Ultrafast Dynamics of Nonequilibrium Short-Range Electron Transfer in Semiquinone Flavodoxin

Short-range protein electron transfer (ET) is crucially important in light-induced biological processes such as in photoenzymes and photoreceptors and often occurs on time scales similar to those of environment fluctuations, leading to a coupled dynamic process. Herein, we use semiquinone Anabaena flavodoxin to characterize the ultrafast photoinduced redox cycle of the wild type and seven mutants by ultrafast spectroscopy. We have found that the forward and backward ET dynamics show stretched behaviors in a few picoseconds (1-5 ps), indicating a coupling with the local protein fluctuations. By comparison with the results from semiquinone D. vulgaris flavodoxin, we find that the electronic coupling is crucial to the ET rates. With our new nonergodic model, we obtain smaller values of the outer reorganization energy (lambda(gamma)(o)) of environment fluctuations and the reaction free energy force (Delta G(gamma)), a signature of nonequilibrium ET dynamics.

Automated summary

Short-range protein electron transfer is crucial in light-induced biological processes, and this study demonstrates how the dynamics are coupled with protein fluctuations. Comparison with a different flavodoxin shows the importance of electronic coupling in ET rates.