Cryptochrome structure and dynamics

Different cryptochromes

The prediction of protein structures presents a formidable challenge due to the intricate nature of protein folding, a complex puzzle in molecular biology. While achieving accurate protein models is arduous, advancements in computational tools like homology modeling or the revolutionary AlphaFold algorithm have substantially streamlined this process. These computational approaches enable the rapid generation of protein models, marking significant progress in this field.

Our research group is delving into the enigmatic world of cryptochrome proteins—a class of proteins hypothesized to play a pivotal role in the biological phenomenon of magnetoreception in animals. We employ extensive Molecular Dynamics (MD) simulations to reconstruct the atomistic structures of cryptochromes. These simulations facilitate the exploration of biomolecular systems, enabling us to probe the time evolution of cryptochrome proteins over microseconds through all-atomic simulations and even longer timescales using coarse-grained methods.

This project aims to unlock more profound insights into various properties governing cryptochrome behavior through this comprehensive time-evolution study. This includes elucidating activation mechanisms, unraveling ligand binding dynamics, assessing structure prediction stability, and comprehending other dynamic processes occurring on the microsecond timescale. By leveraging computational tools to dissect the intricate dance of atoms within cryptochrome proteins, we strive to unravel the secrets behind their functionality and contribution to animal magnetoreception.

Recent Publications

Application of molecular modeling to flavoproteins: insights and challenges, Emil Sjulstok, Ilia A. Solov'yov, Peter L. Freddolino, in: Methods in Enzymology: New approaches for Flavin Catalysis, edited by: Bruce A. Palfey, 277-314, Elsevier Aademic Press, (2019)
Molecular dynamics simulations disclose early stages of the photoactivation of cryptochrome 4, Daniel R. Kattnig, Claus Nielsen, Ilia A. Solov'yov, New Journal of Physics, 20, 083018, (2018)
Electron spin relaxation can enhance the performance of a cryptochrome-based magnetic compass sensor, Daniel R. Kattnig, Jakub K. Sowa, Ilia A. Solov'yov, P. J. Hore, New Journal of Physics, 18, 063007, (2016)
Electron spin relaxation in cryptochrome-based magnetoreception, Daniel R. Kattnig, Ilia A. Solov'yov, P. J. Hore, Physical Chemistry - Chemical Physics, 70, 12443-12456, (2016)
Separation of photo-induced radical pair in cryptochrome to a functionally critical distance, Ilia A. Solov'yov, Tatiana Domratcheva, Klaus Schulten, Scientific Reports, 4, 3845, (2014)