Abstract
Scorpion α-toxins are small proteins inhibiting the inactivation of voltage-gated sodium channels. They can selectively act on either mammalian (mammal toxins) or insect channels (insect toxins), or affect both types of channels (α-like toxins). Currently no model has been proposed that fully explains the dependence of selectivity upon amino acid sequence, but some patterns have already been established. Thus, most mammal toxins have an aspartic acid residue in position 8, which is involved in the formation of the nest motif, but it is still not clear whether this residue interacts directly with channels. The objective of our study was to obtain a derivative of the α-like toxin BeM9 with the replacement of lysine in position 8 by glutamate (K8E), changing the charge, but excluding the formation of the nest motif. In addition, we replaced the tyrosine in position 17 with glycine (Y17G), which is characteristic of mammal toxins. Surprisingly, the double-mutant derivative BeM9EG lost its activity on mammalian channels, becoming an insect toxin. To explain these changes, we constructed models of BeM9 and BeM9EG complexes with channels, and also performed molecular dynamics of isolated toxins. Analysis of intermolecular contacts in the complexes did not explain the reason for the selectivity change. Nevertheless, the structure of intramolecular contacts and data on molecular mobility indicate an important role of residues K8 and Y17 in stabilizing a certain conformation of BeM9 loops. We assume that the replacement of these residues allosterically affects the efficiency of toxin binding to channels.
Highlights
At present, novel compounds that can selectively affect targets in insect nervous system, such as voltagegated sodium channels (VGSCs), are being developed
A careful structural analysis of scorpion α-toxins. Corresponding author (α-NaTx) revealed that in mammal toxins this residue preserves a certain conformation of the RT-loop via formation of several hydrogen bonds with –NH groups of the main chain
In this work we tried to clarify the mechanism behind the observed selectivity change of the α-like toxin BeM9 after introducing two substitutions
Summary
Novel compounds that can selectively affect targets in insect nervous system, such as voltagegated sodium channels (VGSCs), are being developed. VGSCs are transmembrane proteins consisting of four homologous repeats (D I–IV). Each repeat comprises a voltage-sensing domain (VSD), which responds to changes in the transmembrane (TM) potential (TM helices S1–S4 and the loops between them). Two other helices (S5 and S6) from all repeats form a single pore domain (PD), which allows selective Na+ permeation through the membrane. Activation of VSDs I–III is necessary to open the PD, whereas activation of VSD IV leads to a fast inactivation of the channels [1, 2]. The so-called “α-toxins” (α-NaTx) from scorpion venoms inhibit VGSC inactivation after binding to VSD IV
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