Computational modeling of spike generation in serotonergic neurons of the dorsal raphe nucleu

TL;DR

This paper presents a detailed computational model of serotonergic dorsal raphe neurons, incorporating ten ion channel types and calcium dynamics to replicate their pacemaking activity and spike features.

Contribution

It introduces a comprehensive single-compartment model with detailed ion channel components and parameter estimation from voltage clamp data, advancing understanding of serotonergic neuron spike generation.

Findings

Model reproduces slow rhythmic pacemaking activity.

Ion channel interactions influence spike frequency.

Spontaneous spiking occurs with minor parameter adjustments.

Abstract

We consider here a single-compartment model of these neurons which is capable of describing many of the known features of spike generation, particularly the slow rhythmic pacemaking activity often observed in these cells in a variety of species. Included in the model are ten kinds of voltage dependent ion channels as well as calcium-dependent potassium current. Calcium dynamics includes buffering and pumping. In sections 3-9, each component is considered in detail and parameters estimated from voltage clamp data where possible. In the next two sections simplified versions of some components are employed to explore the effects of various parameters on spiking, using a systematic approach, ending up with the following eleven components: a fast sodium current $I_{Na}$, a delayed rectifier potassium current $I_{KDR}$, a transient potassium current $I_A$, a low-threshold calcium current $I_T$, two high threshold calcium currents $I_L$ and $I_N$, small and large conductance potassium currents $I_{SK}$ and $I_{BK}$, a hyperpolarization-activated cation current $I_H$, a leak current $I_{Leak}$ and intracellular calcium ion concentration $Ca_i$. Attention is focused on the properties usually associated with these neurons, particularly long duration of action potential, pacemaker-like spiking and the ramp-like return to threshold after a spike. In some cases the membrane potential trajectories display doublets or have kinks or notches as have been reported in some experimental studies. The computed time courses of $I_A$ and $I_T$ during the interspike interval support the generally held view of a competition between them in influencing the frequency of spiking. Spontaneous spiking could be obtained with small changes in a few parameters from their values with driven spiking.