Peptide-induced super-assembly of biocatalytic metal-organic frameworks for programmed enzyme cascades

Jieying Liang; Federico Mazur; Chuyang Tang; Xunan Ning; Rona Chandrawati; Kang Liang

doi:10.1039/c9sc02021g

Peptide-induced super-assembly of biocatalytic metal-organic frameworks for programmed enzyme cascades

Chem Sci. 2019 Jul 22;10(34):7852-7858. doi: 10.1039/c9sc02021g. eCollection 2019 Sep 14.

Authors

Jieying Liang^{1

2}, Federico Mazur¹, Chuyang Tang¹, Xunan Ning², Rona Chandrawati¹, Kang Liang^{1

3}

Affiliations

¹ School of Chemical Engineering , The University of New South Wales , Sydney , NSW 2052 , Australia . Email: rona.chandrawati@unsw.edu.au ; Email: kang.liang@unsw.edu.au.
² School of Environmental Science and Engineering , Guangdong University of Technology , Guangzhou 510006 , China . Email: ningxunan666@126.com.
³ Graduate School of Biomedical Engineering , The University of New South Wales , Sydney , NSW 2052 , Australia.

Abstract

Despite the promise of metal-organic frameworks (MOFs) as functional matrices for enzyme stabilization, the development of a stimulus-responsive approach to induce a multi-enzyme cascade reaction in MOFs remains a critical challenge. Here, a novel method using peptide-induced super-assembly of MOFs is developed for programmed enzyme cascade reactions on demand. The super-assembled MOF particles containing different enzymes show remarkable 7.3-fold and 4.4-fold catalytic activity enhancements for the two-enzyme and three-enzyme cascade reactions, respectively, as compared with the unassembled MOF nanoparticles. Further digestion of the coiled-coil forming peptides on the MOF surfaces leads to the MOF superstructure disassembly and the programmed enzyme cascade reaction being "switched-off". Research on these stimuli-responsive materials with controllable and predictable biocatalytic functions/properties provide a concept to facilitate the fabrication of next-generation smart materials based on precision chemistry.