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Programming Biomimetically Confined Aptamers with DNA Frameworks

Xiuhai Mao, Mengmeng Liu, Lei Yan, Mengying Deng, Fan Li, Min Li, Fei Wang, Jiang Li, Lihua Wang, Yang Tian, Chunhai Fan, Xiaolei Zuo

2020ACS Nano51 citationsDOI

Abstract

Active sites of proteins are generally encapsulated within three-dimensional peptide scaffolds that provide the molecular-scale confinement microenvironment. Nevertheless, the ability to tune thermodynamic stability in biomimetic molecular confinement relies on the macromolecular crowding effect of lack of stoichiometry and reconfigurability. Here, we report a framework nucleic acid (FNA)-based strategy to increase thermodynamic stability of aptamers. We demonstrate that the molecular-scale confinement increases the thermodynamic stability of aptamers via facilitated folding kinetics, which is confirmed by the single-molecule FRET (smFRET). Unfavorable conformations of aptamers are restricted as revealed by the Monte Carlo simulation. The binding affinity of the DNA framework-confined aptamer is improved by ∼3-fold. With a similar strategy we improve the catalytic activity of hemin-binding aptamer. Our approach thus shows high potential for designing protein-mimicking DNA nanostructures with enhanced binding affinity and catalytic activity for biosensing and biomedical engineering.

Topics & Concepts

AptamerFörster resonance energy transferFolding (DSP implementation)NanotechnologyDNABiosensorNucleic acidMacromoleculeDNA nanotechnologyChemistrySystematic evolution of ligands by exponential enrichmentBiophysicsCombinatorial chemistryMaterials scienceBiologyRNABiochemistryFluorescenceGeneticsEngineeringGeneQuantum mechanicsPhysicsElectrical engineeringAdvanced biosensing and bioanalysis techniquesRNA Interference and Gene DeliveryDNA and Nucleic Acid Chemistry
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