Fluorescence induction in chloroplasts isolated from the green alga, Bryopsis maxima. V. pH dependence of the P-S 1 transient

Abstract

The effects of uncouplers of photophosphorylation on the P-S 1 transient of the fluorescence induction in darkadapted intact chloroplasts of Bryopsis maxima were studied to examine the mechanism of light-dependent regulatory changes in electron transport. (1) Carbonyl cyanide m-chlorophenylhydrazone (CCCP) and nigericin slowed down the fluorescence quenching from P to S 1, whereas the transient was significantly accelerated by the addition of NH 4Cl and methylamine. (2) The P-S 1 decline was slowed down at low pH of the suspending medium, suggesting sensitivity of the transient to the stroma pH. The inhibitory effect of nigericin was markedly enhanced at low pH and at low KCl concentrations, whereas the ionophore stimulated the transient at high pH and at high KCl concentrations. Similar results were obtained on the combined addition of CCCP and valinomycin. (3) Nigericin and the CCCP-valinomycin couple altered the internal pH of intact chloroplast through the H +-K + exchange across the outer limiting membrane. The fluorescence decline was rapid at alkaline internal pH but was suppressed with lowering internal pH below 8.0 (4) A similar internal pH dependence of the transient was obtained when the internal pH was changed by the addition of NH 4Cl and acetate. (5) It is proposed that the photoactivation of electron transport is regulated by the stroma pH. The progress of the photoactivation is slow at acidic or neutral pH but is significantly accelerated by light-induced alkalinization near the light-regulation site of electron transport located on the outer surface of the thylakoid membrane.