用于活细胞中mRNA成像的DNA四面体上的分子内催化发夹组装：改善反应动力学和信号稳定性

An intramolecular catalytic hairpin assembly on a DNA tetrahedron for mRNA imaging in living cells: improving reaction kinetics and signal stability.

作者信息

Qing Zhihe, Hu Jinlei, Xu Jingyuan, Zou Zhen, Lei Yanli, Qing Taiping, Yang Ronghua

机构信息

Hunan Provincial Key Laboratory of Materials Protection for Electric Power and Transportation, Hunan Provincial Engineering Research Center for Food Processing of Aquatic Biotic Resources, School of Chemistry and Food Engineering, Changsha University of Science and Technology Changsha 410114 P. R. China

College of Environment and Resources, Xiangtan University Xiangtan 411105 P. R. China.

出版信息

Chem Sci. 2019 Dec 18;11(7):1985-1990. doi: 10.1039/c9sc04916a.

DOI:10.1039/c9sc04916a

PMID:34123293

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8148388/

Abstract

Enzyme-free amplification techniques based on dynamic DNA self-assembly (DDSA) have recently been developed for the detection of mRNA in living cells. However, signal generation in traditional DDSA amplifiers is mainly dependent on the random diffusion of dissociative probes in a bulk solution, which is generally accompanied by poor kinetics and interference from complex biological systems. In this work, a new amplifier based on the design of an intramolecular catalytic hairpin assembly (intra-CHA) is proposed for the FRET imaging of mRNA in living cells. Compared with that in the free catalytic hairpin assembly (free-CHA), probes H1 and H2 in intra-CHA were simultaneously fixed on a DNA tetrahedron. The distance between them was closer, the local concentration of H1 and H2 in intra-CHA was theoretically approximately 808-times higher than that in free-CHA, and the initial reaction rate was enhanced 15.6 fold. Due to the spatial confinement effect, the reaction kinetics for target-catalyzed signal generation were significantly improved. By virtue of the three-dimensional nanostructure, H1 and H2 in the intra-CHA amplifier entered cells without any transfection or nanocarrier, and the probes and their products were free from biological interference, providing much higher signal stability for the reliable imaging of mRNA in living cells.

摘要

基于动态DNA自组装（DDSA）的无酶扩增技术最近已被开发用于检测活细胞中的mRNA。然而，传统DDSA放大器中的信号产生主要依赖于解离探针在本体溶液中的随机扩散，这通常伴随着较差的动力学以及复杂生物系统的干扰。在这项工作中，提出了一种基于分子内催化发夹组装（intra-CHA）设计的新型放大器，用于活细胞中mRNA的荧光共振能量转移（FRET）成像。与游离催化发夹组装（free-CHA）相比，intra-CHA中的探针H1和H2同时固定在一个DNA四面体上。它们之间的距离更近，理论上intra-CHA中H1和H2的局部浓度比free-CHA中高约808倍，初始反应速率提高了15.6倍。由于空间限制效应，目标催化信号产生的反应动力学得到了显著改善。凭借三维纳米结构，intra-CHA放大器中的H1和H2无需任何转染或纳米载体即可进入细胞，并且探针及其产物不受生物干扰，为活细胞中mRNA的可靠成像提供了更高的信号稳定性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ef44/8148388/40af1b4ba69a/c9sc04916a-s1.jpg

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用于活细胞中mRNA成像的DNA四面体上的分子内催化发夹组装：改善反应动力学和信号稳定性

An intramolecular catalytic hairpin assembly on a DNA tetrahedron for mRNA imaging in living cells: improving reaction kinetics and signal stability.

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