Tianbiao Zhang, Changlin Zhang, Zai-li Dong, Y. Guan
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引用次数: 1
摘要
原子力显微镜(Atomic force microscope, AFM)以其高分辨率和高精度,直接探测自组装嘌呤和嘧啶之间的分子间氢键。在实验中,我们直接拉伸了分别附着在平面修饰玻璃表面和AFM尖端的DNA双链。然而,与以往文献不同的是,我们重点研究了NaCl浓度和保持时间对DNA双螺旋破裂力的影响,并监测了0mM、50mM和100mM三种不同NaCl浓度下DNA双螺旋破裂力的探测过程。结果表明,随着NaCl浓度的增加,互补DNA链更容易结合。同时,我们测试了探测过程,考虑了三个保持持续时间:0S、10S和40S。我们发现,在40S的情况下,互补DNA链形成良好。然后分别用10bp、14bp、20bp三种长度的链进行实验。利用聚类分析方法,我们发现聚类中心间隔约为0.21nN, 0.29nN和0.39nN,我们可以计算出单个G-C的氢键约为20pN。
Measurement of interchain binding affinity of nucleic acid duplex using atomic force microscopy
Atomic force microscope (AFM), as its high resolution and precision, was employed to directly probe intermolecular hydrogen bonds between self-assembled purines and pyrimidines. In the experiment, we directly stretch the DNA double strands that are attached to the planar modified glass surfaces and AFM tip respectively. However, distinguishing from previous literatures we focus on the NaCl density and holding time influencing the rupture force of DNA double helix and monitor the probing process under three different densities of sodium chloride (NaCl): 0mM, 50mM, and 100mM. The result shows complementary DNA strands are easier to bond as the density of NaCl increases. At the same time we test the probing process considering three holding durations: 0S, 10S, and 40S. We find the complementary DNA strands bond forming well under the situation of 40S. Then we separately do experiments with three lengths of strands: 10bp, 14bp, 20bp. Using cluster analysis method we find that the clustering center intervals are about 0.21nN, 0.29nN, and 0.39nN, and we can calculate the hydrogen bond of the single G-C is about 20pN.
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