CTG repeats associated with human genetic disease are inherently flexible.

The lengthening of tracts of CTG, CGG and GAA triplet repeats during progression of a pedigree has been associated with more than 12 human genetic diseases, including fragile X syndrome, myotonic dystrophy and Friedreich's ataxia. These repetitive sequence elements have the potential to form alternative DNA secondary structures that may contribute to their instability. The alternative DNA secondary structures may mediate errors during DNA replication, repair or recombination of the triplet repeat, leading to expansion. Here we show that DNA composed of pure CTG or CGG repeats exhibits anomalously fast mobility on polyacrylamide gels, confirming a previous observation for DNA containing CTG and CGG triplet repeats flanked by mixed sequence DNA. Moreover, we show that even short tracts of duplex CTG repeats have an unusual helix structure. CTG repeats reduce overall curvature associated with phased A-tract or GGCC curves, but alone they do not introduce curvature into DNA. The reduction in curvature of phased A-tracts by CTG repeats is similar to that afforded by an interspersed flexible region associated with a (TT).(TT) mispair. CTG-containing DNAs exhibit a rapid rate of cyclization, consistent with a flexible helix. These results suggest that tracts of (CTG).(CAG) repeats are inherently flexible. In addition, our results suggest that the unusual rapid electrophoretic mobility of CTG or CGG-containing DNA may be a consequence of an extended flexible DNA chain.