Abstract
In neocortical layer-5 pyramidal neurons, the action potential (AP) is generated in the axon initial segment (AIS) when the membrane potential (Vm ) reaches the threshold for activation of the voltage-gated Na+ channels (VGNCs) Nav 1.2 and Nav 1.6. Yet, whereas these VGNCs are known to differ in spatial distribution along the AIS and in biophysical properties, our understanding of the functional differences between the two channels remains elusive. Here, using ultrafast Na+ , Vm and Ca2+ imaging in combination with partial block of Nav 1.2 by the peptide G1 G4 -huwentoxin-IV, we demonstrate an exclusive role of Nav 1.2 in shaping the generating AP. Precisely, we show that selective block of ∼30% of Nav 1.2 widens the AP in the distal part of the AIS and we demonstrate that this effect is due to a loss of activation of BK Ca2+ -activated K+ channels (CAKCs). Indeed, Ca2+ influx via Nav 1.2 activates BK CAKCs, determining the amplitude and the early phase of repolarization of the AP in the AIS. By using control experiments using 4,9-anhydrotetrodotoxin, a moderately selective inhibitor of Nav 1.6, we concluded that the Ca2+ influx shaping the early phase of the AP is exclusive of Nav 1.2. Hence, we mimicked this result with a neuron model in which the role of the different ion channels tested reproduced the experimental evidence. The exclusive role of Nav 1.2 reported here is important for understanding the physiology and pathology of neuronal excitability. KEY POINTS: We optically analysed the action potential generated in the axon initial segment of mouse layer-5 neocortical pyramidal neurons and its associated Na+ and Ca2+ currents using ultrafast imaging techniques. We found that partial selective block of the voltage-gated Na+ channel Nav 1.2, produced by a recently developed peptide, widens the shape of the action potential in the distal part of the axon initial segment. We demonstrate that this effect is due to a reduction of the Ca2+ influx through Nav 1.2 that activates BK Ca2+ -activated K+ channels. To validate our conclusions, we generated a neuron model that reproduces the ensemble of our experimental results. The present results indicate a specific role of Nav 1.2 in the axon initial segment for shaping of the action potential during its generation.
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