Nature Communications (Jun 2024)

Real-time observation of a metal complex-driven reaction intermediate using a porous protein crystal and serial femtosecond crystallography

  • Basudev Maity,
  • Mitsuo Shoji,
  • Fangjia Luo,
  • Takanori Nakane,
  • Satoshi Abe,
  • Shigeki Owada,
  • Jungmin Kang,
  • Kensuke Tono,
  • Rie Tanaka,
  • Thuc Toan Pham,
  • Mariko Kojima,
  • Yuki Hishikawa,
  • Junko Tanaka,
  • Jiaxin Tian,
  • Misaki Nagama,
  • Taiga Suzuki,
  • Hiroki Noya,
  • Yuto Nakasuji,
  • Asuka Asanuma,
  • Xinchen Yao,
  • So Iwata,
  • Yasuteru Shigeta,
  • Eriko Nango,
  • Takafumi Ueno

DOI
https://doi.org/10.1038/s41467-024-49814-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 12

Abstract

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Abstract Determining short-lived intermediate structures in chemical reactions is challenging. Although ultrafast spectroscopic methods can detect the formation of transient intermediates, real-space structures cannot be determined directly from such studies. Time-resolved serial femtosecond crystallography (TR-SFX) has recently proven to be a powerful method for capturing molecular changes in proteins on femtosecond timescales. However, the methodology has been mostly applied to natural proteins/enzymes and limited to reactions promoted by synthetic molecules due to structure determination challenges. This work demonstrates the applicability of TR-SFX for investigations of chemical reaction mechanisms of synthetic metal complexes. We fix a light-induced CO-releasing Mn(CO)3 reaction center in porous hen egg white lysozyme (HEWL) microcrystals. By controlling light exposure and time, we capture the real-time formation of Mn-carbonyl intermediates during the CO release reaction. The asymmetric protein environment is found to influence the order of CO release. The experimentally-observed reaction path agrees with quantum mechanical calculations. Therefore, our demonstration offers a new approach to visualize atomic-level reactions of small molecules using TR-SFX with real-space structure determination. This advance holds the potential to facilitate design of artificial metalloenzymes with precise mechanisms, empowering design, control and development of innovative reactions.