Imperfect hairpins formed by CTG trinucleotide repeats are heteroduplex DNA molecules in living cells

Abstract

AbstractThere are over fifty microsatellite expansion disorders, often neurodegenerative pathologies, due to large expansions of tandem repeat sequences. These microsatellites vary in motif composition, size and copy number in the genome. The ability of these repeats to form secondary structuresin vitrois strongly suspected to trigger the expansion process and therefore, the pathology. However, there is no formal proof that similar structures are formedin vivo, in living and replicating cells.We are focused on the CTG trinucleotide repeat whose expansion is responsible for myotonic dystrophy type 1 (DM1 or Steinert disease), affecting 1 in 8,000 people worldwide.A series of llama nanobodies (VHH) were selected to bind to the secondary structure formed by a synthetic imperfect CTG hairpin. Yeast one-hybrid was used to identify VHH that were able to activate a reporter genein vivo. One of them was shown to be very specific since it binds a CTG hairpin but not a CAG hairpin or a GC-rich sequence. This nanobody also bind to long CTG trinucleotide repeats carried by plasmidic or genomic DNAs, proportionally to the number of repeats, suggesting that longer repeats tend to form more frequently imperfect hairpins. Finally, the VHH was bound to a protein G column and used to selectively enrich structure-containing DNA molecules, that were further observed by electron microscopy. They exhibit different kinds of structures in which only one strand is folded into an imperfect hairpin.Our results unambiguously show that alternative DNA structures are transiently formed by CTG trinucleotide repeats in living bacterial and yeast cells and suggest that imperfect CTG hairpins mainly existin vivomainly as heteroduplex DNA molecules.