1. Modification of wild-type and batrachotoxin-resistant muscle mu1 Na+ channels by veratridine
- Author
-
Sho-Ya Wang, Margaret Seaver, C. Quan, and Ging Kuo Wang
- Subjects
Physiology ,Clinical Biochemistry ,Mutant ,Drug Resistance ,Biology ,complex mixtures ,Ion Channels ,Sodium Channels ,Cell Line ,chemistry.chemical_compound ,Cnidarian Venoms ,Reference Values ,Physiology (medical) ,Humans ,Point Mutation ,Binding site ,Batrachotoxins ,Receptor ,Veratridine ,Point mutation ,Muscles ,Wild type ,Phenotype ,Molecular biology ,Electrophysiology ,Drug Combinations ,chemistry ,Biophysics ,Batrachotoxin - Abstract
Biochemical evidence indicates that veratridine (VTD) and batrachotoxin (BTX) share a common binding site in Na+ channels. Under whole-cell voltage-clamp conditions, we examined this single receptor hypothesis by studying the VTD phenotype in BTX-resistant muscle Na+ channels, microl-I433K, N434K, L437K, F1579K, and N1584K. Derived from point mutations at segments D1-S6 and D4-S6, these mutant Na+ channels are resistant to 5 microM BTX when expressed in human embryonic kidney cells. In contrast to the wild-type phenotype, VTD at 200 microM elicits little or no maintained current during a test pulse at +50 mV, and little or no "tail" current after the test pulse in all BTX-resistant mutant channels. Paradoxically, VTD retains its ability to inhibit the peak Na+ current in BTX-resistant mutant Na+ channels. To explain these mutant phenotypes, we propose a two-step binding reaction scheme. An initial VTD-binding interaction with the Na+ channel results in the inhibition of peak current amplitude, and a second binding reaction results in the trapping of VTD within the D1-S6 and D4-S6 domain interface. The failure of BTX-resistant mutant Na+ channels to trap VTD suggests that segments of D1-S6 and D4-S6 form a common receptor for VTD and BTX.
- Published
- 2000