Nitrogenase activity and nitrogen assimilation in Anabaena flos-aquae growing in continuous culture

Summary Anabaena flos-aquae is grown in chemostats under phosphate and urea-limited conditions. Nitrogenase activity in phosphate-limited cells has a maximum activity at a dilution rate of 0.025 h^-1 and is repressed 24-fold by 15 mM KNO₃. Cultures growing on 1.5 mM nitrate obtain 1/2–2/3 of cell nitrogen from N₂. Cells form inducible nitrite assimilating enzymes when grown on nitrate. Algae growing under A or He on limiting urea or phosphate-limited with nitrate have active nitrogenase. The ratio of nitrogenase activity to heterocyst numbers varied 90-fold depending on source of nitrogen, 15 mM KNO₃ gave the smallest ratio. The regulatory mechanisms controlling the activity of nitrogenase in blue-green algae is discussed.     

CHARACTERISTICS OF PHOSPHORUS LIMITATION IN CHLAMYDOMONAS REINHARDTH (CHLOROPHYCEAE) AND ITS PALMELLOIDS1

Chlamydomonas reinhardtii Dang, was grown in a chemostat culture under phosphate limitation. The steady state concentration of phosphate was below the detection limit (< 1 μg P/L) in all runs. The cellular content of phosphorus (Q_p), polyphosphate (Q_pp) and chlorophyll a increased with increasing dilution rate, and the growth rate of the alga was described by Q_p as well as Q_pp in the Droop model. The ratio Q_pp/Q_p and the activity of alkaline phosphatase were maximal at high and low growth rates, respectively. Palmelloids of Chlamydomonas were found at high dilution rates (D > 0.12 h^?1) and became attached to the wall of the culture vessel. They differed from the vegetative stage in both chemical composition and growth rate. Their contents of phosphorus and chlorophyll a were low, as in the vegetative cells, which grew at a low growth rate, whereas the ration Q_pp/Q_p and the activity of alkaline phosphatase were comparable with those of fast growing vegetative cells. The growth rate of the palmelloids was 0.03 h^?1 whereas maximum growth rate (μ_m) for the vegetative cells was 0.21 h^?1.     

Invertase and phosphatase of yeast in a phosphate-limited continuous culture

Summary Deficiency of inorganic phosphate caused the hyper production of invertase and the derepression of acid phosphatase in a continuous culture ofSaccharomyces carlsbergensis. The specific invertase activity was 40,000 enzyme units per g dry cell weight at a dilution rate lower than 0.05 h^–1 with a synthetic glucose medium of which the molecular ratio of KH₂PO₄ to glucose was less than 0.006. This activity is eight fold higher than in a batch growth and 1.5 fold as much as the highest enzyme activity observed so far in a glucose-limited continuous culture.For the hyper production of invertase, it is necessary to culture the yeast continuously by keeping the Nyholm's conservative inorganic phosphate concentration at less than 0.2 m mole per g dry weight cell. The derepression of acid phosphatase brought about by phosphate deficiency, was similar in both batch and continuous cultures.Nomenclature D dilution rate of continuous culture (h^–1) - E_i invertase concentration in culture (enzyme unit l^–1) - E_p acid phosphatase concentration in culture (enzyme unit l^–1) - P inorganic phosphate concentration in culture (mM) - S glucose concentration in culture (mM) - X cell concentration in culture (g dry weight cell l^–1) Greek Letter specific rate of growth (h^–1) Suffix f feed - 0 initial value     

An analysis of the growth of Gluconobacter oxydans in chemostat cultures

Gluconobacter oxydans was grown successively in glucose and nitrogen-limited chemostat cultures. Construction of mass balances of organisms growing at increasing dilution rates in glucose-limited cultures, at pH 5.5, revealed a major shift from extensive glucose metabolism via the pentose phosphate pathway to the direct pathway of glucose oxidation yielding gluconic acid. Thus, whereas carbon dioxide production from glucose accounted for 49.4% of the carbon input at a dilution rate (D)=0.05 h^-1, it accounted for only 1.3% at D=0.26 h^-1. This decline in pentose phosphate pathway activity resulted in decreasing molar growth yields on glucose. At dilution rates of 0.05 h^-1 and 0.26 h^-1 molar growth yields of 19.5 g/mol and 3.2 g/mol, respectively, were obtained. Increase of the steady state glucose concentration in nitrogen-limited chemostat cultures maintained at a constant dilution rate also resulted in a decreased flow of carbon through the pentose phosphate pathway. Above a threshold value of 15–20 mM glucose in the culture, pentose phosphate pathway activity almost completely inhibited. In G. oxydans the coupling between energy generation and growth was very inefficient; yield values obtained at various dilution rates varied between 0.8–3.4 g/cells synthesized per 0.5 mol of oxygen consumed.     

