Partial Agonist and Antagonist Activities of a Mutant Scorpion β-Toxin on Sodium Channels

Izhar Karbat,Nitza Ilan,Joel Z Zhang,Lior Cohen,Roy Kahn,Morris Benveniste,Todd Scheuer,William A Catterall,Dalia Gordon,Michael Gurevitz

doi:10.1074/jbc.m110.150888

Abstract

Scorpion β-toxin 4 from Centruroides suffusus suffusus (Css4) enhances the activation of voltage-gated sodium channels through a voltage sensor trapping mechanism by binding the activated state of the voltage sensor in domain II and stabilizing it in its activated conformation. Here we describe the antagonist and partial agonist properties of a mutant derivative of this toxin. Substitution of seven different amino acid residues for Glu(15) in Css4 yielded toxin derivatives with both increased and decreased affinities for binding to neurotoxin receptor site 4 on sodium channels. Css4(E15R) is unique among this set of mutants in that it retained nearly normal binding affinity but lost its functional activity for modification of sodium channel gating in our standard electrophysiological assay for voltage sensor trapping. More detailed analysis of the functional effects of Css4(E15R) revealed weak voltage sensor trapping activity, which was very rapidly reversed upon repolarization and therefore was not observed in our standard assay of toxin effects. This partial agonist activity of Css4(E15R) is observed clearly in voltage sensor trapping assays with brief (5 ms) repolarization between the conditioning prepulse and the test pulse. The effects of Css4(E15R) are fit well by a three-step model of toxin action involving concentration-dependent toxin binding to its receptor site followed by depolarization-dependent activation of the voltage sensor and subsequent voltage sensor trapping. Because it is a partial agonist with much reduced efficacy for voltage sensor trapping, Css4(E15R) can antagonize the effects of wild-type Css4 on sodium channel activation and can prevent paralysis by Css4 when injected into mice. Our results define the first partial agonist and antagonist activities for scorpion toxins and open new avenues of research toward better understanding of the structure-function relationships for toxin action on sodium channel voltage sensors and toward potential toxin-based therapeutics to prevent lethality from scorpion envenomation.

Highlights

Voltage-gated sodium channels are the molecular targets for many paralytic neurotoxins, which have highly selective effects on sodium channel function [1,2,3,4]
The functional effects of these mutant toxins were tested by measurement of enhanced activation of rNav1.2a channels expressed in Chinese hamster ovary (CHO) cells caused by voltage sensor trapping by the toxins
These results show that Css4E15R has lost its functional activity, as defined in this standard assay for voltage sensor trapping, it retains high affinity binding to sodium channels

Summary

Introduction

Voltage-gated sodium channels are the molecular targets for many paralytic neurotoxins, which have highly selective effects on sodium channel function [1,2,3,4]. Strong depolarizations that activate the sodium channel greatly enhance toxin action by driving the voltage sensor into its activated state and allowing rapid voltage sensor trapping This three-step process involves initial binding of the toxin, followed by depolarization-dependent activation of the voltage sensor and rapid trapping of the activated voltage sensor [10, 12]. This mechanism predicts that toxin derivatives that bind to neurotoxin receptor site 4, but do not preferentially bind to the activated state of the voltage sensor, would have reduced efficacy in voltage sensor trapping and would be partial agonists or antagonists of the actions of wild-type scorpion ␤-toxins. Our results provide new support for the voltage sensor-trapping model of toxin action and proof of principle for potential development of toxin antagonists as therapeutic agents

Methods

Results

Conclusion