Novel long‐acting antagonists of muscarinic ACh receptors

Acetylcholine (ACh), the first neurotransmitter to be identified 1 , exerts many of its physiological actions via activation of a family of G protein-coupled receptors (GPCRs) known as muscarinic ACh receptors (mAChRs). Although the five mAChR subtypes (M1-M5) share a high degree of sequence homology, they show pronounced differences in G protein coupling preference and the physiological responses they mediate. 2–4 Unfortunately, despite decades of effort, no therapeutic agents endowed with clear mAChR subtype selectivity have been developed to exploit these differences. 5–6 We describe here the structure of the Gq/11-coupled M3 mAChR bound to the bronchodilator drug tiotropium and identify the binding mode for this clinically important drug. This structure, together with that of the Gi/o-coupled M2 receptor, offers new possibilities for the design of mAChR subtype-selective ligands. Importantly, the M3 receptor structure allows the first structural comparison between two members of a mammalian GPCR subfamily displaying different G-protein coupling selectivities. Furthermore, molecular dynamics simulations suggest that tiotropium binds transiently to an allosteric site en route to the binding pocket of both receptors. These simulations offer a structural view of an allosteric binding mode for an orthosteric GPCR ligand and raise additional opportunities for the design of ligands with different affinities or binding kinetics for different mAChR subtypes. Our findings not only offer new insights into the structure and function of one of the most important GPCR families, but may also facilitate the design of improved therapeutics targeting these critical receptors.

The parasympathetic limb of the autonomic nervous system regulates the activity of multiple organ systems. Muscarinic receptors are G protein coupled receptors (GPCRs) that mediate the response to acetylcholine released from parasympathetic nerves. 1–5 Their role in the unconscious regulation of organ and central nervous system function makes them potential therapeutic targets for a broad spectrum of diseases. The M2 muscarinic acetylcholine receptor (M2 receptor) is essential for the physiologic control of cardiovascular function through activation of G protein-coupled inwardly-rectifying potassium channels, and is of particular interest because of its extensive pharmacological characterization with both orthosteric and allosteric ligands. Here we report the structure of antagonist-bound M2 receptor, the first human acetylcholine receptor to be characterized structurally. The antagonist QNB binds in the middle of a long aqueous channel extending approximately two-thirds through the membrane. The orthosteric binding pocket is formed by amino acids that are identical in all 5 muscarinic receptor subtypes, and shares structural homology with other functionally unrelated acetylcholine binding proteins from different species. A layer of tyrosine residues forms an aromatic cap restricting dissociation of the bound ligand. A binding site for allosteric ligands has been mapped to residues at the entrance to the binding pocket near this aromatic cap. The M2 receptor structure provides insights into the challenges of developing subtype-selective ligands for muscarinic receptors and their propensity for allosteric regulation.

Scopolamine is used as a standard/reference drug for inducing cognitive deficits in healthy humans and animals. Effects are often interpreted in terms of a role of acetylcholine in mnemonic and/or attentional processes. In this paper an overview is given of the effects of scopolamine on animal behavior. Examination of the dose-response curve of systemically administered scopolamine indicates that sensory discrimination and attention are most sensitive to disruption. When higher doses (>0.03mg/kg) are used, deficits in other cognitive and non-cognitive functions (e.g., learning and memory, locomotor activity) are reported. Several behavioral processes (taste aversion, anxiety, short-term memory, attention) are found to be affected after intracerebral injections of scopolamine. It is concluded that effects on learning and memory performance which are observed after higher doses of scopolamine are mediated by (1) primary effects on attention and sensory/stimulus discrimination, (2) non-specific effects on behavior (e.g., locomotor activity, anxiety), and (3) peripheral side-effects (e.g., pupil dilation, salivation). Finally, the validity of scopolamine as a pharmacological model for cognitive impairment is discussed. The use of muscarinic M1 antagonists is suggested as a more selective and effective way of inducing cholinergic-induced cognitive deficits.