| Literature DB >> 30588707 |
Joana R Loureiro1,2,3, Cláudia L Oliveira1,2, Carolina Mota1,2, Ana F Castro1,2, Cristina Costa4, José L Loureiro2,5,6, Paula Coutinho2,5, Sandra Martins7,8, Jorge Sequeiros2,3,5, Isabel Silveira1,2.
Abstract
Dynamic mutations by microsatellite instability are the molecular basis of a growing number of neuromuscular and neurodegenerative diseases. Repetitive stretches in the human genome may drive pathogenicity, either by expansion above a given threshold, or by insertion of abnormal tracts in nonpathogenic polymorphic repetitive regions, as is the case in spinocerebellar ataxia type 37 (SCA37). We have recently established that this neurodegenerative disease is caused by an (ATTTC)n insertion within an (ATTTT)n in a noncoding region of DAB1. We now investigated the mutational mechanism that originated the (ATTTC)n insertion within an ancestral (ATTTT)n . Approximately 3% of nonpathogenic (ATTTT)n alleles are interspersed by AT-rich motifs, contrarily to mutant alleles that are composed of pure (ATTTT)n and (ATTTC)n stretches. Haplotype studies in unaffected chromosomes suggested that the primary mutational mechanism, leading to the (ATTTC)n insertion, was likely one or more T>C substitutions in an (ATTTT)n pure allele of approximately 200 repeats. Then, the (ATTTC)n expanded in size, originating a deleterious allele in DAB1 that leads to SCA37. This is likely the mutational mechanism in three similar (TTTCA)n insertions responsible for familial myoclonic epilepsy. Because (ATTTT)n tracts are frequent in the human genome, many loci could be at risk for this mutational process.Entities:
Keywords: ATTTC insertion; DAB1; reelin adapter protein; repeat expansion; repeat instability; repeat interruption; spinocerebellar ataxia type 37
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Year: 2019 PMID: 30588707 DOI: 10.1002/humu.23704
Source DB: PubMed Journal: Hum Mutat ISSN: 1059-7794 Impact factor: 4.878