Switchable Slow Cellular Conductances Determine Robustness and Tunability of Network States

Overview

Journal PLoS Comput Biol

Specialty Biology

Date 2018 Apr 24

PMID 29684009

Citations 2

Authors

Guillaume Drion

Julie Dethier

Alessio Franci

Rodolphe Sepulchre

Affiliations

Soon will be listed here.

Abstract

Neuronal information processing is regulated by fast and localized fluctuations of brain states. Brain states reliably switch between distinct spatiotemporal signatures at a network scale even though they are composed of heterogeneous and variable rhythms at a cellular scale. We investigated the mechanisms of this network control in a conductance-based population model that reliably switches between active and oscillatory mean-fields. Robust control of the mean-field properties relies critically on a switchable negative intrinsic conductance at the cellular level. This conductance endows circuits with a shared cellular positive feedback that can switch population rhythms on and off at a cellular resolution. The switch is largely independent from other intrinsic neuronal properties, network size and synaptic connectivity. It is therefore compatible with the temporal variability and spatial heterogeneity induced by slower regulatory functions such as neuromodulation, synaptic plasticity and homeostasis. Strikingly, the required cellular mechanism is available in all cell types that possess T-type calcium channels but unavailable in computational models that neglect the slow kinetics of their activation.

Citing Articles

Robust switches in thalamic network activity require a timescale separation between sodium and T-type calcium channel activations.

Jacquerie K, Drion G PLoS Comput Biol. 2021; 17(5):e1008997.

PMID: 34003841 PMC: 8162675. DOI: 10.1371/journal.pcbi.1008997.

Co-opting evo-devo concepts for new insights into mechanisms of behavioural diversity.

Hoke K, Adkins-Regan E, Bass A, McCune A, Wolfner M J Exp Biol. 2019; 222(Pt 8).

PMID: 30988051 PMC: 6503947. DOI: 10.1242/jeb.190058.

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