Bidirectional expression of the SCA8 expansion mutation: One mutation, two genes

Spinocerebellar ataxia type 8 (SCA8) is a dominantly inherited, slowly progressive neurodegenerative disorder caused by a CTG·CAG repeat expansion located on chromosome 13q21. The expansion mutation was isolated directly from the DNA of a single patient using RAPID cloning and subsequently shown to co-segregate with disease in additional ataxia families including a seven-generation kindred (the MN-A family). The size-dependent penetrance of the repeat found in the large MN-A kindred makes it appear as though some parts of the family have a dominant disorder while other parts of this same family have recessive or sporadic forms of ataxia. While the linkage and size-dependent penetrance of the SCA8 CTG·CAG expansion in the MN-A family argue that the SCA8 expansion causes ataxia, the reduced penetrance in other SCA8 families and the discovery of expansions in the general population have led to a controversy surrounding whether or not the SCA8 expansion is pathogenic. A recently reported mouse model in which SCA8 BAC-expansion but not BAC-control lines develop a progressive neurological phenotype now demonstrates the pathogenicity of the (CTG·CAG)n expansion. These mice show a loss of cerebellar GABAergic inhibition and, similar to human patients, have 1C2-positive intranuclear inclusions in Purkinje cells and other neurons. Additional studies demonstrate that the SCA8 expansion is expressed in both directions (CUG and CAG) and that a novel gene expressed in the CAG direction encodes a pure polyglutamine expansion protein (ataxin 8, ATXN8). Moreover, the expression of non-coding (CUG)n expansion transcripts (ataxin 8 opposite strand, ATXN8OS) and the discovery of intranuclear polyglutamine inclusions suggest SCA8 pathogenesis may involve toxic gainof-function mechanisms at both the protein and RNA levels. Our data, combined with the recently reported antisense transcripts spanning the DM1 repeat expansion in the CAG direction and the growing number of reports of antisense transcripts expressed throughout the mammalian genome, raises the possibility that bidirectional expression across pathogenic microsatellite expansions may occur in other expansion disorders, and that potential pathogenic effects of mutations expressed from both strands should be considered.

[1]  L. Ranum,et al.  Molecular genetics of spinocerebellar ataxia type 8 (SCA8) , 2003, Cytogenetic and Genome Research.

[2]  V. Kostic,et al.  Genetic and clinical analysis of spinocerebellar ataxia type 8 repeat expansion in Yugoslavia , 2002, Clinical genetics.

[3]  M. Koob,et al.  The KLHL1-antisense transcript ( KLHL1AS) is evolutionarily conserved. , 2002, Mammalian genome : official journal of the International Mammalian Genome Society.

[4]  Mikio Shoji,et al.  Asymptomatic CTG expansion at the SCA8 locus is associated with cerebellar atrophy on MRI , 2000, Journal of the Neurological Sciences.

[5]  N. Wood,et al.  Large, expanded repeats in SCA8 are not confined to patients with cerebellar ataxia , 2000, Nature Genetics.

[6]  R. Mutani,et al.  Analysis of SCA8 and SCA12 loci in 134 Italian ataxic patients negative for SCA1–3, 6 and 7 CAG expansions , 2002, Journal of Neurology.

[7]  A. Zeman,et al.  Spinocerebellar ataxia type 8 in Scotland: genetic and clinical features in seven unrelated cases and a review of published reports , 2004, Journal of Neurology, Neurosurgery & Psychiatry.

[8]  C. Ross,et al.  A repeat expansion in the gene encoding junctophilin-3 is associated with Huntington disease–like 2 , 2001, Nature Genetics.

[9]  M. Mutsuddi,et al.  The Spinocerebellar Ataxia 8 Noncoding RNA Causes Neurodegeneration and Associates with Staufen in Drosophila , 2004, Current Biology.

[10]  T. Bird,et al.  SCA8 CTG repeat: en masse contractions in sperm and intergenerational sequence changes may play a role in reduced penetrance. , 2000, Human molecular genetics.

[11]  S. Sorbi,et al.  Genetic and clinical analysis of spinocerebellar ataxia type 8 repeat expansion in Italy. , 2001, Archives of neurology.

[12]  K. Matsumoto,et al.  Cellular Activities of 20K- and 22K-hGH Do Not Necessarily Correlate with Their Binding Affinities for Rat GH Receptor , 2001, Hormone Research in Paediatrics.

