New Spinocerebellar Ataxia Subtype Caused by Mutation Triggering Mitochondrial Dysregulation (SCA49)

Overview

Journal Brain Commun

Publisher Oxford University Press

Specialty Neurology

Date 2022 Mar 21

PMID 35310830

Authors

Marc Corral-Juan

Pilar Casquero

Natalia Giraldo-Restrepo

Steve Laurie

Alicia Martinez-Pineiro

Raidili Cristina Mateo-Montero

Lourdes Ispierto

Dolores Vilas

Eduardo Tolosa

Victor Volpini

Ramiro Alvarez-Ramo

Ivelisse Sanchez

Antoni Matilla-Duenas

Affiliations

Soon will be listed here.

Abstract

Spinocerebellar ataxias consist of a highly heterogeneous group of inherited movement disorders clinically characterized by progressive cerebellar ataxia variably associated with additional distinctive clinical signs. The genetic heterogeneity is evidenced by the myriad of associated genes and underlying genetic defects identified. In this study, we describe a new spinocerebellar ataxia subtype in nine members of a Spanish five-generation family from Menorca with affected individuals variably presenting with ataxia, nystagmus, dysarthria, polyneuropathy, pyramidal signs, cerebellar atrophy and distinctive cerebral demyelination. Affected individuals presented with horizontal and vertical gaze-evoked nystagmus and hyperreflexia as initial clinical signs, and a variable age of onset ranging from 12 to 60 years. Neurophysiological studies showed moderate axonal sensory polyneuropathy with altered sympathetic skin response predominantly in the lower limbs. We identified the c.1877C > T (p.Ser626Leu) pathogenic variant within the gene as the disease causative genetic defect with a significant log-odds score ( = 3.43; = 0.00; < 3.53 × 10). We demonstrate the mitochondrial location of human SAMD9L protein, and its decreased levels in patients' fibroblasts in addition to mitochondrial perturbations. Furthermore, mutant SAMD9L in zebrafish impaired mobility and vestibular/sensory functions. This study describes a novel spinocerebellar ataxia subtype caused by mutation, SCA49, which triggers mitochondrial alterations pointing to a role of SAMD9L in neurological motor and sensory functions.

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