强电荷生物聚合物的静电学：核酸和蛋白质中的离子介导相互作用与自组装

Electrostatics of strongly charged biological polymers: ion-mediated interactions and self-organization in nucleic acids and proteins.

作者信息

Wong Gerard C L, Pollack Lois

机构信息

Materials Science and Engineering Department, University of Illinois at Urbana-Champaign, Urbana, Illinois 61801, USA.

出版信息

Annu Rev Phys Chem. 2010;61:171-89. doi: 10.1146/annurev.physchem.58.032806.104436.

DOI:10.1146/annurev.physchem.58.032806.104436

PMID:20055668

Abstract

Charges on biological polymers in physiologically relevant solution conditions are strongly screened by water and salt solutions containing counter-ions. However, the entropy of these counterions can result in surprisingly strong interactions between charged objects in water despite short screening lengths, via coupling between osmotic and electrostatic interactions. Widespread work in theory, experiment, and computation has been carried out to gain a fundamental understanding of the rich, yet sometimes counterintuitive, behavior of these polyelectrolyte systems. Examples of polyelectrolyte association in biology include DNA packaging and RNA folding, as well as aggregation and self-organization phenomena in different disease states.

摘要

在生理相关的溶液条件下，生物聚合物上的电荷会被含有抗衡离子的水和盐溶液强烈屏蔽。然而，尽管屏蔽长度较短，但这些抗衡离子的熵可通过渗透相互作用和静电相互作用之间的耦合，导致水中带电物体之间产生惊人的强相互作用。为了从根本上理解这些聚电解质系统丰富但有时违反直觉的行为，人们在理论、实验和计算方面开展了广泛的研究工作。生物学中聚电解质缔合的例子包括DNA包装和RNA折叠，以及不同疾病状态下的聚集和自组织现象。

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强电荷生物聚合物的静电学：核酸和蛋白质中的离子介导相互作用与自组装

Electrostatics of strongly charged biological polymers: ion-mediated interactions and self-organization in nucleic acids and proteins.

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强电荷生物聚合物的静电学：核酸和蛋白质中的离子介导相互作用与自组装

Electrostatics of strongly charged biological polymers: ion-mediated interactions and self-organization in nucleic acids and proteins.

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