Dependence of fluorescence behaviour and other photosystem-II characteristics on the nature of the nitrogen source for the filamentous cyanobacterium Oscillatoria chalybea

The filamentous cyanobacterium Oscillatoria chalybea grows phototrophically on a mineral medium in the presence of either nitrate or ammonium ions as nitrogen source at similar growth rates. In the absence of any combined nitrogen source in the medium the cyanobacterium also grows, although at a reduced growth rate. The steady state rate of oxygen evolution by filaments from these three culture conditions is approximately constant if compared on an equal chlorophyll basis. Qualitative differences, however, emerge, if transient phenomena, e.g. the oxygen gush, are investigated. Only nitrate-and nitrogen-free-grown cultures show an oxygen gush, whereas ammonium sulfate-grown cultures do not show this phenomenon. Fluorescence induction in O. chalybea shows a fast monophasic rise, comparable to the fluorescence rise curves of higher plant chloroplasts in the presence of dithionite. The steady state level of fluorescence in ammonium sulfate-grown cells is up to seven times higher than in nitrate-grown cells when compared on an equal chlorophyll basis. In ammonium sulfate-grown cells, DCMU (N,N-3,4-Dichlorophenyl dimethylurea) causes a further increase in fluorescence level. In nitrate-grown cyanobacteria, however, the effect of DCMU consists of a decrease of the steady state level of fluorescence. In context with earlier research on Anabaena cylindrica, another filamentous cyanobacterium, it appears that the type of the nitrogen source used for growth determines the main location of the DCMU-block in this organism. It thus appears that in O. chalybea the site of DCMU inhibition lies on the oxygen-evolving side of photosystem II, if the organism is grown on nitrate. If grown on ammonium sulfate, no substantial difference of the location of the inhibition site when compared to algae or higher plant chloroplasts is found.Thylakoid preparations of O. chalybea perform the usual Hill reactions with ferricyanide, p-benzoquinone or silicomolybdate as electron acceptors. In each case it is seen that with thylakoids of nitrate-grown cells the steady-state level of fluorescence is lowered by DCMU in the presence of these acceptors, which should be the case, if DCMU inhibits electron transfer on the donor side of photosystem II. According to the literature silicomolybdate accepts electrons mainly before the DCMU-block in higher plant chloroplasts. Hence, in higher plants this reaction is mainly DCMU-insensitive. In thylakoids of O. chalybea, however, the Hill reaction with silicomolybdate is DCMU-sensitive which provides further evidence that the DCMU-block is on the oxygen-evolving side of photosystem II in O. chalybea provided the cells have been grown on nitrate.Abbreviations DCMU N-N-3,4-Dichlorophenyl dimethylurea     

Parameters of unbalanced growth and reversible inhibition of deoxyribonucleic acid synthesis in Brevibacterium ammoniagenes ATCC 6872 induced by depletion of Mn2+. Inhibitor studies on the reversibility of deoxyribonucleic acid synthesis

Unbalanced growth induced by depletion of manganese ions was a prerequisite for production of ribonucleotides in a high salt mineral medium with the wildtype strain Brevibacterium ammoniagenes ATCC 6872. The concentration of manganese strictly controlled the overall deoxyribonucleic acid (DNA) synthesis, whereas ribonucleic acid (RNA), protein and cell wall synthesis remained essentially unimpaired in the manganese-lacking cells.The reversibility of inhibition of overall DNA synthesis was shown by enhanced incorporation (up to threefold compared to the cultures supplied with sufficient manganese) of [8-¹⁴C] adenine into alkali-stable, trichloroacetic acid-insoluble material after subsequent addition of 10 M MnCl₂ to 15 h-old depleted cultures.The results of inhibitor studies on the restoration of overall DNA synthesis due to subsequent addition of manganese ions to depleted cultures suggest that ribonucleotide reduction is the primary target of the manganese starvation during nucleotide fermentation with Brevibacterium ammoniagenes ATCC 6872.     

Phenylalanine uptake in isolated renal brush border vesicles.

