Picosecond kinetics of fluorescence and absorbance changes in photosystem II particles excited at low photon density

Abstract

Oxygen-evolving photosystem II particles (from Synechococcus ) with about 80 chlorophyll molecules per primary electron donor (P ₆₈₀ ) were used for a correlated study of picosecond kinetics of fluorescence and absorbance changes, detected by the single-photon-timing technique and by a pump-probe apparatus, respectively. Chlorophyll fluorescence decays were biexponential with lifetimes τ ₁ = 80 ± 20 ps and τ ₂ = 520 ± 120 ps in open reaction centers and τ ₁ = 220 ± 30 ps and τ ₂ = 1.3 ± 0.15 ns in closed reaction centers. The corresponding fluorescence yield ratio F _max / F _o was 3-4. Absorbance changes were monitored in the spectral range of 620-700 nm after excitation at 675 nm with 10-ps pulses sufficiently weak ( 10 ns). With closed reaction centers, the absorbance changes were biexponential with lifetimes τ ₁ = 170-260 ps and τ ₂ = 1.6-1.75 ns. The results are explained in terms of a kinetic model that assumes P ₆₈₀ to constitute a shallow trap. The results show that Q _A reduction in these photosystem II particles decreases both the apparent rate and the yield of the primary charge separation by a factor of 2-3 and increases the mean lifetime of excitons in the antenna by a factor of 3-4. Thus, we conclude that the long-lived, nanosecond chlorophyll fluorescence is not charge-recombination luminescence but rather emission from equilibrated excited states of antenna chlorophylls.