinoma cells (Baldwin GS, Murphy VJ, Yang Z, and Hashimoto T. J Pharmacol Exp Ther 1998;286:1110-14). This study tested the hypotheses that the GBP bound actin, and that the interaction could be disrupted by gastrin receptor antagonists and NSAIDs. Binding of actin to the GBP was assessed by competition with (125)I-[Nle(15)]-gastrin(2,17) in a covalent cross-linking assay, and by comparison of (125)I-actin binding to the N- and C-terminal GBP domains, which had been expressed independently in E. coli as glutathione-S-transferase (GST) fusion proteins. The ability of gastrin receptor antagonists and NSAIDs to interfere with the actin-GBP interaction was measured by release of (125)I-actin from preformed complexes with the N- and C-terminal domain-GST fusion proteins. Actin purified from skeletal muscle or from gastric mucosal cytosol competed with (125)I-[Nle(15)]-gastrin(2,17) for binding to the GBP with IC(50) values of 2.6 +/- 0.7 microM, and 2.1 +/- 0.7 microM, respectively. The amount of (125)I-actin from either source bound to the N-terminal GBP domain was 8.2 times greater than the amount bound to the C-terminal domain. Binding of actin to both domains was inhibited by the gastrin receptor antagonists proglumide and benzotript, and by NSAIDs. We conclude that the GBP may associate with the cytoskeleton via an interaction between its N-terminal domain and actin, and that the association may be disrupted either by gastrin receptor antagonists or by NSAIDs.     

Molecular modelling of asperlicin derived cholecystokinin A receptor antagonists.

The C3-substituted benzodiazepines derived from asperlicin, e.g. devazepide (L-364,718, MK-329), constitute the most potent class of cholecystokinin A-type (CCKA) receptor antagonists. In order to gain insight into the prerequisites for binding, we examined the conformational properties of both potent and weak representatives of this class with computer assisted molecular modelling (CAMM) techniques. The CAMM results indicate that the binding site for the C3-substituents is a planar slot on the CCKA receptor surface and, in addition, allow the proposal of a model which describes the relative binding mode of the less potent R isomers versus that of the S isomers. The latter model illustrates the unique spatial properties of the benzodiazepine moiety, which we suggest functions primarily as an invertible core which assures an optimal arrangement of attached substituents.     

Rationalizing the activities of diverse cholecystokinin 2 receptor antagonists using molecular field points

Cholecystokinin 2 receptor antagonists encompass a wide range of structures. This makes them unsuitable candidates for existing 3D-QSAR methods and has led us to develop an alternative approach to account for their observed biological activities. A diverse set of 21 antagonists was subjected to a novel molecular field-based similarity analysis. The hypothesis is that compounds with similar field patterns will bind at the same target site regardless of their underlying structure. This initial report demonstrates a linear correlation between ligand similarity and biological activity for this challenging data set. A model generated with three molecules was used to predict the activity of 18 test compounds, with different chemotypes, with a root-mean-square error of 0.68 pKB units. The ability to automatically derive a molecular alignment without knowledge of the protein structure represents an improvement over existing pharmacophore methods and makes the method particularly suitable for scaffold-hopping.     

Recent advances in the chemistry of cholecystokinin receptor ligands (agonists and antagonists)

During the last few years, cholecystokinin (CCK) has emerged as an important hormone. This polypeptide has been located either in peripheral tissues such as the gastro-intestinal tract and the pancreas as well as in the central nervous system. High affinity CCK receptors are divided in two main subtypes: the CCK-A (A for (A for "alimentary") and the CCK-B (B for "brain") receptors. The latters are currently associated with the gastrin receptors. Since CCK is involved in many different biological processes such as gut function, digestive processes, control of feeding behaviour and neurotransmitter release, the therapeutical potential of cholecystokinin receptor ligands seems to be extremely broad and promising. Several families of CCK receptor ligands (peptides, peptidomimetics, peptoids or non-peptides) were prepared during the last twenty years. The main goal of these researches was to improve agonistic or antagonistic potency but also to find selective compounds for a specific CCK receptor subtype. This review presents the recent developments (since 1995) in the chemistry of CCK receptor ligands.     

Memory impairments induced by peripherally administered cholecystokinin a-type receptor antagonists in rats

Intraperitoneal injection of cholecystokinin (CCK) A-type receptor antagonists, L-364,718 and CR 1409, caused dose-dependent memory impairments in passive and active avoidance responses and in Morris water pool test in rats. These antagonist effects were significant at a dose of 1 mg/kg, while with proglumide, 50–100 mg/kg were required to produce a similar memory deficit. The results suggest that loss of biologically active CCK octapeptide (CCK-8), not only in the brain but also in the peripheral tissues, causes memory impairmets in rats. © 1992 Wiley-Liss, Inc.     

