Mapping of ligand binding sites of the cholecystokinin-B/gastrin receptor with lipo-gastrin peptides and molecular modeling

Lutz, Jürgen; Romano-Götsch, Roberta; Escrieut, Chantal; Fourmy, Daniel; Mathä, Barbara; Müller, Gerhard; Kessler, Horst; Moröder, Luis

doi:10.1002/(sici)1097-0282(199706)41:7<799::aid-bip8>3.0.co;2-k

Cited by 19 publications

(66 citation statements)

References 71 publications

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“…Instead, the structure assumed by CCK-8 in the presence of DPC micelles is the one that binds to the N-terminal receptor fragment. This observation is in agreement with the theory of a membrane-bound pathway for the interaction of peptide hormones with their G-protein coupled receptors (51,(59)(60)(61)(62). This hypothesis states that the ligand first interacts with the membrane, inducing the peptide to adopt a specific conformation, and then through a two-dimensional translation, the peptide hormone interacts with the extracellular portion of the receptor.…”

Section: Discussionsupporting

confidence: 92%

Molecular Complex of Cholecystokinin-8 and N-Terminus of the Cholecystokinin A Receptor by NMR Spectroscopy

1999

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The bimolecular complex of the C-terminal octapeptide of cholecystokinin, CCK-8, with the N-terminus of the CCK(A)-receptor, CCK(A)-R(1-47), has been structurally characterized by high-resolution NMR and computational refinement. The conformation of CCK(A)-R(1-47), within the lipid environment used for the spectroscopic studies, consists of a well-defined alpha-helix (residues 3-9) followed by a beta-sheet stabilized by a disulfide linkage between C18 and C29, leading to the first transmembrane alpha-helix (TM1). Titration of CCK(A)-R(1-47) with CCK-8 specifically affects the NMR signals of W39 of the receptor, in a saturable fashion. This association is specific for CCK-8; no association was observed upon titration of CCK(A)-R(1-47) with other peptide hormones. The ligand/receptor complex was characterized by intermolecular NOEs between Tyr(27) and Met(28) of CCK-8 and W39 of CCK(A)-R(1-47). These findings suggest that CCK-8 binds to CCK(A) with the C-terminus within the seven-helical bundle and the N-terminus of the ligand, projecting out between TM1 and TM7, forming specific interactions with the N-terminus of the CCK(A) receptor. This mode of ligand binding, consistent with published mutagenesis studies, requires variation of the interpretation of recent findings from photoaffinity cross-linking studies.

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Section: Discussionsupporting

confidence: 92%

Molecular Complex of Cholecystokinin-8 and N-Terminus of the Cholecystokinin A Receptor by NMR Spectroscopy

1999

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“…An elegant example has been provided by the fatty acid-substituted nonapeptide fragments of cholecystokinin (CCK-9) [46,47] (Figure 2A). Provided that their hydrocarbon tail is sufficiently long, the synthetic constructs become permanently stuck in the membrane.…”

Section: Participation Of the Membrane In The Binding Processmentioning

confidence: 99%

Cell membranes… and how long drugs may exert beneficial pharmacological activity in vivo

