Quantitative and Comprehensive Decomposition of the Ion Atmosphere around Nucleic Acids

The ion atmosphere around nucleic acids critically affects biological and physical processes such as chromosome packing, RNA folding, and molecular recognition. However, the dynamic nature of the ion atmosphere renders it difficult to characterize. The basic thermodynamic description of this atmosph...

Full description

Saved in:
Bibliographic Details
Published in:Journal of the American Chemical Society 2007-01, Vol.129 (48), p.14981-14988
Main Authors: Bai, Yu, Greenfeld, Max, Travers, Kevin J, Chu, Vincent B, Lipfert, Jan, Doniach, Sebastian, Herschlag, Daniel
Format: Article
Language:English
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The ion atmosphere around nucleic acids critically affects biological and physical processes such as chromosome packing, RNA folding, and molecular recognition. However, the dynamic nature of the ion atmosphere renders it difficult to characterize. The basic thermodynamic description of this atmosphere, a full accounting of the type and number of associated ions, has remained elusive. Here we provide the first complete accounting of the ion atmosphere, using buffer equilibration and atomic emission spectroscopy (BE- AES) to accurately quantitate the cation association and anion depletion. We have examined the influence of ion size and charge on ion occupancy around simple, well-defined DNA molecules. The relative affinity of monovalent and divalent cations correlates inversely with their size. Divalent cations associate preferentially over monovalent cations; e.g., with Na super(+) in 4- fold excess of Mg super(2+) (20 vs 5 mM), the ion atmosphere nevertheless has 3- fold more Mg super(2+) than Na super(+). Further, the dicationic polyamine putrescine super(2+) does not compete effectively for association relative to divalent metal ions, presumably because of its lower charge density. These and other BE-AES results can be used to evaluate and guide the improvement of electrostatic treatments. As a first step, we compare the BE-AES results to predictions from the widely used nonlinear Poisson Boltzmann (NLPB) theory and assess the applicability and precision of this theory. In the future, BE- AES in conjunction with improved theoretical models, can be applied to complex binding and folding equilibria of nucleic acids and their complexes, to parse the electrostatic contribution from the overall thermodynamics of important biological processes.
ISSN:1272-7863
1520-5126
DOI:10.1021/ja075020gPII:S0002-7863(07)05020-2