Depletion of stromal Pi induces high 'energy-dependent' antenna exciton quenching (qE) by decreasing proton conductivity at CFO-CF1 ATP synthase

This work tests two models to account for the effects of depletion of stromal inorganic phosphate (P_i), which results in down-regulation of light capture via the exciton quenching (q_E) mechanism and has been proposed to act in feedback regulation of the light reactions. In both models, antenna down-regulation is activated by acidification of the lumen, despite the fact that linear electron flow (LEF) (and associated proton flux) is decreased upon P_i depletion. In one model, an imbalance of ATP or NADPH activates cyclic electron transfer around photosystem I (CEF1), increasing proton influx to the lumen. In the second, the effective conductivity of the CF_O-CF₁ ATP synthase to protons ( g _H⁺) is decreased, retarding proton efflux from the lumen. Sequestering of P_i by mannose infiltration increased sensitivities of q_E and pmf to LEF. The effects were attributable to decreases in g _H⁺, but not to CEF1 and were largely reversed by subsequent P_i feeding. Rapid recovery of g _H⁺ in the dark suggested that dark-labile metabolic pools are responsible for regulation of the ATP synthase. Overall, these results support models where accumulation of Benson–Calvin cycle intermediates or lowering of stromal P_i below its K _Mat the ATP synthase, retards proton efflux from the lumen, leading to build-up of pmf and subsequent down-regulation of photosynthetic light capture.