CAG Repeats Determine Brain Atrophy in Spinocerebellar Ataxia 17: A VBM Study

Abnormal repeat length has been associated with an earlier age of onset and more severe disease progression in the rare neurodegenerative disorder spinocerebellar ataxia 17 (SCA17).To determine whether specific structural brain degeneration and rate of disease progression in SCA17 might be associated with the CAG repeat size, observer-independent voxel-based morphometry was applied to high-resolution magnetic resonance images of 16 patients with SCA17 and 16 age-matched healthy controls. The main finding contrasting SCA17 patients with healthy controls demonstrated atrophy in the cerebellum bilaterally. Multiple regression analyses with available genetic data and also post-hoc correlations revealed an inverse relationship again with cerebellar atrophy. Moreover, we found an inverse relationship between the CAG repeat length and rate of disease progression.Our results highlight the fundamental role of the cerebellum in this neurodegenerative disease and support the genotype-phenotype relationship in SCA17 patients. Genetic factors may determine individual susceptibility to neurodegeneration and rate of disease progression

Demographic and clinical data in SCA17 patients.

<p><b>Abbr.:</b> DD, Disease Duration; ICARS, International Cooperative Ataxia Rating Scale; MMSE, Mini-Mental State Examination.</p

Categorical comparison of SCA17 patients and healthy controls.

<p>Categorical comparison of SCA17 patients and healthy controls.</p

Multiple regressions with abnormal CAG repeat length.

<p>Multiple regressions with abnormal CAG repeat length.</p

Possible Genetic Heterogeneity of Spinocerebellar Ataxia Linked to Chromosome 15

Autosomal dominant spinocerebellar ataxias (SCAs) are a clinically and genetically heterogeneous group of neurodegenerative disorders. We investigated an SCA family from Serbia of Roma ethnic origin; four affected and nine unaffected family members underwent a detailed neurological examination. The presenting symptom in all patients was gait unsteadiness in early adulthood. Additional features included pyramidal signs, depression, and cognitive impairment. The condition follows an autosomal dominant pattern of inheritance. After excluding repeat expansions in nine known SCA genes, a genome-wide linkage analysis with 412 microsatellite markers localized the putative disease gene to a 40.7 cM (42.5 Mb) region on chromosome 15q between markers D15S1006 and D15S116. The maximum model-based multipoint LOD score was 1.75. This region is only 4.3 Mb away from the SCA11 (TTBK2) gene. Accordingly, mutations in TTBK2 were not found, suggesting a second SCA gene on chromosome 15q as cause of this novel form of SCA. In addition, we excluded alterations in two candidate genes in the linked region, namely expansion of a polyglutamine-coding CAG repeat in ARID3B and mutations in SEMA6D. (C) 2010 Movement Disorder Societ

Recessive dystonia-ataxia syndrome in a Turkish family caused by a COX20 (FAM36A) mutation

DYTCA is a syndrome that is characterized by predominant dystonia and mild cerebellar ataxia. We examined two affected siblings with healthy, consanguineous, Turkish parents. Both patients presented with a combination of childhood-onset cerebellar ataxia, dystonia, and sensory axonal neuropathy. In the brother, dystonic features were most pronounced in the legs, while his sister developed torticollis. Routine diagnostic investigations excluded known genetic causes. Biochemical analyses revealed a mitochondrial respiratory chain complex IV and a coenzyme Q10 deficiency in a muscle biopsy. By exome sequencing, we identified a homozygous missense mutation (c.154A>C; p.Thr52Pro) in both patients in exon 2 of the COX20 (FAM36A) gene, which encodes a complex IV assembly factor. This variant was confirmed by Sanger sequencing, was heterozygous in both parents, and was absent from 427 healthy controls. The exact same mutation was recently reported in a patient with ataxia andmuscle hypotonia. Among 128 early-onset dystonia and/ or ataxia patients, we did not detect any other patient with a COX20 mutation. cDNA sequencing and semi-quantitative analysis were performed in fibroblasts from one of our homozygous mutation carriers and six controls. In addition to the exchange of an amino acid, the mutation led to a shift in splicing. In conclusion, we extend the phenotypic spectrumof a recently identified mutation in COX20 to a recessively inherited, early-onset dystonia-ataxia syndrome that is characterized by reduced complex IV activity. Further, we confirm a pathogenic role of this mutation in cerebellar ataxia, but this mutation seems to be a rather rare cause