Evidence for Mitochondrial Regulation of Photosynthesis by a Starchless Mutant of Nicotiana sylvestris

Abstract

Mutant NS458 of Nicotiana sylvestris (Speg. et Comes) contains a defective plastid phosphoglucomutase and accumulates only trace amounts of starch. Determinations of carbon partitioning using tracer d-[3-(14)C]glyceric acid showed that the maximal CO(2) assimilation by mature leaves of the mutant at saturating [CO(2)] and light and low [O(2)] was close to the flux for sucrose formation in the wild type. The mutant is characterized by exceptionally slow oscillations in maximal CO(2) assimilation. The postulate that these slow oscillations follow changes in the cytosolic rate of sucrose phosphate synthesis has been investigated. Studies with wild-type and mutant leaf discs subjected to various treatments failed to indicate that any significant activation-inactivation cycle in sucrose-P synthase activity can occur. The rate of sucrose phosphate synthesis, however, might be altered by variations in the supply of uridine UDP-glucose which is controlled by the rate of ATP regeneration (via UTP regeneration). Treating mutant leaf protoplasts and young leaves with oligomycin, an inhibitor of mitochondrial ATP regeneration, reduced photosynthesis by as much as 25 and 40%, respectively. The wild type failed to show inhibition by oligomycin, i.e. its effect is masked when starch and sucrose synthesis can interact. It is concluded that maximal CO(2) assimilation in the mutant is fine tuned by mitochondrial metabolism such that interactions between sucrose synthesis and mitochondrial processes may generate the observed oscillations.