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拉伸DNA以量化非特异性蛋白质结合。

Stretching DNA to quantify nonspecific protein binding.

作者信息

Goyal Sachin, Fountain Chandler, Dunlap David, Family Fereydoon, Finzi Laura

机构信息

Department of Physics, Emory University, Atlanta, Georgia 30322, USA.

出版信息

Phys Rev E Stat Nonlin Soft Matter Phys. 2012 Jul;86(1 Pt 1):011905. doi: 10.1103/PhysRevE.86.011905. Epub 2012 Jul 10.

DOI:10.1103/PhysRevE.86.011905
PMID:23005450
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3653181/
Abstract

Nonspecific binding of regulatory proteins to DNA can be an important mechanism for target search and storage. This seems to be the case for the lambda repressor protein (CI), which maintains lysogeny after infection of E. coli. CI binds specifically at two distant regions along the viral genome and induces the formation of a repressive DNA loop. However, single-molecule imaging as well as thermodynamic and kinetic measurements of CI-mediated looping show that CI also binds to DNA nonspecifically and that this mode of binding may play an important role in maintaining lysogeny. This paper presents a robust phenomenological approach using a recently developed method based on the partition function, which allows calculation of the number of proteins bound nonspecific to DNA from measurements of the DNA extension as a function of applied force. This approach was used to analyze several cycles of extension and relaxation of λ DNA performed at several CI concentrations to measure the dissociation constant for nonspecific binding of CI (100 nM), and to obtain a measurement of the induced DNA compaction (10%) by CI.

摘要

调节蛋白与DNA的非特异性结合可能是靶标搜索和储存的重要机制。λ阻遏蛋白(CI)似乎就是这种情况,它在感染大肠杆菌后维持溶原状态。CI特异性结合在病毒基因组上两个相距较远的区域,并诱导形成抑制性DNA环。然而,单分子成像以及CI介导的环化的热力学和动力学测量表明,CI也能非特异性地结合DNA,并且这种结合模式可能在维持溶原状态中发挥重要作用。本文提出了一种稳健的唯象学方法,该方法使用了一种基于配分函数的最新开发方法,该方法可以根据作为外力函数的DNA伸展测量值计算非特异性结合到DNA上的蛋白数量。该方法用于分析在几种CI浓度下进行的λDNA的几个伸展和松弛循环,以测量CI非特异性结合的解离常数(约100 nM),并获得CI诱导的DNA压缩率(约10%)的测量值。

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