Mentes Ahmet, Florescu Ana Maria, Brunk Elizabeth, Wereszczynski Jeff, Joyeux Marc, Andricioaei Ioan
Department of Chemistry, University of California, Irvine, Irvine, California.
Max Planck Institute for the Physics of Complex Systems, Dresden, Germany; Interdisciplinary Research Institute, Université des Sciences et des Technologies de Lille, CNRS USR 3078, Villeneuve d'Ascq, France.
Biophys J. 2015 Apr 7;108(7):1727-1738. doi: 10.1016/j.bpj.2015.01.025.
DNA unzipping, the separation of its double helix into single strands, is crucial in modulating a host of genetic processes. Although the large-scale separation of double-stranded DNA has been studied with a variety of theoretical and experimental techniques, the minute details of the very first steps of unzipping are still unclear. Here, we use atomistic molecular-dynamics simulations, coarse-grained simulations, and a statistical-mechanical model to study the initiation of DNA unzipping by an external force. Calculation of the potential of mean force profiles for the initial separation of the first few terminal basepairs in a DNA oligomer revealed that forces ranging between 130 and 230 pN are needed to disrupt the first basepair, and these values are an order of magnitude larger than those needed to disrupt basepairs in partially unzipped DNA. The force peak has an echo of ∼50 pN at the distance that unzips the second basepair. We show that the high peak needed to initiate unzipping derives from a free-energy basin that is distinct from the basins of subsequent basepairs because of entropic contributions, and we highlight the microscopic origin of the peak. To our knowledge, our results suggest a new window of exploration for single-molecule experiments.
DNA解链,即将其双螺旋分离为单链,在调控众多遗传过程中至关重要。尽管双链DNA的大规模分离已通过多种理论和实验技术进行了研究,但解链最初几步的细微细节仍不清楚。在此,我们使用原子分子动力学模拟、粗粒度模拟和统计力学模型来研究外力引发的DNA解链。对DNA寡聚物中最初几个末端碱基对初始分离的平均力势轮廓计算表明,破坏第一个碱基对需要130至230皮牛之间的力,这些值比破坏部分解链DNA中的碱基对所需的力大一个数量级。在解开第二个碱基对的距离处,力峰有一个约50皮牛的回声。我们表明,引发解链所需的高峰源于一个自由能盆地,由于熵的贡献,该盆地与后续碱基对的盆地不同,并且我们突出了该峰的微观起源。据我们所知,我们的结果为单分子实验提出了一个新的探索窗口。