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Bioinspired Hydrogen Bonds of Nucleobases Enable Programmable Morphological Transformations of Mixed Nanostructures

Yangyang Yan, Xinzi Fang, Nan Yao, Haojie Gu, Guang Yang, Zan Hua

2022Macromolecules14 citationsDOI

Abstract

Biological systems enable the efficient implementation of various functions by segregating responsive biomacromolecules or assemblies in disparate compartments, which is highly fascinating and desired by materials scientists. However, it is still challenging to elegantly modulate the responsive behaviors of mixed assemblies in synthetic polymeric systems owing to the lack of delicately responsive nanostructures. Herein, bioinspired complementary hydrogen bonding interactions of nucleobases are harnessed to achieve the programmable morphological transformations of mixed nanostructures from cellulose-grafted bottlebrush polymers. Both adenine- and thymine-containing cellulose-grafted-polymers (Cell-g-PAAc and Cell-g-PTAc) were successfully synthesized by using reversible addition-fragmentation chain transfer (RAFT) polymerization. Furthermore, self-assembly of Cell-g-PAAc and Cell-g-PTAc produces well-defined spherical assemblies MA and MT without the discernible particle–particle interaction. In contrast, MA and MT undergo distinct morphological transformations with the introduction of linear diblock copolymers containing complementary nucleobases. By utilizing the novel properties of nanostructures from cellulose-grafted bottlebrush polymers, it is feasible to achieve the selective responsiveness of mixed nanostructures based on complementary hydrogen bonds of nucleobases. This work presents an efficient bioinspired strategy to elegantly modulate the responsive behaviors of mixed nanostructures, providing a cue for fabricating advanced synthetic stimuli-responsive materials.

Topics & Concepts

NucleobaseNanostructurePolymerCopolymerHydrogen bondThymineMaterials sciencePolymerizationRaftCelluloseTemplateNanotechnologyBiomoleculeChemistryCombinatorial chemistryMoleculeDNAOrganic chemistryBiochemistryAdvanced biosensing and bioanalysis techniquesRNA Interference and Gene DeliverySupramolecular Self-Assembly in Materials
Bioinspired Hydrogen Bonds of Nucleobases Enable Programmable Morphological Transformations of Mixed Nanostructures | Litcius