Chloroplast energization and oxidation of P700/plastocyanin in illuminated leaves at reduced levels of CO2 or oxygen

Chlorophyll fluorescence, light scattering, the electrochromic shift P₅₁₅ and levels of some photosynthetic intermediates were measured in illuminated leaves. Oxygen and CO₂ concentrations in the gas phase were varied in order to obtain information on control of Photosystem II activity under conditions such as produced by water stress, when stomatal closure restricts access of CO₂ to the photosynthetic apparatus. Light scattering and energy-dependent fluorescence quenching indicated a high level of chloroplast energization under high intensity illumination even when linear electron transport was curtailed in CO₂-free air or in 1% oxygen with 35 ll^-1 CO₂. Calculations of the phosphorylation potential based on measurements of phosphoglycerate, dihydroxyacetone phosphate and NADP revealed ratios of intrathylakoid to extrathylakoid proton concentrations, which were only somewhat higher in air containing 35 l l^-1 CO₂ than in CO₂-free air or 1% oxygen/35 l l^-1 CO₂. Anaerobic conditions prevented appreciable chloroplast energization. Acceptor-limitation of electron flow resulted in a high reduction level of the electron transport chain, which is characterized by decreased oxidation of P₇₀₀, not only under anaerobic conditions, but also in air, when CO₂ was absent, and in 1% oxygen, when the CO₂ concentration was reduced to 35 ll^-1. Efficient control of electron transport was indicated by the photoaccumulation of P₇₀₀⁺ at or close to the CO₂ compensation point in air. It is proposed to require the interplay between photorespiratory and photosynthetic electron flows, electron flow to oxygen and cyclic electron flow. The field-indicating electrochromic shift (P₅₁₅) measured as a rapid absorption decrease on switching the light off followed closely the extent of photoaccumulation of P₇₀₀⁺ in the light.Abbreviations F, F₀, F₀, F_M, F_M chlorophyll fluorescence levels - GA glyceraldehyde - P₅₁₅ field indicating rapid absorption change peaking at 522 nm - Q_A primary quinone acceptor in Photosystem II - Q_N non-photochemical quenching of chlorophyll fluorescence - Q_q photochemical quenching of chlorophyll fluorescence