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测定非特异性结合到 DNA 上的蛋白质数量。

Determination of the number of proteins bound non-specifically to DNA.

机构信息

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

出版信息

J Phys Condens Matter. 2010 Oct 20;22(41):414104. doi: 10.1088/0953-8984/22/41/414104. Epub 2010 Sep 30.

DOI:10.1088/0953-8984/22/41/414104
PMID:21386587
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3653182/
Abstract

We have determined the change in the number of proteins bound non-specifically to DNA as a function of applied force using force-extension measurements on tethered DNA. Using magnetic tweezers, single molecules of λ DNA were repeatedly stretched and relaxed in the absence and presence of 170 nM λ repressor protein (CI). CI binds to six specific sites of λ DNA with nanomolar affinity and also binds non-specifically with micromolar affinity. The force versus extension data were analyzed using a recently developed theoretical framework for quantitative determination of protein binding to the DNA. The results indicate that the non-specific binding of CI changes the force-extension relation significantly in comparison to that of naked DNA. The DNA tether used in our experiment would have about 640 bound repressors, if it was completely saturated with bound proteins. We find that as the pulling force on DNA is reduced from 4.81 to 0.13 pN, approximately 138 proteins bind to DNA, which is about 22% of the length of the tethered DNA. Our results show that 0.13 pN is not low enough to cause saturation of DNA by repressor and 4.81 pN is also not high enough to eliminate all the repressors bound to DNA. This demonstrates that the force-extension relation provides an effective approach for estimating the number of proteins bound non-specifically to a DNA molecule.

摘要

我们已经确定了在应用力的情况下,非特异性结合到 DNA 的蛋白质数量随力的变化,这是通过对束缚 DNA 的力-延伸测量来实现的。使用磁镊,λ DNA 的单分子在不存在和存在 170 nM λ 阻遏蛋白(CI)的情况下被反复拉伸和松弛。CI 以纳摩尔亲和力结合到 λ DNA 的六个特定位点,并且以微摩尔亲和力非特异性结合。使用最近开发的用于定量测定蛋白质与 DNA 结合的理论框架分析力与延伸数据。结果表明,与裸 DNA 相比,CI 的非特异性结合显著改变了力-延伸关系。如果我们的实验中使用的 DNA 束缚完全饱和与结合的蛋白质,则该 DNA 束缚将有约 640 个结合的阻遏物。我们发现,当 DNA 上的拉力从 4.81 减少到 0.13 pN 时,大约有 138 个蛋白质结合到 DNA 上,这大约是束缚 DNA 长度的 22%。我们的结果表明,0.13 pN 不足以使 DNA 被阻遏物饱和,而 4.81 pN 也不足以消除所有结合到 DNA 上的阻遏物。这表明力-延伸关系为估计非特异性结合到 DNA 分子上的蛋白质数量提供了一种有效的方法。

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