Encoding signal propagation on topology-programmed DNA origami

IF 19.2 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Nature chemistry Pub Date : 2024-06-17 DOI:10.1038/s41557-024-01565-2

Wei Ji, Xiewei Xiong, Mengyao Cao, Yun Zhu, Li Li, Fei Wang, Chunhai Fan, Hao Pei

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Abstract

Biological systems often rely on topological transformation to reconfigure connectivity between nodes to guide the flux of molecular information. Here we develop a topology-programmed DNA origami system that encodes signal propagation at the nanoscale, analogous to topologically efficient information processing in cellular systems. We present a systematic molecular implementation of topological operations involving ‘glue–cut’ processes that can prompt global conformational change of DNA origami structures, with demonstrated major topological properties including genus, number of boundary components and orientability. By spatially arranging reactive DNA hairpins, we demonstrate signal propagation across transmission paths of varying lengths and orientations, and curvatures on the curved surfaces of three-dimensional origamis. These DNA origamis can also form dynamic scaffolds for regulating the spatial and temporal signal propagations whereby topological transformations spontaneously alter the location of nodes and boundary of signal propagation network. We anticipate that our strategy for topological operations will provide a general route to manufacture dynamic DNA origami nanostructures capable of performing global structural transformations under programmable control. Constructing artificial structures that can imitate complex topological transformation with sophisticated functions is challenging. Now, using topological operations involving ‘glue–cut’ processes, the global conformational change of topology-programmed DNA origami has been demonstrated. The reconfigurable DNA origami system developed here can encode signal propagation at the nanoscale.

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在拓扑编程 DNA 折纸上编码信号传播

生物系统通常依靠拓扑变换来重新配置节点之间的连接，从而引导分子信息的流动。在这里，我们开发了一种拓扑编程 DNA 折纸系统，它可以在纳米尺度上编码信号传播，类似于细胞系统中拓扑高效信息处理。我们提出了一种涉及 "胶切 "过程的拓扑操作的系统分子实现方法，它能促使 DNA 折纸结构发生全局构象变化，其主要拓扑特性包括属、边界成分数和可定向性。通过空间排列活性 DNA 发夹，我们展示了信号在不同长度和方向的传输路径上的传播，以及三维折纸曲面上的曲率。这些 DNA 发丝还能形成动态支架，用于调节信号传播的空间和时间，拓扑变化会自发改变信号传播网络的节点位置和边界。我们预计，我们的拓扑操作策略将为制造能够在可编程控制下进行全局结构转换的动态 DNA 折纸纳米结构提供一条通用路线。

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来源期刊

Nature chemistry 化学-化学综合

CiteScore

29.60

自引率

1.40%

发文量

226

审稿时长

1.7 months

期刊介绍： Nature Chemistry is a monthly journal that publishes groundbreaking and significant research in all areas of chemistry. It covers traditional subjects such as analytical, inorganic, organic, and physical chemistry, as well as a wide range of other topics including catalysis, computational and theoretical chemistry, and environmental chemistry. The journal also features interdisciplinary research at the interface of chemistry with biology, materials science, nanotechnology, and physics. Manuscripts detailing such multidisciplinary work are encouraged, as long as the central theme pertains to chemistry. Aside from primary research, Nature Chemistry publishes review articles, news and views, research highlights from other journals, commentaries, book reviews, correspondence, and analysis of the broader chemical landscape. It also addresses crucial issues related to education, funding, policy, intellectual property, and the societal impact of chemistry. Nature Chemistry is dedicated to ensuring the highest standards of original research through a fair and rigorous review process. It offers authors maximum visibility for their papers, access to a broad readership, exceptional copy editing and production standards, rapid publication, and independence from academic societies and other vested interests. Overall, Nature Chemistry aims to be the authoritative voice of the global chemical community.