DNA Nanostructure Modelling and Simulation

RAN Pub Date : 2016-04-01 DOI:10.11159/ICNMS16.104
M. Kim
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Abstract

Extended Abstract Recently, various DNA nanostructures have been designed and synthesized mostly relying on their self-assembly feature. Once a unit tile structure is precised designed, numerous copies are produced and self-assembled into 2D or 3D nanostructures. However, lack of information about its dynamic characteristics sometimes fails to reach the anticipated DNA nanostructure. For example, planar unit cross-tiles do not form a 2D lattice nanostructure but a 3D nanotube [1]. Modal analysis of DNA nanostructures successfully explained this self-assembly mechanism in terms of mechanical vibration [2]. In this talk, I will briefly introduce a theoretical framework how to model and simulate DNA nanostructure in order to understand its dynamic characteristics which play an important role in DNA nanostructure design and synthesis. First, a DNA nanostructure, either a unit tile or an assembly, is represented by a coarse-grained mass-spring network which contains DNA’s structural information including mass and chemical interaction [3]. Then, a mechanical vibration theory, called normal mode analysis, is applied to the given DNA coarse-grained model to simulate its intrinsic vibrational characteristics. In addition, it will be discussed how to relate intrinsic vibration modes with self-assembly process successfully for various exampled DNA nanostructures including 2D lattice, 2D ring, and 3D bulky ball. Consequently, the proposed theoretical approach enables us to design DNA nanostructures much more precisely and systematically, compared to the conventional trial and error method.
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DNA纳米结构建模与仿真
近年来,各种DNA纳米结构的设计和合成主要依靠其自组装特性。一旦一个单元瓦片结构被精确设计出来,就会产生大量的复制品,并自组装成2D或3D纳米结构。然而,由于缺乏其动态特性的信息,有时无法达到预期的DNA纳米结构。例如,平面单元交叉瓦片形成的不是二维晶格纳米结构,而是三维纳米管[1]。DNA纳米结构的模态分析成功地从机械振动的角度解释了这种自组装机制[2]。在这次演讲中,我将简要介绍如何建模和模拟DNA纳米结构的理论框架,以了解其动态特性,这在DNA纳米结构的设计和合成中起着重要作用。首先,DNA纳米结构,无论是单元瓦片还是组件,都由粗粒度的质量-弹簧网络表示,其中包含DNA的结构信息,包括质量和化学相互作用[3]。然后,将一种称为正态模态分析的机械振动理论应用于给定的DNA粗粒度模型,以模拟其固有振动特性。此外,将讨论如何将固有振动模式与自组装过程成功地联系起来,用于各种示例DNA纳米结构,包括2D晶格,2D环和3D大体积球。因此,与传统的试错法相比,提出的理论方法使我们能够更精确、更系统地设计DNA纳米结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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RAN
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