B-DNA Structure and Stability: the Role of Hydrogen Bonding, π-π Stacking Interactions, Twist-angle, and Solvation

Overview

Journal Org Biomol Chem

Publisher Royal Society of Chemistry

Specialties Biochemistry
Chemistry

Date 2014 May 30

PMID 24871817

Citations 18

Authors

Jordi Poater

Marcel Swart

F Matthias Bickelhaupt

Celia Fonseca Guerra

Affiliations

Soon will be listed here.

Abstract

We have computationally investigated the structure and stability of B-DNA. To this end, we have analyzed the bonding in a series of 47 stacks consisting of two base pairs, in which the base pairs cover the full range of natural Watson-Crick pairs, mismatched pairs, and artificial DNA base pairs. Our analyses provide detailed insight into the role and relative importance of the various types of interactions, such as, hydrogen bonding, π-π stacking interactions, and solvation/desolvation. Furthermore, we have analyzed the functionality of the twist-angle on the stability of the structure. Interestingly, we can show that all stacked base pairs benefit from a stabilization by 6 to 12 kcal mol(-1) if stacked base pairs are twisted from 0° to 36°, that is, if they are mutually rotated from a congruent superposition to the mutually twisted stacking configuration that occurs in B-DNA. This holds especially for stacked AT pairs but also for other stacked base pairs, including GC. The electronic mechanism behind this preference for a twisted arrangement depends on the base pairs involved. We also show that so-called "diagonal interactions" (or cross terms) in the stacked base pairs are crucial for understanding the stability of B-DNA, in particular, in GC-rich sequences.

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