Xuanzhong Liu scite author profile

Xuanzhong Liu

5Publications

75Citation Statements Received

197Citation Statements Given

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295

185

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Jiangnan University

Publications

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Discovery of the Biosynthetic Pathway of Beticolin 1 Reveals a Novel Non‐Heme Iron‐Dependent Oxygenase for Anthraquinone Ring Cleavage

Hou

Deng

et al. 2022

Angew Chem Int Ed

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This study used light-mediated comparative transcriptomics to identify the biosynthetic gene cluster of beticolin 1 in Cercospora. It contains an anthraquinone moiety and an unusual halogenated xanthone moiety connected by a bicyclo[3.2.2]nonane. During elucidation of the biosynthetic pathway of beticolin 1, a novel non-heme iron oxygenase BTG13 responsible for anthraquinone ring cleavage was discovered. More importantly, the discovery of non-heme iron oxygenase BTG13 is well supported by experimental evidence: (i) crystal structure and the inductively coupled plasma mass spectrometry revealed that its reactive site is built by an atypical iron ion coordination, where the iron ion is uncommonly coordinated by four histidine residues, an unusual carboxylated-lysine (Kcx377) and water; (ii) Kcx377 is mediated by His58 and Thr299 to modulate the catalytic activity of BTG13. Therefore, we believed this study updates our knowledge of metalloenzymes.

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Molecular Basis of the Unusual Seven-Membered Methylenedioxy Bridge Formation Catalyzed by Fe(II)/α-KG-Dependent Oxygenase CTB9

Liu

Yuan

et al. 2022

ACS Catal.

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Methylenedioxy bridges (MDBs) are architecturally important motifs in natural products and bioactive molecules. Cercosporin, a typical perylenequinone pigment, contains an unusual seven-membered MDB, which has versatile biological and photocatalytic activities. Although cercosporin has been isolated, characterized, and studied for several decades, its biosynthetic pathway, especially the formation of the seven-membered MDB, has remained unclear. Here, we show that the formation of the seven-membered MDB is catalyzed by Fe(II)/α-ketoglutaric acid (α-KG)-dependent dioxygenase CTB9 in cercosporin biosynthesis. Moreover, crystal structures of CTB9 in complex with an α-KG analogue NOG (CTB9·Cu·NOG) and its substrate pre-cercosporin with NOG (CTB9·Cu·NOG·pre-cercosporin) were determined. These structures, together with site-directed mutagenesis studies and quantum mechanics calculations, help define the mechanism of the unique seven-membered MDB in cercosporin biosynthesis. In summary, these results provide molecular insights into other biosynthetic pathways of natural products containing MDBs.

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Discovery and characterization of a novel perylenephotoreductant for the activation of aryl halides

Guo

et al. 2021

Journal of Catalysis

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Energy-Transfer-Mediated Photocatalysis by a Bioinspired Organic Perylenephotosensitizer HiBRCP

Zhang

Xia

et al. 2021

J. Org. Chem.

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Energy transfer plays a special role in photocatalysis by utilizing the potential energy of the excited state through indirect excitation, in which a photosensitizer determines the thermodynamic feasibility of the reaction. Bioinspired by the energy-transfer ability of natural product cercosporin, here we developed a green and highly efficient organic photosensitizer HiBRCP (hexaisobutyryl reduced cercosporin) through structural modification of cercosporin. After structural manipulation, its triplet energy was greatly improved, and then, it could markedly promote the efficient geometrical isomerization of alkenes from the E-isomer to the Z-isomer. Moreover, it was also effective for energy-transfer-mediated organometallic catalysis, which allowed realization of the cross-coupling of aryl bromides and carboxylic acids through efficient energy transfer from HiBRCP to nickel complexes. Thus, the study on the relationship between structural manipulation and their photophysical properties provided guidance for further modification of cercosporin, which could be applied to more meaningful and challenging energy-transfer reactions.

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Discovery of the Biosynthetic Pathway of Beticolin 1 Reveals a Novel Non‐Heme Iron‐Dependent Oxygenase for Anthraquinone Ring Cleavage

Hou

Deng

et al. 2022

Angewandte Chemie

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This study used light‐mediated comparative transcriptomics to identify the biosynthetic gene cluster of beticolin 1 in Cercospora. It contains an anthraquinone moiety and an unusual halogenated xanthone moiety connected by a bicyclo[3.2.2]nonane. During elucidation of the biosynthetic pathway of beticolin 1, a novel non‐heme iron oxygenase BTG13 responsible for anthraquinone ring cleavage was discovered. More importantly, the discovery of non‐heme iron oxygenase BTG13 is well supported by experimental evidence: (i) crystal structure and the inductively coupled plasma mass spectrometry revealed that its reactive site is built by an atypical iron ion coordination, where the iron ion is uncommonly coordinated by four histidine residues, an unusual carboxylated‐lysine (Kcx377) and water; (ii) Kcx377 is mediated by His58 and Thr299 to modulate the catalytic activity of BTG13. Therefore, we believed this study updates our knowledge of metalloenzymes.

show abstract

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Xuanzhong Liu

Discovery of the Biosynthetic Pathway of Beticolin 1 Reveals a Novel Non‐Heme Iron‐Dependent Oxygenase for Anthraquinone Ring Cleavage

Molecular Basis of the Unusual Seven-Membered Methylenedioxy Bridge Formation Catalyzed by Fe(II)/α-KG-Dependent Oxygenase CTB9

Discovery and characterization of a novel perylenephotoreductant for the activation of aryl halides

Energy-Transfer-Mediated Photocatalysis by a Bioinspired Organic Perylenephotosensitizer HiBRCP

Discovery of the Biosynthetic Pathway of Beticolin 1 Reveals a Novel Non‐Heme Iron‐Dependent Oxygenase for Anthraquinone Ring Cleavage

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