Charybdotoxin binding to Shaker K+ channels is temperature sensitive in high external K+ but not in high external Na.

Charybdotoxin (CTX), a peptide neurotoxin derived from the scorpion Leiurus quinquestriatus, binds to the external entrance of open voltage-gated K+ channels (VGKCs) with minimal conformational impact. By occluding the VGKC pore, CTX blocks passive K+ flow-a defining function of these membrane proteins. Due to its mechanistic simplicity and high signal-to-noise ratio, the CTX-VGKC interaction is an ideal system to investigate the molecular details of binding and unbinding. CTX bound to the Shaker VGKC exhibits thermal motion (wobbling) that permits access of external K+ to the channel pore. To test whether this wobbling is part of the reaction pathway during toxin-channel interaction, the energetic role of external K+ was examined in the association and dissociation kinetics. A high-affinity Shaker K427E-VGKC variant was expressed in Xenopus oocytes, and its activity was monitored via two-electrode voltage clamp between ∼10 and ∼30°C. Nanomolar applications of CTX to open and closed channels, in the presence of high external Na+ or high K+ concentrations, were used to measure blockade kinetics at different voltages and temperatures. In high K+, both the dissociation and association rates showed higher activation enthalpies, by ∼15 kJ/mol and ∼25 kJ/mol, respectively, compared with high Na+ conditions. However, the association rates under high Na+ and K+ were equal at ∼20°C, indicating a compensatory K+-induced activation entropy. We propose transient CTX-wobbling intermediates in both directions of the reaction pathway. Such a wobbling intermediate could enhance the diversity of productive collisions during association, increasing the efficacy of the scorpion venom.