Deciphering the catalytic mechanism of superoxide dismutase activity of carbon dot nanozyme

Wenhui Gao; Jiuyang He; Lei Chen; Xiangqin Meng; Yana Ma; Liangliang Cheng; Kangsheng Tu; Xingfa Gao; Cui Liu; Mingzhen Zhang; Kelong Fan; Dai Wen Pang; Xiyun Yan

doi:10.1038/s41467-023-35828-2

Deciphering the catalytic mechanism of superoxide dismutase activity of carbon dot nanozyme

Wenhui Gao
, Jiuyang He
, Lei Chen
, Xiangqin Meng
, Yana Ma
, Liangliang Cheng
, Kangsheng Tu
, Xingfa Gao
, Cui Liu^*
, Mingzhen Zhang^*
, Kelong Fan^*
, Dai Wen Pang^*
, Xiyun Yan^*

^*此作品的通讯作者

Xi'an Jiaotong University
CAS - Institute of Biophysics
Jilin University
The First Affiliated Hospital of Xi’an Jiaotong University
National Center for Nanoscience and Technology
Zhengzhou University
University of Chinese Academy of Sciences
Nankai University

科研成果: 期刊稿件 › 文章 › 同行评审

552 引用（Scopus）

摘要

Nanozymes with superoxide dismutase (SOD)-like activity have attracted increasing interest due to their ability to scavenge superoxide anion, the origin of most reactive oxygen species in vivo. However, SOD nanozymes reported thus far have yet to approach the activity of natural enzymes. Here, we report a carbon dot (C-dot) SOD nanozyme with a catalytic activity of over 10,000 U/mg, comparable to that of natural enzymes. Through selected chemical modifications and theoretical calculations, we show that the SOD-like activity of C-dots relies on the hydroxyl and carboxyl groups for binding superoxide anions and the carbonyl groups conjugated with the π-system for electron transfer. Moreover, C-dot SOD nanozymes exhibit intrinsic targeting ability to oxidation-damaged cells and effectively protect neuron cells in the ischemic stroke male mice model. Together, our study sheds light on the structure-activity relationship of C-dot SOD nanozymes, and demonstrates their potential for treating of oxidation stress related diseases.

源语言	英语
文章编号	160
期刊	Nature Communications
卷	14
期	1
DOI	https://doi.org/10.1038/s41467-023-35828-2
出版状态	已出版 - 12月 2023
已对外发布	是

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title = "Deciphering the catalytic mechanism of superoxide dismutase activity of carbon dot nanozyme",

abstract = "Nanozymes with superoxide dismutase (SOD)-like activity have attracted increasing interest due to their ability to scavenge superoxide anion, the origin of most reactive oxygen species in vivo. However, SOD nanozymes reported thus far have yet to approach the activity of natural enzymes. Here, we report a carbon dot (C-dot) SOD nanozyme with a catalytic activity of over 10,000 U/mg, comparable to that of natural enzymes. Through selected chemical modifications and theoretical calculations, we show that the SOD-like activity of C-dots relies on the hydroxyl and carboxyl groups for binding superoxide anions and the carbonyl groups conjugated with the π-system for electron transfer. Moreover, C-dot SOD nanozymes exhibit intrinsic targeting ability to oxidation-damaged cells and effectively protect neuron cells in the ischemic stroke male mice model. Together, our study sheds light on the structure-activity relationship of C-dot SOD nanozymes, and demonstrates their potential for treating of oxidation stress related diseases.",

author = "Wenhui Gao and Jiuyang He and Lei Chen and Xiangqin Meng and Yana Ma and Liangliang Cheng and Kangsheng Tu and Xingfa Gao and Cui Liu and Mingzhen Zhang and Kelong Fan and Pang, \{Dai Wen\} and Xiyun Yan",

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doi = "10.1038/s41467-023-35828-2",

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T1 - Deciphering the catalytic mechanism of superoxide dismutase activity of carbon dot nanozyme

AU - Gao, Wenhui

AU - He, Jiuyang

AU - Chen, Lei

AU - Meng, Xiangqin

AU - Ma, Yana

AU - Cheng, Liangliang

AU - Tu, Kangsheng

AU - Gao, Xingfa

AU - Liu, Cui

AU - Zhang, Mingzhen

AU - Fan, Kelong

AU - Pang, Dai Wen

AU - Yan, Xiyun

PY - 2023/12

Y1 - 2023/12

N2 - Nanozymes with superoxide dismutase (SOD)-like activity have attracted increasing interest due to their ability to scavenge superoxide anion, the origin of most reactive oxygen species in vivo. However, SOD nanozymes reported thus far have yet to approach the activity of natural enzymes. Here, we report a carbon dot (C-dot) SOD nanozyme with a catalytic activity of over 10,000 U/mg, comparable to that of natural enzymes. Through selected chemical modifications and theoretical calculations, we show that the SOD-like activity of C-dots relies on the hydroxyl and carboxyl groups for binding superoxide anions and the carbonyl groups conjugated with the π-system for electron transfer. Moreover, C-dot SOD nanozymes exhibit intrinsic targeting ability to oxidation-damaged cells and effectively protect neuron cells in the ischemic stroke male mice model. Together, our study sheds light on the structure-activity relationship of C-dot SOD nanozymes, and demonstrates their potential for treating of oxidation stress related diseases.

AB - Nanozymes with superoxide dismutase (SOD)-like activity have attracted increasing interest due to their ability to scavenge superoxide anion, the origin of most reactive oxygen species in vivo. However, SOD nanozymes reported thus far have yet to approach the activity of natural enzymes. Here, we report a carbon dot (C-dot) SOD nanozyme with a catalytic activity of over 10,000 U/mg, comparable to that of natural enzymes. Through selected chemical modifications and theoretical calculations, we show that the SOD-like activity of C-dots relies on the hydroxyl and carboxyl groups for binding superoxide anions and the carbonyl groups conjugated with the π-system for electron transfer. Moreover, C-dot SOD nanozymes exhibit intrinsic targeting ability to oxidation-damaged cells and effectively protect neuron cells in the ischemic stroke male mice model. Together, our study sheds light on the structure-activity relationship of C-dot SOD nanozymes, and demonstrates their potential for treating of oxidation stress related diseases.

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VL - 14

JO - Nature Communications

JF - Nature Communications

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ER -

Deciphering the catalytic mechanism of superoxide dismutase activity of carbon dot nanozyme

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