Nitrate reductase activity of free-living and symbiotic uptake hydrogenase-positive and uptake hydrogenase-negative strains of Bradyrhizobium japonicum

The nitrate reductase activity (NR) of selected uptake hydrogenase-positive (hup ⁺) and uptake hydrogenase-negative (hup ^-) strains of Bradyrhizobium japonicum were examined both in free-living cells and in symbioses with Glycine max L. (Marr.) cv. Williams. Bacteria were cultured in a defined medium containing either 10 mM glutamate or nitrate as the sole nitrogen source. Nodules and bacteriods were isolated from plants that were only N₂-dependent or grown in the presence of 2 mM KNO₃. Rates of activity in nodules were determined by an in vivo assay, and those of cultured cells and bacteriods were assayed after permeabilization of the cells with alkyltrimethyl ammonium bromide. All seven strains examined expressed NR activity as free-living cells and as symbiotic forms, regardless of the hup genotype of the strain used for inoculation. Although the presence of nitrate increased nitrate reduction by cultures cells and nodules, no differences in NR activity were observed between bacteroids isolated from nodules of plants fed with nitrate or grown on N₂-fixation exclusively. Cultured cells, nodules and bacteriods of strains with hup ^- genotype (USDA 138, L-236, 3. 15B3 and PJ17) had higher rates of NR activity than those with hup ⁺ genotype (USDA 110, USDA 122 DES and CB1003). These results suggest that NR activity is reduced in the presence of a genetic determinant associated with the hup region of B. japonicum.Abbreviations EDTA ethylene-diamine tetraacetic acid - Hup hydrogen uptake - MOPS 3-(N-morpholino)-propane sulfonic acid - NR nitrate reductase - PVP polyvinyl-polypyrrolidone - Tris Tris(hydroxymethyl)-aminomethane     

NUTRITIONAL REQUIREMENTS FOR SEXUAL REPRODUCTION IN MESOTAENIUM KRAMSTAI (CHLOROPHYTA) 1

Optimum conditions for conjugation in the heterothallic saccoderm desmid Mesotaenium kramstai Lemmer-mann have been determined. In culture, cells acquired the ability to form gamete pairs just prior to the onset of stationary phase after sufficient nitrate had been depleted from the medium. The appearance of potential gametes was delayed by increasing the concentration of KNO₃ When cells of both mating types were harvested from 15 to 18 day old cultures, washed, resuspended in fresh medium, and mixed, approximately 50 percent of the cells paired (measured three days after mixing) in a medium containing 0.13 mM or less KNO₃. At greater concentrations, fewer pairs formed; no pairs formed in medium containing 0.5 mM KNO₃. Conjugation was not inhibited by other macronutrients. Calcium and magnesium were essential for maximum conjugation. Although Ca²⁺ and Mg²⁺ contentrations of 0.05 mM and 0. I mM, respectively, were sufficient for optimum growth, maximum conjugation required more than 10 times these values. Few gamete pairs formed when either Ca²⁺ or Mg²⁺ was omitted from the medium, no pairing occurred when both Ca²⁺ and Mg²⁺ were omitted.     

Superoxide dismutase is involved in high tolerance to copper in the deep-sea yeast, Cryptococcus sp. N6

The activity and expression of superoxide dismutase (SOD) was analyzed in a copper-tolerant yeast, Cryptococcus sp. N6. Using cell extracts, two distinct bands exhibiting SOD activity appeared on native PAGE: one band, with higher mobility, appeared when the cells were grown without CuSO₄, and the other band appeared when the cells were grown with 10 mM CuSO₄. Cells grown with 3 mM CuSO₄ produced both SOD isoforms. Western blot analysis, using a monoclonal antibody against human SOD-1, showed that SOD protein was expressed in the absence of CuSO₄ and that the expression level increased when the cells were grown with 3 or 10 mM CuSO₄. The molecular weight of SOD from strain N6 was approx. 18 kDa. Treatment of the cells with the protein synthesis inhibitor, cycloheximide at 0.5 g ml^–1, did not affect cell growth in the absence of CuSO₄ but significantly inhibited growth in the presence of 10 mM CuSO₄ and inhibited expression of SOD protein. This suggests that SOD may play a role in cell growth in the presence of high concentrations of CuSO₄.     

