De novo DNA-based catch bonds.

IF 19.2 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Nature chemistry Pub Date : 2024-06-24 DOI:10.1038/s41557-024-01571-4

Martijn van Galen, Annemarie Bok, Taieesa Peshkovsky, Jasper van der Gucht, Bauke Albada, Joris Sprakel

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Abstract

All primary chemical interactions weaken under mechanical stress, which imposes fundamental mechanical limits on the materials constructed from them. Biological materials combine plasticity with strength, for which nature has evolved a unique solution-catch bonds, supramolecular interactions that strengthen under tension. Biological catch bonds use force-gated conformational switches to convert weak bonds into strong ones. So far, catch bonds remain exclusive to nature, leaving their potential as mechanoadaptive elements in synthetic systems untapped. Here we report the design and realization of artificial catch bonds. Starting from a minimal set of thermodynamic design requirements, we created a molecular motif capable of catch bonding. It consists of a DNA duplex featuring a cryptic domain that unfolds under tension to strengthen the interaction. We show that these catch bonds recreate force-enhanced rolling adhesion, a hallmark feature of biological catch bonds in bacteria and leukocytes. This Article introduces catch bonds into the synthetic domain, and could lead to the creation of artificial catch-bonded materials.

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基于 DNA 的新捕获键。

所有主要的化学作用都会在机械应力作用下减弱，这就对由它们构成的材料施加了基本的机械限制。生物材料兼具可塑性和强度，大自然为此发明了一种独特的解决方案--捕捉键，即在拉力作用下会增强的超分子相互作用。生物捕捉键利用力控构象开关将弱键转化为强键。迄今为止，捕捉键仍是自然界的独有技术，其作为合成系统中机械自适应元素的潜力尚未得到开发。在此，我们报告了人工捕获键的设计与实现。从一组最基本的热力学设计要求出发，我们创造了一种能够接合的分子图案。它由 DNA 双链组成，具有一个在张力作用下展开以加强相互作用的隐藏结构域。我们的研究表明，这些捕捉键可以重现力增强的滚动粘附，这是细菌和白细胞中生物捕捉键的一个标志性特征。这篇文章将捕捉键引入了合成领域，并可能导致人工捕捉键材料的产生。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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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.

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