L. H. Grimme

Distribution of polyphosphates in cell-compartments of Chlorella fusca as measured by 31P-NMR-spectroscopy

In suspensions of the green alga Chlorella fusca the influence of high pH and high ethylene-diamine-tetraacetic acid concentrations in the external medium, of French-press and perchloric acid extraction of the cells and of alkalization of the intracellular pH on the polyphosphate signal in 31P-nuclear magnetic resonance (31P NMR) spectra was investigated.The results show that part of the polyphosphates of asynchronous Chlorella cells are located outside the cytoplasmic membrane and complexed with divalent metal-ions. These polyphosphates are tightly bound to the cell wall and/or the cytoplasmic membrane and are not susceptible to hydrolyzation by strong acid at room temperature, in contrast to the intracytoplasmic polyphosphates.Upon alkalization of the internal pH of Chlorella cells, polyphosphates, previously not visible in the spectra become detectable by 31P-NMR-spectroscopy. 31P-NMR spectroscopic monitoring of polyphosphates during gradual alkalization of the extra-and intracellular space is proposed as a quick method for the estimation of the cellular polyphosphate content and distribution.

P-31 in-vivo NMR investigation on the function of polyphosphates as phosphate-and energysource during the regreening of the green alga Chlorella fusca

The green alga Chlorella fusca accumulates polyphosphates under conditions of nitrogen starvation while deassembling the photosynthetic apparatus. The polyphosphate content of cells regreening after resupply with nitrate under different culture conditions was investigated by P-31 in-vivo NMR spectroscopy. Neither phosphate deficiency nor anaerobiosis during the first hours of regreening inhibited the recovery of the cells. Polyphosphates were degraded during regeening. Differences in the amount of polyphosphates of phosphate supplied and deficient cells occurred only after more then 8 h. After 16 h phosphate deficient cells had still 75% of the polyphosphate content of phosphate suppled cells. In cells kept under anaerobic conditions polyphosphate degradation was much higher than in oxygen supplied cells. After 8 h they contained less than 50% of the polyphosphate content of oxygen supplied cells. These data suggest that polyphosphates serve as obligatory phosphate source during regreening and may be used as an energy source.

The cytoplasmic pH in photosynthesizing cells of the green alga Chlorella fusca, measured by P-31 NMR spectroscopy

P-31 NMR investigations were performed with the green alga Chlorella fusca under anaerobic conditions in the dark and in the light.In spectra of cells in the dark the signal of intracellular, nonvacuolar Pi indicates a pH in its chemical environment of 7.0–7.2. Upon illumination this signal looses intensity and shifts to lower field, corresponding to a pH of 7.7. Further downfield no other signal that could be attributed to a Pi-pool in more alkaline environment was detected. By the use of 2-deoxyglucose-6-phosphate as an indicator of cytoplasmic pH, this Pi-signal was assigned to the cytoplasm. The pH increase in the cytoplasm upon transfer of cells from the dark to the light is the same as that previously observed upon transfer of cells from anaerobic to aerobic conditions.In cells performing only cyclic photophosphorylation the cytoplasmic pH is lower than in photosynthesizing cells but still 0.2 pH units higher than in the cells in the dark. The reasons for the missing of a signal of stromal Pi and for the difference in cytoplasmic pH in photosynthesizing cells and those capable only of cyclic photophosphorylation are discussed.

Respirational activity of Chlorella fusca monitored by in vivo P-31 NMR

Energy metabolism during dark respiration of the green alga Chlorella fusca was investigated by 31P NMR spectroscopy. The kinetics of the transition from anaerobic to aerobic conditions (and vice versa) was followed with a temporal resolution of 16 s. This transition is accompanied by a shift of the cytoplasmic pH from 6.8 to 7.4, while the vacuolar pH remains constant. Simultaneously, an increase in the concentration of nucleoside-triphosphates and a decrease in the concentration of cytoplasmic orthophosphate take place, as well as the formation of “mobile” polyphosphates. The concentration of ATP and Pi reach steady-state levels within 30 s. Upon the reverse transition, from aerobic to anaerobic conditions, steady-state concentrations are obtained only after 3 min.

The dependence of the cytoplasmic pH in aerobic and anaerobic cells of the green algae Chlorella fusca and Chlorella vulgaris on the pH of the medium as determined by 31P in vivo NMR spectroscopy

The pH in the cytoplasm of aerobic and anaerobic cells of the green algae Chlorella fusca and Chlorella vulgaris was determined in dependence on the pH of the external medium, which was varied between pH 3 and pH 10. In aerobic cells of both species the cytoplasmic pH is maintained at a value above 7.2 even at an external pH of 3 and below 7.8 at an external pH of 10. In anaerobic cells the cytoplasmic pH shows linear dependence on external pH in the range of pH 6 to 9 (cytoplasmic pH 6.9 to 7.2), while below an external pH of 6 cytoplasmic pH is maintained at about 6.5.

The significance of hydrogenase activity for the energy metabolism of green algae: anaerobiosis favours ATP synthesis in cells of Chlorella with active hydrogenase

In cells of the green alga Chlorella fusca, which contain active hydrogenase(s), the concentration of ATP, NADH and NADPH were measured during a 5 h period of anaerobiosis in the dark and upon subsequent illumination with high light intensities (770 W/m2), conditions which favour optimal hydrogen photoproduction.ATP concentrations were also determined in cells of Chlorella fusca, whose hydrogenase was inactivated prior to illumination, and in cells of Chlorella vulgaris which do not contain hydrogenase. In the dark, the ATP concentration increased slightly during anaerobiosis in cells with active hydrogenase. This increase in ATP concentration was accompanied by an increase of NADH and a decrease of NADPH content.Upon illumination, the ATP content increased in cells with an active hydrogenase, whereas the NADH content decreased. The rate of phosphorylation was twice that observed in cells without active hydrogenase.This ATP synthesis in the light was not inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) (10 μmol/l) nor by carbonylcyanide-3-chlorophenyl-hydrazone (CCCP) (1 μmol/l) but was diminished by 500 μmol/l dibromothymoquinone (DBMIB) and 6 μmol/l carbonylcyanide-3-chlorophenyl-hydrazone (CCCP).It was concluded that an active hydrogenase can support ATP production under anaerobic conditions in the dark as well as in the light. NADH might serve in vivo as electron donor for a fermentative production of hydrogen in the light.Possible mechanisms underlying ATP production under anaerobiosis and hydrogen productive conditions are discussed.

