Jiang Chu, Tan Ruihao, Li Weiying, Zhang Yinan, Liu Huajie
School of Chemical Science and Engineering, Shanghai Research Institute for Intelligent Autonomous Systems, Key Laboratory of Advanced Civil Engineering Materials of Ministry of Education, Tongji University, Shanghai, 200092, China.
College of Environmental Science and Engineering, Shanghai Institute of Pollution Control and Ecological Security, State Key Laboratory of Pollution Control and Resource Reuse, Tongji University, Shanghai, 200092, China.
Small. 2024 Dec;20(51):e2406470. doi: 10.1002/smll.202406470. Epub 2024 Oct 13.
Conventional cryptographic methods rely on increased computational complexity to counteract the threat posed by growing computing power for sustainable protection. DNA cryptography circumvents this threat by leveraging complex DNA recognition to maintain information security. Specifically, DNA origami has been repurposed for cryptography, using programmable folding of the long scaffold strand carrying additional tagged strands for information encryption. Herein, a subtraction-based cryptographic strategy is presented that uses structural defects on DNA origami to contain encrypted information. Designated staple strands are removed from the staple pool with "hook" strands to create active defect sites on DNA origami for information encryption. These defects can be filled by incubating the structures with the intact pool of biotinylated staple strands, resulting in biotin patterns that can be used for protein-binding steganography. The yields of individual protein pixels reached over 91%, and self-correction codes are implemented to aid the information recovery. Furthermore, the encrypted organization of defective DNA origami structures is investigated to explore the potential of this method for scalable information storage. This method uses DNA origami to encrypt information in hidden structural features, utilizing subtraction for robust cryptography while ensuring the safety and recovery of data.
传统的加密方法依靠增加计算复杂度来应对不断增长的计算能力所带来的威胁,以实现可持续的保护。DNA加密通过利用复杂的DNA识别来维持信息安全,从而规避了这一威胁。具体而言,DNA折纸已被重新用于加密领域,通过对携带额外标记链的长支架链进行可编程折叠来实现信息加密。在此,我们提出了一种基于减法的加密策略,该策略利用DNA折纸上的结构缺陷来存储加密信息。用带有“钩”链的指定短链从短链池中移除,在DNA折纸上创建用于信息加密的活性缺陷位点。通过将结构与完整的生物素化短链池孵育,可以填充这些缺陷,从而产生可用于蛋白质结合隐写术的生物素模式。单个蛋白质像素的产量超过91%,并实施了自纠错码以辅助信息恢复。此外,还对有缺陷的DNA折纸结构的加密组织进行了研究,以探索该方法用于可扩展信息存储的潜力。该方法利用DNA折纸在隐藏的结构特征中加密信息,利用减法实现强大的加密,同时确保数据的安全性和可恢复性。
