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http://dx.doi.org/10.5012/bkcs.2012.33.11.3719

Contribution of Counterion Entropy to the Salt-Induced Transition Between B-DNA and Z-DNA  

Lee, Youn-Kyoung (Department of Chemistry, Seoul National University)
Lee, Juyong (Department of Chemistry, Seoul National University)
Choi, Jung Hyun (Department of Chemistry, Seoul National University)
Seok, Chaok (Department of Chemistry, Seoul National University)
Publication Information
Bulletin of the Korean Chemical Society / v.33, no.11, 2012 , pp. 3719-3726 More about this Journal
Abstract
Formation of Z-DNA, a left-handed double helix, from B-DNA, the canonical right-handed double helix, occurs during important biological processes such as gene expression and DNA transcription. Such B-Z transitions can also be induced by high salt concentration in vitro, but the changes in the relative stability of B-DNA and Z-DNA with salt concentration have not been fully explained despite numerous attempts. For example, electrostatic effects alone could not account for salt-induced B-Z transitions in previous studies. In this paper, we propose that the B-Z transition can be explained if counterion entropy is considered along with the electrostatic interactions. This can be achieved by conducting all-atom, explicit-solvent MD simulations followed by MM-PBSA and molecular DFT calculations. Our MD simulations show that counterions tend to bind at specific sites in B-DNA and Z-DNA, and that more ions cluster near Z-DNA than near B-DNA. Moreover, the difference in counterion ordering near B-DNA and Z-DNA is larger at a low salt concentration than at a high concentration. The results imply that the exclusion of counterions by Z-DNA-binding proteins may facilitate Z-DNA formation under physiological conditions.
Keywords
Z-DNA; B-Z transition; MM-PBSA; Classical density functional theory; Counterion entropy;
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