Characterization of the Electrogenic Sodium Channel from Rat Brain Membranes Using Neurotoxin-Dependent ²²Na Uptake

Abstract

The sodium channel was studied in osmotically-sensitive membrane preparations from rat brain and in innervated and chronically denervated rat soleus and extensor digitorum longus muscles. These experiments were undertaken in order to define a set of parameters for sodium channel function at the subcellular level to be used as a measure of retention of channel integrity upon subsequent isolation of the channel. Various neurotoxins and drugs were employed to control the permeability of the brain membranes to ²²Na and the sodium-conductance properties of the muscles. Batrachotoxin (ED₅₀ = 0.2 μM), veratridine (ED₅₀ = 1 μM), or grayanotoxin I (ED₅₀ = 30 μM) stimulated ²²Na uptake in brain membranes is inhibited in an apparently uncompetitive manner by the sodium channel blocking agents tetrodotoxin and saxitoxin in a simple competitive manner by Ca²⁺ and in a partial or allosteric competitive manner by lidocaine and procaine. This ²²Na uptake assay, which can be equated to a measure of equilibrium toxin binding, shows dependence on the concentration of the membranes and is sensitive to pH, temperature, ionic strength, and the ionic composition of the media. Parallel biophysical studies on sodium channels in rat muscle show that the properties of the sodium channel are similarly affected by these agents.