[13]  D. Geschwind,et al.  SCA8 repeat expansions in ataxia: A controversial association , 2001, Neurology.

[14]  S. Tapscott,et al.  Antisense transcription and heterochromatin at the DM1 CTG repeats are constrained by CTCF. , 2005, Molecular cell.

[15]  L. Schut,et al.  Spinocerebellar ataxia type 8 , 2000, Neurology.

[16]  J. Lieberman,et al.  An unstable trinucleotide-repeat region on chromosome 13 implicated in spinocerebellar ataxia: a common expansion locus. , 2000, American journal of human genetics.

[17]  A. Andrés,et al.  Understanding the dynamics of Spinocerebellar Ataxia 8 (SCA8) locus through a comparative genetic approach in humans and apes , 2003, Neuroscience Letters.

[18]  J. Houseley,et al.  Myotonic dystrophy associated expanded CUG repeat muscleblind positive ribonuclear foci are not toxic to Drosophila. , 2005, Human molecular genetics.

[19]  J. Nemes,et al.  Erratum: The SCA8 transcript is an antisense RNA to a brain-specific transcript encoding a novel actin-binding protein (KLHL1) (Human Molecular Genetics (2000) vol. 9 (1543-1551)) , 2000 .

[20]  J. Vincent,et al.  Spinocerebellar ataxia type 8: molecular genetic comparisons and haplotype analysis of 37 families with ataxia. , 2004, American journal of human genetics.

[21]  Thorsten Schmidt,et al.  Autosomal dominant cerebellar ataxias: clinical features, genetics, and pathogenesis , 2004, The Lancet Neurology.

[22]  V. Willour,et al.  A disorder similar to Huntington's disease is associated with a novel CAG repeat expansion , 2001, Annals of neurology.

[23]  T. Ebner,et al.  Bidirectional expression of CUG and CAG expansion transcripts and intranuclear polyglutamine inclusions in spinocerebellar ataxia type 8 , 2006, Nature Genetics.

[24]  Harry T Orr,et al.  Targeted Deletion of a Single Sca8 Ataxia Locus Allele in Mice Causes Abnormal Gait, Progressive Loss of Motor Coordination, and Purkinje Cell Dendritic Deficits , 2006, The Journal of Neuroscience.

[25]  M. Oda,et al.  SCA8 repeat expansion: large CTA/CTG repeat alleles are more common in ataxic patients, including those with SCA6. , 2003, American journal of human genetics.

[26]  T. Cooper,et al.  RNA-mediated neuromuscular disorders. , 2006, Annual review of neuroscience.

[27]  A. Andrés,et al.  Comparative Genetics of Functional Trinucleotide Tandem Repeats in Humans and Apes , 2004, Journal of Molecular Evolution.

[28]  J. Nemes,et al.  The SCA8 transcript is an antisense RNA to a brain-specific transcript encoding a novel actin-binding protein (KLHL1). , 2000, Human molecular genetics.

[29]  K. Okamoto,et al.  Molecular and clinical analyses of spinocerebellar ataxia type 8 in Japan , 2000, Neurology.

[30]  M. Owen,et al.  Long repeat tracts at SCA8 in major psychosis. , 2000, American journal of medical genetics.

[31]  T. Cooper,et al.  MBNL1 and CUGBP1 modify expanded CUG-induced toxicity in a Drosophila model of myotonic dystrophy type 1. , 2006, Human molecular genetics.

[32]  T. Bird,et al.  An untranslated CTG expansion causes a novel form of spinocerebellar ataxia (SCA8) , 1999, Nature Genetics.

[33]  D. Hoffman-Zacharska,et al.  SCA8 repeat expansion coexists with SCA1--not only with SCA6. , 2003, American journal of human genetics.

[34]  T. Hudson,et al.  Direct detection of novel expanded trinucleotide repeats in the human genome , 1993, Nature Genetics.

[35]  M. Savontaus,et al.  Clinical and genetic findings in Finnish ataxia patients with the spinocerebellar ataxia 8 repeat expansion , 2000, Annals of neurology.

[36]  S. Batalov,et al.  Antisense Transcription in the Mammalian Transcriptome , 2005, Science.

[37]  T. Bird,et al.  Rapid cloning of expanded trinucleotide repeat sequences from genomic DNA , 1998, Nature Genetics.

[38]  P. Maciel,et al.  High germinal instability of the (CTG)n at the SCA8 locus of both expanded and normal alleles. , 2000, American journal of human genetics.