Gap Junction Modulation of Low-Frequency Oscillations in the Cerebellar Granule Cell Layer

Robinson, J.C.; Chapman, C. Andrew; Courtemanche, Richard

doi:10.1007/s12311-017-0858-5

Cited by 11 publications

(9 citation statements)

References 81 publications

(136 reference statements)

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“…The ability to discharge at different rhythms allows them to carry additional information in a more efficient fashion than the average firing rate as it takes the exact spike timing into account (Jirenhed et al, 2017). The cerebellum displays various sorts of rhythmic activities covering both low-frequency (Courtemanche et al, 2002(Courtemanche et al, , 2013Courtemanche & Lamarre, 2005;D'Angelo et al, 2009;Dugu e et al, 2009;Robinson et al, 2017) and high-frequency oscillations (HFO) (Cheron et al, 2004(Cheron et al, , 2014Servais et al, 2005;de Solages et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Beta‐gamma burst stimulations of the inferior olive induce high‐frequency oscillations in the deep cerebellar nuclei

Cheron

Chéron

2018

Eur J of Neuroscience

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The cerebellum displays various sorts of rhythmic activities covering both low- and high-frequency oscillations. These cerebellar high-frequency oscillations were observed in the cerebellar cortex. Here, we hypothesised that not only is the cerebellar cortex a generator of high-frequency oscillations but also that the deep cerebellar nuclei may also play a similar role. Thus, we analysed local field potentials and single-unit activities in the deep cerebellar nuclei before, during and after electric stimulation in the inferior olive of awake mice. A high-frequency oscillation of 350 Hz triggered by the stimulation of the inferior olive, within the beta-gamma range, was observed in the deep cerebellar nuclei. The amplitude and frequency of the oscillation were independent of the frequency of stimulation. This oscillation emerged during the period of stimulation and persisted after the end of the stimulation. The oscillation coincided with the inhibition of deep cerebellar neurons. As the inhibition of the deep cerebellar nuclei is related to inhibitory inputs from Purkinje cells, we speculate that the oscillation represents the unmasking of the synchronous activation of another subtype of deep cerebellar neuronal subtype, devoid of GABA receptors and under the direct control of the climbing fibres from the inferior olive. Still, the mechanism sustaining this oscillation remains to be deciphered. Our study sheds new light on the role of the olivo-cerebellar loop as the final output control of the intercerebellar circuitry.

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Section: Introductionmentioning

confidence: 99%

Beta‐gamma burst stimulations of the inferior olive induce high‐frequency oscillations in the deep cerebellar nuclei

Cheron

Chéron

2018

Eur J of Neuroscience

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“…LFP periods of strong oscillations, in contrast with periods when oscillations were weaker, were identified using spectrograms, calculated using the discrete short-time Fourier transform to evaluate rhythmicity. A multi-parametric algorithm was used to identify oscillatory periods in the 4–12 Hz band of the spectrogram, corresponding with rodent GCL oscillations from other in vivo studies (Hartmann and Bower, 1998 ; O’Connor et al, 2002 ; Dugué et al, 2009 ; Frederick et al, 2014 ; Robinson et al, 2017 ). This algorithm has been used previously to detect and process various rhythmic signals [gamma (Lévesque et al, 2009 ), and theta (Berryer et al, 2016 )].…”

Section: Methodsmentioning

confidence: 99%

“…Intrinsic oscillatory capacities of the GCL local network have been modeled (Maex and De Schutter, 2005 ; Dugué et al, 2009 ; Honda et al, 2011 ; Simões de Souza and De Schutter, 2011 ; Sudhakar et al, 2017 ). For instance, Golgi cell-mediated feedforward and feedback loops (Forti et al, 2006 ; D’Angelo, 2008 ; Dugué et al, 2009 ; Galliano et al, 2010 ), and Golgi-Golgi electrical synapses could be implicated in the rhythm formation (Dugué et al, 2009 ; Vervaeke et al, 2010 ; Simões de Souza and De Schutter, 2011 ; Robinson et al, 2017 ). Further in the circuit, in a limited dataset, we saw that Purkinje cell simple spikes (SSs) can follow the 10–25 Hz GCL rhythm, contrary to complex spikes (Courtemanche et al, 2002 ).…”

Section: Introductionmentioning

confidence: 99%

Cerebellar Cortex 4–12 Hz Oscillations and Unit Phase Relation in the Awake Rat

Lévesque

Gao

Southward

et al. 2020

Front. Syst. Neurosci.

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“…Under these conditions, intrinsic activity and strong electrical coupling is expected to promote spike synchronization in the GoC network, as observed under anesthesia (van Welie et al, 2016). Previous work has shown that electrically-coupled GoC networks contribute to local field potential (LFP) oscillations in the theta band (~ 8 Hz) (Dugué et al, 2009;Robinson et al, 2017).…”

Section: Implications Of Norepinephrine-mediated Modulation Of Electrmentioning

confidence: 99%

Norepinephrine controls the gain of the inhibitory circuit in the cerebellar input layer

Lanore¹,

Rothman²,

Coyle³

et al. 2019

Preprint

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Golgi cells (GoCs) are the main inhibitory interneurons in the input layer of the cerebellar cortex and are electrically coupled together, forming syncytia. GoCs control the excitability of granule cells (GCs) through feedforward, feedback and spillovermediated inhibition. The GoC circuit therefore plays a central role in determining how sensory and motor information is transformed as it flows through the cerebellar input layer. Recent work has shown that GCs are activated when animals perform active behaviours, but the underlying mechanisms remain poorly understood. Norepinephrine (NE), also known as noradrenaline, is a powerful modulator of network function during active behavioral states and the axons of NE-releasing neurons in the locus coeruleus innervate the cerebellar cortex. Here we show that NE hyperpolarizes the GoC membrane potential, decreases spontaneous firing and reduces the gain of the spike frequency versus input-current relationship. The GoC membrane hyperpolarization can be mimicked with an α2-noradrenergic agonist, inhibited with a specific α2 antagonist and is abolished when G protein-coupled inwardly-rectifying potassium (GIRK) channels are blocked. Moreover, NE reduces the effective electrical coupling between GoCs through a persistent sodium current (INaP)-dependent mechanism. Our results suggest that NE controls the gain of the GoC inhibitory circuit by modulating membrane conductances that act to reduce membrane excitability and decrease electrical coupling. These mechanisms appear configured to reduce the level of GoC inhibition onto GCs during active behavioural states.

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Gap Junction Modulation of Low-Frequency Oscillations in the Cerebellar Granule Cell Layer

Cited by 11 publications

References 81 publications

Beta‐gamma burst stimulations of the inferior olive induce high‐frequency oscillations in the deep cerebellar nuclei

Beta‐gamma burst stimulations of the inferior olive induce high‐frequency oscillations in the deep cerebellar nuclei

Cerebellar Cortex 4–12 Hz Oscillations and Unit Phase Relation in the Awake Rat

Norepinephrine controls the gain of the inhibitory circuit in the cerebellar input layer

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