Regulation of nitrogen fixation by Rhizobia export of fixed N2 as NH4+

The metabolic fate of gaseous nitrogen (¹⁵N₂) fixed by free-living cultures of Rhizobia (root nodule bacteria) induced for their N₂-fixation system was followed. A majority of the fixed ¹⁵N₂ was found to be exported into the cell supernatant. For example, as much as 94% of the ¹⁵N₂ fixed by Rhizobium japonicum (soybean symbiont) was recovered as ¹⁵NH₄⁺ from the cell supernatant following alkaline diffusion. Several species of root nodule bacteria also exported large quantities of NH₄⁺ from l-histidine. Evidence is presented that overproduction and export of NH₄⁺ by free-living Rhizobia may be closely linked to the control of several key enzymes of NH₄⁺ assimilation. For instance, NH₄⁺ was found to repress glutamine synthetase whereas l-glutamate repressed glutamate synthase. Assimilation of NH₄⁺ as nitrogen source for growth of Rhizobia was inhibited by glutamate. The mechanism of regulation of NH₄⁺ production by root nodule bacteria is discussed.     

Kinetics of NH(4) Assimilation in Zea mays: Preliminary Studies with a Glutamate Dehydrogenase (GDH1) Null Mutant

In higher plants it is now generally considered that glutamate dehydrogenase (GDH) plays only a small or negligible role in ammonia assimilation. To test this specific point, comparative studies of ¹⁵NH₄⁺ assimilation were undertaken with a GDH1-null mutant of Zea mays and a related (but not strictly isogenic) GDH1-positive wild type from which this mutant was derived. The kinetics of ¹⁵NH₄⁺ assimilation into free amino acids and total reduced nitrogen were monitored in both roots and shoots of 2-week-old seedlings supplied with 5 millimolar 99% (¹⁵NH₄)₂SO₄ via the aerated root medium in hydroponic culture over a 24-h period. The GDH1-null mutant, with a 10- to 15-fold lower total root GDH activity in comparison to the wild type, was found to exhibit a 40 to 50% lower rate of ¹⁵NH₄⁺ assimilation into total reduced nitrogen. Observed rates of root ammonium assimilation were 5.9 and 3.1 micromoles per hour per gram fresh weight for the wild type and mutant, respectively. The lower rate of ¹⁵NH₄⁺ assimilation in the mutant was associated with lower rates of labeling of several free amino acids (including glutamate, glutamine-amino N, aspartate, asparagine-amino N, and alanine) in both roots and shoots of the mutant in comparison to the wild type. Qualitatively, these labeling kinetics appear consistent with a reduced flux of ¹⁵N via glutamate in the GDH1-null mutant. However, the responses of the two genotypes to the potent inhibitor of glutamine synthetase, methionine sulfoximine, and differences in morphology of the two genotypes (particularly a lower shoot:root ratio in the GDH1-null mutant) urge caution in concluding that GDH1 is solely responsible for these differences in ammonia assimilation rate.     

Control of symbiotic nitrogen fixation in Rhizobia regulation of NH4 assimilation

The metabolic fate of gaseous nitrogen (¹⁵N₂) fixed by free-living cultures of Rhizobia (root nodule bacteria) induced for their N₂-fixation system was followed. A majority of the fixed ¹⁵N₂ was found to be exported into the cell supernatant. For example, as much as 94% of the ¹⁵N₂ fixed by Rhizobium japonicum (soybean symbiont) was recovered as ¹⁵NH₄⁺ from the cell supernatant following alkaline diffusion. Several species of root nodule bacteria also exported large quantities of NH₄⁺ from l-histidine. Evidence is presented that overproduction and export of NH₄⁺ by free-living Rhizobia may be closely linked to the control of several key enzymes of NH₄⁺ assimilation. For instance, NH₄⁺ was found to repress glutamine synthetase whereas l-glutamate repressed glutamate synthase. Assimilation of NH₄⁺ as nitrogen source for growth of Rhizobia was inhibited by glutamate. The mechanism of regulation of NH₄⁺ production by root nodule bacteria is discussed.     

