Validated multi‐step approach for <i>in vivo</i> recording and analysis of optogenetically evoked glutamate in the mouse globus pallidus

Viereckel, Thomas; Konradsson-Geuken, Åsa; Wallén-Mackenzie, Åsa

doi:10.1111/jnc.14288

Cited by 12 publications

(12 citation statements)

References 42 publications

(116 reference statements)

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“…The STN is the only glutamatergic nucleus in the BG, and it represents the main excitatory input to GP neurons (Kita and Kitaï, 1987;Smith et al, 1990). It has been shown in mice that optogenetic activation of STN axon terminals within the GP increases glutamate release (Viereckel et al, 2018) and c-Fos expression (Tian et al, 2018). We show here that, similar to D2-SPN inputs, STN inputs differentially impact the activity of prototypic and arkypallidal neurons.…”

Section: Stn Inputs Cause a Disynaptic Inhibition In Arkypallidal Neumentioning

confidence: 52%

A disynaptic circuit in the globus pallidus controls locomotion inhibition

Aristieta

Barresi

Lindi

et al. 2020

Preprint

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Basal ganglia (BG) inhibit movement through two independent pathways, the indirect- and the hyperdirect-pathways. The globus pallidus (GP) has always been viewed as a simple relay within these two pathways, but its importance has changed drastically with the discovery of two functionally-distinct cell types, namely the prototypic and the arkypallidal neurons. Classic BG models suggest that all GP neurons receive GABAergic inputs from striato-pallidal indirect spiny projection neurons and glutamatergic inputs from subthalamic neurons. However, whether this synaptic connectivity scheme applies to both GP cell-types is currently unknown. Here, we optogenetically dissect the input organization of prototypic and arkypallidal neurons and further define the circuit mechanism underlying action inhibition in BG. Our results highlight that an increased activity of arkypallidal neurons is required to inhibit locomotion. Finally, this work supports the view that arkypallidal neurons are part of a novel disynaptic feedback loop that broadcast inhibitory control on movement execution.

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Section: Stn Inputs Cause a Disynaptic Inhibition In Arkypallidal Neumentioning

confidence: 52%

A disynaptic circuit in the globus pallidus controls locomotion inhibition

Aristieta

Barresi

Lindi

et al. 2020

Preprint

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“…The Pitx2 gene encodes a transcription factor essential for STN development and function [26][27][28] . We recently verified that expression of the optogenetic ion channel Channelrhodopsin (ChR2) in the STN of Pitx2-Cre mice causes post-synaptic currents and glutamate release in STN target areas upon photostimulation 24,25 , thus validating the use of optogenetics in Pitx2-Cre mice for the study of STN.…”

Section: Expression Of Optogenetic Constructs In the Stn Of Pitx2-crementioning

confidence: 88%

“…By implementing optogenetics, new possibilities to directly compare the behavioral readout upon STN excitation and inhibition has opened up. Based on our previous data showing that 20 Hz photostimulation was sufficient to release glutamate in the GP of Pitx2/ChR2 mice 25 , a photoexcitation protocol designed for behavioral motor analysis was formulated. We found that GP neurons were excited already upon a 0. the open field test, immediate self-grooming was initiated upon STN excitation.…”

Section: Discussionmentioning

confidence: 99%

“…This finding verified functional connectivity between the STN and GP. Next, based on previous confirmation of glutamate release upon optogenetic excitation 25 , a photostimulation protocol designed to drive STN excitation in freely-moving animals was tested (Behavior protocol, Hz, 5 ms pulses, 5-8 mW; 100 seconds). Recordings in the GP identified increased frequency and firing rate of GP neurons for the whole duration of the stimulation, after which they returned to normal ( Figure 2G-H).…”

Section: Optogenetic Activation Excites Stn Neurons and Induces Post-mentioning

confidence: 99%

“…In this study, we aimed to tease out the impact of the STN on several movement parameters during non-pathological conditions. Based on our previous work validating optogenetic excitation of the STN using Pitx2-Cre mice to achieve selectivity 24,25 , protocols were here designed to allow direct comparison of the impact of optogenetic STN excitation and inhibition on motor output. Results now show that optogenetic excitation and inhibition gives rise to distinct mirror effects in several different motor parameters: STN inhibition enhances locomotion and reduces grooming; STN excitation reduces locomotion and induces grooming; STN excitation reduces balance and coordination.…”

Section: Introductionmentioning

confidence: 99%

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Optogenetic investigation into the role of the subthalamic nucleus in motor control

Guillaumin

Serra

Georges

et al. 2020

Preprint

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AbstractBackgroundThe subthalamic nucleus (STN) is a major regulator of intended movements. The STN is controlled by both excitatory and inhibitory inputs. Dysregulation of the STN contributes to motor deficiency in Parkinson’s disease (PD). Both STN-lesioning and high-frequency electrical stimulation of the STN improve motor symptoms in PD.However, despite a pivotal clinical target, the natural role of the STN in motor regulation has remained elusive. In fact, controlled excitatory or inhibitory manipulations have been poorly explored. By controlled regulation, new functional knowledge of the STN can be reached.ObjectiveTo uncover the role of the STN in several aspects of motor function during non-pathological conditions.MethodsThe Pitx2-Cre mouse model has been described as a transgenic tool to direct genetic targeting events to the STN. Here, Pitx2-Cre mice were used to direct optogenetic excitation and inhibition to the STN. The impact of each type of stimulation on motor output was recorded and compared.ResultsOptogenetic excitation of the STN triggered action potentials in a key component of the basal ganglia. Optogenetic excitation of the STN in the freely-moving animal reduced vertical and horizontal movement, induced immediate grooming and caused loss of motor coordination. In contrast, optogenetic inhibition increased general locomotion and reduced natural grooming. Opposite rotations were observed upon unilateral excitation and inhibition of the STN.ConclusionsOptogenetic excitation and inhibition of the STN give rise to opposite motor responses in several parameters relevant to voluntary motor control that are commonly disturbed in PD.

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