Abstract
Amiloride is a small molecule diuretic, which has been used to dissect sodium transport pathways in many different systems. This drug is known to interact with the epithelial sodium channel and acid-sensing ion channel proteins, as well as sodium/hydrogen antiporters and sodium/calcium exchangers. The exact structural basis for these interactions has not been elucidated as crystal structures of these proteins have been challenging to obtain, though some involved residues and domains have been mapped. This work examines the interaction of amiloride with acid-sensing ion channel-1, a protein whose structure is available using computational and experimental techniques. Using molecular docking software, amiloride and related molecules were docked to model structures of homomeric human ASIC-1 to generate potential interaction sites and predict which analogs would be more or less potent than amiloride. The predictions made were experimentally tested using whole-cell patch clamp. Drugs previously classified as NCX or NHE inhibitors are shown to also inhibit hASIC-1. Potential docking sites were re-examined against experimental data to remove spurious interaction sites. The voltage sensitivity of inhibitors was also examined. Using the aggregated data from these computational and experimental experiments, putative interaction sites for amiloride and hASIC-1 have been defined. Future work will experimentally verify these interaction sites, but at present this should allow for virtual screening of drug libraries at these putative interaction sites.
Highlights
Amiloride is a small molecule best known for its ability to inhibit channels formed by the epithelial sodium channel (ENaC)2/degenerin (Deg) family of proteins [1]
This study focuses on the interactions of hASIC-1 and hASIC-3 with amiloride in order to define binding pockets for future inhibitor studies
The interaction of amiloride with the ENaC/Deg proteins has been studied extensively because they were elucidated as the target of this sodium channel inhibitor [1]
Summary
Template Structures—The work of Gouaux’s group described the structure of Gallus gallus ASIC-1 arranged to form a homomeric channel, available as PDB ID 2QTS and PDB ID 3HGC [16, 17]. The scripts used for modeling, in addition to adding support for the chloride ions, increased the thoroughness of the default optimization protocol. Ments, NaCl was replaced with N-methyl-D-glucamine, and NIH SAVES results are shown in supplemental Table S1 for the calcium was omitted to create a high Naϩ solution with 10 mM individual models and the template molecules. N-methyl-D-glucamine/120 mM NaCl and a low Naϩ solution Small Molecule Docking to hASIC-1 Models—Small molewith 120 mM N-methyl-D-glucamine/10 mM NaCl. Cells were cules were blind docked, screening the flexible ligands against held at Ϫ60 mV and pH 6.0 pulses of 3-s duration were applied the entirety of the rigid protein models. Data are energy for the remaining poses for each drug was computed and presented as averages Ϯ S.D. as calculated by Excel 2007.
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