Synthetic DNA filaments exploit the programm-ability of the individual units and their predictable self-association to mimic the structural and dynamic features of natural protein filaments. Among them, DNA origami filamentous structures are of particular interest, due to the versatility of morphologies, mechanical properties, and functionalities attainable. We here explore the thermodynamic and kinetic properties of linear structures grown from a ditopic DNA origami unit, i.e., a monomer with two distinct interfaces, and employ either base-hybridization or base-stacking interactions to trigger the dimerization and polymerization process. By observing the temporal evolution of the system toward equilibrium, we reveal kinetic aspects of filament growth that cannot be easily captured by postassembly studies. Our work thus provides insights into the thermodynamics and kinetics of hierarchical DNA origami assembly and shows how it can be mastered by the anisotropy of the building unit and its self-association mode.
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机译:合成 DNA 细丝利用单个单元的可编程能力及其可预测的自缔合来模拟天然蛋白质细丝的结构和动态特征。其中,由于形态、机械性能和可获得的功能的多功能性,DNA 折纸丝状结构特别令人感兴趣。我们在这里探索了从双位DNA折纸单元(即具有两个不同界面的单体)生长的线性结构的热力学和动力学性质,并采用碱基杂交或碱基堆叠相互作用来触发二聚化和聚合过程。通过观察系统向平衡的时间演变,我们揭示了灯丝生长的动力学方面,这些方面不容易被组装后研究捕捉到。因此,我们的工作提供了对分层DNA折纸组装的热力学和动力学的见解,并展示了如何通过构建单元的各向异性及其自缔合模式来掌握它。
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