Ligand Binding Ensembles Determine Graded Agonist Efficacies at a G Protein-coupled Receptor

Böck, Andreas; Bermudez, Marcel; Krebs, Fabian; Matera, Carlo; Chirinda, Brian; Sydow, Dominique; Dallanoce, Clelia; Holzgrabe, Ulrike; Amici, Marco De; Lohse, Martin J.; Wolber, Gerhard; Mohr, Klaus

doi:10.1074/jbc.m116.735431

Cited by 73 publications

(95 citation statements)

References 70 publications

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“…[5] Such ligands are able to overcome the problem of subtype selectivity for the M 1 subtype by making use of cooperativity in the selective binding and activation of the receptor. [6] To take this concept one step further, dualsteric (or bitopic) ligands are developed herein that covalently connect ah igh-affinity/low-selectivity orthosteric moiety to highly selective allosteric building blocks for concomitant interac- tion with both binding sites.R ecently,o ur groups have reported several sets of dualsteric M 1 and M 2 agonists for which dynamic ligand binding is assumed, leading to partial agonism for the M 1 receptor ( Figure 1) [7] as well as for the M 2 receptor. [8] Based on these findings,d ualsteric ligands hold great potential both as future therapeutics and as pharmacological tools owing to their unprecedented selectivity at Mreceptor subtypes,t heir specificity for signaling pathways ("biased signaling"), their capability for partial agonism, and their potential for studying the process of receptor activation at the molecular level.…”

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confidence: 99%

A Photoswitchable Dualsteric Ligand Controlling Receptor Efficacy

et al. 2017

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The investigation of the mode and time course of the activation of G-protein-coupled receptors (GPCRs), in particular muscarinic acetylcholine (mACh or M) receptors, is still in its infancy despite the tremendous therapeutic relevance of M receptors and GPCRs in general. We herein made use of a dualsteric ligand that can concomitantly interact with the orthosteric, that is, the neurotransmitter, binding site and an allosteric one. We synthetically incorporated a photoswitchable (photochromic) azobenzene moiety. We characterized the photophysical properties of this ligand called BQCAAI and investigated its applicability as a pharmacological tool compound with a set of FRET techniques at the M receptor. BQCAAI proved to be an unprecedented molecular tool; it is the first photoswitchable dualsteric ligand, and its activity can be regulated by light. We also applied BQCCAI to investigate the time course of several receptor activation processes.

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confidence: 99%

A Photoswitchable Dualsteric Ligand Controlling Receptor Efficacy

et al. 2017

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“…Disingrini et al, 2006) We found that these hybrid compounds are characterized by a truly bitopic (orthosteric and allosteric) binding mode (hence the term "dualsteric" ligands), (Antony et al, 2009) as well as other distinctive features when compared to their parent compounds, such as receptor subtype selectivity and biased agonism. (Bock et al, 2016;De Min et al, 2017) We also demonstrated that some of these hybrid compounds display interesting pharmacological properties, (Cristofaro et al, 2018;Riefolo et al, 2019) including remarkable analgesic effects in vivo in mice. Noteworthy, one of these compounds, from now on named Iper-8-N ( Figure 1, compound 8b in the reporting article), even combined the potent antinociceptive activity with the absence of relevant cholinergic side effects.…”

Section: Introductionmentioning

confidence: 79%

Novel Analgesic Agents Obtained by Molecular Hybridization of Orthosteric and Allosteric Ligands

Matera

Flammini

Riefolo

et al. 2019

Preprint

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Despite the high incidence of acute and chronic pain in the general population, the efficacy of currently available medications is unsatisfactory. Insufficient management of pain has a profound impact on the quality of life and can have serious physical, psychological, social, and economic consequences. This unmet need reflects a failure to develop novel classes of analgesic drugs with superior clinical properties and lower risk of abuse. Nevertheless, recent advances in our understanding of the neurobiology of pain are offering new opportunities for developing different therapeutic approaches. Among those, the activation of M2 muscarinic acetylcholine receptors, which play a key role in the cholinergic regulation of the nociceptive transmission, constitutes one of the most promising strategies. We have recently developed a small library of novel pharmacological agents by merging the structures of known orthosteric and allosteric muscarinic ligands through their molecular hybridization, an emerging approach in medicinal chemistry based on the combination of pharmacophoric moieties of different bioactive substances to produce a new compound with improved pharmacological properties. Herein we report the functional characterization of the new ligands in vitro and the assessment of their efficacy as analgesic agents and tolerability in mice. This work provides new insights for the development and optimization of novel muscarinic hybrid compounds for the management of pain.

