Dysfunction of parvalbumin neurons in the cerebellar nuclei produces an action tremor
Mu Zhou, … , Wei Xu, Thomas C. Südhof
Mu Zhou, … , Wei Xu, Thomas C. Südhof
Published July 7, 2020
Citation Information: J Clin Invest. 2020;130(10):5142-5156. https://doi.org/10.1172/JCI135802.
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Research Article Neuroscience

Dysfunction of parvalbumin neurons in the cerebellar nuclei produces an action tremor

Abstract

Essential tremor is a common brain disorder affecting millions of people, yet the neuronal mechanisms underlying this prevalent disease remain elusive. Here, we showed that conditional deletion of synaptotagmin-2, the fastest Ca2+ sensor for synaptic neurotransmitter release, from parvalbumin neurons in mice caused an action tremor syndrome resembling the core symptom of essential tremor patients. Combining brain region–specific and cell type–specific genetic manipulation methods, we found that deletion of synaptotagmin-2 from excitatory parvalbumin-positive neurons in cerebellar nuclei was sufficient to generate an action tremor. The synaptotagmin-2 deletion converted synchronous into asynchronous neurotransmitter release in projections from cerebellar nuclei neurons onto gigantocellular reticular nucleus neurons, which might produce an action tremor by causing signal oscillations during movement. The tremor was rescued by completely blocking synaptic transmission with tetanus toxin in cerebellar nuclei, which also reversed the tremor phenotype in the traditional harmaline-induced essential tremor model. Using a promising animal model for action tremor, our results thus characterized a synaptic circuit mechanism that may underlie the prevalent essential tremor disorder.

Authors

Mu Zhou, Maxwell D. Melin, Wei Xu, Thomas C. Südhof

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Figure 6

Loss of fast synchronous neurotransmitter release at CBN → GRN synapses may induce the action tremor.

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Loss of fast synchronous neurotransmitter release at CBN → GRN synapses ...
(A) Bright field and fluorescence images of GRN sections from PVcre Syt2fl or control mice showing ChR2-EYFP expression in nerve terminals originating from CBN neurons. Slice is arranged upright. (B) Example traces showing spontaneous EPSCs recorded from GRN neurons in slices from control and PVcre Syt2fl mice. (C) Summary graph of the sEPSC frequency (left) and amplitude (right) recorded from GRN neurons in slices from control and PVcre Syt2fl mice (n = 12 control, n = 22 PVcre Syt2fl for both frequency and amplitude). (D) Example traces showing 1-ms, 50-Hz blue laser–evoked EPSCs recorded from GRN neurons in control (left) and PVcre Syt2fl (right) slices. (E) Summary of 50-Hz light–evoked EPSC amplitude recorded from GRN neurons in control and PVcre Syt2fl slices. All amplitudes are normalized to the first EPSC responses for both groups (n = 5 control, n = 7 PVcre Syt2fl). For C and E, data are shown as means ± SEM from at least 3 independent litters. *P < 0.05; **P < 0.01; ***P < 0.001 by 2-sided, unpaired t test (C) or 2-sided, unpaired t test (E). Scale bars: 0.5 mm (A); 10 pA (B, vertical); 1 s (B, horizontal); 20 pA (D vertical left); 0.1 s (D horizontal left); 4 pA (D vertical right); 0.1 s (D horizontal right).