Kinetic and Thermodynamic Control of G-Quadruplex Polymorphism by Na + and K + Cations.

G-Quadruplexes (G4s) are ubiquitous nucleic acid folding motifs that exhibit structural diversity that is dependent on cationic conditions. In this work, we exploit temperature-controlled single-molecule fluorescence resonance energy transfer (smFRET) to elucidate the kinetic and thermodynamic mechanisms by which monovalent cations (K + and Na + ) impact folding topologies for a simple G-quadruplex sequence (5'-GGG-(TAAGGG) 3 -3') with a three-state folding equilibrium. Kinetic measurements indicate that Na + and K + influence G4 formation in two distinctly different ways: the presence of Na + modestly enhances an antiparallel G4 topology through an induced fit (IF) mechanism with a low affinity ( K d = 228 ± 26 mM), while K + drives G4 into a parallel/hybrid topology via a conformational selection (CS) mechanism with much higher affinity ( K d = 1.9 ± 0.2 mM). Additionally, temperature-dependent studies of folding rate constants and equilibrium ratios reveal distinctly different thermodynamic driving forces behind G4 binding to K + (Δ H ° bind > 0, Δ S ° bind > 0) versus Na + (Δ H ° bind < 0, Δ S ° bind < 0), which further illuminates the diversity of the possible pathways for monovalent facilitation of G-quadruplex folding.