Abstract

Activity-dependent regulation of intrinsic excitability has been shown to greatly contribute to the overall plasticity of neuronal circuits. Such neuroadaptations are commonly investigated in patch clamp experiments using current step stimulation and the resulting input-output functions are analyzed to quantify alterations in intrinsic excitability. However, it is rarely addressed, how such changes translate to the function of neurons when they operate under natural synaptic inputs. Still, it is reasonable to expect that a strong correlation and near proportional relationship exist between static firing responses and those evoked by synaptic drive. We challenge this view by performing a high-yield electrophysiological analysis of cultured mouse hippocampal neurons using both standard protocols and simulated synaptic inputs via dynamic clamp. We find that under these conditions the neurons exhibit vastly different firing responses with surprisingly weak correlation between static and dynamic firing intensities. These contrasting responses are regulated by two intrinsic K-currents mediated by Kv1 and Kir channels, respectively. Pharmacological manipulation of the K-currents produces differential regulation of the firing output of neurons. Static firing responses are greatly increased in stuttering type neurons under blocking their Kv1 channels, while the synaptic responses of the same neurons are less affected. Pharmacological blocking of Kir-channels in delayed firing type neurons, on the other hand, exhibit the opposite effects. Our subsequent computational model simulations confirm the findings in the electrophysiological experiments and also show that adaptive changes in the kinetic properties of such currents can even produce paradoxical regulation of the firing output.

Highlights

  • In addition to the well-known forms of synaptic plasticity, intrinsic properties of neurons are regulated by activity-dependent mechanisms

  • Most action potentials that neurons emit during their lifetime are produced by a dynamic interplay between the synaptic inputs and the intrinsic biophysical properties of the postsynaptic neuron

  • In the present study we investigate the firing output of hundreds of hippocampal neurons under standard current step stimulation and when they are bombarded by simulated synaptic inputs via dynamic clamp

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Summary

Introduction

In addition to the well-known forms of synaptic plasticity, intrinsic properties of neurons are regulated by activity-dependent mechanisms. Similar form of Kv1 channel mediated long-term potentiation of intrinsic excitability (LTP-IE) has been found in CA3 neurons evoked solely by somatic electrical stimulation [4]. LTP-IE often involves the downregulation of various Kchannels [4,5,6,7,8], but additional ion channel targets have been identified [9,10] All these findings indicate that intrinsic adaptations play as important role in cellular mechanisms of learning as the well-known synaptic forms of long-term plasticity

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