Enhancing Radiation-resistance and Peroxidase-like Activity of Single-atom Copper Nanozyme Via Local Coordination Manipulation

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Jul 22

PMID 39039047

Authors

Jiabin Wu

Xianyu Zhu

Qun Li

Qiang Fu

Bingxue Wang

Beibei Li

Shanshan Wang

Qingchao Chang

Huandong Xiang

Chengliang Ye

Qiqiang Li

Liang Huang

Yan Liang

Dingsheng Wang

Yuliang Zhao

Yadong Li

Affiliations

Soon will be listed here.

Abstract

The inactivation of natural enzymes by radiation poses a great challenge to their applications for radiotherapy. Single-atom nanozymes (SAzymes) with high structural stability under such extreme conditions become a promising candidate for replacing natural enzymes to shrink tumors. Here, we report a CuN-centered SAzyme (CuN-SAzyme) that exhibits higher peroxidase-like catalytic activity than a CuN-centered counterpart, by locally regulating the coordination environment of single copper sites. Density functional theory calculations reveal that the CuN active moiety confers optimal HO adsorption and dissociation properties, thus contributing to high enzymatic activity of CuN-SAzyme. The introduction of X-ray can improve the kinetics of the decomposition of HO by CuN-SAzyme. Moreover, CuN-SAzyme is very stable after a total radiation dose of 500 Gy, without significant changes in its geometrical structure or coordination environment, and simultaneously still retains comparable peroxidase-like activity relative to natural enzymes. Finally, this developed CuN-SAzyme with remarkable radioresistance can be used as an external field-improved therapeutics for enhancing radio-enzymatic therapy in vitro and in vivo. Overall, this study provides a paradigm for developing SAzymes with improved enzymatic activity through local coordination manipulation and high radioresistance over natural enzymes, for example, as sensitizers for cancer therapy.

Citing Articles

Surface immobilization of single atoms on heteroatom-doped carbon nanospheres through phenolic-mediated interfacial anchoring for highly efficient biocatalysis.

Zhang Y, He Y, Jiao Y, Yang G, Pu Y, Wan Z Chem Sci. 2025; 16(8):3479-3489.

PMID: 39877823 PMC: 11770272. DOI: 10.1039/d4sc07775j.

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