Structural characterization of electron transfer in D.m (6-4) photolyase by time-resolved X-ray crystallography
Abstract
Photolyases are flavoproteins widely spread in bacteria, archea, fungi, plants and animals. These enzymes absorb blue light and use it as an energy source for repairing damages that are induced on DNA after a prolonged exposure to UV-light. The mechanism of DNA repair in photolyases requires a first step of photo-excitation known as photoactivation. During this process, the chromophore uptakes an electron from a close tryptophan. This event triggers an electron transfer along a chain of tryptophans and results into the reduction of the chromophore to its catalytic form.
This thesis is focusing on unravelling the structural changes associated with photoactivation in a photolyase from Drosophila Melanogaster. We employed time-resolved serial crystallography as the main technique of investigation. In the three papers, we present the crystallography techniques and conditions that were used for time-resolved experiments in synchrotron and in x-ray free electron laser facilities (XFEL). At first, we solved the structure of the protein in its resting state and then we
characterized the structural changes that occur after light activation. We recorded data at different time delays from illumination ranging from ps to ms. The findings show structural changes around the chromophore and the tryptophans involved in the electron transfer.
These results contribute to the understanding of the structural adaptation of photolyase during the first electron transfer process. However,further studies are needed to structurally characterized the second step of photoactivation and the process of DNA repair.
Parts of work
paper I: Andrea Cellini ∗ , Weixiao Yuan Wahlgren ∗ , Léocadie Henry, Suraj Pandey, Swagatha Ghosh, Leticia Castillon, Elin Claesson, Heikki Takala, Joachim Kübel, Amke Nimmrich, Valentina Kuznetsova, Eriko Nango, So Iwata, So Owada, Emina A. Stojković, Marius Schmidt, Janne A. Ihalainen and Sebastian Westenhoff. "The three-dimensional structure of Drosophila melanogaster (6–4) photolyase at room temperature". Acta Crystallographica Section D: Structural Biology, 2021, 77.8: 1001-1009. https://doi.org/10.1107/S2059798321005830 ∗ Equally contributed. paper II: Andrea Cellini, Weixiao Yuan Wahlgren, Madan Kumar, Amke Nimmrich, Tek Malla, Antonia Furrer, Melissa Carrillo, Jennifer Mutisya, Emma V. Beale , Florian Dworkowskic, Camilla Bacellar , Joerg Standfuss, Tobias Weinert,Janne A. Ihalainen and Sebastian Westenhoff. "Ultrafast conformational changes of the photoactivation of a (6-4) photolyase captured by time-resolved crystallography" (unpublished manuscript). paper III: Andrea Cellini, Madan Kumar Shankar, Weixiao Yuan Wahlgren, Amke Nimmrich, Antonia Furrer, Daniel James, Maximilian Wranik, Sylvain Aumonier, Emma V. Beale, Florian Dworkowski, Joerg Standfuss, Tobias Weinert and Sebastian Westenhoff. "Structural basis of the radical pair state in photolyases and cryptochromes". Chemical Communications, 2022, 58.31: 4889-4892. https://doi.org/10.1039/D2CC00376G
Degree
Doctor of Philosophy
University
Gothenburg University, Faculty of Science
Institution
Department of Chemistry and Molecular Biology ; Institutionen för kemi och molekylärbiologi
Disputation
Fredagen den 11 November 2022, kl. 13.00, 2119 Hälsovetabacken, Arvid Wallgrensbacke
Date of defence
2022-11-11
andrea.cellini@outlook.com
Date
2022-10-18Author
Cellini, Andrea
Keywords
photolyase, time-resolved crystallography
Publication type
Doctoral thesis
ISBN
978-91-8069-011-9(print)/9789180690126(pdf)
Language
eng