Functional Modification of Bacterial Voltage-Gated Sodium Channels by Batrachotoxin

Abstract

Batrachotoxin (BTX) is an excitatory component in the skin secretions of dendrobatid frogs, which advertise their armament with the gaudy colors of their lethal skin. BTX is a hydrophobic alkaloid, which crosses cell membranes and activates voltage-gated sodium (Nav) channels of muscle, nerve and heart. BTX binding causes a shift of the activation curve toward more negative voltages, and suppresses fast and slow inactivation resulting in a massive increase in excitability of the tissue and ultimately causing paralysis. BTX is thought to act by binding in the cytoplasmic cavity of the ion-conducting pore, of pseudo-symmetric eukaryotic Nav channels. This binding site is near, or overlapping, receptor sites for amphiphylic inhibitor drugs including local anesthetics, anticonvulsants and anti-arrhythmics.The four homologous domains of eukaryotic Navs parallel the homo-tetrameric arrangement of BacNav channels, which have yielded high-resolution crystal structures. Despite the absence of a “ball-and chain” or “hinged-lid” fast inactivation mechanism, BacNavs display a “pore based” inactivation, that in some cases is quite rapid. Thus, they offer an opportunity to explore BTX actions on a molecular system of gating that is amenable to structural verification.The BacNav channels NaChBac and NavSp1 both show dramatic modification by BTX, with negative shifts of activation and inhibition of inactivation. These actions are enhanced by phenylalanine substitutions of pore domain (S6) residues, at positions which align with Phe residues that are important for BTX activation in eukaryotic Nav channels.