DNA can transiently fold into variable arrangements, which are expected to exploit regulatory functions. Guanine-rich sequences can fold into G-quadruplexes (G4s), while the complementary strand adopts potentially i-Motif (iM) arrangements. Their concomitant formation at the same genomic site is still under debate. However, recently, single-molecule analyses have shown the simultaneous G4 and iM presence within a double-stranded (ds) DNA context, addressing them as synergic blockers of replication fork progression. While these findings point to a functional interplay between G4 and iM, a deeper understanding of the factors enabling their coexistence remains unclear. In this work, we unravel the equilibria governing G4- and iM-folding within dsDNA, adopting an extensive biophysical approach allowing analysis of an optimized modular system, scalable across constructs of increasing molecular complexity. Our findings corroborate the simultaneous formation model and further clarify the thermodynamic determinants driving duplex denaturation and the favorable folding of stable G4 and iM structures.
Auricchio et al. (Mon,) studied this question.