| Literature DB >> 35393554 |
Manuel Maestre-Reyna1, Cheng-Han Yang1, Eriko Nango2,3, Wei-Cheng Huang1, Eka Putra Gusti Ngurah Putu1, Wen-Jin Wu1, Po-Hsun Wang1, Sophie Franz-Badur4, Martin Saft4, Hans-Joachim Emmerich4, Hsiang-Yi Wu1, Cheng-Chung Lee1, Kai-Fa Huang1, Yao-Kai Chang1, Jiahn-Haur Liao1, Jui-Hung Weng1, Wael Gad1, Chiung-Wen Chang1, Allan H Pang1, Michihiro Sugahara2, Shigeki Owada5, Yuhei Hosokawa6, Yasumasa Joti2,5, Ayumi Yamashita2,3, Rie Tanaka2,3, Tomoyuki Tanaka2,3, Fangjia Luo2,3, Kensuke Tono5, Kai-Cheng Hsu7, Stephan Kiontke4, Igor Schapiro8, Roberta Spadaccini9, Antoine Royant10,11, Junpei Yamamoto6, So Iwata2,3, Lars-Oliver Essen12, Yoshitaka Bessho13,14, Ming-Daw Tsai15,16.
Abstract
Flavin coenzymes are universally found in biological redox reactions. DNA photolyases, with their flavin chromophore (FAD), utilize blue light for DNA repair and photoreduction. The latter process involves two single-electron transfers to FAD with an intermittent protonation step to prime the enzyme active for DNA repair. Here we use time-resolved serial femtosecond X-ray crystallography to describe how light-driven electron transfers trigger subsequent nanosecond-to-microsecond entanglement between FAD and its Asn/Arg-Asp redox sensor triad. We found that this key feature within the photolyase-cryptochrome family regulates FAD re-hybridization and protonation. After first electron transfer, the FAD•- isoalloxazine ring twists strongly when the arginine closes in to stabilize the negative charge. Subsequent breakage of the arginine-aspartate salt bridge allows proton transfer from arginine to FAD•-. Our molecular videos demonstrate how the protein environment of redox cofactors organizes multiple electron/proton transfer events in an ordered fashion, which could be applicable to other redox systems such as photosynthesis.Entities:
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Year: 2022 PMID: 35393554 DOI: 10.1038/s41557-022-00922-3
Source DB: PubMed Journal: Nat Chem ISSN: 1755-4330 Impact factor: 24.274