主要研究方向:1. 基于电子顺磁共振(EPR)的联用设备研制与方法发展 2. 催化反应中间体分析 3. 生物物质与能量代谢电子传递路径分析
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luyuesr@ustc.edu.cn
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2024年至今,研究员,中国科学技术大学
2018年-2019年,访问学者,美国伊利诺伊大学厄巴纳-香槟分校
2014年-2024年,助理研究员/副研究员,中国科学院合肥物质科学研究院 强磁场科学中心
2009年-2014年,博士研究生,中国科学技术大学
2005年-2009年,本科,中国科学技术大学
围绕化学与生物体系中的氧化还原过程,发展具备低温、原位、时间分辨、电化学联用、高场等优势的电子顺磁共振(EPR)设备与方法,开展自由基中间体检测和电子传递机制分析。具体包括:
1. 发展原位-时间分辨-低温变温-电化学联用的EPR设备与方法。
2. 环境微生物氧化还原酶催化污染物转化降解过程的机制研究。
徐元植顺磁共振波谱学优秀青年奖
第32届中国化学会-生物物理化学青年科学探索奖
中国科学院青年创新促进会会员
Xu, Y.Y.#; Chen, H.W.#; Yu, L.#; Peng, X.C.; Zhang, J.W.; Xing, Z.Q.; Bao, Y.Y.; Liu, A.K.; Zhao, Y.; Tian, C.L.; Liang, Y.; Huang, X.Q.*, A Light-Driven Enzyme for Enantioselective Radical Acylation, Nature, 2024, 625(7993): 74–78.
Zhao, B.B.#; Feng, J.Q.#; Yu, L.#; Xing, Z.Q.; Chen, B.; Liu, A.K.; Liu, F.L.; Shi, F.M.; Zhao, Y.; Tian, C.L.; Wang, B.J.; Huang, X.Q.*, Direct visible-light-excited flavoproteins for redox-neutral asymmetric radical hydroarylation, Nature Catalysis, 2023, 6: 996–1004.
Yu, L.; Tian, C.L., Electron Spin Resonance Analysis of Photoenzymatic Catalysis, National Science Review, 2024, 11, nwae095.
Hu, X.#; Wang, C.#; Yu, L.#; Tong, Y.Z.; Li, Z.; Li, Y.; Chang, Z.; Zhang, J.Y.; Kuang, J.; Liu, D.G.; Tian, C.L.; Xu, Y.H.; Lu, X.*; Fu, Y.*, Modular Construction of α- or β-Stereogenic Organosilanes and Organogermanes via Enantioselective Alkene Hydroalkylation, Nature Synthesis, 2025, accepted.
Zhang, X.; Wu, J.Y.; Wang, J.M.; He, H.M.; Liu, A.K.; Hong, X.; Yu, Y.Y.; Pei, X.K.; Fang, X.J.; Xin, Y.Y.; Yu, L.*; Tian, C.L.*; Xu, X.L.*, Structural Basis of Menaquinone Reduction by Succinate Dehydrogenase from Chloroflexus aurantiacus, Nature Communications, 2025, accepted.
Liao, L.X.#; Kuang, J.#; Wu, P.#; Sang, X.H.; Yin, H.; Tian, C.L.; Zhang, X.W.; Peng, W.; Yu, L.*; Wang, B.J.*, A Molecular Mechanism for the Reduction of the Cu Site in Lytic Polysaccharide Monooxygenases by Phenol Reductants, JACS Au, 2025, 5(9): 4233-4248.
Kuang, J.; Liu, A.K.; Xu, L.Y.; Wang, G.X.; Zhang, Z.T.; Tian, C.L.*; Yu, L.*, Electron Paramagnetic Resonance Insights into Direct Electron Transfer Between FDX1 and Elesclomol-Cu²⁺ Complex in Cuproptosis, Chemistry – A European Journal, 2025, 31, 50, e202501145.
Liu, A.K.; Kuang, J.; Wei, R.T.; Zhang, Z.T.; Li, J.B.; Tian, C.L.*; Yu, L.*, Electron Paramagnetic Resonance Analysis of Hydroquinone Polymerization Catalyzed by Small Laccase, ChemCatChem, 2025, 17(2), e202401048.
Yu, L.; Min, Z.Z.; Liu, M.H.; Xin, Y.Y.; Liu, A.K.; Kuang, J.; Wu, W.P.; Wu, J.Y.; He, H.M.; Xin, J.Y.; Blankenship, R.E.; Tian, C.L.; Xu, X.L.*, A cytochrome c551 mediates the cyclic electron transport chain of the anoxygenic phototrophic bacterium Roseiflexus castenholzii, Plant Communications, 2024, 4, 100715.
Liu, A.K.#; Kuang, J.#; Zhou, Y.M.; Xu, A.; Tian, C.L.*; Yu, L.*, EPR-based in situ enzymatic activity detection of endogenous caspase-3 in apoptosis cell lysates, Chemical Communications, 2022, 58(61): 8528-8531.
Xing, Z.Q.#; Liu, F.L.#; Feng, J.Q.#; Yu, L.; Wu, Z.P.; Zhao, B.B.; Chen, B.; Ping, H.; Xu, Y.Y.; Liu, A.K.; Zhao, Y.; Wang, C.Y.; Wang, B.J.*; Huang, X.Q.*, Synergistic photobiocatalysis for enantioselective triple-radical sorting, Nature, 2025, 637, 1118–1123.
Chen, C.C.#; Yu, Z.P.#; Liu, Z.W.#; Yao, Y.P.#; Hagedoorn, P.L.; Schmitz, R.A.; Yang, L.J.; Yu, L.; Liu, A.K.; Sheng, X.; Su, H.; Ma, Y.Q.; Wang, T.; Huang, J.W.; Zhang, L.L.; Yan, J.Z.; Bao, J.P.; Cui, C.S.; Li, X.; Shen, P.P.; Zhang, W.Y.; Min, J.; Wang, C.Y.; Guo, R.T.*; Gao, S.S.*, Chanoclavine synthase operates by an NADPH-independent superoxide mechanism, Nature, 2025, 640, 840-846.
Zhao, B.B.#; Xu, Y.Y.#; Zhu, Q.; Liu, A.K.; Peng, X.C.; Zhang, T.Y.; Yu, L.; Zhang, Y.; Huang, X.Q.*, Electricity-driven enzymatic dynamic kinetic oxidation, Nature, 2025, 643, 699-704.
