High-Threshold K+Current Increases Gain by Offsetting a Frequency-Dependent Increase in Low-Threshold K+Current

Abstract

High-frequency firing neurons are found in numerous central systems, including the auditory brainstem, thalamus, hippocampus, and neocortex. The kinetics of high-threshold K⁺ currents (IK_HT) from the Kv3 subfamily has led to the proposal that these channels offset cumulative Na⁺ current inactivation and stabilize tonic high-frequency firing. However, all high-frequency firing neurons, examined to date, also express low-threshold K⁺ currents (IK_LT) that have slower kinetics and play an important role in setting the subthreshold and filtering properties of the neuron. IK_LT has also been shown to dampen excitability and is therefore likely to oppose high-frequency firing. In this study, we examined the role of IK_HT in pyramidal cells of the electrosensory lobe of weakly electric fish, which are characterized by high-frequency firing, a very wide frequency range, and high levels of IK_HT. In particular, we examined the mechanisms that allow IK_HT to set the gain of the F-I relationship by interacting with another low-threshold K⁺ current. We found that IK_HT increases the gain of the F-I relationship and influences spike waveform almost exclusively in the high-frequency firing range. The frequency dependence arises from IK_HT influencing both the IK_LT and Na⁺ currents. IK_HT thus plays a significant role in stabilizing high-frequency firing by preventing a steady-state accumulation of IK_LT that is as important as preventing Na⁺ current inactivation.