Specific distribution of sodium channels in axons of rat embryo spinal motoneurones

Abstract

1 The distribution of Na⁺ channels and development of excitability were investigated in vitro in purified spinal motoneurones obtained from rat embryos at E14, using electrophysiological, immunocytochemical and autoradiographical methods. 2 One hour after plating the motoneurones (DIV0), only somas were present. They expressed a robust delayed rectifier K⁺ current (I_DR) and a fast-inactivating A-type K⁺ current (I_A). The rapid neuritic outgrowth was paralleled by the emergence of a fast-activating TTX-sensitive sodium current (I_Na), and by an increase in both K⁺ currents. 3 The change in the three currents was measured daily, up to DIV8. The large increase in I_Na observed after DIV2 was accompanied by the onset of excitability. Spontaneous activity was observed as from DIV6. 4 The occurrence of axonal differentiation was confirmed by the fact that (i) only one neurite per motoneurone generated antidromic action potentials; and (ii) ¹²⁵I-α-scorpion toxin binding, a specific marker of Na⁺ channels, labelled only one neurite and the greatest density was observed in the initial segment. Na⁺ channels therefore selectively targeted the axon and were absent from the dendrites and somas. 5 The specific distribution of Na⁺ channels was detectable as soon as the neurites began to grow. When the neuritic outgrowth was blocked by nocodazole, no I_Na developed. 6 It was concluded that, in spinal embryonic motoneurone in cell culture, Na⁺ channels, the expression of which starts with neuritic differentiation, are selectively addressed to the axonal process, whereas K⁺ channels are present in the soma prior to the neuritic outgrowth.