Covalent recruitment of polymers and nanoparticles onto glycan-engineered cells enhances gene delivery during short exposure

Qiao Tang; Ruben M. F. Tomás; Matthew I. Gibson

doi:10.1039/D4SC03666B

Covalent recruitment of polymers and nanoparticles onto glycan-engineered cells enhances gene delivery during short exposure

Qiao Tang, Ruben M. F. Tomás, Matthew I. Gibson

Materials Chemistry

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Abstract

Non-viral gene delivery with cationic polymers/nanoparticles relies on iterative optimization of the carrier to achieve delivery. Here we demonstrate, instead, that precision engineering of cell surfaces to covalently capture a polyplex accelerates gene delivery within just 10 min of exposure. Azides were installed into cell-surface sialic acids, which enabled the rapid and selective recruitment of cyclooctyne-functional polyplexes, leading to increased delivery of fluorescent cargo, and also increased plasmid expression and siRNA knockdown. Covalent delivery enhancement was also shown for a polymer-coated nanoparticle delivery system. This validates using cellular metabolic engineering (or other synthetic biology) tools to overcome payload delivery challenges.

Original language	English
Pages (from-to)	15731-15736
Journal	Chemical Science
Volume	15
Issue number	38
Early online date	9 Sept 2024
DOIs	https://doi.org/10.1039/D4SC03666B
Publication status	Published - 28 Nov 2024

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10.1039/D4SC03666BLicence: CC BY

FinalFinal published version, 832 KBLicence: CC BY

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AB - Non-viral gene delivery with cationic polymers/nanoparticles relies on iterative optimization of the carrier to achieve delivery. Here we demonstrate, instead, that precision engineering of cell surfaces to covalently capture a polyplex accelerates gene delivery within just 10 min of exposure. Azides were installed into cell-surface sialic acids, which enabled the rapid and selective recruitment of cyclooctyne-functional polyplexes, leading to increased delivery of fluorescent cargo, and also increased plasmid expression and siRNA knockdown. Covalent delivery enhancement was also shown for a polymer-coated nanoparticle delivery system. This validates using cellular metabolic engineering (or other synthetic biology) tools to overcome payload delivery challenges.

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Covalent recruitment of polymers and nanoparticles onto glycan-engineered cells enhances gene delivery during short exposure

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