Ammonium influence on nitrogen assimilating enzymes and protein accumulation in suspension cultures of Paul's Scarlet rose

The influence of NH₄⁺ on protein accumulation was examined by growing suspension cultures of Rosa cv. Paul's Scarlet on two defined media. Both contained 1920 μmol of NO₃^? but only one contained 72.8 μmol of NH₄⁺. At the conclusion of a 14-day growth period, cultures grown with NH₄⁺ possessed twice as much protein as cultures grown without NH₄⁺. The influence of NH₄⁺ did not appear to be a substrate effect, since the amount of NH₄⁺ provided accounted for only 10% of the nitrogen recovered in protein. The provision of NH₄⁺ in the starting medium increased the activity (μmol substrate. h^?1· g^?1 fr wt) of glutamate dehydrogenase and glutamate synthase, and reduced the activity of glutamine synthetase. A comparison of the total activity per culture for each of these enzymes with the rate of nitrogen incorporation into protein showed that the enzymatic potential of glutamine synthetase and glutamate dehydrogenase greatly exceeded the actual in vivo rate of nitrogen assimilation through the respective pathways. Thus it was concluded that the availability of either of these enzymes does not limit nitrogen assimilation in rose cells and the fluctuations in their level brought about by NH₄⁺ was of no physiological importance. The activity of glutamate synthase per culture approximated the rate of nitrogen incorporation into protein during early stages of growth, and for that reason may have limited nitrogen assimilation or caused a diversion of nitrogen through the alternative pathway to glutamate catalyzed by glutamate dehydrogenase.     

Implications of N acquisition from atmospheric NH3 for acid-bAse and cation-anion balance of Lolium perenne

In the atmosphere, ammonia (NH₃) is the third most abundant N species which, due to various natural and anthropogenic sources, can locally reach high concentrations. The acquisition of atmospheric NH₃ by plant shoots will lead to two opposing effects on acid-base balance. Absorption and dissolution of NH₃ will cause an alkalinisation, while the assimilation of NH₃ results in an acidification. Different rates of these processes would lead to an acid-base imbalance with consequences for the ionic balance of the plant. As there is only a limited capacity for biochemical disposal of excess H⁺ in shoots, pH regulation may involve a pattern of (in)organic ion flow between shoots and roots followed by H⁺/OH^? extrusion into the media via roots. The acquisition of NH₃ as additional N source should lead to a reduction in the ratio of mol H⁺/OH^? gained per mol N assimilated. We have recently investigated the NH₃ acquisition by Lolium perenne L. cv. Centurion and studied the effects of gas phase NH₃ on growth, acid-base balance and water-use efficiency. The experiments, therefore, included the application of a range of ¹⁴NH₃ to the shoots and of ¹⁵N as NO₃^?, NH₄⁺ or NH₄NO₃ to the roots. After a summary of the main conclusions from those experiments, we discuss the implications of the use of atmospheric NH₃ for the mineral composition of the plants. Over the range of NH₃ supplied, plants from all treatments could utilize gas-phase NH₃. Plants receiving NO₃^? via their roots had a higher capacity to use gaseous NH₃ than those growing with NH₄⁺. NH₃ assimilation in shoots reduced both the acid load with NH₄⁺ nutrition and the alkaline load with NO₃^? supply to the roots. The most significant effect of fumigation on the ion balance was an increase in K⁺ within all treatments, and this effect was highest in the NH₄⁺-fed plants. The results of the experiments support predictions of a combination of neutralizing biochemical reactions as well as transport of organic anion salts between shoots and roots as possible acid-base regulation mechanisms of the whole plant.     

Ammonia Production and Assimilation in Glutamate Synthase Mutants of Arabidopsis thaliana

