Physical association modeling of DNA alkylation

Biochimica et Biophysica Acta (BBA) - Nucleic Acids and Protein Synthesis Pub Date : 1981-10-27 DOI:10.1016/0005-2787(81)90055-1

R.A. Pearlstein, Ph.L. Dreno, M. Pensak, A.J. Hopfinger

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引用次数: 4

Abstract

The widespread occurrence of physical binding between biological macromolecules and small molecules has prompted us to hypothesize that physical binding contributes to DNA alkylation specificity. The preferred physical binding sites for a CH⁺₃-like test probe were predicted for several sequences of DNA using molecular mechanics free space calculation methods. Sequences containing $A = T$ basepairs direct physical binding to the minor groove, whereas sequences containing $G ≡ C$ basepairs direct physical binding to the major groove. Physical binding calculations were also performed for model ‘unwound’ DNA conformations. The results of the test probe studies were subsequently employed as starting points to predict the preferred physical binding sites for the more complicated case of an actual alkylating agent, the dimethylaziridinium ion. These studies demonstrate that physical binding specificity is highly dependent upon DNA sequence and conformation, and correlates well with the DNA alkylation site specificity observed for alkylating agents in the dimethylaziridine class.

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DNA烷基化的物理关联模型

生物大分子和小分子之间广泛存在的物理结合促使我们提出物理结合有助于DNA烷基化特异性的假设。利用分子力学自由空间计算方法，预测了几个DNA序列的类CH+3测试探针的首选物理结合位点。含有A = T碱基对的序列直接与小槽物理结合，而含有G≡C碱基对的序列直接与大槽物理结合。物理结合计算也进行了模型“未缠绕”的DNA构象。测试探针研究的结果随后被用作起点，以预测更复杂的实际烷基化剂二甲基肼离子的首选物理结合位点。这些研究表明，物理结合特异性高度依赖于DNA的序列和构象，并且与二甲基二氮吡啶类烷基化剂的DNA烷基化位点特异性密切相关。

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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Biochimica et Biophysica Acta (BBA) - Nucleic Acids and Protein Synthesis

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