脱氧核酶
DNA
化学
纳米技术
生物传感器
适体
合成生物学
逻辑门
核酸
组合化学
生物化学
电子线路
计算机科学
计算生物学
DNA纳米技术
材料科学
生物
物理
分子生物学
量子力学
算法
作者
Hong Wang,Huimin Wang,Itamar Willner,Fuan Wang
标识
DOI:10.1007/s41061-020-0284-x
摘要
Nucleic acids are considered not only extraordinary carriers of genetic information but also are perceived as the perfect elemental materials of molecular recognition and signal transduction/amplification for assembling programmable artificial reaction networks or circuits, which are similar to conventional electronic logic devices. Among these sophisticated DNA-based reaction networks, catalytic hairpin assembly (CHA), hybridization chain reaction (HCR), and DNAzyme represent the typical nonenzymatic amplification methods with high robustness and efficiency. Furthermore, their extensive hierarchically cascade integration into multi-layered autonomous DNA circuits establishes novel paradigms for constructing more different catalytic DNA nanostructures and for regenerating or replicating diverse molecular components with specific functions. Various DNA and inorganic nanoscaffolds have been used to realize the surface-confined DNA reaction networks with significant biomolecular sensing and signal-regulating functions in living cells. Especially, the specific aptamers and metal-ion-bridged duplex DNA nanostructures could extend their paradigms for detecting small molecules and proteins in even living entities. Herein, the varied enzyme-free DNA circuits are introduced in general with an extensive explanation of their underlying molecular reaction mechanisms. Challenges and outlook of the autonomous enzyme-free DNA circuits will also be discussed at the end of this chapter.
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