Assay of molybdenum cofactor of barley

Conditions for assay of molybdenum cofactor in barley shoot extracts in the presence of molybdate (25 mM N₂MoO₄) and the sulphydryl-group protector, reduced glutathione (5 mM) were optimized. Both total Mo-cofactor (assayed after heat-treatment of cell-free extracts) and ‘free’ Mo-cofactor (assayed in untreated cell-free extracts) were assayed. Compared to control plants grown in the absence of an exogenous nitrogen source total Mo-cofactor levels increased around 70 % when plants were grown for 4 days in the presence of either 15 mM KNO₃ or 15 mM NH₄NO₃. Growth in the presence of 15 mM (NH₄)₂SO₄ did not affect the Mo-cofactor level. Very similar results were seen when plants were transferred to these nitrogen sources for 24 hr after previous growth in the absence of an exogenous nitrogen source. In contrast ‘free’ Mo-cofactor levels of both KNO₃ and NH₄NO₃-treated plants were increased 2-3-fold over untreated controls. Growth in the presence of (NH₄)₂SO₄ did not affect the ‘free’ Mo-cofactor level.     

Kinetics of yeast growth and enzyme syntheses in a phosphate-limited continuous culture

Summary The effect of a deficiency of inorganic phosphate on the growth rate and on the invertase and phosphatase activities inSaccharomyces carlsbergensis was studied in a chemostat culture using a synthetic medium in which ethanol was the sole carbon source.The kinetic relationship between the growth rate and both the rates of phosphate uptake and the ethanol consumption agreed well with the threshold model but not the multicative model. The invertase activity of the yeast increased as the dilution rate decreased. As the phosphate concentration in the feed was reduced, the enzyme synthesis increased remarkably. Acid phosphatase activity was repressed completely above a critical molecular ratio, 0.015, of monopotassium phosphate to ethanol in the feed medium. As the phosphate concentration in the feed decreased, the maximum specific enzyme activity increased and the corresponding optimum dilution rate decreased. These experimental changes in enzyme synthesis were expressed mathematically using the modified operon models for enzyme regulation in terms of two fractions of limited inorganic phosphate; one which affects growth and the other which is incorporated in excess by the cells.Nomenclature A ethanol concentration in the culture (mM) - a, b, c, d exponents in the operon model - D dilution rate (h^–1) - E enzyme concentration in the culture (enzyme unit l^–1) - K_a, K_b, K_c, K_d, k equilibrium constants used in the operon model, see Toda (1976b) - o operator gene - P inorganic phosphate concentration in the culture (mM) - Pi limited inorganic phosphate concentration in the cells (mmole inorganic phosphate/g dry weight of cell) - Q specific enzyme activity, no units: (E/X)/(E/X)_max - Q_c, Q_d as defined in Eq. 12 - R repressor - r regulator gene - X cell concentration in the culture (dry cell weight l^–1) Greek Letters molecular ratio of inorganic phosphate to ethanol in the feed medium (mole/mole) - specific growth rate (h^–1) - A specific uptake rate of ethanol (mmole/g cell·h) - P specific uptake rate of inorganic phosphate (mmole/g cell·h) Suffix crit critical value - f feed - max maximum - min minimum - t total - 1, 2 number of species Superfix eff effective for cell growth - exc excess - str structural     

