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具有吸引力的蛋白-聚合物相互作用显著改变了大分子拥挤对蛋白缔合平衡的影响。

Attractive protein-polymer interactions markedly alter the effect of macromolecular crowding on protein association equilibria.

机构信息

State Key Laboratory of Virology, College of Life Sciences, Wuhan University, Wuhan, China.

出版信息

Biophys J. 2010 Aug 4;99(3):914-23. doi: 10.1016/j.bpj.2010.05.013.

DOI:10.1016/j.bpj.2010.05.013
PMID:20682270
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2913179/
Abstract

The dependence of the fluorescence of catalase upon the concentration of added superoxide dismutase (SOD) indicates that SOD binds to saturable sites on catalase. The affinity of SOD for these sites varies with temperature, and with the concentration of each of three nominally inert polymeric additives--dextran 70, Ficoll 70, and polyethylene glycol 2000. At room temperature (25.0 degrees C) and higher, the addition of high concentrations of polymer is found to significantly enhance the affinity of SOD for catalase, but with decreasing temperature the enhancing effect of polymer addition diminishes, and at 8.0 degrees C, addition of polymer has little or no effect on the affinity of SOD for catalase. The results presented here provide the first experimental evidence for the existence of competition between a repulsive excluded volume interaction between protein and polymer, which tends to enhance association of dilute protein, and an attractive interaction between protein and polymer, which tends to inhibit protein association. The net effect of high concentrations of polymer upon protein associations depends upon the relative strength of these two types of interactions at the temperature of measurement, and may vary significantly between different proteins and/or polymers.

摘要

过氧化氢酶的荧光强度依赖于外加超氧化物歧化酶(SOD)的浓度,这表明 SOD 结合在过氧化氢酶的可饱和结合位点上。SOD 与这些结合位点的亲和力随温度和三种名义上惰性的聚合添加剂(葡聚糖 70、Ficoll 70 和聚乙二醇 2000)的浓度而变化。在室温(25.0°C)及更高温度下,发现添加高浓度聚合物可显著提高 SOD 与过氧化氢酶的亲和力,但随着温度降低,聚合物添加的增强效果减弱,在 8.0°C 时,聚合物的添加对 SOD 与过氧化氢酶的亲和力几乎没有影响或没有影响。本研究结果首次提供了实验证据,证明了蛋白质与聚合物之间的排斥性排除体积相互作用与蛋白质和聚合物之间的吸引力相互作用之间存在竞争,前者倾向于增强稀蛋白的缔合,后者倾向于抑制蛋白缔合。聚合物对蛋白质缔合的高浓度的净效应取决于在测量温度下这两种相互作用的相对强度,并且可能在不同蛋白质和/或聚合物之间有显著差异。

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