Christine Linne, Eva Heemskerk, Jos W. Zwanikken, Daniela J. Kraft and Liedewij Laan
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Here, we address this question with a multivalent experimental model system based on star shaped branched DNA nanostructures (DNA nanostars) with each branch featuring a single stranded overhang that binds to complementary receptors on a target surface. Each DNA nanostar possesses a fluorophore, to directly visualize DNA nanostar surface adsorption by total internal reflection fluorescence microscopy (TIRFM). We observe that DNA nanostars can bind superselectively to surfaces and bind optimally at a valency of three, for a given binding strength and concentration. We explain this optimum by extending the current theory with interactions between DNA nanostar binding sites (ligands). Our results add to the understanding of multivalent interactions, by identifying cooperative mechanisms that lead to optimal selectivity, and providing quantitative values for the relevant parameters. 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We explain this optimum by extending the current theory with interactions between DNA nanostar binding sites (ligands). Our results add to the understanding of multivalent interactions, by identifying cooperative mechanisms that lead to optimal selectivity, and providing quantitative values for the relevant parameters. 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引用次数: 0
摘要
弱多价相互作用支配着细胞-细胞粘附和病毒-宿主相互作用等多种生物过程。这些系统根据受体密度(即所谓的超选择性)对不同的表面进行区分。目前的实验研究通常涉及数十或数百种相互作用,从而产生高熵贡献,导致高选择性。然而,配体较少的系统(如多域蛋白质和噬菌体与其宿主的结合)是否会表现出超选择性,以及如何表现出超选择性,则是一个未决问题。在这里,我们用一种多价实验模型系统来解决这个问题,该系统基于星形支化 DNA 纳米结构(DNA 纳米星),每个支化都具有单链悬垂,可与靶表面的互补受体结合。每个 DNA 纳米柱都有一个荧光团,可通过全内反射荧光显微镜(TIRFM)直接观察 DNA 纳米柱的表面吸附情况。我们观察到,DNA 纳米柱可以超选择性地与表面结合,在给定的结合强度和浓度下,最佳结合价为 3。我们通过扩展 DNA 纳米星结合位点(配体)之间相互作用的现有理论来解释这种最佳状态。我们的研究结果确定了导致最佳选择性的合作机制,并提供了相关参数的定量值,从而加深了人们对多价相互作用的理解。这些发现启发了更多的设计规则,从而改进了未来定向给药中的选择性靶向工作。
Optimality and cooperativity in superselective surface binding by multivalent DNA nanostars†
Weak multivalent interactions govern a large variety of biological processes like cell–cell adhesion and virus–host interactions. These systems distinguish sharply between surfaces based on receptor density, known as superselectivity. Present experimental studies typically involve tens or hundreds of interactions, resulting in a high entropic contribution leading to high selectivities. However, if, and if so how, systems with few ligands, such as multi-domain proteins and bacteriophages binding to their host, show superselective behavior is an open question. Here, we address this question with a multivalent experimental model system based on star shaped branched DNA nanostructures (DNA nanostars) with each branch featuring a single stranded overhang that binds to complementary receptors on a target surface. Each DNA nanostar possesses a fluorophore, to directly visualize DNA nanostar surface adsorption by total internal reflection fluorescence microscopy (TIRFM). We observe that DNA nanostars can bind superselectively to surfaces and bind optimally at a valency of three, for a given binding strength and concentration. We explain this optimum by extending the current theory with interactions between DNA nanostar binding sites (ligands). Our results add to the understanding of multivalent interactions, by identifying cooperative mechanisms that lead to optimal selectivity, and providing quantitative values for the relevant parameters. These findings inspire additional design rules which improve future work on selective targeting in directed drug delivery.