Interactions of the human telomere sequence with the nanocavity of the α-hemolysin ion channel reveal structure-dependent electrical signatures for hybrid folds.

Human telomeric DNA consists of tandem repeats of the sequence 5'-TTAGGG-3', including a 3' terminal single-stranded overhang of 100-200 nucleotides that can fold into quadruplex structures in the presence of suitable metal ions. In the presence of an applied voltage, the α-hemolysin (α-HL) protein ion channel can produce unique current patterns that are found to be characteristic for various interactions between G-quadruplexes and the protein nanocavity. In this study, the human telomere in a complete sequence context, 5'-TAGGG(TTAGGG)3TT-3', was evaluated with respect to its multiple folding topologies. Notably, the coexistence of two interchangeable conformations of the K(+)-induced folds, hybrid-1 and hybrid-2, were readily resolved at a single-molecule level along with triplex folding intermediates, whose characterization has been challenging in experiments that measure the bulk solution. These results enabled us to profile the thermal denaturation process of these structures to elucidate the relative distributions of hybrid-1, hybrid-2, and folding intermediates such as triplexes. For example, at 37 °C, pH 7.9, in 50 mM aqueous KCl, the ratio of hybrid-1:hybrid-2:triplex is approximately 11:5:1 in dilute solution. The results obtained lay the foundation for utilizing the α-HL ion channel as a simple tool for monitoring how small molecules and physical context shift the equilibrium between the many G-quadruplex folds of the human telomere sequence.