Chemistry Department, University of Central Florida, 4111 Libra Drive, Physical Sciences 255, Orlando, FL, 32816-2366, USA.
Chemistry. 2021 Feb 1;27(7):2421-2426. doi: 10.1002/chem.202003959. Epub 2020 Dec 30.
DNA-based computers can potentially analyze complex sets of biological markers, thereby advancing diagnostics and the treatment of diseases. Despite extensive efforts, DNA processors have not yet been developed due, in part, to limitations in the ability to integrate available logic gates into circuits. We have designed a NAND gate, which is one of the functionally complete set of logic connectives. The gate's design avoids stem-loop-folded DNA fragments, and is capable of reusable operations in RNase H-containing buffer. The output of the gate can be translated into RNA-cleaving activity or a fluorescent signal produced either by a deoxyribozyme or a molecular beacon probe. Furthermore, three NAND-gate-forming DNA strands were crosslinked by click chemistry and purified in a simple procedure that allowed ≈10 gates to be manufactured in 16 h, with a hands-on time of about 30 min. Two NAND gates can be joined into one association that performs a new logic function simply by adding a DNA linker strand. Approaches developed in this work could contribute to the development of biocompatible DNA logic circuits for biotechnological and medical applications.
基于 DNA 的计算机可以潜在地分析复杂的生物标志物集,从而推进诊断和疾病治疗。尽管进行了广泛的努力,但由于将现有逻辑门集成到电路中的能力有限,因此尚未开发出 DNA 处理器。我们设计了一种 NAND 门,它是功能齐全的逻辑连接件集之一。该门的设计避免了茎环折叠的 DNA 片段,并且能够在含有 RNase H 的缓冲液中进行可重复使用的操作。门的输出可以转化为 RNA 切割活性或荧光信号,该信号由脱氧核酶或分子信标探针产生。此外,通过点击化学将三个形成 NAND 门的 DNA 链交联,并通过简单的程序进行纯化,该程序允许在 16 小时内制造约 10 个门,实际操作时间约为 30 分钟。通过添加 DNA 连接链,可以将两个 NAND 门连接成一个关联,从而执行新的逻辑功能。这项工作中开发的方法可以为生物技术和医疗应用的生物兼容 DNA 逻辑电路的开发做出贡献。
