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DNA聚合酶保真度:从遗传学走向生化理解

DNA polymerase fidelity: from genetics toward a biochemical understanding.

作者信息

Goodman M F, Fygenson K D

机构信息

Department of Biological Sciences, Hedco Molecular Biology Laboratories, University of Southern California, Los Angeles 90089-1340, USA.

出版信息

Genetics. 1998 Apr;148(4):1475-82. doi: 10.1093/genetics/148.4.1475.

DOI:10.1093/genetics/148.4.1475
PMID:9560367
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1460091/
Abstract

This review summarizes mutagenesis studies, emphasizing the use of bacteriophage T4 mutator and antimutator strains. Early genetic studies on T4 identified mutator and antimutator variants of DNA polymerase that, in turn, stimulated the development of model systems for the study of DNA polymerase fidelity in vitro. Later enzymatic studies using purified T4 mutator and antimutator polymerases were essential in elucidating mechanisms of base selection and exonuclease proofreading. In both cases, the base analogue 2-aminopurine (2AP) proved tremendously useful-first as a mutagen in vivo and then as a probe of DNA polymerase fidelity in vitro. Investigations into mechanisms of DNA polymerase fidelity inspired theoretical models that, in turn, called for kinetic and thermodynamic analyses. Thus, the field of DNA synthesis fidelity has grown from many directions: genetics, enzymology, kinetics, physical biochemistry, and thermodynamics, and today the interplay continues. The relative contributions of hydrogen bonding and base stacking to the accuracy of DNA synthesis are beginning to be deciphered. For the future, the main challenges lie in understanding the origins of mutational hot and cold spots.

摘要

本综述总结了诱变研究,重点介绍了噬菌体T4突变体和抗突变体菌株的应用。早期对T4的遗传学研究鉴定出DNA聚合酶的突变体和抗突变体变体,这反过来又推动了体外研究DNA聚合酶保真度的模型系统的发展。后来使用纯化的T4突变体和抗突变体聚合酶进行的酶学研究对于阐明碱基选择和核酸外切酶校对机制至关重要。在这两种情况下,碱基类似物2-氨基嘌呤(2AP)都被证明非常有用——首先作为体内诱变剂,然后作为体外DNA聚合酶保真度的探针。对DNA聚合酶保真度机制的研究催生了理论模型,反过来,这些模型又需要进行动力学和热力学分析。因此,DNA合成保真度领域从多个方向发展起来:遗传学、酶学、动力学、物理生物化学和热力学,如今这种相互作用仍在继续。氢键和碱基堆积对DNA合成准确性的相对贡献正开始被解读。展望未来,主要挑战在于理解突变热点和冷点的起源。

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