Ammonia production and assimilation¹ were examined in photorespiratory mutants of Arabidopsis thaliana L. lacking ferredoxin-dependent glutamate synthase (Fd-GluS) activity. Although photosynthesis was rapidly inhibited in these mutants in normal air, NH₄⁺ continued to accumulate. The accumulation of NH₄⁺ was also seen after an initial lag of 30 minutes in 2% O₂, 350 microliters per liter of CO₂ and after 90 minutes in 2% O₂, 900 microliters per liter of CO₂. The accumulation of NH₄⁺ in normal air and low O₂ was also associated with an increase in the total pool of amino acid-N and glutamine, and a decrease in the pools of glutamate, aspartate, alanine, and serine. Upon return to dark conditions, or to 21% O₂, 1% CO₂ in the light, the NH₄⁺ which had accumulated in the leaves was reassimilated into amino acids. The addition of methionine sulfoximine (MSO) resulted in higher accumulations of NH₄⁺ in glutamate synthase mutants and prevented the reassimilation of NH₄⁺ upon return to the dark. The addition of MSO also resulted in the accumulation of NH₄⁺ in glutamate synthase mutants in the light and in 21% O₂, 1% CO₂. These results indicate that glutamine synthetase is essential for the reassimilation of photorespiratory NH₄⁺ and for primary N assimilation in the leaves and strongly suggest that glutamate dehydrogenase plays only a minimal role in the assimilation of ammonia. Levels of NADH-dependent glutamate synthase (NADH-GluS) appear to be sufficient to account for the assimilation of NH₄⁺ by a GS/NADH-GluS cycle.     

Amino acids as repressors of nitrogenase biosynthesis in Klebsiella pneumoniae

Nitrogenase biosynthesis in Klebsiella pneumoniae including mutant strains, which produce nitrogenase in the presence of NH₄⁺ (Shanmugam, K.T., Chan, Irene, and Morandi, C. (1975) Biochim. Biophys. Acta 408, 101–111) is repressed by a mixture of L-amino acids. Biochemical analysis shows that glutamine synthetase activity in strains SK-24, SK-28, and SK-29 is also repressed by amino acids, with no detectable effect on glutamate dehydrogenase. Among the various amino acids, L-glutamine in combination with L-aspartate was found to repress nitrogenase biosynthesis completely. In the presence of high concentrations of glutamine (1 mg/ml) even NH₄⁺ repressed nitrogenase biosynthesis in the strains SK-27, SK-37, SK-55 and SK-56. Under these conditions, increased glutamate dehydrogenase activity was also detected. Physiological studies show that nitrogenase derepressed strains are unable to utilize NH₄⁺ as sole source of nitrogen for biosynthesis of glutamate, whereas back mutations leading to NH₄⁺ utilization results in sensitivity to repression by NH₄⁺. These findings suggest that amino acids play an important role as regulators of nitrogen fixation.     

Azolla-Anabaena Relationship : XIII. Fixation of [N]N(2)

The major radioactive products of the fixation of [¹³N]N₂ by Azolla caroliniana Willd.-Anabaena azollae Stras. were ammonium, glutamine, and glutamate, plus a small amount of alanine. Ammonium accounted for 70 and 32% of the total radioactivity recovered after fixation for 1 and 10 minutes, respectively. The presence of a substantial pool of [¹³N]N₂-derived ¹³NH₄⁺ after longer incubation periods was attributed to the spatial separation between the site of N₂-fixation (Anabaena) and a second, major site of assimilation (Azolla). Initially, glutamine was the most highly radioactive organic product formed from [¹³N]N₂, but after 10 minutes of fixation glutamate had 1.5 times more radiolabel than glutamine. These kinetics of radiolabeling, along with the effects of inhibitors of glutamine synthetase and glutamate synthase on assimilation of exogenous and [¹³N]N₂-derived ¹³NH₄⁺, indicate that ammonium assimilation occurred by the glutamate synthase cycle and that glutamate dehydrogenase played little or no role in the synthesis of glutamate by Azolla-Anabaena.     

Acid-Base Regulation by Azolla spp. with N2 as Sole N Source and with Supplementation by NH+4 or NO−3

Diazotrophic cultures of three species of Azolla (Az. caroliniana, Az. microphylla, Az. pinnata) symbiotic with Anabaena azollae accumulated some 0.10–0.24 mol organic anion per mol N assimilated (0.010–0.018 mol organic anion per mol C assimilated), with a corresponding efflux of 0.05–0.11 mol H⁺ per mol N assimilated (0.006–0.009 mol H⁺ per mol C assimilated). These values are lower than those found for terrestrial diazotrophic vascular plants; this may be related to the decreased possibility of increasing Fe and P availability by rhizosphere acidification in a free-floating plant. Modification of the organic anion content, and of the quantity (and direction) of H⁺ exchange with the medium, with 5 mol m^?3 NH⁺₄ or NO^?₃ added to diazotrophic cultures, are consistent with substantial N acquisition from combined N as well as N₂ assimilation. This conclusion is consistent with previously published work with ¹⁵N.     