N-15 in vivo NMR spectroscopic investigation of nitrogen deprived cell suspensions of the green alga Chlorella fusca

The possibility to apply N-15 in vivo NMR spectroscopy to study algal N-metabolism has been investigated. N-15 labelled cells of the green alga Chlorella fusca, subjected to nitrogen starvation and N-14 labelled cells supplied with K15NO3 after prolonged nitrogen starvation were monitored by N-15 in vivo NMR spectroscopy at different times after the change in their nitrogen supply. During 20–40 min, necessary for the acquisition of 1 spectrum, the cells were under dark anaerobic conditions, but the relative amounts of the metabolites detected did not change. Signals from 2 acid amides, from the side chain nitrogens of arginine and lysine, from prolin as well as 4 signals from α amino groups of amino acids were detected. Besides two signals not yet reported in the literature were found. They may be due to amino compounds, but not to amino acids. The amount of free amino acids in the cells increases not only upon resupply of nitrogen starved cells with nitrate but also during the first hours after nitrate depletion. The spectra obtained from N-15 labelled autospores show that N-15 in vivo NMR spectroscopy can be applied to the investigation of N metabolism of the cells.

P-31 NMR saturation transfer experiments in Chlamydomonas reinhardtii : evidence for the NMR visibility of chloroplastidic Pi

ATP synthesis and consumption in respiring cells of the green alga Chlamydomonas reinhardtii were measured with 31P in vivo NMR saturation transfer experiments to determine the intracellular compartmentation of inorganic phosphate. Most of the observed flux towards ATP synthesis was catalyzed by the coupled enzymes glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase (GAPDH/PGK). The attribution of the measured flux to these enzymes is supported by the observation, that (i) the magnetization transfer was strongly reduced by iodoacetate, an irreversible inhibitor of GAPDH and that (ii) the unidirectional flux was much greater than the net flux through the mitochondrial F0F1-ATPase as determined by oxygen consumption measurements. In Chlamydomonas, glycolysis is divided into a chloroplastidic and a cytosolic part with the enzymes GAPDH/PGK being located in the chloroplast stroma (Klein 1986). The 31P-NMR signal of inorganic phosphate must, therefore, originate from the chloroplast. The life time of the magnetic label transferred to Pi by these enzymes is too short for it to be transported to the cytosol via the phosphate translocator of the chloroplast envelope. When the intracellular compartmentation of Pi was taken into consideration the calculated unidirectional ATP synthesis rate was equal to the consumption rate, indicating operation of GAPDH/PGK near equilibrium. The assignment of most of the intracellular Pi to the chloroplast is in contradiction to earlier reports, which attributed the Pi signal to the cytosol. This is of special interest for the use of the chemical shift of the Pi signal as an intracellular pH-marker in plant cells.

O-Dealkylation of coumarin and resorufin ethers by unicellular green algae: kinetic properties of Chlorella fusca and Chlorella sorokiniana

O-Dealkylations of resorufin and coumarin ethers, mediated by microsomal cytochrome P450 monooxygenases from animals, plants and microorganisms, are shown here to be performed also by intact cells of the unicellular green algae Chlorella fusca and Chlorella sorokiniana. The activity of the O-dealkylation of these ethers was up to tenfold higher with Chlorella sorokiniana. Both algae dealkylated methyl-, ethyl-, and pentylethers of resorufin and coumarin. Dealkylation in vivo indicated efficient absorption of methoxy- and ethoxyresorufin, confirmed by the respective absorption kinetics. Piperonylbutoxide and 1-aminobenzotriazole, known inhibitors of plant and mammalian cytochrome P450s, significantly inhibited the O-dealkylase activity of both algal strains. The use of synchronized cultures of both algae revealed that efficiency of O-dealkylation depends on the stage of the cell cycle: during the growth phase, the O-dealkylase activities increased more than proportional, and the distinct drop in activity during the last hours of the light period indicated the appearance of an endogenous substrate.

In vivo NMR spectroscopy: in situ 15N pulse labelling NMR spectroscopy with photoautotrophic microorganisms

Abstract For studying the nitrogen metabolism in plants 15N NMR spectroscopy can be used. For in vivo 15N NMR (natural abundance of 15N: 0.37%) enrichment of the sample with the isotope 15N is compulsory. The detection of time courses of 15N assimilation from cells, which are enriched in culture is restricted in scope. Here, a method, the 15N pulse labelling NMR spectroscopy, is demonstrated, which permits labelling of different nitrogen compounds in photoautotrophic microorganisms during the NMR spectroscopic measurement. Using an effective illumination system it is possible to maintain photosynthesis in plant samples of high biomass densities in the magnet necessary for ammonia assimilation. The technique thus enables to directly observe ammonia assimilation pathways by application of a 15NO3 − or 15NH4 − pulses. Fur das Studium des Stickstoffstoffwechsels der Pflanzen kann die 15N-NMR-Spektroskopie herangezogen werden. Hierzu ist bei der in-vivo-15N-NMR (naturliche Haufigkeit von 15N: 0.37%) eine Anrei...