Augmentation of Recovery from Inactivation by Site-3 Na Channel Toxins: A Single-Channel and Whole-Cell Study of Persistent Currents

doi:10.1085/jgp.113.2.333

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Augmentation of Recovery from Inactivation by Site-3 Na Channel Toxins

A Single-Channel and Whole-Cell Study of Persistent Currents

G. Richard Benzinger, Gayle S. Tonkovich, and Dorothy A. Hanck

From the Committee on Neurobiology, The University of Chicago, Chicago, Illinois 60637

Site-3 toxins isolated from several species of scorpion andsea anemone bind to voltage-gated Na channels and prolong thetime course of I_Na by interfering with inactivation with littleor no effect on activation, effects that have similaritiesto those produced by genetic diseases in skeletal muscle (myotoniasand periodic paralysis) and heart (long QT syndrome). Some publishedreports have also reported the presence of a noninactivatingpersistent current in site-3 toxin-treated cells. We have usedthe high affinity site-3 toxin Anthopleurin B to study thekinetics of this current and to evaluate kinetic differencesbetween cardiac (in RT4-B8 cells) and neuronal (in N1E-115 cells)Na channels. By reverse transcription–PCR from N1E-115cell RNA multiple Na channel transcripts were detected; mostoften isolated were sequences homologous to rBrII, althoughat low frequency sequences homologous to rPN1 and rBrIII werealso detected. Toxin treatment induced a voltage-dependent plateaucurrent in both isoforms for which the relative amplitude (plateaucurrent/peak current) approached a constant value with depolarization,although the magnitude was much greater for neuronal (17%) thancardiac (5%) I_Na. Cell-attached patch recordings revealed distinctquantitative differences in open times and burst durations betweenisoforms, but for both isoforms the plateau current compriseddiscrete bursts separated by quiescent periods, consistent withtoxin induction of an increase in the rate of recovery frominactivation rather than a modal failure of inactivation. Inaccord with this hypothesis, toxin increased the rate of whole-cellrecovery at all tested voltages. Moreover, experimental datasupport a model whereby recovery at negative voltages is augmented through closed states rather than through the open state. Weconclude that site-3 toxins produce qualitatively similar effectsin cardiac and neuronal channels and discuss implications forchannel kinetics.

Key Words: patch clamp • voltage clamp • sea anemone toxin • cnidarian venoms

Address correspondence to Dr. Dorothy Hanck, MC6094, The Universityof Chicago, 5841 S. Maryland Ave., Chicago, IL 60637. Fax: 773-702-6789; E-mail: d-hanck{at}uchicago.edu

Abbreviations: ApB, Anthopleurin B toxin; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; RT-PCR, reverse transcription–PCR

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