Enzymes of ammonia assimilation and their regulation inAzospirillum lipoferum strain D-2

Azospirillum lipoferum strain D-2 possesses the following enzymes for the assimilation of N₂ and NH ₄ ⁺ : nitrogenase, glutamine synthetase, NADPH-dependent glutamate synthase, NADH-/NADPH-dependent glutamate dehydrogenase, and NADH-dependent alanine dehydrogenase. Nitrogenase and glutamine synthetase are repressed, whereas glutamate dehydrogenase and alanine dehydrogenase are induced by NH ₄ ⁺ . Glutamine synthetase activity is modulated by both repression and depression and also by adenylylation.     

Regulation of nitrogen fixation. Nitrogenase-derepressed mutants of Klebsiella pneumoniae

1. A new procedure is described for selecting nitrogenase-derepressed mutants based on the method of Brenchley et al. (Brenchley, J. E., Prival, M. J. and Magasanik, B. (1973) J. Biol. Chem. 248, 6122–6128) for isolating histidase-constitutive mutants of a non-N₂-fixing bacterium.2. Nitrogenase levels of the new mutants in the presence of NH₄⁺ were as high as 100% of the nitrogenase activity detected in the absence of NH₄⁺.3. Biochemical characterization of these nitrogen fixation (nif) derepressed mutants reveals that they fall into three classes. Three mutants (strains SK-24, 28 and 29), requiring glutamate for growth, synthesize nitrogenase and glutamine synthetase constitutively (in the presence of NH₄⁺). A second class of mutants (strains SK-27 and 37) requiring glutamine for growth produces derepressed levels of nitrogenase activity and synthesized catalytically inactive glutamine synthetase protein, as determined immunologically. A third class of glutamine-requiring, nitrogenase-derepressed mutants (strain SK-25 and 26) synthesizes neither a catalytically active glutamine synthetase enzyme nor an immunologically cross-reactive glutamine synthetase protein.4. F-prime complementation analysis reveals that the mutant strains SK-25, 26, 27, 37 map in a segment of the Klebsiella chromosome corresponding to the region coding for glutamine synthetase. Since the mutant strains SK-27 and SK-37 produce inactive glutamine synthetase protein, it is concluded that these mutations map within the glutamine synthetase structural gene.     

The photoproduction of H2 and NH4 fixed from N2 by a derepressed mutant of Rhodospirillum rubrum.

A mutant of Rhodospirillum rubrum has been isolated, after mutagenesis with nitrosoguanidine, which is characterized by its inability to grow in the light on malate-minimal media with exogenous ammonia or alanine, poor growth on glutamine and vigorous growth on glutamate. This mutant produces low levels of a key NH+4 assimilation enzyme, glutamate synthase (NADPH-dependent). It also exhibits significant derepression of nitrogenase biosynthesis in the presence of ammonia or alanine, being 15% derepressed for the former and about 70% derepressed for the latter. Some of this mutant's fixed N2 is excreted into the medium as NH+4 (1 mumol NH+4 per mg cell protein in 50 h). Nitrogenase-mediated H2 production by this strain is considerable (42 mumol H2 per mg cell protein in 50 h), approximately twice that of the wild type assayed under similar conditions. These results demonstrate that genetic alteration of the photosynthetic N2-fixer's NH+4 assimilation system disrupts the tight coupling of N2 fixation and NH+4 assimilation normally observed in these organisms, enabling photochemical conversion steps to be utilized for the photoproduction of NH+4 and H2.     

