A1 Refereed original research article in a scientific journal
Determination of binding site residues responsible for the subunit selectivity of novel marine-derived compounds on kainate receptors
Authors: Sanders JM, Pentikainen OT, Settimo L, Pentikainen U, Shoji M, Sasaki M, Sakai R, Johnson MS, Swanson GT
Publisher: AMER SOC PHARMACOLOGY EXPERIMENTAL THERAPEUTICS
Publication year: 2006
Journal: Molecular Pharmacology
Journal name in source: MOLECULAR PHARMACOLOGY
Journal acronym: MOL PHARMACOL
Volume: 69
Issue: 6
First page : 1849
Last page: 1860
Number of pages: 12
ISSN: 0026-895X
DOI: https://doi.org/10.1124/mol.106.022772
Abstract
Dysiherbaine (DH) and related molecules are high-affinity, subunit-selective kainate receptor (KAR) ligands originally isolated from a marine sponge. To elucidate why DH, an agonist, and MSVIII-19, a competitive antagonist, bind selectively to glutamate receptor (GluR) 5 but not to the KA2 KAR subunit, we used molecular dynamics simulations to generate binding models that were tested experimentally in radioligand binding and electrophysiological assays. Three candidate sites, Val685, Leu735, and Ser741 in GluR5, corresponding to Ile669, Phe719, and Met725 in KA2, were predicted to underlie the distinct binding profiles of the marine toxins. Single or multiple reciprocal mutations introduced into the receptor subunits produced a variety of effects on binding affinity. Most notably, mutation of Met725 to serine in KA2 increased the affinity of DH by 350-fold; in contrast, mutation of one or more of the residues in GluR5 did not markedly alter DH binding. MSVIII-19 affinity for the KA2 subunit was significantly increased in multiple site mutants, and reciprocal mutations in the GluR5 subunit produced substantial (700-fold) reductions in MSVIII-19 affinity. Physiological characterization of the double- and triple-mutant subunits demonstrated altered functional behavior consistent with the changes in binding affinity. The results provide experimental support for the importance of these three ligand binding domain (LBD) residues and suggest steric hindrance in the KA2 subunit LBD is largely responsible for the very low affinity for the two compounds. In this study, we identified the molecular basis for subunit selectivity of these marine-derived molecules on KARs, which could facilitate the rational design of selective ligands with distinct pharmacological profiles.
Dysiherbaine (DH) and related molecules are high-affinity, subunit-selective kainate receptor (KAR) ligands originally isolated from a marine sponge. To elucidate why DH, an agonist, and MSVIII-19, a competitive antagonist, bind selectively to glutamate receptor (GluR) 5 but not to the KA2 KAR subunit, we used molecular dynamics simulations to generate binding models that were tested experimentally in radioligand binding and electrophysiological assays. Three candidate sites, Val685, Leu735, and Ser741 in GluR5, corresponding to Ile669, Phe719, and Met725 in KA2, were predicted to underlie the distinct binding profiles of the marine toxins. Single or multiple reciprocal mutations introduced into the receptor subunits produced a variety of effects on binding affinity. Most notably, mutation of Met725 to serine in KA2 increased the affinity of DH by 350-fold; in contrast, mutation of one or more of the residues in GluR5 did not markedly alter DH binding. MSVIII-19 affinity for the KA2 subunit was significantly increased in multiple site mutants, and reciprocal mutations in the GluR5 subunit produced substantial (700-fold) reductions in MSVIII-19 affinity. Physiological characterization of the double- and triple-mutant subunits demonstrated altered functional behavior consistent with the changes in binding affinity. The results provide experimental support for the importance of these three ligand binding domain (LBD) residues and suggest steric hindrance in the KA2 subunit LBD is largely responsible for the very low affinity for the two compounds. In this study, we identified the molecular basis for subunit selectivity of these marine-derived molecules on KARs, which could facilitate the rational design of selective ligands with distinct pharmacological profiles.
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