解析基于纳米碳的人工过氧化物酶：在石墨烯量子点上鉴定催化活性和底物结合位点的化学方法。

Deciphering a nanocarbon-based artificial peroxidase: chemical identification of the catalytically active and substrate-binding sites on graphene quantum dots.

机构信息

Laboratory of Chemical Biology and State Key Laboratory of Rare Earth Resource Utilization, Changchun Institute of Applied Chemistry, Chinese Academy of Sciences, Changchun, Jilin 130022 (China).

University of Chinese Academy of Science, Beijing, 100039 (China).

出版信息

Angew Chem Int Ed Engl. 2015 Jun 8;54(24):7176-80. doi: 10.1002/anie.201500626. Epub 2015 May 4.

DOI:10.1002/anie.201500626

PMID:25940927

Abstract

The design and construction of efficient artificial enzymes is highly desirable. Recent studies have demonstrated that a series of carbon nanomaterials possess intrinsic peroxidase activity. Among them, graphene quantum dots (GQDs) have a high enzymatic activity. However, the catalytic mechanism remains unclear. Therefore, in this report, we chose to decipher their peroxidase activity. By selectively deactivating the ketonic carbonyl, carboxylic, or hydroxy groups and investigating the catalytic activities of these GQD derivatives, we obtained evidence that the -C=O groups were the catalytically active sites, whereas the O=C-O- groups acted as substrate-binding sites, and -C-OH groups can inhibit the activity. These results were corroborated by theoretical studies. This work should not only enhance our understanding of nanocarbon-based artificial enzymes, but also facilitate the design and construction of other types of target-specific artificial enzymes.

摘要

高效人工酶的设计和构建是非常可取的。最近的研究表明，一系列碳纳米材料具有内在的过氧化物酶活性。在这些碳纳米材料中，石墨烯量子点（GQDs）具有很高的酶活性。然而，其催化机制尚不清楚。因此，在本报告中，我们选择对其过氧化物酶活性进行解析。通过选择性地使酮羰基、羧基或羟基失活，并研究这些 GQD 衍生物的催化活性，我们获得了证据，证明 -C=O 基团是催化活性位点，而 O=C-O-基团充当底物结合位点，-C-OH 基团可以抑制活性。这些结果得到了理论研究的证实。这项工作不仅应加深我们对基于纳米碳的人工酶的理解，而且还应促进其他类型的靶向特定人工酶的设计和构建。

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解析基于纳米碳的人工过氧化物酶：在石墨烯量子点上鉴定催化活性和底物结合位点的化学方法。

Deciphering a nanocarbon-based artificial peroxidase: chemical identification of the catalytically active and substrate-binding sites on graphene quantum dots.

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