Central mechanistic principles of protein function, such as the lock-and-key principle in substrate binding, have been identified over the past decades. CRC1078 has proposed to put a further key principle into place, namely the control and coordination of complex protein functions by protonation dynamics. Spatio-temporal fluctuations of the functionally relevant hydrogen-bonded networks result from protonation dynamics, that is, the movement of protons on various time and length scales – from femtoseconds to seconds and from less than 0.1 to more than 10 nm. The experimental works are actively linked to theory and simulations to achieve a profound understanding of protonation-dependent mechanisms in the selected proteins. Different facets of protonation dynamics have been and will be studied in two central proteins involved in biological energy conversion: Oxygen reduction coupled to proton pumping in cytochrome c oxidase and water oxidation in photosystem II. The latter will be amended by a new project on protonation dynamics in photosystem I. Whereas larger structural changes are supposed to slow down or even obstruct electron transfer in proteins, light-induced conformational changes play vital roles in phytochromes and channelrhodopsins. These structural changes are associated with or even driven by protonation events. Based on the expertise of CRC1078 and the inclusion of new projects, we will extend the scope of research by investigating pH-gated proton channels that are involved in viral infection (viroporins). Therefore, we will transfer the developed methodologies and acquired knowledge on protonation dynamics to study this new class of ion channels in the next funding period. The development and adaption of various advanced methods to the requirements of the specific protein systems was and will be a major asset of this CRC1078, including the incorporation of non-canonical amino acids into proteins, time-resolved serial femtosecond X-ray crystallography using free electron lasers, nuclear magnetic resonance spectroscopy at high magnetic fields, time-resolved electronic and vibrational spectroscopies in a wide dynamic range, and multiscale computational approaches such as quantum-mechanics, molecular dynamics simulations and their hybrids. The application of such sophisticated techniques to the research agenda of the CRC is challenging as most of the proteins are integral membrane proteins.In conclusion, CRC1078 aims at the comprehensive understanding of protonation dynamics and their role in the function of the five selected proteins and to establish this process as a generic principle in protein function. Beyond the anticipated scientific success of CRC1078, the training of graduate students in this truly interdisciplinary field is particularly rewarding as a basis is generated for career development not only in academia but also for the employability in industry.

DFG Programme Collaborative Research Centres

International Connection Israel

• A01 - Electron-driven protonation dynamics in cytochrome c oxidase (Project Heads Heberle, Joachim ;  Weidinger, Inez )
• A02 - Protonation and conformational changes at the surface of proteins (Project Heads Alexiev, Ulrike ;  Heberle, Joachim )
• A04 - Tracking protonation dynamics in photosynthetic water oxidation in wild-type and mutated photosystem II (Project Head Dau, Holger )
• A05 - Structural basis of proton release from the water-oxidizing complex in cyanobacterial photosystem II (Project Heads Dobbek, Holger ;  Zouni, Athina )
• A06 - Proton turnover rates of single heme copper oxidases operating against electrochemical gradients (Project Head Block, Stephan )
• B01 - Proton exchange processes in phytochromes and retinal proteins investigated by MAS NMR (Project Heads Hegemann, Peter ;  Oschkinat, Hartmut )
• B02 - Gating and ion transport dynamics in channelrhodopsins and light-driven pumps (Project Heads Budisa, Nediljko ;  Hegemann, Peter )
• B03 - Identification of proton and hydrogen bond dynamics in channelrhodopsin and related systems (Project Heads Heberle, Joachim ;  Heyne, Karsten )
• B04 - Hydrogen bonding network in channel- and other rhodopsins and phytochromes analyzed by site-directed mutagenesis and labeling (Project Heads Bittl, Robert ;  Schlesinger, Ramona )
• B05 - Spectroscopic investigations of proton transfer processes and hydrogen bonded networks in channelrhodopsins and phytochromes (Project Head Bartl, Franz )
• B06 - Proton-coupled conformational changes in photoreceptors (Project Heads Hildebrandt, Peter ;  Scheerer, Patrick )
• B07 - Ultrafast dynamics and structural studies of prokaryotic and plant phytochromes (Project Heads Heyne, Karsten ;  Hughes, Ph.D., Jonathan )
• B09 - Dissecting the mechanism of proton and cation conductance in viroporins using vibrational spectroscopy (Project Head Kozuch, Jacek Artur )
• B10 - Atomic structure and conduction mechanism of viral proton channels in liposomes studied by solid-state NMR (Project Head Lange, Adam )
• C01 - Large-scale and small-scale diffusive and dielectric aspects of proton motion (Project Head Netz, Roland )
• C02 - Understanding proton transfer in phytochrome and cytochrome c oxidase (Project Heads Knapp, Ernst-Walter ;  Mroginski, Maria Andrea )
• C06 - Protonation depending photochemistry in rhodopsin and phytochrome photoreceptors (Project Head Schapiro, Igor )
• C07 - Structural bases of proton dynamics in viroporins by multiscale modelling and simulation (Project Head Clementi, Ph.D., Cecilia )
• C08 - Proton permeation pathway and ion selectivity of viroporins investigated by atomistic molecular dynamics simulations (Project Head Sun, Han )
• MGK - Integrated Research Training Group (Project Heads Alexiev, Ulrike ;  Dau, Holger ;  Heyne, Karsten ;  Hildebrandt, Peter )
• Z - Central Tasks of the Collaborative Research Center (Project Heads Dau, Holger ;  Heberle, Joachim )

• A03 - THz spectra of protein surface regions depending on the catalytic state (Project Head Ernsting, Nikolaus P. )
• B08 - Prokaryotic to plant phytochrome function (Project Head Hughes, Ph.D., Jonathan )
• C03 - Role of protons in long timescale dynamics of phytochromes (Project Heads Mroginski, Maria Andrea ;  Utesch, Tillmann )
• C04 - Coupling between protein, water, and protonation dynamics in channelrhodopsins and photosystem II (Project Head Bondar, Ph.D., Ana Nicoleta )
• C05 - Redox-state dependent communication and protonation dynamics in cytochrome c oxidase (Project Head Imhof, Petra )

Applicant Institution Freie Universität Berlin

Participating University Humboldt-Universität zu Berlin; Justus-Liebig-Universität Gießen; Technische Universität Berlin; Technische Universität Dresden; Hebrew University of Jerusalem
The Paul Baerwald School of Social Work & Social Welfare

Participating Institution Charité - Universitätsmedizin Berlin; Leibniz-Forschungsinstitut für Molekulare Pharmakologie (FMP)
im Forschungsverbund Berlin e.V.

Spokespersons Professor Dr. Holger Dau, until 3/2017; Professor Dr. Joachim Heberle, since 3/2017