The thermodynamics of DNA structural motifs.

Annual review of biophysics and biomolecular structure Pub Date : 2004-01-01 DOI:10.1146/annurev.biophys.32.110601.141800

John SantaLucia, Donald Hicks

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引用次数: 1130

Abstract

DNA secondary structure plays an important role in biology, genotyping diagnostics, a variety of molecular biology techniques, in vitro-selected DNA catalysts, nanotechnology, and DNA-based computing. Accurate prediction of DNA secondary structure and hybridization using dynamic programming algorithms requires a database of thermodynamic parameters for several motifs including Watson-Crick base pairs, internal mismatches, terminal mismatches, terminal dangling ends, hairpins, bulges, internal loops, and multibranched loops. To make the database useful for predictions under a variety of salt conditions, empirical equations for monovalent and magnesium dependence of thermodynamics have been developed. Bimolecular hybridization is often inhibited by competing unimolecular folding of a target or probe DNA. Powerful numerical methods have been developed to solve multistate-coupled equilibria in bimolecular and higher-order complexes. This review presents the current parameter set available for making accurate DNA structure predictions and also points to future directions for improvement.

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DNA结构基序的热力学。

DNA二级结构在生物学、基因分型诊断、各种分子生物学技术、体外选择DNA催化剂、纳米技术和基于DNA的计算中发挥着重要作用。使用动态规划算法准确预测DNA二级结构和杂交需要一个包括沃森-克里克碱基对、内部错配、末端错配、末端悬垂端、发夹、凸起、内部环和多分支环等多个基序的热力学参数数据库。为了使该数据库适用于各种盐条件下的预测，我们建立了单价和镁依赖热力学的经验方程。双分子杂交常常被靶DNA或探针DNA的竞争性单分子折叠所抑制。求解双分子和高阶配合物中多态耦合平衡的数值方法已经得到了强有力的发展。本文综述了目前可用于准确预测DNA结构的参数集，并指出了未来的改进方向。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Annual review of biophysics and biomolecular structure

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