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通过肽核酸诱导的DNA环化来调控限制性内切酶PleI的活性

Tailoring the activity of restriction endonuclease PleI by PNA-induced DNA looping.

作者信息

Protozanova Ekaterina, Demidov Vadim V, Soldatenkov Viatcheslav, Chasovskikh Sergey, Frank-Kamenetskii Maxim D

机构信息

Center for Advanced Biotechnology, Boston University, MA 02115, USA.

出版信息

EMBO Rep. 2002 Oct;3(10):956-61. doi: 10.1093/embo-reports/kvf192. Epub 2002 Sep 13.

DOI:10.1093/embo-reports/kvf192
PMID:12231505
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1307623/
Abstract

DNA looping is one of the key factors allowing proteins bound to different DNA sites to signal one another via direct contacts. We demonstrate that DNA looping can be generated in an arbitrary chosen site by sequence-directed targeting of double-stranded DNA with pseudocomplementary peptide-nucleic acids (pcPNAs). We designed pcPNAs to mask the DNA from cleavage by type IIs restriction enzyme PleI while not preventing the enzyme from binding to its primary DNA recognition site. Direct interaction between two protein molecules (one bound to the original recognition site and the other to a sequence-degenerated site) results in a totally new activity of PleI: it produces a nick near the degenerate site. The PNA-induced nicking efficiency varies with the distance between the two protein-binding sites in a phase with the DNA helical periodicity. Our findings imply a general approach for the fine-tuning of proteins bound to DNA sites well separated along the DNA chain.

摘要

DNA 环化是使结合在不同 DNA 位点上的蛋白质能够通过直接接触相互传递信号的关键因素之一。我们证明,通过用假互补肽核酸(pcPNA)对双链 DNA 进行序列定向靶向,可以在任意选定的位点产生 DNA 环化。我们设计 pcPNA 来掩盖 DNA,使其不被 II 型限制性内切酶 PleI 切割,同时又不阻止该酶与其主要 DNA 识别位点结合。两个蛋白质分子(一个结合在原始识别位点,另一个结合在序列简并位点)之间的直接相互作用导致了 PleI 的全新活性:它在简并位点附近产生一个切口。PNA 诱导的切口效率随两个蛋白质结合位点之间的距离呈周期性变化,与 DNA 螺旋周期一致。我们的研究结果暗示了一种对沿 DNA 链相距较远的 DNA 位点上结合的蛋白质进行微调的通用方法。

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