Subcellular distribution of persistent sodium conductance in cortical pyramidal neurons

Cortical pyramidal neurons possess a persistent Na¹ current (I_NaP), which, in contrast to the larger transient current, does not undergo rapid inactivation. Although relatively quite small, I_NaP is active at subthreshold voltages and therefore plays an important role in neuronal input–output processing. The subcellular distribution of channels responsible for I_NaP and the mechanisms that render them persistent are not known. Using high-speed fluorescence Na¹ imaging and whole-cell recordings in brain slices obtained from mice of either sex, we reconstructed the I_NaP elicited by slow voltage ramps in soma and processes of cortical pyramidal neurons. We found that in all neuronal compartments, the relationship between persistent Na¹ conductance and membrane voltage has the shape of a Boltzmann function. Although the density of channels underlying I_NaP was about twofold lower in the axon initial segment (AIS) than in the soma, the axonal channels were activated by;10 mV less depolarization than were somatic channels. This difference in voltage dependence explains why, at functionally critical subthreshold voltages, most I_NaP originates in the AIS. Finally, we show that endogenous polyamines constrain I_NaP availability in both somatodendritic and axonal compartments of nondialyzed cortical neurons.