Why do G-quadruplexes dimerize through the 5'-ends? Driving forces for G4 DNA dimerization examined in atomic detail.
Mateusz KogutCyprian KleistJacek CzubPublished in: PLoS computational biology (2019)
G-quadruplexes (G4) are secondary structures formed by guanine-rich nucleic acid sequences and shown to exist in living cells where they participate in regulation of gene expression and chromosome maintenance. G-quadruplexes with solvent-exposed guanine tetrads show the tendency to associate together through cofacial stacking, which may be important for packaging of G4-forming sequences and allows for the design of higher-order G4 DNA structures. To understand the molecular driving forces for G4 association, here, we study the binding interaction between two parallel-stranded G-quadruplexes using all-atom molecular dynamics simulations. The predicted dimerization free energies show that direct binding through the 5'-G-tetrads is the most preferred of all possible end-to-end stacking orientations, consistently with all available experimental data. Decomposition of dimerization enthalpies in combination with simulations at varying ionic strength further indicate that the observed orientational preferences arise from a fine balance between the electrostatic repulsion of the sugar-phosphate backbones and favorable counterion binding at the dimeric interface. We also demonstrate how these molecular-scale findings can be used to devise means of controlling G4 dimerization equilibrium, e.g., by altering salt concentration and using G4-targeted ligands.
Keyphrases
- molecular dynamics simulations
- nucleic acid
- single molecule
- living cells
- gene expression
- molecular dynamics
- fluorescent probe
- binding protein
- molecular docking
- circulating tumor
- dna binding
- high resolution
- dna methylation
- ionic liquid
- cell free
- density functional theory
- electronic health record
- big data
- air pollution
- genetic diversity
- deep learning
- drug delivery
- artificial intelligence
- mass spectrometry