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DNA Volume, Topology, and Flexibility Dictate Nanopore Current Signals

Yunxuan Li, Sarah E. Sandler, Ulrich F. Keyser, Jinbo Zhu

2023Nano Letters14 citationsDOIOpen Access PDF

Abstract

Nanopores have developed into powerful single-molecule sensors capable of identifying and characterizing small polymers, such as DNA, by electrophoretically driving them through a nanoscale pore and monitoring temporary blockades in the ionic pore current. However, the relationship between nanopore signals and the physical properties of DNA remains only partly understood. Herein, we introduce a programmable DNA carrier platform to capture carefully designed DNA nanostructures. Controlled translocation experiments through our glass nanopores allowed us to disentangle this relationship. We vary DNA topology by changing the length, strand duplications, sequence, unpaired nucleotides, and rigidity of the analyte DNA and find that the ionic current drop is mainly determined by the volume and flexibility of the DNA nanostructure in the nanopore. Finally, we use our understanding of the role of DNA topology to discriminate circular single-stranded DNA molecules from linear ones with the same number of nucleotides using the nanopore signal.

Topics & Concepts

NanoporeDNANanotechnologyNanostructureTopology (electrical circuits)Materials scienceIonic bondingNanoscopic scaleDNA nanotechnologyDNA origamiA-DNAChemistryIonBiochemistryOrganic chemistryCombinatoricsMathematicsNanopore and Nanochannel Transport StudiesAdvanced biosensing and bioanalysis techniquesIon-surface interactions and analysis
DNA Volume, Topology, and Flexibility Dictate Nanopore Current Signals | Litcius