Divalent Cations Stabilize Unstacked Conformations of DNA and RNA by Interacting with Base Π Systems

Nucleic acid structure, stability, and reactivity are governed substantially by cations. We propose that magnesium and other biological inorganic ions unstack bases of DNA and RNA. This unstacking function of cations opposes their previously accepted role in stabilizing DNA and RNA duplexes and high...

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Bibliographic Details
Published in:Biochemistry (Easton) 1998-12, Vol.37 (49), p.17105-17111
Main Authors: McFail-Isom, Lori, Shui, Xiuqi, Williams, Loren Dean
Format: Article
Language:English
Subjects:
Animals
Base Composition
Cations, Divalent
DNA - chemistry
DNA, Protozoan - chemistry
Magnesium Hydroxide - chemistry
Models, Molecular
Nucleic Acid Conformation
Oligodeoxyribonucleotides - chemistry
RNA, Fungal - chemistry
RNA, Protozoan - chemistry
RNA, Transfer, Phe - chemistry
Tetrahymena
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Summary:Nucleic acid structure, stability, and reactivity are governed substantially by cations. We propose that magnesium and other biological inorganic ions unstack bases of DNA and RNA. This unstacking function of cations opposes their previously accepted role in stabilizing DNA and RNA duplexes and higher assemblies. We show that cations interact favorably with π-systems of nucleic acid bases. These cation-π interactions require access of cations or their first hydration shells to faces of nucleic acid bases. We observe that hydrated magnesium ions located in the major groove of B-DNA pull cytosine bases partially out from the helical stack, exposing π-systems to positive charge. A series of critical cation-π interactions contribute to the stability of the anticodon arm of yeast-tRNAphe, and to the magnesium core of the Tetrahymena group I intron P4−P6 domain. The structural consequences of divalent cation-π interactions are clearly distinct from, and some cases in opposition to, cation−electron lone pair interactions. These observations of cation-π interactions suggest a number of new mechanistic roles for cations in DNA bending, DNA−protein recognition, base-flipping, RNA folding, and catalysis.
ISSN:0006-2960
1520-4995
DOI:10.1021/bi982201+