Issue 35, 2022

Mutual effects between single-stranded DNA conformation and Na+–Mg2+ ion competition in mixed salt solutions

Abstract

The ion-dependence of single-stranded DNA (ssDNA) conformational changes has attracted growing attention because of its biological and technological importance. Although single-species ion effects have been extensively explored, it is challenging to study the ssDNA conformational properties under mixed monovalent/divalent ion conditions due to the complications of ssDNA flexibility and ion–ion competition. In this study, we apply Langevin dynamics simulations to investigate mixed Na+/Mg2+ ion-dependent ssDNA conformations. The ssDNA structure is described using a coarse-grained model, in which the phosphate, base, and sugar of each nucleotide are represented by three different beads. A novel improvement in our simulation model is that mixed-salt-related electrostatic interactions are computed via combining Manning counterion condensation (MCC) theory with the Monte Carlo tightly bound ion (MCTBI) model. Based on this MCC-MCTBI combination, we report new empirical functions to describe the ion-concentration-dependent and ssDNA conformation/structure-dependent electrostatic effects. The calculation results relating to the ion binding properties and the simulation results relating to the ssDNA conformational properties are validated against experimental results. In addition, our simulation results suggest a quantitative relationship between the ssDNA conformation and Na+–Mg2+ competition; this in turn reveals their mutual impact in the ion atmosphere.

Graphical abstract: Mutual effects between single-stranded DNA conformation and Na+–Mg2+ ion competition in mixed salt solutions

Supplementary files

Article information

Article type
Paper
Submitted
16 Jun 2022
Accepted
18 Aug 2022
First published
19 Aug 2022

Phys. Chem. Chem. Phys., 2022,24, 20867-20881

Mutual effects between single-stranded DNA conformation and Na+–Mg2+ ion competition in mixed salt solutions

L. Sun, J. Qian, P. Cai and X. Xu, Phys. Chem. Chem. Phys., 2022, 24, 20867 DOI: 10.1039/D2CP02737B

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