Clinical and molecular genetic assessment of a chorea-acanthocytosis pedigree.

BACKGROUND: Chorea-acanthocytosis (ChAc) is an autosomal recessive hereditary disease characterized by neurodegeneration in the striatum and acanthocytosis that is caused by mutations in the VPS13A gene. There are only few reports that studied clinical status of the obligate carriers of ChAc. Clinical courses with follow-up neuroradiological and neuropsychological evaluations in individuals with ChAc have been rarely reported. METHODS: We followed an index patient with ChAc and evaluated the clinical features of the pedigree members. Genetic analyses of VPS13A and genes responsible for other neuroacanthocytotic and neurodegenerative diseases were performed. CONCLUSIONS: The index patient was homozygous for a 3889C>T nonsense mutation in the VPS13A gene and presented with a typical ChAc phenotype. Neuropsychological evaluation with brain imaging in the patient over 3 years revealed atrophy and a decrease in blood flow at the basal ganglia and frontal lobe, and impairment in cognitive function reflecting frontal lobe dysfunction in progressive manners. Four out of five heterozygous mutation carriers in the pedigree showed signs or symptoms potentially attributable to a heterozygous VPS13A mutation.

Brain-specific transcript variants of 5' and 3' ends of mouse VPS13A and VPS13C.

Mutations in vacuolar protein sorting 13A (VPS13A) gene are responsible for chorea-acanthocytosis (ChAc). We previously determined the full-length sequence and exon-intron structure of mouse VPS13A and generated a ChAc model mouse by using the gene targeting technique. In the process, we found diverse 5' and 3' transcript variants. Since ChAc is a rare neurodegenerative disorder, the mouse model should be useful for investigation of ChAc molecular pathogenesis, and the model's brain specific variants of VPS13A will be indispensable in these investigations. In the present study, we investigated mouse VPS13A transcript variants. We found brain-specific variants of mouse VPS13A, which may be involved in the brain-specific pathology of ChAc. In addition, we identified for the first time mouse VPS13C cDNA sequences and brain-specific variants of VPS13C.

In vivo distribution and localization of chorein.

Chorea-acanthocytosis (ChAc) is a hereditary neurodegenerative disorder caused by loss of function mutations in the VPS13A gene encoding chorein. In this study, we produced an antibody against chorein and examined its protein-level expression and localization in mouse. Immunoblot analysis revealed that chorein was expressed in a gene dose-dependent manner in the VPS13A deletion-mice that we recently developed, which confirms the sensitivity of the antibody. Chorein was highly expressed in testis, kidney, spleen, and brain, and was expressed ubiquitously in various brain regions. Subcellular analysis of the brain showed high levels of chorein in microsomal and synaptosomal fractions. Immunohistochemically, chorein-like immunoreactivity was ubiquitously observed in the brain in the neuronal perinuclear region, cytoplasm and fibers. In testis and kidney, clear cell-specific patterns of chorein-like immunoreactivity were detected. Our findings provide basic information on chorein in vivo and may contribute to taking the first step toward understanding molecular pathogenesis of ChAc.

Chorein deficiency leads to upregulation of gephyrin and GABA(A) receptor.

Chorea-acanthocytosis (ChAc) is a hereditary neurodegenerative disorder caused by loss of function mutations in the VPS13A gene encoding chorein. Recently, using a gene-targeting technique to delete exons 60-61, we produced a ChAc-model mouse that corresponds to a human disease mutation. In this study, a comparative microarray analysis of gene expression in the striatum revealed an increased level of gephyrin gene expression in the ChAc-model mice compared with wild type mice. Since gephyrin is known as a GABA(A) receptor-anchoring protein, we compared the protein-level expression and localization of gephyrin and the GABA(A) receptor alpha1 (GABRA1) and gamma2 (GABRG2) subunits. Gephyrin and GABRG2 immunoreactivities in the striatum and hippocampus of the ChAc-model mice were significantly higher than those in the wild types. Our results suggest that chorein functional loss may lead to a compensatory upregulation of gephyrin and GABRG2 in the pathologic condition in ChAc.