Abstract
Synaptic inputs received at dendrites are converted into digital outputs encoded by action potentials generated at the axon initial segment in most neurons. Here, we report that alternative splicing regulates polarized targeting of Kv3.1 voltage-gated potassium (Kv) channels to adjust the input-output relationship. The spiking frequency of cultured hippocampal neurons correlated with the level of endogenous Kv3 channels. Expression of axonal Kv3.1b, the longer form of Kv3.1 splice variants, effectively converted slow-spiking young neurons to fast-spiking ones; this was not the case for Kv1.2 or Kv4.2 channel constructs. Despite having identical biophysical properties as Kv3.1b, dendritic Kv3.1a was significantly less effective at increasing the maximal firing frequency. This suggests a possible role of channel targeting in regulating spiking frequency. Mutagenesis studies suggest the electrostatic repulsion between the Kv3.1b N/C termini, created by its C-terminal splice domain, unmasks the Kv3.1b axonal targeting motif. Kv3.1b axonal targeting increased the maximal spiking frequency in response to prolonged depolarization. This finding was further supported by the results of local application of channel blockers and computer simulations. Taken together, our studies have demonstrated that alternative splicing controls neuronal firing rates by regulating the polarized targeting of Kv3.1 channels.
Highlights
Ion channels play critical roles in converting synaptic inputs into digital outputs encoded by action potentials
The simulation results suggest that Kv3.1 axonal targeting is a powerful means to increase the maximal spiking frequency, consistent with our experimental results. We show that both biophysical properties and axonal targeting of Kv3.1 channels are critical to enable neurons to fire action potential (AP) at the maximal frequency (Fig. 8C)
We further reveal novel mechanistic insights into Kv3.1 axonal targeting, which includes electrostatic interactions between the N/C termini of the channel (Fig. 5A)
Summary
Ion channels play critical roles in converting synaptic inputs into digital outputs encoded by action potentials. We report that alternative splicing regulates polarized targeting of Kv3.1 voltage-gated potassium (Kv) channels to adjust the input-output relationship. Despite having identical biophysical properties as Kv3.1b, dendritic Kv3.1a was significantly less effective at increasing the maximal firing frequency This suggests a possible role of channel targeting in regulating spiking frequency. The widest range of spiking frequencies is usually attributable to the presence of Kv3 channels, because of their unique biophysical properties, high activation threshold (about Ϫ20 mV), and rapid deactivation kinetics [28, 29] It remains unknown whether Kv3 channel expression is sufficient for fast spiking, because not all Kv3-expressing neurons spike rapidly [11]. Our results show that besides their essential role in increasing AP firing frequency, the expression of axonal Kv3.1b channels is sufficient to convert a slow-spiking young neuron to a fast-spiking one. Kv3.1 Polarized Targeting and Spiking Frequency ies suggest that axon-dendrite targeting of Kv3.1 channels can effectively adjust the maximal spiking frequency
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