Growth responses of the perennial legume Sesbania sesban to NH4 and NO3 nutrition and effects on root nodulation

Preference for NH₄⁺ or NO₃⁻ nutrition by the perennial legume Sesbania sesban (L.) Merr. was assessed by supplying plants with NH₄⁺ and NO₃⁻ alone or mixed at equal concentrations (0.5 mM) in hydroponic culture. In addition, growth responses of S. sesban to NH₄⁺ and NO₃⁻ nutrition and the effects on root nodulation and nutrient and mineral composition of the plant tissues were evaluated in a hydroponic setup at a range of external concentration of NH₄⁺ and NO₃⁻ (0, 0.1, 0.2, 0.5, 2 and 5 mM). Seedlings of S. sesban grew equally well when supplied with either NH₄⁺ or NO₃⁻ alone or mixed and had high relative growth rates (RGRs) ranging between 0.19 and 0.21 d⁻¹. When larger plants of S. sesban were supplied with NH₄⁺ or NO₃⁻ alone, the RGRs and shoot elongation rates were not affected by the external concentration of inorganic N. At external N concentrations up to 0.5 mM nodulation occurred and contributed to the N nutrition through fixation of gaseous N₂ from the atmosphere. For both NH₄⁺ and NO₃⁻-fed plants the N concentration in the plant tissues, particularly water-extractable NO₃⁻, increased at high supply concentrations, and concentrations of mineral cations generally decreased. It is concluded that S. sesban can grow without an external inorganic N supply by fixing atmospheric N₂ gas via root nodules. Also, S. sesban grows well on both NH₄⁺ and NO₃⁻ as the external N source and the plant can tolerate relatively high concentrations of NH₄⁺. This wide ecological amplitude concerning N nutrition makes S. sesban very useful as a N₂-fixing fallow crop in N deficient areas and also a candidate species for use in constructed wetland systems for the treatment of NH₄⁺ rich waters.     

Nitrogen Assimilation in Mycorrhizas : Ammonium Assimilation in the N-Starved Ectomycorrhizal Fungus Cenococcum graniforme

Ammonium assimilation was followed in N-starved mycelia from the ectomycorrhizal Ascomycete Cenococcum graniforme. The evaluation of free amino acid pool levels after the addition of 5 millimolar NH₄⁺ indicated that the absorbed ammonium was assimilated rapidly. Post-feeding nitrogen content of amino acids was very different from the initial values. After 8 hours of NH₄⁺ feeding, glutamine accounted for the largest percentage of free amino acid nitrogen (43%). The addition of 5 millimolar methionine sulfoximine (MSX) to NH₄⁺-fed mycelia caused an inhibition of glutamine accumulation with a corresponding increase in glutamate and alanine levels.

Using ¹⁵N as a tracer, it was found that the greatest initial labeling was into glutamine and glutamate followed by aspartate, alanine, and ornithine. On inhibiting glutamine synthetase using MSX, ¹⁵N enrichment of glutamate, alanine, aspartate, and ornithine continued although labeling of glutamine was quite low. Moreover, the incorporation of ¹⁵N label in insoluble nitrogenous compounds was lower in the presence of MSX. From the composition of free amino acid pools, the ¹⁵N labeling pattern and effects of MSX, NH₄⁺ assimilation in C. graniforme mycelia appears to proceed via glutamate dehydrogenase pathway. This study also demonstrates that glutamine synthesis is an important reaction of ammonia utilization.

     

Initial organic products of assimilation of [N]ammonium and [N]nitrate by tobacco cells cultured on different sources of nitrogen

Glutamine is the first major organic product of assimilation of ¹³NH₄⁺ by tobacco (Nicotiana tabacum L. cv. Xanthi) cells cultured on nitrate, urea, or ammonium succinate as the sole source of nitrogen, and of ¹³NO₃⁻ by tobacco cells cultured on nitrate. The percentage of organic ¹³N in glutamate, and subsequently, alanine, increases with increasing periods of assimilation. ¹³NO₃⁻, used for the first time in a study of assimilation of nitrogen, was purified by new preparative techniques. During pulse-chase experiments, there is a decrease in the percentage of ¹³N in glutamine, and a concomitant increase in the percentage of ¹³N in glutamate and alanine. Methionine sulfoximine inhibits the incorporation of ¹³N from ¹³NH₄⁺ into glutamine more extensively than it inhibits the incorporation of ¹³N into glutamate, with cells grown on any of the three sources of nitrogen. Azaserine inhibits glutamate synthesis extensively when ¹³NH₄⁺ is fed to cells cultured on nitrate. These results indicate that the major route for assimilation of ¹³NH₄⁺ is the glutamine synthetase-glutamate synthase pathway, and that glutamate dehydrogenase also plays a role, but a minor one. Methionine sulfoximine inhibits the incorporation of ¹³N from ¹³NO₃⁻ into glutamate more strongly than it inhibits the incorporation of ¹³N into glutamine, suggesting that the assimilation of ¹³NH₄⁺ derived from ¹³NO₃⁻ may be mediated solely by the glutamine synthetase-glutamate synthase pathway.     