The uptake of L-phenylalanine into brush border microvilli vesicles and basolateral plasma membrane vesicles isolated from rat kidney cortex by differential centrifugation and free flow electrophoresis was investigated using filtration techniques. Brush border microvilli but not basolateral plasma membrane vesicles take up L-phenylalanine by an Na+-dependent, saturable transport system. The apparent affinity of the transport system for L-phenylalanine is 6.1 mM at 100 mM Na+ and for Na+ 13mM at 1 mM L-phenylalanine. Reduction of the Na+ concentration reduces the apparent affinity of the transport system for L-phenylalanine but does not alter the maximum velocity. In the presence of an electrochemical potential difference of Na+ across the membrane (etaNao greater than etaNai) the brush border microvilli accumulate transiently L-phenylalanine over the concentration in the incubation medium (overshoot pheomenon). This overshoot and the initial rate of uptake are markedly increased when the intravesicular space is rendered electrically more negative by membrane diffusion potentials induced by the use of highly permeant anions, of valinomycin in the presence of an outwardly directed K+ gradient and of carbonyl cyanide p-trifluoromethoxyphenylhydrazone in the presence of an outward-directed proton gradient. These results indicate that the entry of L-phenylalanine across the brush border membrane into the proximal tubular epithelial cells involves cotransport with Na+ and is dependent on the concentration difference of the amino acid, on the concentration difference of Na+ and on the electrical potential difference. The exit of L-phenylalanine across the basolateral plasma membranes is Na+-independent and probably involves facilitated diffusion.     

Pyruvate fermentation in Rhodospirillum rubrum and after transfer from aerobic to anaerobic conditions in the dark

The fermentative metabolism of Rhodospirillum rubrum (strain Ha, F₁, S₁) was studied after transfering the cells from aerobic to anaerobic dark culture conditions. Pyruvate was metabolized mainly to acetate and formate, and to a lesser extent to CO₂ and propionate, by all strains. Therefore, pyruvate formate lyase would appear to be the characteristic key enzyme of the dark anaerobic fermentation metabolism in R. rubrum. Strain F₁ and S₁ metabolized the formate further to H₂ and CO₂. It is concluded that this cleavage was catalysed by a formate hydrogen lyase system. Strain Ha was unable to metabolize formate. The cleavage of formate and the synthesis of poly--hydroxy-butyric acid were increased by a low pH value (6.5). Fermentation equations and schemes of the pyruvate metabolism are discussed.     

The size of mitochondrial DNA from a cytoplasmic petite mutant of Saccharomyces cerevisiae

Summary Mitochondrial DNA has been isolated from a cytoplasmic petite mutant of Saccharomyces cerevisiae which has retained only about 2% of the mitochondrial wild type genome. The denatured DNA was analyzed by agarose gel electrophoresis and a homogeneous, single band of DNA was found. Petite and wild type mitochondrial DNAs exhibited similar gel electrophoretic mobilities. Using denatured DNA from the E. coli phages T4 and T3 for comparison a molecular weight of 55×10⁶ daltons has been calculated for the double-stranded petite mitochondrial DNA. On the basis of this observation most of the mitochondrial DNA of this petite mutant appeared to consist of a polymer of about 50 repeats to account for a size similar to that of the wild type molecule. Thus a regulatory mechanism might exist which keeps constant the physical size of the mitochondrial DNA molecule in spite of the elimination of large fractions of the wild type genome.Dedicated to Dr. Dr. h. c. Peter Michaelis on the occasion of his 75th birthday     

Preserving Neural Function under Extreme Scaling

Important brain functions need to be conserved throughout organisms of extremely varying sizes. Here we study the scaling properties of an essential component of computation in the brain: the single neuron. We compare morphology and signal propagation of a uniquely identifiable interneuron, the HS cell, in the blowfly (Calliphora) with its exact counterpart in the fruit fly (Drosophila) which is about four times smaller in each dimension. Anatomical features of the HS cell scale isometrically and minimise wiring costs but, by themselves, do not scale to preserve the electrotonic behaviour. However, the membrane properties are set to conserve dendritic as well as axonal delays and attenuation as well as dendritic integration of visual information. In conclusion, the electrotonic structure of a neuron, the HS cell in this case, is surprisingly stable over a wide range of morphological scales.