Toxins (Jun 2024)

Unveiling Tst3, a Multi-Target Gating Modifier Scorpion α Toxin from <i>Tityus stigmurus</i> Venom of Northeast Brazil: Evaluation and Comparison with Well-Studied Ts3 Toxin of <i>Tityus serrulatus</i>

  • Diogo Vieira Tibery,
  • João Antonio Alves Nunes,
  • Daniel Oliveira da Mata,
  • Luis Felipe Santos Menezes,
  • Adolfo Carlos Barros de Souza,
  • Matheus de Freitas Fernandes-Pedrosa,
  • Werner Treptow,
  • Elisabeth Ferroni Schwartz

DOI
https://doi.org/10.3390/toxins16060257
Journal volume & issue
Vol. 16, no. 6
p. 257

Abstract

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Studies on the interaction sites of peptide toxins and ion channels typically involve site-directed mutations in toxins. However, natural mutant toxins exist among them, offering insights into how the evolutionary process has conserved crucial sequences for activities and molecular target selection. In this study, we present a comparative investigation using electrophysiological approaches and computational analysis between two alpha toxins from evolutionarily close scorpion species of the genus Tityus, namely, Tst3 and Ts3 from T. stigmurus and T. serrulatus, respectively. These toxins exhibit three natural substitutions near the C-terminal region, which is directly involved in the interaction between alpha toxins and Nav channels. Additionally, we characterized the activity of the Tst3 toxin on Nav1.1-Nav1.7 channels. The three natural changes between the toxins did not alter sensitivity to Nav1.4, maintaining similar intensities regarding their ability to alter opening probabilities, delay fast inactivation, and induce persistent currents. Computational analysis demonstrated a preference for the down conformation of VSD4 and a shift in the conformational equilibrium towards this state. This illustrates that the sequence of these toxins retained the necessary information, even with alterations in the interaction site region. Through electrophysiological and computational analyses, screening of the Tst3 toxin on sodium isoform revealed its classification as a classic α-NaTx with a broad spectrum of activity. It effectively delays fast inactivation across all tested isoforms. Structural analysis of molecular energetics at the interface of the VSD4-Tst3 complex further confirmed this effect.

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