The mitochondrial CMSII mutation of Nicotiana sylvestris impairs adjustment of photosynthetic carbon assimilation to higher growth irradiance.

The CMSII mutant of Nicotiana sylvestris, which lacks a functional mitochondrial complex I, was used to investigate chloroplast-mitochondria interactions in light acclimation of photosynthetic carbon assimilation. CMSII and wild-type (WT) plants were grown at 80 micromol m(-2) s(-1) photosynthetic active radiation (PAR; 80) and 350 micromol m(-2) s(-1) PAR (350). Carbon assimilation at saturating PFD was markedly higher in WT 350 leaves as compared with WT 80 leaves, but was similar in CMS 80 and CMS 350 leaves, suggesting that the mutant is unable to adjust photosynthesis to higher growth irradiance. WT 350 leaves showed several general characteristic light acclimation responses [increases in leaf specific area (LSA), total chlorophyll content, and chlorophyll a/b ratio, and a higher light compensation point]. In contrast, a similar chlorophyll content and chlorophyll a/b ratio were measured for both CMS 80 and CMS 350 leaves, while LSA and the light compensation point acclimated as in the WT. The failure of CMSII to adjust photosynthesis to growth PFD did not result from lower quantum efficiency of PSII, lower whole-chain electron transport rates (ETRs), or lower ribulose-1,5-bisphosphate carboxylase oxygenase (Rubisco) and sucrose phosphate synthase (SPS) capacities. Excess ETR not used for carbon assimilation was even higher in CMS 350 than in WT 350. Since photochemical fluorescence quenching and the initial activity of NADP malate dehydrogenase (NADP-MDH) were identical in WT 350 and CMS 350 leaves but the activation state of NADP-MDH was different, redox signals from primary ETR are not involved in the signal transduction of light acclimation, while a contribution of stromal redox state cannot be excluded. When mature plants were transferred between 350 and 80 conditions, the mutant showed acclimatory tendencies, although adjustments were not as rapid or as marked as in the WT, and the response of the initial activities of Rubisco and NADP-MDH was impaired or altered. Initial activities of Rubisco and SPS at limiting concentration were also affected in CMS 350 as compared with WT plants when compared at growth irradiance or after in situ activation at 1000 micromol m(-2) s(-1) PAR. The data demonstrate that chloroplast-mitochondria interactions are important in light acclimation, and modulation of the activation state of key photosynthetic enzymes could be an important mechanism in this cross-talk.

The nitrogen source-dependent 126-kDa protein from Synechococcus PCC 7942 plasmalemma: a trimer of the NrtA nitrate-binding protein.

Expression of a 126-kDa protein in the plasmalemma (cytoplasmic membrane) from Synechococcus PCC 7942 is dependent on the nitrogen source. Polyclonal antibody raised against the NrtA protein reacted with the 126-kDa protein. Two peptide sequences from the 126-kDa protein were retrieved in NrtA. FPLC purification of plasmalemma solubilised in Triton X-100 gave a fraction consisting mainly of a 126-kDa component (72.6%), as shown by sedimentation velocity. Equilibrium sedimentation of the same fraction gave evidence of the existence of an oligomeric structure (Ka = 2 x 10(3) and 2.9 subunits). Thus, the 126-kDa protein is considered as a trimeric arrangement of the 45-kDa protein in the plasmalemma.

Nitrogen source-dependent expression of a 126 kDa protein in the plasma membrane of the cyanobacterium Synechococcus PCC 7942.

The expression of a 126 kDa protein in the cytoplasmic membrane of Synechococcus PCC 7942 is shown to be dependent on the nitrogen source. It is absent in ammonium-grown cells and its quantity is inversely related to the concentration of nitrate or nitrite in the growth medium. Addition of ammonium-grown cells to a medium containing nitrate or L-methionine-DL-sulfoximine results in the expression of this protein. It is present in the plasmalemma of the Synechococcus NC3 mutant (nrtC gene deleted) and absent in the NA3 mutant (nrtABCD genes deleted). These results may suggest involvement of the 126 kDa protein in nitrate transport through Synechococcus cytoplasmic membrane.