Physiological effects of a long term exposure to low concentrations of NH3, NO2 and SO2 on Douglas fir (Pseudotsuga menziesii)

The above-ground parts of two years old seedlings of Douglas fir (Pseudotsuga menziesii) were exposed to filtered air, NH₃, NO₂₊, SO₂ (66, 96 and 95 μg m^?3, respectively), to a mixture of NO₂+NH₃ (55 + 82 μg m^?3) or SO₂+NO₂ (128 + 129 μg m^?3), for 8 months in fumigation chambers. Both chlorophyll fluorescence and gas exchange measurements were carried out on shoots which had sprouted at the beginning of the exposure period. The chlorophyll fluorescence measurements were performed after 3 and 5 months of exposure (average shoot age 70 and 140 days, respectively). Light response curves of electron transport rate (J) were determined, in which J was deduced from chlorophyll fluorescence. In addition, light response curves of net CO₂ assimilation were determined after 5 months of exposure. After 3 months of exposure (average shoot age 70 days) all exposure treatments showed a lower maximum electron transport rate (J_max) as compared to the control shoots (filtered air). A large reduction (45%) was observed for shoots exposed to SO₂+NO₂. During the exposure period between 3 and 5 months (average shoot age 70 and 140 days, respectively) a decrease of J_max was observed for all treatments. J_max had further declined some time after termination of the exposure, when average shoot age was 310 days. Shoots exposed to SO₂ and SO₂+NO₂ also showed a reduction in maximum net CO₂ assimilation (P_max) as compared to the control shoots. However, shoots exposed to NO₂ showed no reduction and even a higher P_max was observed for shoots exposed to NH₃ or NO₂+NH₃. Needles of these treatments also showed a higher chlorophyll content which might explain the contradictory results obtained for these treatments: the increased amount of photosynthetic units counteracts the reduction in J_max and consequently no reduction in P_max is measured. Shoots exposed to SO₂ and SO₂+NO₂ also showed a reduction in maximum stomatal conductance (g_s). However, the stomatal opening was larger than could be expected on basis of their (maximum) CO₂ assimilation rate. Consequently, water use efficiency of these shoots was lower than that of the control shoots. Also shoots exposed to NO₂ had a lower water use efficiency due to a significantly higher maximum g_s. Shoots exposed to NH₃ showed a high transpiration rate in the dark, indicating imperfect stomatal closure.     

Ammonia Assimilation in Alnus glutinosa and Glycine max: SHORT-TERM STUDIES USING [N]AMMONIUM

The pattern of assimilation of NH₄⁺ by Alnus glutinosa, a N₂-fixing, nonleguminous angiosperm, was examined. Detached nodules, roots, and nodulated roots of intact plants were exposed to ¹³NH₄⁺ for up to 15 minutes. Glutamine was the most highly labeled compound at all times; the only other compound labeled significantly was glutamate. Similar results were obtained after incubating soybean (L. merr) nodules and roots with ¹³NH₄⁺. These observations and the results of pulse-labeling and inhibitor studies with nodules of Alnus were distinctly different from those predicted for the assimilation of NH₄⁺ via glutamine synthetase and glutamate synthase and suggest that glutamate dehydrogenase may play a major role in the assimilation of exogenously supplied NH₄⁺.     

Kinetics of nitrate and ammonium absorption and accompanying H+ fluxes in roots of Lolium perenne L. and N2-fixing Trifolium repens L.

