DNA拓扑异构酶的结构、分子机制和进化关系。

Kevin D Corbett, James M Berger
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引用次数: 386

摘要

拓扑异构酶是利用DNA链断裂、操纵和再连接活动来直接调节DNA拓扑结构的酶。这些行为提供了一种强大的手段来影响DNA超缠绕水平的变化,并允许一些拓扑异构酶解开和十烯化染色体。自从三十多年前首次发现拓扑异构酶以来,研究人员已经积累了丰富的关于拓扑异构酶的细胞作用和调控的信息,并描绘了拓扑异构酶的化学和物理机制的一般模型。拓扑异构酶现在被认为是细胞生物和许多病毒生存所必需的,并且是抗癌和抗菌治疗的丰富临床靶点。近年来,已经获得了四种拓扑异构酶的晶体结构,它们具有许多不同的构象和底物结合状态。此外,复杂的生物物理方法已被用于研究拓扑异构酶反应动力学和酶学的细节。这些方法的综合为研究人员提供了新的物理见解,了解拓扑异构酶如何利用化学和变构来指导DNA链相互传递所需的大规模分子运动。
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Structure, molecular mechanisms, and evolutionary relationships in DNA topoisomerases.

Topoisomerases are enzymes that use DNA strand scission, manipulation, and rejoining activities to directly modulate DNA topology. These actions provide a powerful means to effect changes in DNA supercoiling levels, and allow some topoisomerases to both unknot and decatenate chromosomes. Since their initial discovery over three decades ago, researchers have amassed a rich store of information on the cellular roles and regulation of topoisomerases, and have delineated general models for their chemical and physical mechanisms. Topoisomerases are now known to be necessary for the survival of cellular organisms and many viruses and are rich clinical targets for anticancer and antimicrobial treatments. In recent years, crystal structures have been obtained for each of the four types of topoisomerases in a number of distinct conformational and substrate-bound states. In addition, sophisticated biophysical methods have been utilized to study details of topoisomerase reaction dynamics and enzymology. A synthesis of these approaches has provided researchers with new physical insights into how topoisomerases employ chemistry and allostery to direct the large-scale molecular motions needed to pass DNA strands through each other.

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