Litcius/Paper detail

Firing rate-dependent phase responses of Purkinje cells support transient oscillations

Yunliang Zang, Sungho Hong, Erik De Schutter

2020eLife23 citationsDOIOpen Access PDF

Abstract

Both spike rate and timing can transmit information in the brain. Phase response curves (PRCs) quantify how a neuron transforms input to output by spike timing. PRCs exhibit strong firing-rate adaptation, but its mechanism and relevance for network output are poorly understood. Using our Purkinje cell (PC) model, we demonstrate that the rate adaptation is caused by rate-dependent subthreshold membrane potentials efficiently regulating the activation of Na + channels. Then, we use a realistic PC network model to examine how rate-dependent responses synchronize spikes in the scenario of reciprocal inhibition-caused high-frequency oscillations. The changes in PRC cause oscillations and spike correlations only at high firing rates. The causal role of the PRC is confirmed using a simpler coupled oscillator network model. This mechanism enables transient oscillations between fast-spiking neurons that thereby form PC assemblies. Our work demonstrates that rate adaptation of PRCs can spatio-temporally organize the PC input to cerebellar nuclei.

Topics & Concepts

NeurosciencePhysicsMembrane potentialBiological systemPhase response curveOscillation (cell signaling)NeuronSubthreshold conductionBiophysicsComputer scienceChemistryBiologyVoltageCircadian clockTransistorCircadian rhythmBiochemistryQuantum mechanicsNeural dynamics and brain functionNeuroscience and Neuropharmacology ResearchPhotoreceptor and optogenetics research