The role of Ca2+ ions in modulating changes induced in bean plants by an excess of Cu2+ ions. Chlorophyll fluorescence measurements

Ca²⁺-dependent influence of excess Cu²⁺ on the photosynthetic akpparatus monitored through chlorophyll fluorescence measurements was investigated in runner bean plants (Phaseolus coccineus L. cv. Pie kny Ja?) at three different growth stages. It was observed that the toxic effect of excess Cu²⁺ on plants depends both on their growth stages and the Ca²⁺ content in the medium. Increased Ca²⁺ content limits Cu²⁺ action on plants at their initial growth stage (I) through: stabilization of the PSII complex (increase of the ratio of variable to minimal fluorescence [F_v/F₀]), improved electron flow and reoxidative processes of the quinone primary electron acceptor of PSII (Q_A) (increase of quantum yield of PSII electron transport [φ_e] and photochemical quenching of fluorescence [q_P] values) and elimination of nonphotochemical energy dissipation (decrease of nonphotochemical fluorescence quenching from the Stern-Volmer equation [NPQ] and fraction of the absorbed light energy not used for photochemistry [LNU] values). At this growth stage excess Cu²⁺ decreases the rates of Q_A reduction as a result of decreased PSII activity at its donor side only at lower Ca²⁺ level. At the intermediate growth stage (II) the plants were less sensitive to Cu²⁺ treatment and also to changed Ca²⁺ content. A weakening of some photochemical processes by excess Cu²⁺ could be observed only at a higher Ca²⁺ dose. At the final growth stage of plants (III) Ca²⁺ ions exerted a decisively different effect on the mechanism of excess Cu²⁺ action on bean plants, visualized by decreased PSII stabilization and utilization of absorbed light energy at increased Ca²⁺ content in the medium.