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“…Atropine either moves out of the M 3 receptor or into the orthosteric site, as is also evident from the on‐rate of atropine which is about 10 times faster than that of tiotropium (Dowling & Charlton, ). Previously, dual binding at both binding sites was described for the M 2 receptor, were one ligand occupied both sites (Bock et al, ). M 2 receptors are not involved in airway smooth muscle contraction, which is solely mediated via M 3 receptors (Roffel et al, ).…”

Section: Discussionmentioning

confidence: 99%

Second M₃ muscarinic receptor binding site contributes to bronchoprotection by tiotropium

Kistemaker

Elzinga

Tautermann

et al. 2019

British J Pharmacology

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Background and Purpose The bronchodilator tiotropium binds not only to its main binding site on the M3 muscarinic receptor but also to an allosteric site. Here, we have investigated the functional relevance of this allosteric binding and the potential contribution of this behaviour to interactions with long‐acting β‐adrenoceptor agonists, as combination therapy with anticholinergic agents and β‐adrenoceptor agonists improves lung function in chronic obstructive pulmonary disease. Experimental Approach ACh, tiotropium, and atropine binding to M3 receptors were modelled using molecular dynamics simulations. Contractions of bovine and human tracheal smooth muscle strips were studied. Key Results Molecular dynamics simulation revealed extracellular vestibule binding of tiotropium, and not atropine, to M3 receptors as a secondary low affinity binding site, preventing ACh entry into the orthosteric binding pocket. This resulted in a low (allosteric binding) and high (orthosteric binding) functional affinity of tiotropium in protecting against methacholine‐induced contractions of airway smooth muscle, which was not observed for atropine and glycopyrrolate. Moreover, antagonism by tiotropium was insurmountable in nature. This behaviour facilitated functional interactions of tiotropium with the β‐agonist olodaterol, which synergistically enhanced bronchoprotective effects of tiotropium. This was not seen for glycopyrrolate and olodaterol or indacaterol but was mimicked by the interaction of tiotropium and forskolin, indicating no direct β‐adrenoceptor–M3 receptor crosstalk in this effect. Conclusions and Implications We propose that tiotropium has two binding sites at the M3 receptor that prevent ACh action, which, together with slow dissociation kinetics, may contribute to insurmountable antagonism and enhanced functional interactions with β‐adrenoceptor agonists.

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Ligand Binding Ensembles Determine Graded Agonist Efficacies at a G Protein-coupled Receptor

Cited by 73 publications

References 70 publications

A Photoswitchable Dualsteric Ligand Controlling Receptor Efficacy

A Photoswitchable Dualsteric Ligand Controlling Receptor Efficacy

Novel Analgesic Agents Obtained by Molecular Hybridization of Orthosteric and Allosteric Ligands

Second M₃ muscarinic receptor binding site contributes to bronchoprotection by tiotropium

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Ligand Binding Ensembles Determine Graded Agonist Efficacies at a G Protein-coupled Receptor

Cited by 73 publications

References 70 publications

A Photoswitchable Dualsteric Ligand Controlling Receptor Efficacy

A Photoswitchable Dualsteric Ligand Controlling Receptor Efficacy

Novel Analgesic Agents Obtained by Molecular Hybridization of Orthosteric and Allosteric Ligands

Second M3 muscarinic receptor binding site contributes to bronchoprotection by tiotropium

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Second M₃ muscarinic receptor binding site contributes to bronchoprotection by tiotropium