Kinetic parameters for NH₄⁺ and NO₃^? uptake were measured in intact roots of Lolium perenne and actively N₂-fixing Trifolium repens. Simultaneously, net H⁺ fluxes between the roots and the root medium were recorded, as were the net photosynthetic rate and transpiration of the leaves. A Michaelis–Menten-type high-affinity system operated in the concentration range up to about 500 mmol m^?3 NO₃^? or NH₄⁺. In L. perenne, the V_max of this system was 9–11 and 13–14 μmol g^?1 root FW h^?1 for NO₃^? and NH₄⁺, respectively. The corresponding values in T. repens were 5–7 and 2 μmol g^?1 root FW h^?1. The K_m for NH₄⁺ uptake was much lower in L. perenne than in T. repens (c. 40 compared with 170 mmol m^?3), while K_m values for NO₃^? absorption were roughly similar (around 130 mmol m^?3) in the two species. There were no indications of a significant efflux component in the net uptake of the two ions. The translocation rate to the shoots of nitrogen derived from absorbed NO₃^?-N was higher in T. repens than in L. perenne, while the opposite was the case for nitrogen absorbed as NH₄⁺. Trifolium repens had higher rates of transpiration and net photosynthesis than L. perenne. Measurements of net H⁺ fluxes between roots and nutrient solution showed that L. perenne absorbing NO₃^? had a net uptake of H⁺, while L. perenne with access to NH₄⁺ and T. repens, with access to NO₃^? or NH₄⁺, in all cases acidified the nutrient solution. Within the individual combinations of plant species and inorganic N form, the net H⁺ fluxes varied only a little with external N concentration and, hence, with the absorption rate of inorganic N. Based on assessment of the net H⁺ fluxes in T. repens, nitrogen absorption rate via N₂ fixation was similar to that of inorganic N and was not down-regulated by exposure to inorganic N for 2 h. It is concluded that L. perenne will have a competitive advantage over T. repens with respect to inorganic N acquisition.     

Assimilation of ammonia inParacoccus denitrificans

Two pathways serve for assimilation of ammonia inParacoccus denitrificans. Glutamate dehydrogenase (NADP⁺) catalyzes the assimilation at a high NH₄ ⁺ concentration. If nitrate serves as the nitrogen source, glutamate is synthesized by glutamate-ammonia ligase and glutamate synthase (NADPH). At a very low NH₄ ⁺ concentration, all three enzymes are synthesized simultaneously. No direct relationship exists between glutamate dehydrogenase (NADP⁺) and glutamate-ammonia ligase inP. denitrificans, while the glutamate synthase (NADPH) activity changes in parallel with that of the latter enzyme. Ammonia does not influence the induction or repression of glutamate dehydrogenase (NADP⁺). The inner concentration of metabolites indicates a possible repression of glutamate dehydrogenase (NADP⁺) by the high concentration of glutamine or its metabolic products as in the case when NH₄ ⁺ is formed by assimilative nitrate reduction. No direct effect of the intermediates of nitrate assimilation on the synthesis of glutamate dehydrogenase (NADP⁺) was observed.     

H2 production from chemostat fermentation of glucose byClostridium butyricum andClostridium pasteurianum in ammonium- and phosphate limitation

Summary In ammonium-limitation (4.55 mM NH₄ ⁺) at a dilution rate (D)=0.081 h^–1,Clostridium butyricum produced 2 mol H₂ per mol glucose consumed at pH 5.0, but at a low fermentation rate. At higher pH, important amounts of extracellular protein were produced. Phosphatelimitation (0.5 mM PO₄ ^–3) at D=0.061 h^–1 and pH 7.0 were the best conditions tested for hydrogen gas production (2.22 mol H₂ per mol glucose consumed) at a high fermentation rate. Steady-state growth at lower pH and with 0.1 mM PO₄ ^–3 resulted in proportional higher glucose incorporation into biomass and lower H₂ production. C. pasteurianum in NH₄ ⁺ limitation showed higher fermentation rates thanC. butyricum and a stabilized H₂ production around 2.08 (±0.06) mol per mol glucose consumed at various defined pH conditions, although the acetate/butyrate ratio increased to 1 at pH 7.0. The latter was also observed in phosphate-limitation, but here H₂ production was maximal (1.90 mol. per mol glucose consumed) at the lowest pH (5.5) tested.