Persistent Sodium Current in Layer 5 Neocortical Neurons Is Primarily Generated in the Proximal Axon

Abstract

In addition to the well described fast-inactivating component of the Na⁺current [transient Na⁺current (I_NaT)], neocortical neurons also exhibit a low-voltage-activated, slowly inactivating “persistent” Na⁺current (I_NaP), which plays a role in determining neuronal excitability and synaptic integration. We investigated the Na⁺channels responsible forI_NaPin layer 5 pyramidal cells using cell-attached and whole-cell recordings in neocortical slices. In simultaneous cell-attached and whole-cell somatic recordings, no persistent Na⁺channel activity was detected at potentials at which whole-cellI_NaPoperates. Detailed kinetic analysis of late Na⁺channel activity in cell-attached patches at 36°C revealed that somatic Na⁺channels do not demonstrate “modal gating” behavior and that the probability of single late openings is extremely low (−4or I_NaT). Ensemble averages of these currents did not reveal a sustained component whose amplitude and voltage dependence could account forI_NaPas seen in whole-cell recordings. Local application of TTX to the axon blocked somatically recordedI_NaP, whereas somatic and dendritic application had little or no effect. Finally, simultaneous current-clamp recordings from soma and apical dendrite revealed that Na⁺plateau potentials originate closer to the axon. Our data indicate that the primary source ofI_NaPis in the spike initiation zone in the proximal axon. The focal axonal presence of regenerative subthreshold conductance with voltage and time dependence optimal to manipulate integration of synaptic input, spike threshold, and the pattern of repetitive firing provides the layer 5 pyramidal neuron with a mechanism for dynamic control of its gain.