Relative blood-brain barrier permeabilities of the cholecystokinin receptor antagonists devazepide and A-65186 in rats.

The blood-brain barrier permeabilities of the type-A cholecystokinin receptor antagonists devazepide and A-65186 (Nalpha-3-quinolinoyl-D-Glu-N,N-dipentylamide) have been compared with those of the reference compounds iodoantipyrine, which readily penetrates the blood-brain barrier, and mannitol, which does not. Anaesthetized rats received a bolus injection into the left carotid artery of [14C]iodoantipyrine (0.25 microCi) combined with [3H]mannitol, [3H]devazepide or [3H]A-65186 (1 microCi each). Rats were decapitated 12s after injection and the brains were removed. Four samples of left cerebrum (ca 100 mg each) were solubilized overnight and 14C and 3H activity were measured. The brain-uptake index for each test compound was determined as [(3H/l4C for sample)]/[(3H/14C for injectate)] x 100, with a value of 100 representing blood-brain barrier permeability equal to that for iodoantipyrine. The brain-uptake index (mean+/-s.e.m.) was 1.6+/-0.3 for [3H]mannitol (n=5), 90.6+/-4.1 for [3H]devazepide (n=7, P<0.001 compared with mannitol) and 3.5+/-0.7 for [3H]A-65186 (n=4, P > 0.05 compared with mannitol, P < 0.001 compared with devazepide). Thus, devazepide readily penetrated the blood-brain barrier whereas A-65186 did not. It is concluded that devazepide and A-65186 are likely to be useful pharmacological tools for determining whether cholecystokinin is acting peripherally or at brain sites beyond the blood-brain barrier to produce satiety or any other function mediated by the type A cholecystokinin receptor.     

胆囊收缩素B受体蛋白在胰腺癌组织中的表达

目的 探讨胆囊收缩素B受体(CCKB)在人正常组织及胰腺癌组织中的表达.方法 运用免疫组化染色法检测CCKB受体在20例胰腺癌组织和4例正常胰腺组织中的表达与病理分级之间的关系.结果 20例胰腺癌组织中CCKB受体有15例呈阳性表达,阳性表达率为75%,4例正常人胰腺组织CCKB受体全部呈阴性表达.不同病理学分级各组间CCKB受体阳性表达率无显著性差异(P均＞0.05).结论 CCKB受体可能在肿瘤的发生发展过程中起一定的作用,也可用作胰腺癌临床诊断的有效生物学标志,并为胰腺癌的临床治疗提供了有效的靶受体.     

Development of peptide 3D structure mimetics: rational design of novel peptoid cholecystokinin receptor antagonists

The two hormones cholecystokinin and gastrin share the same C-terminal sequence of amino acids, namely Gly(29)-Trp(30)-Met(31)-Asp(32)-Phe(33)-NH(2). Nevertheless, this congruence has not precluded using this structure to develop selective ligands for either CCK(1) or CCK(2) receptors. Manipulation of the hydrophobic residues at positions 31 and 33 gave a series of CCK(1) tripeptide antagonists, typified by N-t-BOC-Trp-2-Nal-Asp-2-(phenyl)ethylamide (pK(B) 6.8 +/- 0.3). Molecular modeling was used to identify the bioactive conformation of these CCK(1)-selective compounds and prompted the design of new peptoid structures. We aimed to maintain the conformation of the parent series by exploiting patterns of hydrogen-bonding and pi-stacking interactions present in the original molecule, rather than introducing additional covalent bonds. The prototype, N-(succinyl-D-Asp-2-phenylethylamido)-L-Trp-2-(2-naphthyl)ethylami de, was a potent and selective CCK(1) antagonist (pK(B) 7.2 +/- 0.3). Furthermore, the new series showed patterns of biological activity that mirrored those of the parent tripeptides. These compounds contain elements of both peptide primary and secondary structure and represent a novel approach to designing peptidomimetics. Interesting results were obtained from comparing models of a representative tripeptide CCK(1) antagonist with a conformation of CCK(30)(-)(33) that others have proposed to be responsible for its activity at the CCK(2) receptor. The results suggest that CCK(1) and CCK(2) receptors recognize enatiomeric dispositions of the Trp(30) indole, Asp(32) carboxylic acid, and C-terminal phenyl groups arrayed about a common backbone configuration. This "functional chirality" may underpin the mechanism by which these closely related receptor systems bind CCK(30)(-)(33) and explain patterns of selectivity observed with optical isomers of a number of peptoid and nonpeptide ligands.     

