Time-Resolved X-ray Crystallography and Quantum Chemical Calculations of the Proton Pumping Mechanism in Cytochrome c Oxidase
Abstract
Aerobic respiration and photosynthesis are arguably the two most essential processes for life
on earth as known to us. These two processes occur on an immense scale every day and the
electron transport chain of aerobic organisms effectively utilizes the energy available from the
exergonic reduction of the high potential electron acceptor oxygen. In order to couple the
exergonic reaction to energy available for the cell, an electrochemical gradient is generated
across the cell membrane which can be used for energy demanding process. The last step of
the electron transport chain's generation of the gradient is performed by the enzyme
cytochrome c oxidase which catalyses the formation of water and makes use of the free energy
by the translocation of protons across the membrane against this gradient. How the enzyme
couples this proton translocation to the exergonic redox events of the catalytic mechanism is
currently not known in detail, although many of the requirements of the event have been
elucidated. Insights of the mechanistic details can help not only to understand this vital
process, but also essential aspects of energy transduction efficiency with potential future
applicability.
Time-Resolved Serial Femtosecond X-ray crystallography enables the 3D visualization of
protein structures by their illumination in the crystalline form. By collection of diffraction
images at certain time delays in relation to the reaction initiation, structural information of the
catalytic mechanism can be retrieved. There are many technical barriers to this however, and
those are the topic of the first half of this thesis where overcoming them is the main hurdle.
Novel structural information is successfully retrieved in three different papers while one
paper investigates and optimizes the chemical barriers to enabling the experiment to as great
extent as possible.
In the last part of the thesis additional insights of the mechanistic details of the catalytic cycle
are gained by applying computational chemistry to study processes within the active site of
the enzyme. These methods can give even further detailed information for where temporal
and spatial resolution limit the experimental techniques and the insights gained from these
are presented in the last two papers.
Parts of work
I. Time-resolved serial crystallography to track the dynamics of carbon monoxide in the active site of cytochrome c oxidase Cecilia Safari; Swagatha Ghosh; Rebecka Andersson; Jonatan Johannesson; Petra Båth; Owens Uwangue; Peter Dahl; Doris Zoric; Emil Sandelin; Adams Vallejos; Eriko Nango; Rie Tanaka; Robert Bosman; Per Börjesson; Elin Dunevall; Greger Hammarin; Giorgia Ortolani; Matthijs Panman; Tomoyuki Tanaka; Ayumi Yamashita; Toshi Arima; Michihiro Sugahara; Mamoru Suzuki; Tetsuya Masuda; Hanae Takeda; Raika Yamagiwa; Kazumasa Oda; Masahiro Fukuda; Takehiko Tosha; Hisashi Naitow; Shigeki Owada; Kensuke Tono; Osamu Nureki; So Iwata; Richard Neutze and Gisela Brändén Sci. Adv. (2023); 9(49). DOI: https://doi.org/10.1126/sciadv.adh4179 II. Characterization and evaluation of photolabile (μ-peroxo)(μ- hydroxo)bis[bis(bipyridyl)cobalt caged oxygen compounds towards enabling time-resolved crystallographic studies of cytochrome c oxidase Emil Sandelin; Jonatan Johannesson; Ola Wendt; Gisela Brändén; Richard Neutze and Carl-Johan Wallentin. Photochem Photobiol Sci 23, 839–851 (2024). DOI: https://doi.org/10.1007/s43630-024-00558-x III. Structural changes in cytochrome c oxidase following the reduction of dioxygen to water Doris Zorić†; Jonatan Johannesson†; Adams Vallejos; Emil Sandelin; Arpitha Kabbinale; Swagatha Ghosh; Aaron Flink; Monika Bjelčić; John Rönnholm; Peter Dahl; Emma Victoria Beale; Christoph Bostedt; Claudio Cirelli; Camila Bacellar Cases da Silveira; Philip Johnson; Dmitry Ozerov; Alex Batyuk; Sebastien Boutet; Chris Kupitz; Ariana N. Peck; Fred Poitevin; Ray Sierra; Stella Lisova; Carl-Johan Wallentin; Gisela Brändén and Richard Neutze. Submitted manuscript (2024) †These authors contributed equally to this work. IV. Drastically altered structure of the cytochrome c oxidase active site visualized by serial femtosecond crystallography Jonatan Johannesson†; Arpitha Kabbinale†; Doris Zorić; Emil Sandelin; Adams Vallejos; John Rönnholm; Johan Glerup; Lucija Ostojic; Andrew Aquila; Greg Gate; Fred Poitevin; Stella Lisova; Sandra Mous; Maithri Kashipathy; Carl- Johan Wallentin; Richard Neutze and Gisela Brändén. Manuscript (2024) †These authors contributed equally to this work. V. CASSCF/NEVPT2 study of the structural identity of the proton induced Q- band blue shift of the P to F transition in Cytochrome c Oxidase Jonatan Johannesson, Rikard Wahlström, Jürgen Gräfenstein, Richard Neutze and Gisela Brändén Manuscript (2024). VI. Quantum chemical investigation of the active site proton donor of Cytochrome c Oxidase suggests novel identity Jonatan Johannesson; Jürgen Gräfenstein, Richard Neutze and Gisela Brändén. Manuscript (2024)
Degree
Doctor of Philosophy
University
University of Gothenburg, Faculty of Science
Institution
Department of Chemistry and Molecular Biology ; Institutionen för kemi och molekylärbiologi
Disputation
Fredag den 17 Januari 2025, kl. 13:00 i 2128 Orangeriet, Natrium, Medicinaregatan 7B, Göteborg
Date of defence
2025-01-17
jonatan.johannesson@gu.se
View/
Date
2024-12-13Author
Johannesson, Jonatan
Keywords
Cytokromoxidas
Komplex IV
Cytochrome c Oxidase
beräkningskemi
täthetsfunktionalteori
tidsupplöst seriell kristallografti
hämgrupper
fotolabila substratburar
Publication type
Doctoral thesis
ISBN
978-91-8115-042-1 (TRYCKT) och 978-91-8115-043-8 (PDF)
Language
eng