Condensed DNA Nanosphere for DNA Origami Cryptography

Q3 Chemistry
Chemistry Pub Date : 2023-11-08 DOI:10.3390/chemistry5040159
Rui Gao, Zhuang Cai, Jianbang Wang, Huajie Liu
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引用次数: 0

Abstract

Maintaining the confidentiality and integrity of the messages during a transmission is one of the most important aims of encrypted communication systems. Many achievements were made using biomolecules to improve the quality of the messages in communication. At the same time, it is still a challenge to construct cooperative communications based on the interactions between biomolecules to achieve the confidentiality and integrity of the transmitted messages. DNA-based encrypted communications have been developed, and in particular, DNA-origami-based message encryption can combine steganography and pattern encryption and exhibits extremely high confidentiality. Nevertheless, limited by biological characteristics, encrypted messages based on DNA require a strict storage environment in the process of transmission. The integrity of the message encoded in the DNA may be damaged when the DNA is in an unfriendly and hard environment. Therefore, it is particularly significant to improve the stability of DNA when it is exposed to a harsh environment during transmission. Here, we encoded the information into the DNA strands that were condensed for encryption to form a nanosphere covered with a shell of SiO2, which brings high-density messages and exhibits higher stability than separated DNA. The solid shell of SiO2 could prevent DNA from contacting the harsh environment, thereby protecting the DNA structure and maintaining the integrity of the information. At the same time, DNA nanospheres can achieve high throughput input and higher storage density per unit volume, which contribute to confusing the message strand (M-strand) with the interference strand in the stored information. Condensing DNA into the nanosphere that is used for DNA origami cryptography has the potential to be used in harsh conditions with higher confidentiality and integrity for the transmitted messages.
用于DNA折纸密码学的浓缩DNA纳米球
在传输过程中保持消息的机密性和完整性是加密通信系统最重要的目标之一。生物分子在提高信息质量方面取得了许多成就。同时,如何构建基于生物分子间相互作用的协作通信,以实现传输信息的保密性和完整性,仍然是一个挑战。基于dna的加密通信已经发展起来,特别是基于dna折纸的消息加密可以结合隐写和模式加密,具有极高的保密性。然而,受生物学特性的限制,基于DNA的加密信息在传输过程中需要严格的存储环境。当DNA处于不友好和恶劣的环境中时,其编码信息的完整性可能会受到破坏。因此,提高DNA在传播过程中暴露于恶劣环境时的稳定性就显得尤为重要。在这里,我们将信息编码到DNA链中,这些DNA链被压缩并加密,形成一个覆盖有SiO2外壳的纳米球,它带来高密度的信息,并且比分离的DNA具有更高的稳定性。SiO2的固体外壳可以防止DNA与恶劣环境接触,从而保护DNA结构,保持信息的完整性。同时,DNA纳米球可以实现高通量输入和单位体积的高存储密度,这有助于将存储信息中的信息链(m链)与干扰链混淆。将DNA压缩到纳米球中用于DNA折纸密码术,有可能在恶劣条件下使用,对传输的信息具有更高的保密性和完整性。
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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来源期刊
CiteScore
2.50
自引率
0.00%
发文量
0
审稿时长
11 weeks
期刊介绍: Chemistry—A European Journal is a truly international journal with top quality contributions (2017 ISI Impact Factor: 5.16). It publishes a wide range of outstanding Reviews, Minireviews, Concepts, Full Papers, and Communications from all areas of chemistry and related fields.
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