Journal article
Molecular Brain, 2022
APA
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Mustafá, E. R., Gambeta, E., Stringer, R. N., Souza, I. A., Zamponi, G., & Weiss, N. (2022). Electrophysiological and computational analysis of Cav3.2 channel variants associated with familial trigeminal neuralgia. Molecular Brain.
Chicago/Turabian
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Mustafá, E. R., Eder Gambeta, Robin N. Stringer, I. A. Souza, G. Zamponi, and N. Weiss. “Electrophysiological and Computational Analysis of Cav3.2 Channel Variants Associated with Familial Trigeminal Neuralgia.” Molecular Brain (2022).
MLA
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Mustafá, E. R., et al. “Electrophysiological and Computational Analysis of Cav3.2 Channel Variants Associated with Familial Trigeminal Neuralgia.” Molecular Brain, 2022.
BibTeX Click to copy
@article{e2022a,
title = {Electrophysiological and computational analysis of Cav3.2 channel variants associated with familial trigeminal neuralgia},
year = {2022},
journal = {Molecular Brain},
author = {Mustafá, E. R. and Gambeta, Eder and Stringer, Robin N. and Souza, I. A. and Zamponi, G. and Weiss, N.}
}
Trigeminal neuralgia (TN) is a rare form of chronic neuropathic pain characterized by spontaneous or elicited paroxysms of electric shock-like or stabbing pain in a region of the face. While most cases occur in a sporadic manner and are accompanied by intracranial vascular compression of the trigeminal nerve root, alteration of ion channels has emerged as a potential exacerbating factor. Recently, whole exome sequencing analysis of familial TN patients identified 19 rare variants in the gene CACNA1H encoding for Cav3.2T-type calcium channels. An initial analysis of 4 of these variants pointed to a pathogenic role. In this study, we assessed the electrophysiological properties of 13 additional TN-associated Cav3.2 variants expressed in tsA-201 cells. Our data indicate that 6 out of the 13 variants analyzed display alteration of their gating properties as evidenced by a hyperpolarizing shift of their voltage dependence of activation and/or inactivation resulting in an enhanced window current supported by Cav3.2 channels. An additional variant enhanced the recovery from inactivation. Simulation of neuronal electrical membrane potential using a computational model of reticular thalamic neuron suggests that TN-associated Cav3.2 variants could enhance neuronal excitability. Altogether, the present study adds to the notion that ion channel polymorphisms could contribute to the etiology of some cases of TN and further support a role for Cav3.2 channels.