Strategies to maintain redox homeostasis during photosynthesis under changing conditions.

Plants perform photosynthesis and assimilatory processes in a continuously changing environment. Energy production in the various cell compartments and energy consumption in endergonic processes have to be well adjusted to the varying conditions. In addition, dissipatory pathways are required to avoid any detrimental effects caused by over-reduction. A large number of short-term and long-term mechanisms interact with each other in a flexible way, depending on intensity and the type of impact. Therefore, all levels of regulation are involved, starting from energy absorption and electron flow events through to post-transcriptional control. The simultaneous presence of strong oxidants and strong reductants during oxygenic photosynthesis is the basis for regulation. However, redox-dependent control also interacts with other signal transduction pathways in order to adapt metabolic processes and redox-control to the developmental state. Examples are given here for short-term and long-term control following changes of light intensity and photoperiod, focusing on the dynamic nature of the plant regulatory systems. An integrating network of all these mechanisms exists at all levels of control. Cellular homeostasis will be maintained as long as the mechanisms for acclimation are present in sufficiently high capacities. If an impact is too rapid, and acclimation on the level of gene expression cannot occur, cellular damage and cell death are initiated.

The plant homolog to the human sodium/dicarboxylic cotransporter is the vacuolar malate carrier.

Malate plays a central role in plant metabolism. It is an intermediate in the Krebs and glyoxylate cycles, it is the store for CO2 in C4 and crassulacean acid metabolism plants, it protects plants from aluminum toxicity, it is essential for maintaining the osmotic pressure and charge balance, and it is therefore involved in regulation of stomatal aperture. To fulfil many of these roles, malate has to be accumulated within the large central vacuole. Many unsuccessful efforts have been made in the past to identify the vacuolar malate transporter; here, we describe the identification of the vacuolar malate transporter [A. thaliana tonoplast dicarboxylate transporter (AttDT)]. This transporter exhibits highest sequence similarity to the human sodium/dicarboxylate cotransporter. Independent T-DNA [portion of the Ti (tumor-inducing) plasmid that is transferred to plant cells] Arabidopsis mutants exhibit substantially reduced levels of leaf malate, but respire exogenously applied [14C]malate faster than the WT. An AttDT-GFP fusion protein was localized to vacuole. Vacuoles isolated from Arabidopsis WT leaves exhibited carbonylcyanide m-chlorophenylhydrazone and citrate inhibitable malate transport, which was not stimulated by sodium. Vacuoles isolated from mutant plants import [14C]-malate at strongly reduced rates, confirming that this protein is the vacuolar malate transporter.

Co-existence of two regulatory NADP-glyceraldehyde 3-P dehydrogenase complexes in higher plant chloroplasts.

Light/dark modulation of the higher plant Calvin-cycle enzymes phosphoribulokinase (PRK) and NADP-dependent glyceraldehyde 3-phosphate dehydrogenase (NADP- GAPDH-A2B2) involves changes of their aggregation state in addition to redox changes of regulatory cysteines. Here we demonstrate that plants possess two different complexes containing the inactive forms (a) of NADP-GAPDH and PRK and (b) of only NADP-GAPDH, respectively, in darkened chloroplasts. While the 550-kDa PRK/GAPDH/CP12 complex is dissociated and activated upon reduction alone, activation and dissociation of the 600-kDa A8B8 complex of NADP-GAPDH requires incubation with dithiothreitol and the effector 1,3-bisphosphoglycerate. In the light, PRK is therefore completely in its activated state under all conditions, even in low light, while GAPDH activation in the light is characterized by a two-step mechanism with 60-70% activation under most conditions in the light, and the activation of the remaining 30-40% occurring only when 1,3-bisphosphoglycerate levels are strongly increasing. In vitro studies with the purified components and coprecipitation experiments from fresh stroma using polyclonal antisera confirm the existence of these two aggregates. Isolated oxidized PRK alone does not reaggregate after it has been purified in its reduced form; only in the presence of both CP12 and purified NADP-GAPDH, some of the PRK reaggregates. Recombinant GapA/GapB constructs form the A8B8 complex immediately upon expression in E. coli.