Relationships between chemical structure and affinity for acetylcholine receptors

1 . Series of analogues of acetylcholine have been prepared in which the acetyl group was replaced by phenylacetyl, cyclohexylacetyl, diphenylacetyl, dicyclohexylacetyl, (±)‐phenylcyclohexylacetyl, benziloyl and (±)‐phenyl‐cyclohexylhydroxyacetyl groups and the trimethylammonium group was replaced b...

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Published in:British journal of pharmacology 1969-09, Vol.37 (1), p.207-233
Main Authors: ABRAMSON, F. B., BARLOW, R. B., MUSTAFA, M. G., STEPHENSON, R. P.
Format: Article
Language:English
Subjects:
Acetylcholine - pharmacology
Animals
Binding Sites
Chemical Phenomena
Chemistry
Cyclohexanes - pharmacology
Guinea Pigs
Ileum - drug effects
In Vitro Techniques
Parasympatholytics - pharmacology
Parasympathomimetics - pharmacology
Quaternary Ammonium Compounds - pharmacology
Receptors, Drug
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Summary:1 . Series of analogues of acetylcholine have been prepared in which the acetyl group was replaced by phenylacetyl, cyclohexylacetyl, diphenylacetyl, dicyclohexylacetyl, (±)‐phenylcyclohexylacetyl, benziloyl and (±)‐phenyl‐cyclohexylhydroxyacetyl groups and the trimethylammonium group was replaced by Me2EtN+, MeEt2N+, Et3N+, Further series were prepared in which the acetoxyethyl group was replaced by ethoxyethyl, phenylethoxyethyl, cyclohexylethoxyethyl, diphenylethoxyethyl, and dicyclohexylethoxyethyl groups, and by n‐pentyl, 5‐phenylpentyl, 5‐cyclohexylpentyl and 5:5‐diphenylpentyl groups. 2 . The ethoxyethyl and n‐pentyl series contain some compounds which are agonists or partial agonists when tested on the isolated guinea‐pig ileum, but all the other compounds are antagonists. 3 . The affinity of the compounds for the postganglionic (“muscarine‐sensitive”) acetylcholine receptors has been measured in conditions in which the antagonists have been shown to be acting competitively. There were considerable differences between their affinities, the most active (log K, 9.8) having one million times the affinity of the least active (log K, 3.7). 4 . The changes in affinity as the onium group was modified were not entirely independent of changes in the rest of the molecule. Increasing the size of the onium group, as judged from conductivity measurements on simpler onium salts, increased affinity in the series containing one large group (phenyl or cyclohexyl) but, in the series with two large groups, affinity declined when the size was increased beyond ‐N+MeEt2. 5 . In general, the effects of changes in the rest of the molecule on affinity were bigger than the effects of changes in the onium group and there were bigger interactions. Affinity was increased to a greater extent by introducing one phenyl and one cyclohexyl group together than by introducing either two phenyl or two cyclohexyl groups; the increment was greater than the separate contributions made by one phenyl and one cyclohexyl group. 6 . The factors which influence the binding of molecules to receptors are discussed. There is no evidence that the separation between the onium group and the group in the receptor with which it interacts is greater in compounds with high affinity nor is there any evidence, from the study of the series which contain agonists and partial agonists, that ability to activate receptors depends upon the onium group being able to come close to this charged group in the recept
ISSN:0007-1188
1476-5381
DOI:10.1111/j.1476-5381.1969.tb09539.x