Abstract

Understanding the neural mechanisms of action potential generation is critical to establish the way neural circuits generate and coordinate activity. Accordingly, we investigated the dynamics of action potential initiation in the GABAergic thalamic reticular nucleus (TRN) using in vivo intracellular recordings in cats in order to preserve anatomically-intact axo-dendritic distributions and naturally-occurring spatiotemporal patterns of synaptic activity in this structure that regulates the thalamic relay to neocortex. We found a wide operational range of voltage thresholds for action potentials, mostly due to intrinsic voltage-gated conductances and not synaptic activity driven by network oscillations. Varying levels of synchronous synaptic inputs produced fast rates of membrane potential depolarization preceding the action potential onset that were associated with lower thresholds and increased excitability, consistent with TRN neurons performing as coincidence detectors. On the other hand the presence of action potentials preceding any given spike was associated with more depolarized thresholds. The phase-plane trajectory of the action potential showed somato-dendritic propagation, but no obvious axon initial segment component, prominent in other neuronal classes and allegedly responsible for the high onset speed. Overall, our results suggest that TRN neurons could flexibly integrate synaptic inputs to discharge action potentials over wide voltage ranges, and perform as coincidence detectors and temporal integrators, supported by a dynamic action potential threshold.

Highlights

  • Brain activity is structured by the dynamic encoding and processing of information in neuronal circuits

  • These results show that the voltage threshold for action potentials in thalamic reticular nucleus (TRN) neurons is very dynamic, and the wide operational range is robust as it is expressed in two different oscillatory network dynamics

  • We have studied the dynamics of initiation of action potentials in the GABAergic TRN neurons in vivo

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Summary

Introduction

Brain activity is structured by the dynamic encoding and processing of information in neuronal circuits. In some neuronal classes the voltage threshold for spike generation depends on the rate of preceding membrane depolarization [3,4,5,6] This effect is determined by the gating kinetics of sodium and potassium channels [2,7,8], which enhance the sensitivity to rapid depolarizations. The spikegenerating mechanism has been proposed to amplify coincident inputs, because rapid depolarizations may arise in response to synchronous synaptic inputs This suggests that some neuronal populations can perform as temporal integrators [3,9]

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