Multiple pathways of charge recombination revealed by the temperature dependence of electron transfer kinetics in cyanobacterial photosystem I

The kinetics of charge recombination in Photosystem I P₇₀₀-F_A/F_B complexes and P₇₀₀-F_X cores lacking the terminal iron‑sulfur clusters were studied over a temperatures range of 310 K to 4.2 K. Analysis of the charge recombination kinetics in this temperature range allowed the assignment of backward electron transfer from the different electron acceptors to P₇₀₀ ⁺. The kinetic and thermodynamic parameters of these recombination reactions were determined. The kinetics of all electron transfer reactions were activation-less below 170 K, the glass transition temperature of the water-glycerol solution. Above this temperature, recombination from [F_A/F_B]⁻ in P₇₀₀-F_A/F_B complexes was found to proceed along two pathways with different activation energies (E_a). The charge recombination via A_1A has an E_a of ~290 meV and is dominant at temperatures above ~280 K, whereas the direct recombination from F_X ⁻ has an E_a of 22 meV and is prevalent in the 200 K to 270 K temperature range. Charge recombination from the F_X cluster becomes highly heterogeneous at temperatures below 200 K. The conformational mobility of Photosystem I was studied by molecular dynamics simulations. The F_X cluster was found to ‘swing’ by ~30° along the axis between the two sulfur atoms proximal to F_A/F_B. The partial rotation of F_X is accompanied by significant changes of electric potential within the iron‑sulfur cluster, which may induce preferential electron localization at different atoms of the F_X cluster. These effects may account for the partial arrest of forward electron transfer and for the heterogeneity of charge recombination observed at the glass transition temperature.