Growth of Hansenula polymorpha in a methanol-limited chemostat

Hansenula polymorpha has been grown in a methanol-limited continuous culture at a variety of dilution rates. Cell suspensions of the yeast grown at a dilution rate of 0.16 h^-1 showed a maximal capacity to oxidize excess methanol (QO ₂ ^max ) which was 1.6 times higher than the rate required to sustain the growth rate (Q _O2). When the dilution rate was decreased to 0.03 h^-1, QO ₂ ^max of the cells increased to a value of more than 20 times that of Q _O2. The enzymatic basis for this tremendous overcapacity for the oxidation of excess methanol at low growth rates was found to be the methanol oxidase content of the cells. The level of this enzyme increased from 7% to approximately 20% of the soluble protein when the growth rate was decreased from 0.16 to 0.03 h^-1. These results were explained on the basis of the poor affinity of methanol oxidase for its substrates. Methanol oxidase purified from Hansenula polymorpha showed an apparent K _mfor methanol of 1.3 mM in air saturated reaction mixtures and the apparent K _mof the enzyme for oxygen was 0.4 mM at a methanol concentration of 100 mM.The involvement of an oxygen dependent methanol oxidase in the dissimilation of methanol in Hansenula polymorpha was also reflected in the growth yield of the organism. The maximal yield of the yeast was found to be low (0.38 g cells/g methanol). This was not due to a very high maintenance energy requirement which was estimated to be 17 mg methanol/g cells x h.     

Solubilization of rock phosphates byRhizobium andBradyrhizobium

The ability ofRhizobium andBradyrhizobium strains to solubilize phosphate from hydroxyapatite was determined in a medium containing NH₄Cl or KNO₃. The presence of NH₄ ⁺ in the medium resulted in higher solubilization of phosphate as compared to the presence of KNO₃, with the exception ofR. leguminosarium bv. viceae strain TAL 1236 and 1402 which solubilized comparable amounts of phosphate in a medium containing either KNO₃ or NH₄Cl. These results suggest that the strains employ two different mechanisms for phosphate solubilization, one depending on the presence of NH₄ ⁺, the other not requiring its presence. Temperature and aeration (O₂ demand) optima were 30°C and 4.2 Hz (shaking frequency), respectively. In nonsterile soil the tested strain (R. meliloti TAL 1236) was very effective in solubilizing rock phosphate.     

The role of carbon dioxide in glucose metabolism of Bacteroides fragilis

The effect of CO₂ concentration on growth and glucose fermentation of Bacteroides fragilis was studied in a defined mineral medium. Batch culture experiments were done in closed tubes containing CO₂ concentrations ranging from 10% to 100% (with appropriate amounts of bicarbonate added to maintain the pH at 6.7). These experiments revealed that CO₂ had no influence on growth rate or cell yield when the CO₂ concentration was above 30% CO₂ (minimum available CO₂–HCO ₃ ^- , 25.5 mM), whereas a slight decrease in these parameters was observed at 20% and 10% CO₂ (available CO₂–HCO ₃ ^- , 17 and 8.5 mM, respectively). If CO₂–HCO ₃ ^- concentrations were below 10 mM, the lag phase lengthened and a decrease in maximal growth rate and cell yield were observed. The amount of acetate made decreased, while d-lactate concentration increased. A net production of CO₂ allowed growth under conditions of extremely low concentrations of added CO₂.When B. fragilis was grown in continuous culture with 100% CO₂ or 100% N₂, the dilution rate influenced the concentrations of acetate, succinate, propionate, d-lactate, l-malate and formate formed. Decreasing the dilution rate favored propionate and acetate production under both conditions. When the organism was grown with 100% N₂, the amount of propionate formed was greater than the amount of succinate formed at all dilution rates. Except at slow dilution rates the reverse was true when 100% CO₂ was used. B. fragilis was unable to grow at dilution rates faster than 0.154 h^-1 when grown with 100% N₂; the Y _glc ^max was 67.9 g DW cells/mol glucose and m _s was 0.064 mmol glucose/g DW·h. If the gas atmosphere was 100% CO₂ the organism was washed out of the culture when the dilution rate exceeded 0.38 h^-1; the Y _glc ^max was 59.4 g DW cells/mol glucose and m _s was 0.094 mmol glucose/g DW·h.Measurement of the phosphoenolpyruvate (PEP) carboxykinase (E.C. 4.1.1.49) with whole, permeabilized cells of B. fragilis showed an increase of specific enzyme activity with decreasing CO₂ concentrations. The mechanisms used by B. fragilis to adjust to low levels of CO₂ are discussed.     