Vauquelin

2016

Brit J Clinical Pharma

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The time course of the beneficial pharmacological effect of a drug has long been considered to depend merely on the temporal fluctuation of its free concentration. Only in the last decade has it become widely accepted that target-binding kinetics can also affect in vivo pharmacological activity. Although current reviews still essentially focus on genuine dissociation rates, evidence is accumulating that additional micro-pharmacokinetic (PK) and -pharmacodynamic (PD) mechanisms, in which the cell membrane plays a central role, may also increase the residence time of a drug on its target. The present review provides a compilation of otherwise widely dispersed information on this topic. The cell membrane can intervene in drug binding via the following three major mechanisms: (i) by acting as a sink/repository for the drug; (ii) by modulating the conformation of the drug and even by participating in the binding process; and (iii) by facilitating the approach (and rebinding) of the drug to the target. To highlight these mechanisms, we focus on drugs that are currently used in clinical therapy, such as the antihypertensive angiotensin II type 1 receptor antagonist candesartan, the atypical antipsychotic agent clozapine and the bronchodilator salmeterol. Although the role of cell membranes in PK-PD modelling is gaining increasing interest, many issues remain unresolved. It is likely that novel biophysical and computational approaches will provide improved insights in the near future. IntroductionThe pharmacokinetic (PK) and pharmacodynamic (PD) properties of a drug are determinants of its efficacy and the duration of its clinical action [1]. PK and PD have long been considered to be separate disciplines, and the time course of the pharmacological effect of a drug has essentially been considered in terms of the temporal fluctuation of its free concentration [2]. In accordance with this principle, the frequently observed time lag between the concentration of a drug in the systemic circulation and its effect was initially attributed to slow equilibration between the plasma and a hypothetical target-surrounding 'effect compartment' [3]. By contrast, preclinical screening studies traditionally aim to optimize drug candidates in terms of only their efficacy and potency (i.e. PD properties). Inherent to this practice is the proposal that drug-target interactions are adequately described by equilibrium equations and, hence, that association and dissociation rates play only subordinate roles. In addition to a few noteworthy exceptions [4,5], it is only in the last decade that it has become fashionable to include binding kinetics as an additional criterion for clinical efficacy. This insight was largely sparked by the seminal articles by Swinney [6] and Copeland et al. [7]. The numerous review articles that have been published subsequently have focused mainly on long residence times. This property is now recognized to play a key role with respect to the clinical British Journal of Clinical Pharmacology Br J Clin Pharmacol (2016...

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“…E) The 'exosite' hypothesis model stipulates that part of the ligand binds very tightly to an 'exosite' that is located at the interface between the lipid's hydrocarbon chains and the receptor. This allows the 'active' part of the ligand to reach its binding site by pivoting between the receptor's TM domains (left side) [49,61,73] or its extracellular loops (for larger peptides, right side) [70,71]. F) The ability of ligand molecules to undergo several binding--unbinding sequences with the same receptor or those nearby before drifting away (a phenomenon referred to as 'rebinding' [6,16,80]) could be favored if they reach their receptor faster via a random 2D route in the membrane than via a 3D random walk in solution [75][76][77].…”

Section: Membranes Act As a Repositorymentioning

confidence: 99%

“…The first mode of approach by this hydrophilic region has been elegantly illustrated with fatty acid-substituted nonapeptide fragments of cholecsystokinin (CCK-9) [70,71]. While the initial elongation of the fatty acid decreased the affinity of these constructs for their receptor, the decrease stalled upon further elongation from the moment on that the fatty acid moiety could no longer escape from the membrane.…”

Section: Membranes Act As a Repositorymentioning

confidence: 99%

On the ‘micro’-pharmacodynamic and pharmacokinetic mechanisms that contribute to long-lasting drug action

Vauquelin

2015

Expert Opinion on Drug Discovery

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The PK profile, as well as the target dissociation kinetics of a drug, may fail to account for its long-lasting efficiency in intact tissues and in vivo. This lacuna could potentially be alleviated by incorporating some of the enumerated 'microscopic' mechanisms and, to unveil them, dedicated experiments on sufficiently physiologically relevant biological material like cell monolayers can already be implemented early on in the lead optimization process.

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Mapping of ligand binding sites of the cholecystokinin-B/gastrin receptor with lipo-gastrin peptides and molecular modeling

Cited by 19 publications

References 71 publications

Molecular Complex of Cholecystokinin-8 and N-Terminus of the Cholecystokinin A Receptor by NMR Spectroscopy

Molecular Complex of Cholecystokinin-8 and N-Terminus of the Cholecystokinin A Receptor by NMR Spectroscopy

Cell membranes… and how long drugs may exert beneficial pharmacological activity in vivo

On the ‘micro’-pharmacodynamic and pharmacokinetic mechanisms that contribute to long-lasting drug action

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