Studies on the functional organization of Photosystem II. The effect of protein-modifying procedures and of ADRY agents on the reaction pattern of photosystem II in Tris-washed chloroplasts

The role of the protein matrix embedding the functionally active redox components of Photosystem II reaction centers has been studied by investigating the effects of procedures which modify the structure of proteins. In order to reduce the influence of the electron transport involving secondary donor and acceptor components, Triswashed chloroplasts were used which are completely deprived of their oxygen-evolving capacity. The functional activity was detected via absorption changes, reflecting at 334 and 690 or 834 nm the turnover of the primary plastoquinone acceptor, X320, and of the photochemically active chlorophyll a complex, Chl a_II, respectively, and at 520 nm the transient formation of a transmembrane electric potential gradient. Under repetitive flash excitation of Tris-washed chloroplasts it was found that: (a) The relaxation kinetics at 690 nm become significantly accelerated in the presence of external electron donors. (b) Trypsin treatment blocks to a high degree the turnover of Chl a_II and X320 unless exogenous acceptors are present, which directly oxidize X320^?, such as K₃Fe(CN)₆. (c) In the presence of K₃Fe(CN)₆ the recovery kinetics of Chl a_II and X320 are retarded markedly by trypsin, followed by a progressive decline in the extent thereof. (d) 2-(3-Chloro-4-trifluoromethyl)anilino-3,5-dinitrothiophene (ANT 2p), known to reduce the lifetime of S₂ and S₃ in normal chloroplasts, significantly accelerates the recovery of Chl a_II. 10 μs kinetics are observed which correspond with the electron-transfer rate from D₁ to Chl a⁺_II. ANT 2p simultaneously retards the decay kinetics of X320^? and of the electrochromic absorption changes. (e) The kinetic pattern of the electrochromic absorption changes is also affected by the salt content of the suspension. Under dark-adapted conditions, the 10 μs relaxation kinetics of the 834 nm absorption change due to the first flash are hardly affected by mild trypsinization of 5–10 min duration, whereas the amplitude decreases by approx. 30%. The data obtained in Tris-washed chloroplasts could consistently be interpreted as a modification of the back reaction between X320^? and Chl a⁺_II which is caused solely by a change in the reactivity of X320 due to trypsin-induced degradation of the native X320-B apoprotein. Furthermore, ADRY agents are inferred to stimulate cyclic electron flow, which leads to reduction of D⁺₁ between the flashes. A simplified scheme is discussed which describes the functional organization of the reaction center complex.