Effect of nitrate supply on the in-vivo synthesis and distribution of trifollin A,a Rhizobium trifolii-binding lectin,in Trifolium repens seedlings

In-vivo synthesis of the white-clover lectin, trifoliin A, was examined by the incorporation of labeled amino acids into protein during heterotrophic growth of intact Trifolium repens L. seedlings. Lectin synthesis was quantified by measuring the level of labeled protein immunoprecipitated from root exudate, from the hapten (2-deoxyglucose) eluate of the roots, and from root and shoot homogenates. The presence of labeled trifoliin A was confirmed by non-denaturing and sodium dodecyl sulfate-polyacrylamide gel electrophoresis, followed by fluorography and comparison with trifoliin A standards. In-vivo-labeled trifoliin A was detected in seedling root homogenate 2 h after the addition of labeled amino acids and on the root surface by 8 h. Incorporation of labeled amino acids into protein and trifoliin A was greatest with 2-d-old seedlings and was greater when the plants were grown continuously in the dark than when they were exposed to 14 h light daily. Significantly more labeled lectin accumulated on the root surface of seedlings grown with 1.5 mM KNO₃ than of seedlings grown either without N or with 15.0 mM KNO₃. The labeled lectin from the root surface in all nitrate treatments and from the rootexudate samples of seedlings grown N-free and with 1.5 mM KNO₃ was fully able to bind to Rhizobium trifolii. In contrast, only 2% of the immunoprecipitable protein found in the root exudate of seedlings grown with 15.0 mM KNO₃ was able to bind to the bacteria. Thus, excess nitrate does not repress the synthesis of trifoliin A in the root, but does affect the distribution and activity of this newly synthesized lectin in a way which reduces its ability to interact with R. trifolii. By using Western blot analysis, much more total trifoliin A is detected in the homogenates of shoots than roots. However, greater than 80% of the total labeled protein and 85–90% of the total labeled lectin were found in the root homogenates of 2-d-old dark-grown seedlings incubated for 5 h with labeled amino acids. In addition, Western blot analysis indicated that the shoot homogenate contained smaller-molecular-weight peptides which reacted with the specific anti-trifoliin A antibody. These studies indicate that stored trifoliin A in the seed is degraded in the shoots during seedling development, while newly synthesized trifoliin A in the roots is excreted to the root surface and external environment.Abbreviations IgG immunoglobulin G - LPS lipopolysaccharide - PBS 10 mM potassium-phosphate buffer, pH 7.0, containing 0.8% NaCl - PBS-T 20 mM phosphate-buffered saline, pH 7.4, containing 0.05% Tween 20 - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Regulation of the Expression of the Photosynthetic Apparatus of Rhodobacter capsulatus Grown in Nitrogen-Limited Chemostat Cultures

Rhodobacter capsulatus was grown in chemostat cultures under different dilution rates and with ammonium ions as the limiting nutrient. The maximal growth rate (μmax) and the Monod cell growth saturation coefficient (K_s), were calculated from batch cultures grown at different concentrations of NH₄ ⁺. The experiments in chemostat were carried out at 0.25 mM (NH₄)₂SO₄, and the dilution rates were varied between 38% and 75% of μmax. The results indicated that under continuous culture conditions the cell yield coefficient (Y) (mg dry weight × μmol consumed ammonium sulfate⁻¹) decreased with increasing dilution rate (D). On the contrary, the cell yield was constant when expressed as mg cellular protein ×μmol consumed ammonium sulfate⁻¹. This occurred as a consequence of both an increase in the consumed ammonium sulfate and a simultaneous decrease in the cell biomass production at increasing growth rates. The cells produced at higher growth rates had a higher protein content per cell. The specific content of bacteriochlorophyll (Bchl) decreased (between 3 and 4 times) with increasing growth rates measured in either cells or chromatophores. However, the absorption spectra of the cells indicated that the ratio LHI (light-harvesting complex I) to LHII (light-harvesting complex II) Bchl complexes did not change. The reaction center (RC) complex content varied in parallel with the total Bchl content, yielding a constant photosynthetic unit of 65 mol Bchl × mol RC⁻¹ at different Ds. On the other hand, the uncoupled ATPase-specific activity measured in chromatophores was usually between 30% and 40% higher at the highest growth rates reached in these experiments. Received: 22 January 1996 / Accepted: 9 March 1996     

