Synthetic Lipid Membrane Channels Formed by Designed DNA Nanostructures

“…The negatively charged DNA pores carry hydrophobic membrane anchors for membrane insertion. DNA pores have so far only been placed into lipid bilayer membranes,6a–6f and it is not known whether they also anchor into polymersomes to form membrane‐puncturing nanosized holes.…”

mentioning

confidence: 99%

Biomimetic Hybrid Nanocontainers with Selective Permeability

et al. 2016

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Chemistry plays a crucial role in creating synthetic analogues of biomacromolecular structures. Of particular scientific and technological interest are biomimetic vesicles that are inspired by natural membrane compartments and organelles but avoid their drawbacks, such as membrane instability and limited control over cargo transport across the boundaries. In this study, completely synthetic vesicles were developed from stable polymeric walls and easy‐to‐engineer membrane DNA nanopores. The hybrid nanocontainers feature selective permeability and permit the transport of organic molecules of 1.5 nm size. Larger enzymes (ca. 5 nm) can be encapsulated and retained within the vesicles yet remain catalytically active. The hybrid structures constitute a new type of enzymatic nanoreactor. The high tunability of the polymeric vesicles and DNA pores will be key in tailoring the nanocontainers for applications in drug delivery, bioimaging, biocatalysis, and cell mimicry.

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Section: Applications Of Dna Origamimentioning

confidence: 99%

“…Transmembrane channel structures in lipid bilayers were created via a transmembrane ‘stem’ that pierced the length of the lipid membrane was created along with a barrel-shaped ‘cap’ [28]. The ‘cap’ was attached to the membrane through 26 cholesterol moieties [28]. The physiological functionality of natural ion channels was mimicked, such that conductances of one nanosiemens and channel gating were achieved [28].…”

Section: Applications Of Dna Origamimentioning

confidence: 99%

“…The ‘cap’ was attached to the membrane through 26 cholesterol moieties [28]. The physiological functionality of natural ion channels was mimicked, such that conductances of one nanosiemens and channel gating were achieved [28]. Similarly, a transmembrane molecular valve which controls gated transport of material across a phospholipid bilayer has been created [27].…”

Section: Applications Of Dna Origamimentioning

confidence: 99%

See 1 more Smart Citation

Beyond the smiley face: applications of structural DNA nanotechnology

Arora

Silva

2018

Nano Reviews & Experiments

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Since the development of DNA origami by Paul Rothemund in 2006, the field of structural DNA nanotechnology has undergone tremendous growth. Through DNA origami and related approaches, self-assembly of specified DNA sequences allows for the ‘bottom-up’ construction of diverse nanostructures. By utilizing different sets of small ‘staple’ DNA strands to direct the folding of a long scaffold strand in diverse ways, DNA origami has particularly been incorporated into a variety of prototypical applications beyond the two-dimensional (2D) smiley face. In this review, the basis of DNA nanotechnology, methods of self-assembly, and Rothemund’s DNA origami breakthrough are discussed first. Next, some of the most promising applications of structural DNA nanotechnology since 2006 are summarized. These include utilizing DNA origami as a tool for creating 3D nanostructures (including DNA bricks), as well as structural (ligand capsid binding, viral capsid binding, DNA NanoOctahedron, DNA mold, photonic devices, energy transfer units), and dynamic (DNA box-with-lid, DNA nano-robot, DNA barges, amphipathic DNA structures, DNA nanocircuits) applications of DNA origami.

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Synthetic Lipid Membrane Channels Formed by Designed DNA Nanostructures

Cited by 665 publications

References 47 publications

Application of nucleic acid–lipid conjugates for the programmable organisation of liposomal modules

Application of nucleic acid–lipid conjugates for the programmable organisation of liposomal modules

Biomimetic Hybrid Nanocontainers with Selective Permeability

Beyond the smiley face: applications of structural DNA nanotechnology

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