Rasmus Schøler Sørensen scite author profile

Transmembrane nanostructures like ion channels and transporters perform key biological functions by controlling flow of molecules across lipid bilayers. Much work has gone into engineering artificial nanopores and applications in selective gating of molecules, label-free detection/sensing of biomolecules and DNA sequencing have shown promise. Here, we use DNA origami to create a synthetic 9 nm wide DNA nanopore, controlled by programmable, lipidated flaps and equipped with a size-selective gating system for the translocation of macromolecules. Successful assembly and insertion of the nanopore into lipid bilayers are validated by transmission electron microscopy (TEM), while selective translocation of cargo and the pore mechanosensitivity are studied using optical methods, including single-molecule, total internal reflection fluorescence (TIRF) microscopy. Size-specific cargo translocation and oligonucleotide-triggered opening of the pore are demonstrated showing that the DNA nanopore can function as a real-time detection system for external signals, offering potential for a variety of highly parallelized sensing applications.

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Intracellular Delivery of a Planar DNA Origami Structure by the Transferrin‐Receptor Internalization Pathway

Schaffert

Okholm

Sørensen

et al. 2016

Small

127

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DNA origami provides rapid access to easily functionalized, nanometer-sized structures making it an intriguing platform for the development of defined drug delivery and sensor systems. Low cellular uptake of DNA nanostructures is a major obstacle in the development of DNA-based delivery platforms. Herein, significant strong increase in cellular uptake in an established cancer cell line by modifying a planar DNA origami structure with the iron transport protein transferrin (Tf) is demonstrated. A variable number of Tf molecules are coupled to the origami structure using a DNA-directed, site-selective labeling technique to retain ligand functionality. A combination of confocal fluorescence microscopy and quantitative (qPCR) techniques shows up to 22-fold increased cytoplasmic uptake compared to unmodified structures and with an efficiency that correlates to the number of transferrin molecules on the origami surface.

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Quantification of cellular uptake of DNA nanostructures by qPCR

Okholm

Nielsen

Vinther

et al. 2014

Methods

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Enzymatic Ligation of Large Biomolecules to DNA

et al. 2013

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The ability to synthesize, characterize, and manipulate DNA forms the foundation of a range of advanced disciplines including genomics, molecular biology, and biomolecular engineering. In particular for the latter field, DNA has proven useful as a structural or functional component in nanoscale self-assembled structures, antisense therapeutics, microarray diagnostics, and biosensors. Such applications frequently require DNA to be modified and conjugated to other macromolecules, including proteins, polymers, or fatty acids, in order to equip the system with properties required for a particular application. However, conjugation of DNA to large molecular components using classical chemistries often suffers from suboptimal yields. Here, we report the use of terminal deoxynucleotidyl transferase (TdT) for direct enzymatic ligation of native DNA to nucleotide triphosphates coupled to proteins and other large macromolecules. We demonstrate facile synthesis routes for a range of NTP-activated macromolecules and subsequent ligation to the 3' hydroxyl group of oligodeoxynucleotides using TdT. The reaction is highly specific and proceeds rapidly and essentially to completion at micromolar concentrations. As a proof of principle, parallelly labeled oligonucleotides were used to produce nanopatterned DNA origami structures, demonstrating rapid and versatile incorporation of non-DNA components into DNA nanoarchitectures.

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Functional Patterning of DNA Origami by Parallel Enzymatic Modification

et al. 2011

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We demonstrate here a rapid and cost-effective technique for nanoscale patterning of functional molecules on the surface of a DNA origami. The pattern is created enzymatically by transferring a functionalized dideoxynucleotide to the 3'-end of an arbitrary selected set of synthetic DNA oligonucleotides positioned approximately 6 nm apart in a 70 × 100 nm(2) rectangular DNA origami. The modifications, which are performed in a single-tube reaction, provide an origami surface modified with a variety of functional groups including chemical handles, fluorescent dyes, or ligands for subsequent binding of proteins. Efficient labeling and patterning was demonstrated by gel electrophoresis shift assays, reverse-phase HPLC, mass spectrometry, atomic force microscopy (AFM) analysis, and fluorescence measurements. The results show a very high yield of oligonucleotide labeling and incorporation in the DNA origami. This method expands the toolbox for constructing several different modified DNA origami from the same set of staple strands.

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