Nanoscale materials made using DNA have been increasingly used for applications ranging from bio-sensors to nanoelectronics. Specifically, DNA origami - where one long single-stranded DNA scaffold is folded into nanoscale shapes and structures using short 'staple' oligonucleotides - typically relies on a single-stranded DNA scaffold derived from a viral genome. The sizes of structures that are made rely on the length of the scaffold strand; the most frequently used DNA scaffold is the single-stranded 7249-nucleotide circular M13mp18 genome. Modern techniques used in genome tailoring are now widely exploited for the creation of DNA scaffolds of various lengths for use in DNA origami. DNA scaffolds of lengths ranging from similar to 700-nucleotides to similar to 51,000 nucleotides have been prepared using biotechniques such as polymerase chain reaction, a combination of site-directed mutagenesis and site- and ligation independent cloning, and using the molecular toolbox of restriction and ligation enzymes. Such tailor-made DNA scaffolds allow the creation of origami nanostructures of desired sizes. (C) 2016 Elsevier B.V. All rights reserved.
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机译:使用DNA制成的纳米级材料越来越多地用于从生物传感器到纳米电子学的各种应用。具体来说,DNA折纸 - 其中一个长的单链DNA支架使用短的“主食”寡核苷酸折叠成纳米级的形状和结构 - 通常依赖于源自病毒基因组的单链DNA支架。结构的尺寸取决于脚手架股的长度;最常用的 DNA 支架是单链 7249 核苷酸环状 M13mp18 基因组。用于基因组剪裁的现代技术现在被广泛用于创建用于 DNA 折纸的各种长度的 DNA 支架。使用聚合酶链反应等生物技术制备了长度从相似的 700 个核苷酸到相似的 51,000 个核苷酸的 DNA 支架,这些技术结合了定点诱变和位点和连接非依赖性克隆,并使用限制性和连接酶的分子工具箱。这种量身定制的DNA支架可以创建所需尺寸的折纸纳米结构。(c) 2016 Elsevier B.V.保留所有权利。
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