Phenylmereuric Acetate and Phosphate Control of Light-Dependent Shrinkage and Reactions in Chloroplasts

An investigation of the action of phenylmereuric acetate (PMA) and phosphate on light-induced shrinkage (measured by light scattering and Coulter Counter techniques) and on photosynthetic reactions in spinach chloroplasts led to the following conclusions:

• 1) PMA stimulated light-induced shrinkage (under conditions of cyclic and non-cyclic electron flow) at concentrations which completely inhibited cyclic and non-cyclic photophosphorylation and nicotinamide adenine dinucleotide phosphate (NADP) reduction, though ferricyanide reduction was activated. Although PMA inhibited NADP reduction (probably because this sulfhydryl reagent interfered with the ferredoxin-NADP rednetase) it ean also be considered an uncoiipler (when ferricyanide is the electron acceptor).
• 2) Phosphate maximized light-induced shrinkage (under conditions of cyclic and non cyclic electron flow) at concentrations which did not affect ferricyanide reduction but caused a 40 to 50 per cent inhibition of NADP reduction.
• 3) The pattern of the light scattering response to these two compounds was quite different. In the presence of PMA, the forward (light on) and hack (light off) reactions went to completion rapidly. In the presence of phosphate, the back reaction was rapid but, in the light-induced reaction, three phases were discernible.
• 4) Compared with uncouplers such as NH₄Cl, carbonyl cyanide m-chlorophenyl-hydrazone, pentachlorophenol, and dicoumarol, all of which inhibited both photophosphorylation and conformational changes in chloroplasts, PMA (like quinacrine) had a specific action since it inhibited photophosphorylation while shrinkage was stimulated.
• 5) It appeared that PMA acted at a site beyond the formation of high energy inter-mediates and that, in the absence of photophosphorylation, more energy was diverted to mechanical work (shrinkage). It would seem that, in a cyclic electron flow system, in which ATP synthesis is blocked at a late step (e.g. by PMA), shrinkage may be an indirect method for measuring electron flow.