Margaret Seidenberg scite author profile

Gallamine allosterically modulates the binding of classical muscarinic ligands with a potency order of M(2) > M(1),M(4) > M(3), M(5). We have suggested previously that the M(2)/M(5) and M(2)/M(3) selectivities are attributable to an epitope in the sixth transmembrane region or third outer loop (o3) region of the receptor. In this study, analysis of numerous point mutations in this region of the M(5) receptor found that a mutation of V --> N resulted in an increased affinity toward gallamine, suggesting that the asparagine residue at M(2)(419) is responsible for gallamine's M(2)/M(5) selectivity. Mutations in the other subtypes indicated that the acidic residues found at this position in M(1) and M(4) are associated with slightly higher affinity toward gallamine, whereas the valine and lysine residues of M(5) and M(3), respectively, are associated with significantly lower affinity. In the o2 region, replacement of an acidic sequence of M(2) (EDGE) by the corresponding neutral sequence of M(1) (LAGQ) reduced the affinity toward gallamine, as reported previously by others; the converse substitution of the acidic sequence into M(1) significantly increased affinity for gallamine. Substitution of the M(1) sequence into this region of M(5) markedly reduced affinity toward gallamine, whereas substitution into M(4) had no effect. All of the above mutations are consistent with gallamine binding with a similar orientation at each subtype, such that it interacts with acidic residues in the o2 region of M(3) and M(5) and with acidic residues in the o3 region of M(1) and M(4); gallamine appears to interact with both regions of the M(2) subtype.

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Interactions of Alcuronium, TMB-8, and Other Allosteric Ligands with Muscarinic Acetylcholine Receptors: Studies with Chimeric Receptors

Ellis

Seidenberg

2000

Mol Pharmacol

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A series of ligands that allosterically modulate the binding of classical ligands to muscarinic receptors was evaluated at wild-type and chimeric receptors. All of the ligands studied had highest affinity toward the M(2) subtype and lowest affinity toward the M(5) subtype. The chimeric receptors were mostly M(5) sequence; the amount of M(2) sequence ranged from about 6 to just under 30%. Alcuronium and TMB-8 had much higher affinity for the chimeric receptor that included the M(2) second outer loop of the receptor plus flanking regions of TM4 and TM5 than for any of the other chimeric receptors (the affinities of which remained similar to that of the M(5) subtype). However, this chimera retained the negative cooperativity between alcuronium and the classical antagonist N-methylscopolamine that is characteristic of M(5) (these ligands are positively cooperative at M(2)). Verapamil, tetrahydroaminoacridine, and d-tubocurarine were also sensitive to that chimeric substitution, although verapamil and tetrahydroaminoacridine had even higher affinity for a chimera with M(2) sequence in TM7. None of these ligands shared gallamine's sensitivity to a region of the third outer loop, but studies in which obidoxime reversed the allosteric effects of gallamine and other ligands suggested that they nevertheless compete for a common site. In summary, although the present data are consistent with previous studies that have suggested that allosteric ligands bind to the outermost regions of muscarinic receptors, it appears that different allosteric ligands may derive subtype selectivity from different regions of the receptor.

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Heterotropic Cooperativity within and between Protomers of an Oligomeric M₂Muscarinic Receptor

et al. 2012

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At least four allosteric sites have been found to mediate the dose-dependent effects of gallamine on the binding of [3H]quinuclidinylbenzilate (QNB) and N-[3H]methylscopolamine (NMS) to M2 muscarinic receptors in membranes and solubilized preparations from porcine atria, CHO cells, and Sf9 cells. The rate of dissociation of [3H]QNB was affected in a bell-shaped manner with at least one Hill coefficient (nH) greater than 1, indicating that at least three allosteric sites are involved. Binding of [3H]QNB was decreased in a biphasic manner, revealing at least two allosteric sites; binding of [3H]NMS was affected in a triphasic, serpentine manner, revealing at least three sites, and values of nH greater than 1 pointed to at least four sites. Several lines of evidence indicate that all effects of gallamine were allosteric in nature and observable at equilibrium. The rates of equilibration and dissociation suggest that the receptor was predominately oligomeric, and the heterogeneity revealed by gallamine can be attributed to differences in its affinity for the constituent protomers of a tetramer. Those differences appear to arise from inter- and intramolecular cooperativity between gallamine and the radioligand.

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