Tokyo Tech News

Scientists develop DNA microcapsules with built-in ion channels


Published: September 18, 2019

A Research group led by Tokyo Tech reports a way of constructing DNA-based microcapsules that hold great promise for the development of new functional materials and devices (Figure 1). They showed that tiny pores on the surface of these capsules can act as ion channels. Their study will accelerate advances in artificial cell engineering and molecular robotics, as well as nanotechnology itself.

Conceptual illustration of DNA nanoplate-based microcapsules

Figure 1. Conceptual illustration of DNA nanoplate-based microcapsules

DNA-based, self-assembled nanostructures are promising building blocks for new kinds of micro- and nanodevices for biomedical and environmental applications. Much research is currently focused on adding functionality to such structures in order to expand their versatility.

For example, engineered capsules called liposomes that have a lipid-bilayer membrane are already successfully being used as sensors, diagnostic tools and drug delivery systems. Another group of capsules that do not have a lipid bilayer but are instead composed of colloidal particle membrane, known as Pickering emulsions1 or colloidosomes, also have potential for many biotechnologically useful applications.

Now, a research group led by biophysicist Masahiro Takinoue of Tokyo Tech reports a new type of Pickering emulsion with the added functionality of ion channels — an achievement that opens up new routes to designing artificial cells and molecular robots.

"For the first time, we have demonstrated ion channel function using pored DNA nanostructures without the presence of a lipid-bilayer membrane," says Takinoue.

The team's design exploits the self-assembling properties of DNA origami nanoplates2. The resulting Pickering emulsions are stabilized by the amphiphilic3 nature of the nanoplates. (See Figure 2.)

Representation of DNA nanoplate-based microcapsules

Figure 2. Representation of DNA nanoplate-based microcapsules

(a) Two types of DNA nanoplates (non-pored and pored) were constructed and modified to confer hydrophobicity to one face of the nanoplates. The resultant amphiphilic DNA nanoplates self-assemble at the oil–water interface to form emulsion droplets, or microcapsules, even without any supporting membrane such as lipid membrane.
(b) The nanopores were successfully shown in this study to function as ion channels between two microcapsules.

One of the most exciting implications of the study, Takinoue explains, is that it will be possible to develop stimuli-responsive systems — ones that are based on the concept of open–close switching. Such systems could eventually be used to develop artificial neural networks mimicking the way the human brain works.

"In addition, a stimuli-responsive shape change of the DNA nanoplates could serve as a driving force for autonomous locomotion, which would be useful for the development of molecular robots," Takinoue says.

The present study highlights the team's strengths in combining DNA nanotechnology with a perspective grounded in biophysics and soft-matter physics.

1 Pickering emulsions

Microcapsules formed by the assembly of colloidal particles at the interface of emulsion droplets.

2 DNA origami nanoplates

Nanoscale building blocks formed by an assembly technique that "folds" DNA molecules into desired structures.

3 amphiphilic

A term describing compounds that have both hydrophilic and lipophilic properties, meaning that they have a good affinity for water and oil.


Daisuke Ishikawa,a, g Yuki Suzuki,b Chikako Kurokawa,c Masayuki Ohara,d Misato Tsuchiya,a Masamune Morita,a Miho Yanagisawa,c,e Masayuki Endo,f Ryuji Kawano,d Masahiro Takinouea
Title of original paper:
DNA Origami Nanoplate-Based Emulsion with Nanopore Function
Angewandte Chemie International Edition (2019)

a Department of Computer Science, Tokyo Institute of Technology

b Frontier Research Institute for Interdisciplinary Sciences, Tohoku University

c Department of Applied Physics, Graduate School of Engineering, Tokyo University of Agriculture and Technology

d Department of Life Science and Biotechnology, Tokyo University of Agriculture and Technology

e Komaba Institute for Science, Graduate School of Arts and Sciences, The University of Tokyo

f Department of Chemistry, Graduate School of Science, Kyoto University

g Present address: Research Center for Gold Chemistry, Graduate School of Urban Environmental Sciences, Tokyo Metropolitan University

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Further Information

Associate Professor Masahiro Takinoue
Department of Computer Science, School of Computing,
Tokyo Institute of Technology

Tel +81-45-924-5680


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