Modulation of the structure-binding relationships of antagonists for muscarinic acetylcholine receptor subtypes

Abstract

1 Membranes from rat cerebral cortex, myocardium and extraorbital lacrimal gland were used as sources of M₁ M₂ and M₃ muscarinic acetylcholine receptors respectively and the affinities of seven antagonists for the three subtypes were examined under different experimental conditions. 2 The affinities for the membrane-bound receptors were measured at different ionic strengths and temperatures and compared with those determined on the receptor solubilised in the neutral detergent digitonin or the zwitterionic detergent, CHAPSO. 3 The range of measured affinity constants of a given antagonist for a specific subtype varied from 2 (atropine at M₁ receptors) to 1000 (AF-DX 116 at M₂ receptors). 4 As a consequence of these changes in affinity, which were dependent on the drug, the subtype and the experimental conditions, both the structure-binding relationships of a given subtype can be markedly changed as well as the selectivity of a drug for the different subtypes. For example it is possible to change the relative affinities of AF-DX 116 and gallamine at membrane-bound M₁ receptors from 50:1 to 1:60. 5 Experimental conditions for the observation of high selectivity of pirenzepine, AF-DX 116, gallamine and hexahydrosiladiphenidol for the three subtypes are given. 6 When the receptors are removed from their membrane environment by solubilisation in detergent, antagonist affinities are changed but the subtypes still retain different structure-binding relationships. 7 In general, AF-DX 116 and the allosteric antagonist, gallamine, behave differently from the other antagonists, suggesting that they bind in different ways to muscarinic receptors. 8 Careful attention should therefore be paid to the experimental conditions in binding assays used to assess the affinities and selectivities of new muscarinic antagonists in order to avoid misleading results. 9 The ability to produce enhanced or attenuated affinities and selectivities of antagonists, resulting from the induction of different conformations of the receptor by a variety of physical, chemical or molecular biological perturbations may lead to a better understanding of the structural basis of drug receptor interactions.