LIGHT/DARK-PHASED CELL DIVISION IN EUGLENA GRACILIS (Z) (EUGLENOPHYCEAE) IN PO4-LIMITED CONTINUOUS CULTURE1

Eugene gracilis Klebs (Z) was grown in a cyclostat (continuous culture on a light/dark cycle) at growth limiting levels of phosphate. Cell division was restricted to the dark period regardless of the proportion of the cells dividing during each 24 h period. Growth rate, as reflected by the amplitude of the cell density oscillation, was correlated with dilution rate. The width of the division gate was analyzed using a phasing index and found to be narrowest at dilution rates where the mean generation time of the cell population was an even multiple of 24 h. The effect was attributed to enhanced phasing of the cell division process by the biological clock of Euglena. Residual phosphate levels in the cyclostat were less than 0.3 μM PO₄ at all submaximal growth rates. Cellular phosphorus concentration increased with dilution rate as described by a hyperbola saturating at D_max= 0.74 day⁻¹ with 8 × 10⁻⁸μM P/cell as the minimum intracellular phosphorus concentration for growth. The results are discussed, in terms of the inherent similarities and differences between a cyclostat and a steady state chemostat, and the advantages of the cyclostat for studies in phytoplankton ecology.     

Role of nitrogen metabolism in the development of salt tolerance in barley plants

The 7- to 8-day-old barley (Hordeum vulgare L.) seedlings grown in KNO3 solutions (1-40 mM) were characterized by the substrate activation of nitrate reductase (NR) in the apical leaf segments (1–2 cm in length), as well as by stimulated growth, broadened leaf blades, and by vigorously developed system of shortened roots. When the seedlings were grown in the presence of 20 mM KNO₃, the ability of leaf segments to generate superoxide anion radical remained at the level typical of control plants grown in water. The content of 5-aminolevulinic acid (ALA) in plants grown in the presence of 20 mM KNO₃ was 2.2–2.4 times higher than in control plants. The plants grown in the presence of nitrate had an elevated content of chlorophylls a and b, heme, and protein (by 42%). At the same time, the proline content was almost twofold lower than in control plants, which was due to substantial reduction (by 40%) in activity of Δ¹-pyrroline-5-carboxylate synthetase (P5CS). It is concluded that the substrate activation of NR by KNO₃ under normal growth conditions results in predominant utilization of glutamic acid (the primary product of inorganic nitrogen assimilation) for biosynthesis of tetrapyrroles and protein amino acids at the expense of inhibition of proline synthesis. When barley seedlings were grown in 150 mM NaCl solution, the plant growth and the root system development were suppressed to the levels of 63 ± 6% and 61 ± 11% of the control values, respectively. In the apical leaf tissues of plants adapted to NaCl, there was a slight decrease in the total NR activity (by 10%), a significant reduction in protein content (by 32%), and a parallel increase in the content of ALA (by a factor of 4.3), chlorophylls, heme, carotenoids, proline (2.2-fold) and P5CS (1.6-fold) with respect to the control values. It is proposed that the accumulation of ALA and proline under salinity-induced suppression of nitrogen assimilation results from the predominant allocation of glutamate for biosyntheses of ALA and proline at the expense of inhibition of growth-related processes requiring intense protein synthesis. The substrate activation of NR by KNO₃ under salinity conditions was associated with prevailing allocation of the assimilated nitrogen for synthesis of proline and protein amino acids, which reinforced plant cell protection against salinity and stimulated plant growth.     

The effects of KNO3 concentration in callus induction medium for wheat anther culture

KNO₃ concentration was found to significantly affect the anther culture of wheat (Triticum aestivum L.). When KNO₃ was increased from 0 to 15 mM (in cultivar Jinghua 1) or from 10 to 15 mM (in cultivars 2531-10, Xiaoyan 759 and Norin 10), the callus induction frequency increased significantly. When KNO₃ was increased further above 20 mM, the callus induction frequency decreased significantly in all the tested cultivars. The subsequent frequency of green plantlet regeneration increased significantly, and the ratio of green to albino regenerants increased sharply when KNO₃ concentration increased. Further experiments found that the decrease of callus induction frequency in the medium with too much KNO₃ might be caused by NO₃ ^- ion alone, while the effect of KNO₃ on green plantlet regeneration might be caused by both K⁺ and NO₃ ^- ions, and that the effects of NO₃ ^- concentration were independent of NH₄ ⁺ concentration in the medium.     

