位于蛋白质螺旋末端的偶极子使电荷稳定。

Dipoles localized at helix termini of proteins stabilize charges.

作者信息

Aqvist J, Luecke H, Quiocho F A, Warshel A

机构信息

Department of Chemistry, University of Southern California, Los Angeles 90089-1062.

出版信息

Proc Natl Acad Sci U S A. 1991 Mar 1;88(5):2026-30. doi: 10.1073/pnas.88.5.2026.

DOI:10.1073/pnas.88.5.2026

PMID:2000410

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC51159/

Abstract

The charge-stabilization effect associated with alpha-helices in proteins has been reexamined by microscopic calculations without any a priori assumptions about the dielectric constant of the protein. The calculations reproduce the observed charge stabilization effect of a helix in two well-defined test cases: a histidine residue situated at the C-terminal end of a helix in barnase and the sulfate ligand located near the N-terminal end of a helix of the sulfate-binding protein. They also show that the effective dielectric constant for helix-charge interactions is much larger than previously assumed and that the stabilizing effect of the helix is not associated with the helix macrodipole but rather with a few localized dipoles confined mostly to the first turn of the helix. It is predicted that mutations at one end of the helix should have very small effects on the stabilization of charges at the opposite terminus. It is pointed out that the relatively short-ranged effect of the helix is essentially similar to other cases in which localized dipoles play key roles in electrostatic stabilization.

摘要

通过微观计算重新审视了蛋白质中与α-螺旋相关的电荷稳定效应，该计算没有对蛋白质的介电常数做任何先验假设。在两个明确的测试案例中，计算重现了观察到的螺旋电荷稳定效应：一个位于巴纳酶螺旋C末端的组氨酸残基，以及位于硫酸结合蛋白螺旋N末端附近的硫酸根配体。计算还表明，螺旋-电荷相互作用的有效介电常数比之前假设的要大得多，并且螺旋的稳定作用与螺旋大偶极无关，而是与一些主要局限于螺旋第一圈的局部偶极有关。预计螺旋一端的突变对另一端电荷的稳定作用影响很小。需要指出的是，螺旋相对较短程的效应与局部偶极在静电稳定中起关键作用的其他情况基本相似。

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