Picosecond time-resolved study on the nature of high-energy-state quenching in isolated pea thylakoids different localization of zeaxanthin dependent and independent quenching mechanisms

Abstract

The influence of the transthylakoid proton gradient on the kinetics of picosecond fluorescence decay was examined using isolated pea thylakoids having high or low zeaxanthin contents. Fluorescence lifetime measurements were performed with open (Fo) and closed (Fm) PS II reaction centers. Zeaxanthin formation in membrane energized isolated thylakoids led to a marked decrease of the average fluorescence lifetime at both Fm and Fo. In contrast, when zeaxanthin synthesis was blocked by the inhibitor DTT, the fluorescence lifetime decrease was less pronounced in the Fm state and totally missing in the Fo state. Samples containing the uncoupler ammonium chloride did not exhinit any zeaxanthin influence on the fluorescence decay kinetics. By detailed kinetic analysis of the fluorescence data based on the exciton/radical pair equilibrium model it was possible to separately locate and quantify the effects of zeaxanthin, on the one hand, and the proton gradient, on the other hand, in terms of rate constants of individual primary processes within PS II. It is shown that the enhanced non-photochemical fluorescence quenching (NPQ) in the presence of zeaxanthin mainly originates in the antenna, while without zeaxanthin smaller changes in the Fm state are owing to changes in processes located at the reaction center. Possible mechanisms of zeaxanthin dependent and independent nonphotochemical fluorescence quenching in open and closed PS II are discussed.