BACKGROUND: Lafora's disease is a progressive myoclonus epilepsy with pathognomonic inclusions (polyglucosan bodies) caused by mutations in the EPM2A gene. EPM2A codes for laforin, a protein with unknown function. Mutations have been reported in the last three of the gene's exons. To date, the first exon has not been determined conclusively. It has been predicted based on genomic DNA sequence analysis including comparison with the mouse homologue. OBJECTIVES: 1) To detect new mutations in exon 1 and establish the role of this exon in Lafora's disease. 2) To generate hypotheses about the biological function of laforin based on bioinformatic analyses. METHODS: 1) PCR conditions and components were refined to allow amplification and sequencing of the first exon of EPM2A. 2) Extensive bioinformatic analyses of the primary structure of laforin were completed. RESULTS: 1) Seven new mutations were identified in the putative exon 1. 2) Laforin is predicted not to localize to the cell membrane or any of the organelles. It contains all components of the catalytic active site of the family of dual-specificity phosphatases. It contains a sequence predicted to encode a carbohydrate binding domain (coded by exon 1) and two putative glucohydrolase catalytic sites. CONCLUSIONS: The identification of mutations in exon 1 of EPM2A establishes its role in the pathogenesis of Lafora's disease. The presence of potential carbohydrate binding and cleaving domains suggest a role for laforin in the prevention of accumulation of polyglucosans in healthy neurons.
BACKGROUND:Lafora's disease is a progressive myoclonus epilepsy with pathognomonic inclusions (polyglucosan bodies) caused by mutations in the EPM2A gene. EPM2A codes for laforin, a protein with unknown function. Mutations have been reported in the last three of the gene's exons. To date, the first exon has not been determined conclusively. It has been predicted based on genomic DNA sequence analysis including comparison with the mouse homologue. OBJECTIVES: 1) To detect new mutations in exon 1 and establish the role of this exon in Lafora's disease. 2) To generate hypotheses about the biological function of laforin based on bioinformatic analyses. METHODS: 1) PCR conditions and components were refined to allow amplification and sequencing of the first exon of EPM2A. 2) Extensive bioinformatic analyses of the primary structure of laforin were completed. RESULTS: 1) Seven new mutations were identified in the putative exon 1. 2) Laforin is predicted not to localize to the cell membrane or any of the organelles. It contains all components of the catalytic active site of the family of dual-specificity phosphatases. It contains a sequence predicted to encode a carbohydrate binding domain (coded by exon 1) and two putative glucohydrolase catalytic sites. CONCLUSIONS: The identification of mutations in exon 1 of EPM2A establishes its role in the pathogenesis of Lafora's disease. The presence of potential carbohydrate binding and cleaving domains suggest a role for laforin in the prevention of accumulation of polyglucosans in healthy neurons.
Authors: E M Chan; D E Bulman; A D Paterson; J Turnbull; E Andermann; F Andermann; G A Rouleau; A V Delgado-Escueta; S W Scherer; B A Minassian Journal: J Med Genet Date: 2003-09 Impact factor: 6.318
Authors: Wei Wang; Hannes Lohi; Alexander V Skurat; Anna A DePaoli-Roach; Berge A Minassian; Peter J Roach Journal: Arch Biochem Biophys Date: 2006-11-03 Impact factor: 4.013
Authors: Carlos Romá-Mateo; Maria Del Carmen Solaz-Fuster; José Vicente Gimeno-Alcañiz; Vikas V Dukhande; Jordi Donderis; Carolyn A Worby; Alberto Marina; Olga Criado; Antonius Koller; Santiago Rodriguez De Cordoba; Matthew S Gentry; Pascual Sanz Journal: Biochem J Date: 2011-10-15 Impact factor: 3.857