Issue 4, 2020

On the role of flexibility in linker-mediated DNA hydrogels

Abstract

Three-dimensional DNA networks, composed of tri- or higher valent nanostars with sticky, single-stranded DNA overhangs, have been previously studied in the context of designing thermally responsive, viscoelastic hydrogels. In this work, we use linker-mediated gels, where the sticky ends of two trivalent nanostars are connected through the complementary sticky ends of a linear DNA duplex. We can design this connection to be either rigid or flexible by introducing flexible, non-binding bases. The additional flexibility provided by these non-binding bases influences the effective elasticity of the percolating gel formed at low temperatures. Here we show that by choosing the right length of the linear duplex and non-binding flexible joints, we obtain a completely different phase behaviour to that observed for rigid linkers. In particular, we use dynamic light scattering as a microrheological tool to monitor the self-assembly of DNA nanostars with linear linkers as a function of temperature. While we observe classical gelation when using rigid linkers, the presence of flexible joints leads to a cluster fluid with a much-reduced viscosity. Using both the oxDNA model and a coarse-grained simulation to investigate the nanostar-linker topology, we hypothesise on the possible structure formed by the DNA clusters. Moreover, we present a systematic study of the strong viscosity increase of aqueous solutions in the presence of these DNA building blocks.

Graphical abstract: On the role of flexibility in linker-mediated DNA hydrogels

Supplementary files

Article information

Article type
Paper
Submitted
10 Jul 2019
Accepted
26 Nov 2019
First published
27 Nov 2019

Soft Matter, 2020,16, 990-1001

On the role of flexibility in linker-mediated DNA hydrogels

I. D. Stoev, T. Cao, A. Caciagli, J. Yu, C. Ness, R. Liu, R. Ghosh, T. O’Neill, D. Liu and E. Eiser, Soft Matter, 2020, 16, 990 DOI: 10.1039/C9SM01398A

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