Phosphatase synthesis in Klebsiella (Aerobacter) aerogenes growing in continuous culture

1. Phosphatase synthesis was studied in Klebsiella aerogenes grown in a wide range of continuous-culture systems. 2. Maximum acid phosphatase synthesis was associated with nutrient-limited, particularly carbohydrate-limited, growth at a relatively low rate, glucose-limited cells exhibiting the highest activity. Compared with glucose as the carbon-limiting growth material, other sugars not only altered the activity but also changed the pH–activity profile of the enzyme(s). 3. The affinity of the acid phosphatase in glucose-limited cells towards p-nitrophenyl phosphate (K_m 0.25–0.43mm) was similar to that of staphylococcal acid phosphatase but was ten times greater than that of the Escherichia coli enzyme. 4. PO₄³⁻-limitation derepressed alkaline phosphatase synthesis but the amounts of activity were largely independent of the carbon source used for growth. 5. The enzymes were further differentiated by the effect of adding inhibitors (F⁻, PO₄³⁻) and sugars to the reaction mixture during the assays. In particular, it was shown that adding glucose, but not other sugars, stimulated the rate of hydrolysis of p-nitrophenyl phosphate by the acid phosphatase in carbohydrate-limited cells at low pH values (<4.6) but inhibited it at high pH values (>4.6). Alkaline phosphatase activity was unaffected. 6. The function of phosphatases in general is discussed and possible mechanisms for the glucose effect are outlined.     

Growth and fermentation responses of Selenomonas ruminantium to limiting and non-limiting concentrations of ammonium chloride

 The objective of this study was to assess fermentation product, growth rate and growth yield responses of Selenomonas ruminantium HD₄ to limiting and non-limiting ammonia concentrations. The ammonia half-inhibition constant for S. ruminantium in batch culture was 296 mM. Cells were grown in continuous culture with a defined ascorbate-reduced basal medium containing either 0.5, 5, 25, 50, 100 or 200 mM NH₄Cl and dilution rates were 0.07, 0.14, 0.24 or 0.40 h^-1. Ammonia was the growth-limiting nutrient when 0.5 mM NH₄Cl was provided and the half-saturation constant was 72 μM. Specific rates of glucose utilization and fermentation acid carbon formation were highest for 0.5 mM NH₄Cl. Lactate production (moles per mole of glucose disappearing) increased at the fastest dilution rate (0.40 h^-1) for 5.0 mM NH₄Cl while acetate and propionate decreased when compared to slower dilutions (0.07 and 0.14 h^-1). Lactate production remained low while acetate and propionate remained high for all dilution rates when NH₄Cl concentrations were 25 mM or greater. Yield (Y _Glc and Y _ATP) were nearly doubled when NH₄Cl was increased from 0.5 mM (25.1 g cells/mol glucose used and 13.9 g cells/mol ATP produced respectively) to the higher concentrations. Y _Glc was highest at 25 mM and 50 mM NH₄Cl (48.2 cells/mol and 43.1 cells/mol respectively) as was Y _ATP (23.2 cells/mol and 20.8 cells/mol respectively). Y _NH3 was highest at the lowest NH₄Cl concentration. The maximal fermentation product formation rate occurred at a growth-limiting ammonia concentration, while maximal glucose and ATP bacterial yields occurred at non-growth-limiting ammonia concentrations. Given the growth response of this ruminal bacterium, it is possible that maximization of ruminal bacterial yield may necessitate sacrificing the substrate degradation rate and vice versa. Received: 5 December 1995/Received revision: 2 April 1996/Accepted: 22 April 1996     

Identification of the Pseudornonas aeruginosa acid phosphatase as a phosphorylcholine phosphatase activity

Summary Choline, betaine and N,N-dimethylglycine as the sole carbon and nitrogen source induced a periplasmic acid phosphatase activity in Pseudomonas aeruginosa. This enzyme produced the highest rates of hydrolysis in phosphorylcholine and phosphorylethanolamine among the various phosphoric esters tested. At saturating concentrations of Mg²⁺, the K_m values were 0.2 and 0.7 mM for phosphorylcholine and phosphorylethanolamine respectively. At high concentrations both compounds were inhibitors of the enzyme activity. The K _inf1 ^sups values for phosphorylcholine and phosphorylethanolamine were 1.0 and 3.0 mM respectively. The higher catalytic efficiency was that of phosphorylcholine. Considering these results it is possible to suggest that the Pseudomonas aeruginosa acid phosphatase is a phosphorylcholine phosphatase. The existence of this activity which is induced jointly with phospholipase C by different choline metabolites, in a high phosphate medium, suggests that the attack of Pseudomonas aeruginosa on the cell host may also be produced under conditions of high phosphate concentrations, when the alkaline phosphatase is absent.