Issue 6, 2023

Unveiling the orientation and dynamics of enzymes in unstructured artificial compartments of metal–organic frameworks (MOFs)

Abstract

Confining enzymes in well-shaped MOF compartments is a promising approach to mimic the cellular environment of enzymes and determine enzyme structure–function relationship therein. Under the cellular crowding, however, enzymes can also be confined in unstructured spaces that are close to the shapes/outlines of the enzyme. Therefore, for a better understanding of enzymes in their physiological environments, it is necessary to study enzymes in these unstructured spaces. However, practically it is challenging to create compartments that are close to the outline of an enzyme and probe enzyme structural information therein. Here, for proof-of-principle, we confined a model enzyme, lysozyme, in the crystal defects of a MOF via co-crystallization, where lysozyme served as the nuclei for MOF crystal scaffolds to grow on so that unstructured spaces close to the outline of lysozyme are created, and determined enzyme relative orientation and dynamics. This effort is important for understanding enzymes in near-native environments and guiding the rational design of biocatalysts that mimic how nature confines enzymes.

Graphical abstract: Unveiling the orientation and dynamics of enzymes in unstructured artificial compartments of metal–organic frameworks (MOFs)

Supplementary files

Article information

Article type
Communication
Submitted
28 Nov 2022
Accepted
12 Jan 2023
First published
12 Jan 2023
This article is Open Access
Creative Commons BY license

Nanoscale, 2023,15, 2573-2577

Unveiling the orientation and dynamics of enzymes in unstructured artificial compartments of metal–organic frameworks (MOFs)

Y. Pan, Q. Li, W. Liu, Z. Armstrong, A. MacRae, L. Feng, C. McNeff, P. Zhao, H. Li and Z. Yang, Nanoscale, 2023, 15, 2573 DOI: 10.1039/D2NR06659A

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