A system capable of verifiably and privately screening global DNA synthesis

• Published in: arXiv.org
• Main Authors: Baum, Carsten, Berlips, Jens, Chen, Walther, Cui, Hongrui, Damgard, Ivan, Dong, Jiangbin, Esvelt, Kevin M, Foner, Leonard, Gao, Mingyu, Gretton, Dana, Kysel, Martin, Li, Juanru, Li, Xiang, Paneth, Omer, Rivest, Ronald L, Sage-Ling, Francesca, Shamir, Adi, Shen, Yue, Sun, Meicen, Vaikuntanathan, Vinod, Lynn Van Hauwe, Vogel, Theia, Weinstein-Raun, Benjamin, Wang, Yun, Wichs, Daniel, Wooster, Stephen, Yao, Andrew C, Yu, Yu, Zhang, Haoling, Zhang, Kaiyi
• Format: Paper
• Language: English
• Published: Ithaca Cornell University Library, arXiv.org 10.09.2024
• Subjects: Counterfeit; Currencies; Gene sequencing; Operational hazards; Printers; Privacy; Screening; Synthesis; Synthesizers; Trade secrets
• ISSN: 2331-8422

Printing custom DNA sequences is essential to scientific and biomedical research, but the technology can be used to manufacture plagues as well as cures. Just as ink printers recognize and reject attempts to counterfeit money, DNA synthesizers and assemblers should deny unauthorized requests to make viral DNA that could be used to ignite a pandemic. There are three complications. First, we don't need to quickly update printers to deal with newly discovered currencies, whereas we regularly learn of new viruses and other biological threats. Second, anti-counterfeiting specifications on a local printer can't be extracted and misused by malicious actors, unlike information on biological threats. Finally, any screening must keep the inspected DNA sequences private, as they may constitute valuable trade secrets. Here we describe SecureDNA, a free, privacy-preserving, and fully automated system capable of verifiably screening all DNA synthesis orders of 30+ base pairs against an up-to-date database of hazards, and its operational performance and specificity when applied to 67 million base pairs of DNA synthesized by providers in the United States, Europe, and China.