Structural basis for triplet repeat disorders: a computational analysis

doi:10.1093/bioinformatics/15.11.918

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Bioinformatics Vol. 15 no. 11 1999
Pages 918-929
© 1999 Oxford University Press

Structural basis for triplet repeat disorders: a computational analysis

Pierre Baldi ¹, Søren Brunak ², Yves Chauvin ³ and Anders Gorm Pedersen ²

¹ Department of Information and Computer Science and Department of Biological Chemistry, College of Medicine, University of California, Irvine, Irvine, CA 92697-3425, USA
² Center for Biological Sequence Analysis, The Technical University of Denmark, DK-2800 Lyngby, Denmark
³ Net-ID, Inc., San Francisco, CA 94114, USA

Pierre Baldi

Motivation: Over a dozen major degenerative disorders, including myotonic distrophy, Huntington’s disease and fragileX syndrome, result from unstable expansions of particular trinucleotides. Remarkably, only some of all the possible triplets, namely CAG/CTG, CGG/CCG and GAA/TTC, have been associated withthe known pathological expansions. This raises some basicquestions at the DNA level. Why do particular triplets seemto be singled out? What is the mechanism for their expansionand how does it depend on the triplet itself? Could othertriplets or longer repeats be involved in other diseases?

Results: Using several different computational models of DNA structure, we show that the triplets involved in the pathological repeats generally fall into extreme classes. Thus, CAG/CTGrepeats are particularly flexible, whereas GCC, CGG and GAArepeats appear to display both flexible and rigid (but curved)characteristics depending on the method of analysis. The factthat (1) trinucleotide repeats often become increasingly unstablewhen they exceed a length of approximately 50 repeats, and(2) repeated 12-mers display a similar increase in instabilityabove 13 repeats, together suggest that approximately 150bp is a general threshold length for repeat instability. Sincethis is about the length of DNA wrapped up in a single nucleosomecore particle, we speculate that chromatin structure may playan important role in the expansion mechanism. We furthermoresuggest that expansion of a dodecamer repeat, which we predictto have very high flexibility, may play a role in the pathogenesisof the neurodegenerative disorder multiple system atrophy(MSA).

Contact: pfbaldi{at}ics.uci.edu, yves{at}netid.com, brunak{at}cbs.dtu.dk, gorm{at}cbs.dtu.dk

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