Structure of cholecystokinin receptor binding sites and mechanism of activation/inactivation by agonists/antagonists

Delineation of CCK receptor binding sites is a prerequisite for the understanding of the molecular basis for ligand recognition, partial agonism, ligand-induced traffiking of receptor signalling. In the current paper, we illustrate how, in the past 5 years, studies from our laboratory and others have provided new data on the molecular basis of the pharmacology and functioning of CCK1 and CCK2 receptors. Available data on CCK1 and CCK2R binding sites indicate that 1) homologous regions of the two receptors are involved in the binding site of CCK, however, positioning of CCK slightly differs; 2) binding sites of non-peptide agonists/antagonist are buried in the pocket formed by transmembrane helices and overlap that of CCK and 3) residues of the binding sites as well as of conserved motifs such as E/DRY, NPXXY are crucial for receptor activation.     

Involvement of cholecystokinin within craving for cocaine: role of cholecystokinin receptor ligands

In the brain, cholecystokinin (CCK) has been described to act as a central neurotransmitter or neuromodulator involved in functions such as food consumption, stress and anxiety. Recently, the CCK system has been involved in drug dependence phenomena and proposed to be correlated to a putative state of ‘drug preferring’ phenotype within free choice tests. CCK exerts its action in the CNS through at least two different G-protein coupled high affinity receptors, CCK1 and CCK2. Various selective CCK receptor agonists and antagonists have been synthesised. In particular, L-364,718 has been demonstrated to be a potent and selective CCK1 receptor antagonist, whereas L-365,260 is a potent and selective CCK2 receptor antagonist. More recently, GV150013 has been reported to be a highly selective CCK2 receptor antagonist. This paper reviews the putative role of the CCK system within drug dependence phenomena. In particular, it analyses the relationship between central CCK activity and the exhibition of spontaneous preference for drugs of abuse, such as cocaine or alcohol. The potential therapeutic role for CCK receptor antagonists is also discussed.     

Involvement of cholecystokinin within craving for cocaine: role of cholecystokinin receptor ligands

In the brain, cholecystokinin (CCK) has been described to act as a central neurotransmitter or neuromodulator involved in functions such as food consumption, stress and anxiety. Recently, the CCK system has been involved in drug dependence phenomena and proposed to be correlated to a putative state of 'drug preferring' phenotype within free choice tests. CCK exerts its action in the CNS through at least two different G-protein coupled high affinity receptors, CCK1 and CCK2. Various selective CCK receptor agonists and antagonists have been synthesised. In particular, L-364,718 has been demonstrated to be a potent and selective CCK1 receptor antagonist, whereas L-365,260 is a potent and selective CCK2 receptor antagonist. More recently, GV150013 has been reported to be a highly selective CCK2 receptor antagonist. This paper reviews the putative role of the CCK system within drug dependence phenomena. In particular, it analyses the relationship between central CCK activity and the exhibition of spontaneous preference for drugs of abuse, such as cocaine or alcohol. The potential therapeutic role for CCK receptor antagonists is also discussed.     

New anthranilic acid based antagonists with high affinity and selectivity for the human cholecystokinin receptor 1 (hCCK1-R)

The anthranilic acid diamides represent the most recent class of nonpeptide CCK(1) receptor (CCK(1)-R) antagonists. Herein we describe the second phase of the anthranilic acid C-terminal optimization using nonproteinogenic amino acids containing a phenyl ring in their side chain. The Homo-Phe derivative 2 (VL-0797) enhanced 12-fold the affinity for the rat CCK(1)-R affinity and 15-fold for the human CCK(1)-R relative to the reference compound 12 (VL-0395). The eutomer of 2 (6) exhibited a nanomolar range affinity toward the human CCK(1)-R and was at least 400-fold selective for the CCK(1)-R over the CCK(2)-R. Molecular docking in the modeled CCK(1)-R and its validation by site-directed mutagenesis experiments showed that the 6 binding site overlaps that occupied by the C-terminal bioactive region of the natural agonist CCK. Owing to their interesting properties, new compounds provided by this study represent a solid basis for further advances aimed at synthesis of clinically valuable CCK(1)-R antagonists.     

Quantitative structure-activity relationship studies on cholecystokinin antagonists.

