CryoEM Reveals the Complex Self-assembly of a Chemically Driven Disulfide Hydrogel

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2024 Jan 19

PMID 38239701

Authors

Paul Joshua Hurst

Justin T Mulvey

Rebecca A Bone

Serxho Selmani

Redford F Hudson

Zhibin Guan

Jason R Green

Joseph P Patterson

Affiliations

Soon will be listed here.

Abstract

Inspired by the adaptability of biological materials, a variety of synthetic, chemically driven self-assembly processes have been developed that result in the transient formation of supramolecular structures. These structures form through two simultaneous reactions, forward and backward, which generate and consume a molecule that undergoes self-assembly. The dynamics of these assembly processes have been shown to differ from conventional thermodynamically stable molecular assemblies. However, the evolution of nanoscale morphologies in chemically driven self-assembly and how they compare to conventional assemblies has not been resolved. Here, we use a chemically driven redox system to separately carry out the forward and backward reactions. We analyze the forward and backward reactions both sequentially and synchronously with time-resolved cryogenic transmission electron microscopy (cryoEM). Quantitative image analysis shows that the synchronous process is more complex and heterogeneous than the sequential process. Our key finding is that a thermodynamically unstable stacked nanorod phase, briefly observed in the backward reaction, is sustained for ∼6 hours in the synchronous process. Kinetic Monte Carlo modeling show that the synchronous process is driven by multiple cycles of assembly and disassembly. The collective data suggest that chemically driven self-assembly can create sustained morphologies not seen in thermodynamically stable assemblies by kinetically stabilizing transient intermediates. This finding provides plausible design principles to develop and optimize supramolecular materials with novel properties.

Citing Articles

Design and Fabrication of Viscoelastic Hydrogels as Extracellular Matrix Mimicry for Cell Engineering.

Li Z, Li T, Yang H, Ding M, Chen L, Yu S Chem Bio Eng. 2025; 1(11):916-933.

PMID: 39975568 PMC: 11835267. DOI: 10.1021/cbe.4c00129.

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