Correlation between membrane potential changes and proliferation of murine peritoneal lymphocytes stimulated by Nocardia water soluble mitogen.

A comparative study of Nocardia water soluble mitogen (NWSM) action on membrane potential and proliferation rate of murine peritoneal lymphocytes was performed at various incubation times. The membrane surface charge was evaluated by laser doppler velocimetry (LDV) through the measurement of the cell electrophoretic mobility at different pH values (from pH 5 to 9). We demonstrated that NWSM treatment decreases the lymphocyte membrane potential. This variation reached a maximal level after 24 hrs. at pH 7 and remained unchanged during the 72 hrs. observation. A significant stimulation of lymphocyte proliferation was noted after a 24 hrs. incubation. However, the highest rate of [3H]-thymidine incorporation was observed at 48 hrs. with a subsequent decrease at 72 hrs. On the basis of these data, it is suggested, that membrane potential changes may represent an early important step in the mechanism of lymphocyte activation by NWSM, as it has been shown for some mitogenic compounds.

Characterization of the plasmalemma ATPase from the cyanobacteria Synechococcus PCC 6311 and PCC 7942.

Biochemical properties of the ATPase from the plasma membrane of the cyanobacteria Synechococcus PCC 6311 and PCC 7942 were examined. ATPase activity associated with purified plasma membrane vesicles was strongly inhibited by 100 microM vanadate (87%), 100 microM diethylstilbestrol (70%) and 100 mM fluoride ions (83%). No inhibition was observed in the presence of dicyclohexylcarbodiimide, nitrate, azide, or molybdate. A 50% activation was observed in the presence of 50 mM KCl but none was observed in the presence of NaCl or NH4Cl. This ATPase was able to form a pH gradient, the amplitude of which was decreased by the presence of 100 microM vanadate. On Western blot of the plasmalemma proteins, no labeling was observed with a monoclonal antibody against the beta subunit of the F0-F1 ATPase, although staining was observed with the 55-kDa subunit of the thylakoid membrane ATPase. After phosphorylation of plasmalemma vesicles, by [gamma-32P]ATP, the autoradiograms of the electrophoreses, performed under acid conditions, exhibited labeling of a 110-kDa protein. The results indicated that the Synechococcus plasma membrane ATPase can be classified as a H+ translocating P-type ATPase and compared to the plant plasmalemma ATPase.

Pyrocystis lunula bioluminescence: physicochemical characterization of the luciferin precursor.

The luminescence of the dinoflagellate Pyrocystis lunula is controlled by the reduction state of the luciferin precursor. This molecule (P630) is a chromopeptide more stable than luciferin in methanolic solutions at low temperature. Cations may oxidize P630 or cleave the bond between the peptidic chain and the extended tetrapyrrole. Reduction of P630 is performed enzymatically by a NAD(P)H-dependent oxidoreductase or chemically by 2-mercaptoethanol or dithiothreitol. The state of reduction is monitored by the absorption and fluorescence emission which reveal a conformational change of the chromopeptide depending on the pH. These data will be useful for forthcoming studies on intracellular reducing power regulation and luminescence rhythms of these cells.

Dinoflagellate luminescence: purification of a NAD(P)H-dependent reductase and of its substrate.

The soluble enzymatic luminescent system of the dinoflagellate Pyrocystis lunula (luciferase-luciferin) is coupled with an enzymatic NAD(P)H-dependent reaction. The enzyme is a soluble reductase (Mr 47,000) which catalyzes, in the presence of NAD(P)H, the reduction of a molecule called P630. Reduced P630 has the same spectral characteristics as the purified luciferin. The luciferase can oxidize this reduced molecule with a light emission at 480 nm. These observations suggest that reduced P630 is a luciferin molecule. The oxidized form seems, in these conditions, to be the precursor of luciferin.