DNA-controlled dynamic colloidal nanoparticle systems for mediating cellular interaction

Seiichi Ohta; Dylan Glancy; Warren C.W. Chan

doi:10.1126/science.aad4925

DNA-controlled dynamic colloidal nanoparticle systems for mediating cellular interaction

Seiichi Ohta, Dylan Glancy, Warren C.W. Chan^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

187 Citations (Scopus)

Abstract

Precise control of biosystems requires development of materials that can dynamically change physicochemical properties. Inspired by the ability of proteins to alter their conformation to mediate function, we explored the use of DNA as molecular keys to assemble and transform colloidal nanoparticle systems. The systems consist of a core nanoparticle surrounded by small satellites, the conformation of which can be transformed in response toDNAvia a toe-hold displacementmechanism.The conformational changes can alter the optical properties and biological interactions of the assembled nanosystem. Photoluminescent signal is altered by changes in fluorophore-modified particle distance, whereas cellular targeting efficiency is increased 2.5 times by changing the surface display of targeting ligands.These concepts provide strategies for engineering dynamic nanotechnology systems for navigating complex biological environments.

Original language	English
Pages (from-to)	841-845
Number of pages	5
Journal	Science
Volume	351
Issue number	6275
DOIs	https://doi.org/10.1126/science.aad4925
Publication status	Published - Feb 19 2016
Externally published	Yes

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AB - Precise control of biosystems requires development of materials that can dynamically change physicochemical properties. Inspired by the ability of proteins to alter their conformation to mediate function, we explored the use of DNA as molecular keys to assemble and transform colloidal nanoparticle systems. The systems consist of a core nanoparticle surrounded by small satellites, the conformation of which can be transformed in response toDNAvia a toe-hold displacementmechanism.The conformational changes can alter the optical properties and biological interactions of the assembled nanosystem. Photoluminescent signal is altered by changes in fluorophore-modified particle distance, whereas cellular targeting efficiency is increased 2.5 times by changing the surface display of targeting ligands.These concepts provide strategies for engineering dynamic nanotechnology systems for navigating complex biological environments.

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DNA-controlled dynamic colloidal nanoparticle systems for mediating cellular interaction

Abstract

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