Controlled twisting of individual, double-stranded DNA molecules provides a unique method to investigate the enzymes that alter DNA topology. Such twisting requires a single DNA molecule to be torsionally constrained. This constraint is achieved by anchoring the opposite ends of the DNA to two separate surfaces via multiple bonds. The traditional protocol for making such DNA involves a three-way ligation followed by gel purification, a laborious process that often leads to low yield both in the amount of DNA and the fraction of molecules that is torsionally constrained. We developed a simple ligation-free procedure for making torsionally constrained DNA via polymerase chain reaction (PCR). This PCR protocol used two ‘megaprimers’, 400-base-pair long double-stranded DNA that were labelled with either biotin or digoxigenin. We obtained a relatively high yield of gel-purified DNA (∼500 ng/100 µl of PCR reaction). The final construct in this PCR-based method contains only one labelled strand in contrast to the traditional construct in which both strands of the DNA are labelled. Nonetheless, we achieved a high yield (84%) of torsionally constrained DNA when measured using an optical-trap-based DNA-overstretching assay. This protocol significantly simplifies the application and adoption of torsionally constrained assays to a wide range of single-molecule systems.
展开▼
机译:单个双链DNA分子的可控扭曲为研究改变DNA拓扑结构的酶提供了独特的方法。这种扭曲需要扭转地限制单个DNA分子。这种限制是通过将DNA的相对两端通过多个键锚定到两个单独的表面来实现的。制备此类DNA的传统方法包括三步连接,然后进行凝胶纯化,这是一个费力的过程,通常会导致DNA数量和受扭力约束的分子部分的收率降低。我们开发了一种简单的无连接程序,可通过聚合酶链反应(PCR)制作受扭转约束的DNA。该PCR方案使用了两个带有生物素或洋地黄毒苷标记的“ megaprimers”,400个碱基对的长双链DNA。我们获得了相对较高的凝胶纯化DNA产量(约500 ng / 100 µl PCR反应)。与传统的构建体(其中DNA的两条链都被标记)相比,这种基于PCR的方法中的最终构建体仅包含一条标记的链。但是,当使用基于光学陷阱的DNA过度拉伸测定法进行测量时,我们获得了高产量(84%)的受扭转约束的DNA。该协议极大地简化了扭转约束分析在各种单分子系统中的应用和采用。
展开▼
