Xia Wang, Ying Wang, Mingyan Gao, Fengyan Hou, Junxi Wang, Jingyu Wang, Ye Li, Zuobin Wang
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引用次数: 0
Abstract
As a flexible biomolecule, the spatial structure of DNA is variable. The effects of concentration, metal cations, and low pH on DNA morphology were studied. For the high concentration of DNA, the cross-linked branch-like or network structures were formed. For the low concentration of DNA, isolated, random and freely loose linear DNA chains were presented. These phenomena were related to the intermolecular interactions. Branch-like DNA structures were reformed with the addition of metal cations to the low concentration of DNA at pH 7-4, suggesting the negative charges of DNA were neutralized, thus transforming the spatial structure of DNA into a low charge density morphology and presenting the hypochromic effect. Compared to the monovalent alkaline metal cations, more negative charges of DNA were screened by the alkaline-earth metal cations. Distinct DNA morphologies were observed for pH 3. The linear and condensed DNA structures were simultaneously observed, which was met regardless of the solution with or without the addition of metal cations. This was further confirmed by the absorbance of DNA. Compared to the pure DNA, bulky and aggregated DNA collapsed structures were formed when the sodium and magnesium cations were added to the reaction solution. In addition, it was verified that the condensed DNA structures failed to revert back to the chain structure by neutralizing acidic solutions with alkali, but the compacted DNA spheres became loose. The conductivities of various DNA morphologies were measured. They were morphology-dependent. This study provides guidance for the behavior of DNA in the acidic solutions and further promotes the application of DNA in DNA-based nano-optoelectronic devices.
作为一种灵活的生物大分子,DNA 的空间结构是多变的。研究了浓度、金属阳离子和低 pH 对 DNA 形态的影响。高浓度 DNA 会形成交联的枝状或网状结构。而低浓度 DNA 则呈现出孤立、随机和自由松散的线性 DNA 链。这些现象与分子间的相互作用有关。在 pH 值为 7-4 的低浓度 DNA 中加入金属阳离子后,枝状 DNA 结构发生重塑,这表明 DNA 的负电荷被中和,从而使 DNA 的空间结构转变为低电荷密度形态,并呈现出低色度效应。与单价碱金属阳离子相比,碱土金属阳离子能筛选出更多的 DNA 负电荷。在 pH 值为 3 的溶液中观察到了不同的 DNA 形态,同时观察到了线型和缩合型 DNA 结构,这与添加或不添加金属阳离子的溶液是一致的。DNA 的吸光度进一步证实了这一点。与纯 DNA 相比,在反应溶液中加入钠和镁阳离子时,会形成膨大和聚集的 DNA 折叠结构。此外,还验证了用碱中和酸性溶液时,凝结的 DNA 结构无法恢复到链状结构,但压缩的 DNA 球体变得松散。测量了各种 DNA 形态的电导率。它们与形态有关。这项研究为 DNA 在酸性溶液中的行为提供了指导,并进一步推动了 DNA 在基于 DNA 的纳米光电器件中的应用。
期刊介绍:
Microscopy Research and Technique (MRT) publishes articles on all aspects of advanced microscopy original architecture and methodologies with applications in the biological, clinical, chemical, and materials sciences. Original basic and applied research as well as technical papers dealing with the various subsets of microscopy are encouraged. MRT is the right form for those developing new microscopy methods or using the microscope to answer key questions in basic and applied research.
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