Abstract
Voltage-gated sodium (NaV) channels generate and propagate action potentials in excitable cells, and several NaV subtypes have become important targets for pain management. The μ-conotoxins inhibit subtypes of the NaV with varied specificity but often lack of specificity to interested subtypes. Engineering the selectivity of the μ-conotoxins presents considerable complexity and challenge, as it involves the optimization of their binding affinities to multiple highly conserved NaV subtypes. In this study, a model of NaV1.4 bound with μ-conotoxin PIIIA complex was constructed using homology modeling, docking, molecular dynamic simulations and binding energy calculations. The accuracy of this model was confirmed based on the experimental mutagenesis data. The complex models of PIIIA bound with varied subtypes of NaV1.x (x = 1, 2, 3, 5, 6, 7, 8, or 9) were built using NaV1.4/PIIIA complex as a template, and refined using molecular dynamic simulations. The binding affinities of PIIIA to varied subtypes of NaV1.x (x = 1 to 9) were calculated using the Molecular Mechanics Generalized Born/Surface Area (MMGB/SA) and umbrella sampling, and were compared with the experimental values. The binding affinities calculated using MMGB/SA and umbrella sampling are correlated with the experimental values, with the former and the latter giving correlation coefficient of 0.41 (R2) and 0.68 (R2), respectively. Binding energy decomposition suggests that conserved and nonconserved residues among varied NaV subtypes have a synergistic effect on the selectivity of PIIIA.
Highlights
The μ-conotoxins are short snail peptide toxins targeting subtypes of NaVVoltage-gated sodium (NaV) and are considered as important drug leads
Prediction of the Binding Mode of the PIIIA at NaV 1.4 μ-Conotoxin PIIIA was positioned on the pore surface of the extracellular domain of NaV 1.4 based on docking
The PIIIA was positioned at the surface of the NaV 1.4 with varied conformations (Figure S2A,B)
Summary
The μ-conotoxins are short snail peptide toxins targeting subtypes of NaV and are considered as important drug leads. The first step for engineering the specificity of μ-conotoxins is understanding of the molecular interaction mechanism between the μ-conotoxins and varied subtypes of the NaV. Accurate determination of the molecular determinants that confer the specificity of the μ-conotoxin PIIIA to different NaV subtypes is essential for further engineering the specificity of the μ-conotoxins for therapeutic purposes. Voltage-gated sodium (NaV ) channels play important roles in cell excitability and mediation of the ionic conductance through the cells [1,2,3]. Members of the NaV channel family are classified. Mar. Drugs 2018, 16, 153; doi:10.3390/md16050153 www.mdpi.com/journal/marinedrugs
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