Quantitative Analysis of Nucleic Acid Stability with Ligands Under High Pressure to Design Novel Drugs Targeting G-Quadruplexes

Volumetric Strategy for Quantitatively Elucidating a Local Hydration Network around a G-Quadruplex

Hydration around nucleic acids, such as DNA and RNA, is an important factor not only for the stability of nucleic acids but also for their interaction with binding molecules. Thus, it is necessary to quantitatively elucidate the hydration properties of nucleic acids around a certain structure. In this study, volumetric changes in G-quadruplex (G4) RNA formation were investigated by systematically changing the number of G-quartet stacks under high pressure. The volumetric contribution at the level of each G4 structural unit revealed that the core G4 helix was significantly more dehydrated than the other parts, including the edges of G-quartets and loops. These findings will help in predicting the binding of G4 ligands on the surface of G4, depending on the chemical structure of the ligand and solution environment. Therefore, the preset volumetric parameter provides information that can predict molecular interactions in G4 formations during molecular crowding in cells.

Quantitative Analysis of Stall of Replicating DNA Polymerase by G-Quadruplex Formation

The formation of guanine-quadruplexes (G4s) in genomic DNA and RNA inhibits replication, transcription, and translation. Although several regions of the human genome exhibit G4-forming potential, the stability and topology of the G4s formed vary depending on the molecular environment. Here, we describe a protocol to quantitatively analyze the inhibitory effects of G4s with different stabilities and topologies on replication in conditions of molecular crowding.