Switchable slow cellular conductances determine robustness and tunability of network states

Drion, Guillaume; Dethier, Julie; Franci, Alessio; Sepulchre, Rodolphe

doi:10.1371/journal.pcbi.1006125

Cited by 17 publications

(44 citation statements)

References 87 publications

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“…In the absence of a slow negative conductance at the cellular level, breaking network symmetry and increasing cellular heterogeneity results in the incapacity to generate any circuit rhythm for most randomly picked parameter sets and neuromodulatory states, even with strong network connectivity. We do not show any quantitative result here, but identical observations are reported in variable circuits and heterogeneous networks in Drion et al, 2018).…”

Section: Resultssupporting

confidence: 64%

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Cellular switches orchestrate rhythmic circuits

2018

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Small inhibitory neuronal circuits have long been identified as key neuronal motifs to generate and modulate the coexisting rhythms of various motor functions. Our paper highlights the role of a cellular switching mechanism to orchestrate such circuits. The cellular switch makes the circuits reconfigurable, robust, adaptable, and externally controllable. Without this cellular mechanism, the circuit rhythms entirely rely on specific tunings of the synaptic connectivity, which makes them rigid, fragile, and difficult to control externally. We illustrate those properties on the much studied architecture of a small network controlling both the pyloric and gastric rhythms of crabs. The cellular switch is provided by a slow negative conductance often neglected in mathematical modeling of central pattern generators. We propose that this conductance is simple to model and key to computational studies of rhythmic circuit neuromodulation.

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Section: Resultssupporting

confidence: 64%

“…This property is provided for instance by slowly-activating calcium channels. The role of this specific intrinsic property has been extensively studied by the authors in the recent years Franci et al, 2018;Drion et al, 2018). It acts as a switch of excitability for the neuron.…”

Section: Introductionmentioning

confidence: 99%

Cellular switches orchestrate rhythmic circuits

2018

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“…An external current is exerted on the inhibitory cells (see Figure 4A). This hyperpolarizing current causes a cellular switch and drives the neurons in a synchronous bursting mode as previously shown with the isolated E-I circuit in Figure 2A [Drion et al (2018)]. This change in cellular firing pattern is translated by an oscillatory behavior at the network level.…”

Section: Resultsmentioning

confidence: 57%

“…Throughout this paper, we compare six well-established conductance-based models of thalamic neurons [Drion, Dethier, Franci, and Sepulchre (2018)] (model 1), [Destexhe, Contreras, Steriade, Sejnowski, and Huguenard (1996)] (model 2), [Destexhe, Neubig, Ulrich, and Huguenard (1998)] (model 3), [Huguenard and McCormick (1992); McCormick and Huguenard (1992)] (model 4), [X. J. Wang (1994)] (model 5) and [Rush and Rinzel (1994)] (model 6).…”

Section: Resultsmentioning

confidence: 99%

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

Jacquerie

Drion

2020

Preprint

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Switches in brain states, synaptic plasticity and neuromodulation are fundamental processes in our brain that take place concomitantly across several spatial and timescales. All these processes target neuron intrinsic properties and connectivity to achieve specific physiological goals, raising the question of how they can operate without interfering with each other. Here, we highlight the central importance of a timescale separation in the activation of sodium and T-type calcium channels to sustain robust switches in brain states in thalamic neurons that are compatible with synaptic plasticity and neuromodulation. We quantify the role of this timescale separation by comparing the robustness of rhythms of six published conductance-based models at the cellular, circuit and network levels. We show that robust rhythm generation requires a T-type calcium channel activation whose kinetics are situated between sodium channel activation and T-type calcium channel inactivation in all models despite their quantitative differences.

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“…Similarly, the molecular interactions among signal transduction pathway components determine physiological features such as the alternation between two firing states in hunger-related neurons in the mouse hypothalamus (Yang et al, 2011). Computational models implicate specific calcium channel subtypes in supporting positive feedback necessary for alternative firing patterns (Franci et al, 2018;Drion et al, 2018); hence, specific biochemical changes could tune criticality and adjust neural firing state based on internal or external cues. Understanding how neural circuits adjust criticality more broadly will offer novel insights into the ways in which genetic changes and experience contribute to individual variation in neural system function and behaviour.…”

Section: Tipping Pointsmentioning

confidence: 99%

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

Hoke

Adkins‐Regan

Bass

et al. 2019

Journal of Experimental Biology

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We propose that insights from the field of evolutionary developmental biology (or 'evo-devo') provide a framework for an integrated understanding of the origins of behavioural diversity and its underlying mechanisms. Towards that goal, in this Commentary, we frame key questions in behavioural evolution in terms of molecular, cellular and network-level properties with a focus on the nervous system. In this way, we highlight how mechanistic properties central to evo-devo analysessuch as weak linkage, versatility, exploratory mechanisms, criticality, degeneracy, redundancy and modularityaffect neural circuit function and hence the range of behavioural variation that can be filtered by selection. We outline why comparative studies of molecular and neural systems throughout ontogeny will provide novel insights into diversity in neural circuits and behaviour.

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Switchable slow cellular conductances determine robustness and tunability of network states

Cited by 17 publications

References 87 publications

Cellular switches orchestrate rhythmic circuits

Cellular switches orchestrate rhythmic circuits

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

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

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