A review is presented on quantitative structure-activity relationship (QSAR) studies on cholecystokinin antagonists. Cholecystokinin (CCK) is a gastrointestinal peptide hormone closely related chemically to gastrin. However, its receptors are found in both peripheral and central nervous systems. Those present in peripheral system have been termed as CCK-A receptors and those present in central nervous system as CCK-B receptors. QSAR studies verify that CCK-B receptors are closely related structurally to gastrin receptors. QSAR studies have been reported on different classes of CCK antagonists, e.g., benzodiazepine derivatives, amino acid derivatives, quinazolinones, and peptides and pseudopeptide analogs. These QSAR studies unravel the mechanisms of interactions of each category of antagonists with the CCK receptors. In the case of benzodiazepines, the hydrophobic interactions and hydrogen bondings are found to be the most important binding force, while in the case of quinazolinones, only the hydrogen bonding is found to be important. The hydrophobic as well as the dispersion interactions are shown to be important for the binding of glutamic acid analogs and steric factors appear to govern the activity of peptides and pseudopeptide analogs.     

Affinity of serotonin receptor antagonists and agonists to recombinant and native alpha1-adrenoceptor subtypes.

Binding affinities of serotonin (5-HT)-receptor antagonists and agonists at human recombinant alpha1-adrenoceptor subtypes (alpha1a-, alpha1b- and alpha1d-subtypes) were examined and compared with the functional affinities obtained in rat caudal artery (alpha1A-subtype), dog carotid artery (alpha1B-subtype) and rat thoracic aorta (alpha1D-subtype). Most of the 5-HT-receptor antagonists and agonists tested showed relatively high affinity to three alpha1-adrenoceptor subtypes. The highest affinity close to 1 nM was seen for NAN-190 (5-HT1A antagonist) in binding and functional studies. 5-Methylurapidil (5-HT1A agonist) and BMY7378 (5-HT1A agonist) showed, respectively, alpha1a(alpha1A)- or alpha1d(alpha1D)-subtype selectivity in both binding and functional affinities, but spiperone (5-HT2A antagonist) showed alpha1b-selectivity only in binding affinity. Functional affinity of ritanserin (5-HT2A antagonist) to the alpha1B-subtype was approximately 500-fold lower than that of affinity to the alpha1b-subtype. The present results show that many 5-HT-receptor antagonists and agonists have high affinity to alpha1-adrenoceptors, but suggest that there is deviation between their functional affinities and binding affinities for some drugs.     

Combined dose-ratio analysis of cholecystokinin receptor antagonists, devazepide, lorglumide and loxiglumide in the guinea-pig gall bladder.

1. Interactions between cholecystokinin octapeptide (CCK-8) and CCKA-receptor antagonists derived from benzodiazepines (devazepide) and glutamic acid (lorglumide and loxiglumide) have been examined in an improved bioassay using the guinea-pig, isolated, gall bladder preparation. 2. The presence of CCKB-receptors in the assay was provisionally-ruled out on the basis of the low potency of pentagastrin in the assay. By applying analyses of both agonism and antagonism, pentagastrin was shown to behave as a partial agonist at the CCKA-receptor. 3. Devazepide, lorglumide and loxiglumide behaved as simple competitive antagonists of CCKA-receptors and pKB values of 9.98, 7.59 and 7.07 were estimated, respectively. 4. Application of a combined dose-ratio analysis to the interactions between CCK-8 and combinations of devazepide/lorglumide and devazepide/loxiglumide indicated that these molecules behave as syntopic, competitive, antagonists at the CCKA-receptor. 5. We conclude that the guinea-pig gall bladder assay contains a homogeneous population of CCKA-receptors and offer an explanation for the differences between our results and those obtained recently by Maubach et al. (1991) which were taken as preliminary evidence for CCKA-receptor heterogeneity.     

AMPA receptor antagonists for the treatment of stroke

Signal transduction via ionotropic glutamate receptors is found in many life forms, from protozoa to mammals. Glutamate is the main excitatory neurotransmitter in the mammalian CNS, were fast postsynaptic depolarisation is induced by the activation of AMPA (alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid) receptors. In addition to their important physiological role, excessive AMPA receptor stimulation is also a hallmark of excitotoxicity-related diseases, like ischaemic stroke. Conversely, AMPA receptor inhibitors were proposed to be useful neuroprotective drugs. First generation AMPA receptor blockers were competitive antagonists, like NBQX, which showed robust neuroprotection in a variety of disease-related animal models. Its clinical use, however, was restricted by the very low solubility, inducing kidney precipitaton in vivo. Second generation competitive antagonists are available, which do not possess this property. None of those, however, up to now is in clinical use. Competitive AMPA receptor antagonists are not the first choice for neuroprotective drugs, since due to receptor kinetics they preferently suppress the physiological relevant component of the postsynaptic glutamate response. Non-competitive blockers, like 2,3-benzodiazepines or the novel neuroprotectant BIIR 561 should be suited better for the treatment of stroke. The latter compound is also described as blocker of voltage-gated sodium channels. Targetting more than one mechanism in the excitotoxicity cascade might be a fruitful approach for the development of neuroprotective drugs.