Mutations in GNAL: a novel cause of craniocervical dystonia.

IMPORTANCE: Mutations in the GNAL gene have recently been shown to cause primary torsion dystonia. The GNAL-encoded protein (Gαolf) is important for dopamine D1 receptor function and odorant signal transduction. We sequenced all 12 exons of GNAL in 461 patients from Germany, Serbia, and Japan, including 318 patients with dystonia (190 with cervical dystonia), 51 with hyposmia and Parkinson disease, and 92 with tardive dyskinesia or acute dystonic reactions. OBSERVATIONS: We identified the following two novel heterozygous putative mutations in GNAL: p.Gly213Ser in a German patient and p.Ala353Thr in a Japanese patient. These variants were predicted to be pathogenic in silico, were absent in ethnically matched control individuals, and impaired Gαolf coupling to D1 receptors in a bioluminescence energy transfer (BRET) assay. Two additional variants appeared to be benign because they behaved like wild-type samples in the BRET assay (p.Ala311Thr) or were detected in ethnically matched controls (p.Thr92Ala). Both patients with likely pathogenic mutations had craniocervical dystonia with onset in the fifth decade of life. No pathogenic mutations were detected in the patients with hyposmia and Parkinson disease, tardive dyskinesias, or acute dystonic reactions. CONCLUSIONS AND RELEVANCE: Mutations in GNAL can cause craniocervical dystonia in different ethnicities. The BRET assay may be a useful tool to support the pathogenicity of identified variants in the GNAL gene.

X-linked Dystonia-Parkinsonism manifesting in a female patient due to atypical turner syndrome.

BACKGROUND: Recessive X-linked dystonia-parkinsonism almost exclusively affects men. We investigated the genetic mechanisms causing this disorder in a female patient. METHODS: We confirmed the presence of an X-linked dystonia-parkinsonism-specific change in our patient by sequencing. In addition, we employed quantitative real-time PCR and array comparative genomic hybridization to determine the patient's X-chromosome copy number. RESULTS: The patient's sequence electropherogram suggested a higher amount of the mutated allele compared with the wild-type allele. Subsequently, extensive gene dosage analyses revealed a copy number of the X chromosomes between 1 and 2, indicating loss of 1 X chromosome in a subset of cells. Phenotypic reevaluation of the patient showed several clinical features of Turner syndrome. CONCLUSIONS: Our female X-linked dystonia-parkinsonism patient suffered from an undiagnosed X-chromosome monosomy in a subset of cells (45,X/46,XX), suggesting an atypical Turner syndrome and contributing the first molecular explanation for the manifestation of an X-linked dystonia-parkinsonism phenotype in women. © 2013 Movement Disorder Society.