Can a limitation in pholem supply to nodules account for the inhibitory effect of nitrate on nitrogenase activity in soybean?

Within 48 h of exposure of nodulated soybean [Glycine max (L.) Merr. cv. Harosoy 63 x Bradyrhizobium japonicum USDA 16] to 10 mM NO₃, significant decreases were observed in nodule-specific nitrogenase (EC 1.7.99.2) activity and CO₂ evolution and in the proportion of [¹⁴C]-labeled photosynthate partitioned to nodule biomass and respiration. These trends continued over the subsequent 3 days of the study period. Concomitant with these events was an 137% increase in the relative growth rate of the whole plant and a cessation in nodule growth. Although the concentration of total soluble sugar in nodules was not affected by NO₃ treatment, the concentration of starch declined to 13% of the control level after 2 days exposure to NO₃^?. In contrast to the effects of NO₃^?, nodules in which nitrogenase activity was partially inhibited by a 30 min exposure to 100% O₂, showed a 52% increase over control in the starch pool over a 72 h period. The results were compared with recent studies of NO₃^? inhibition of nitrogenase activity in legumes, and in contrast to these studies it was concluded that the inhibitory effects of NO₃^? could be accounted for by alterations in photosynthate partitioning to nodules. A hypothesis is proposed which attempts to account for the recent observation (J. K. Vessey, K. B. Walsh, and D. B. Layzell 1988. Physiol. Plant. 73: 113–121) that nitrogenase activity in phloem-limited and nitrate-inhibited nodules is limited by O₂ diffusion. This hypothesis separates the concepts of photosynthate partitioning and phloem supply from that of carbohydrate deprivation and related effects on the size of the carbohydrate pools in nodules.     

Nitrogenase activity of two genotypes of Acacia mangium as affected by phosphorus nutrition

The specific nodulation, nitrogenase activity (acetylene reduction) and budgets of carbon allocation to respiration by nodulated roots were examined in two provenances of Acacia mangium Willd. grown in a glasshouse for 17 weeks to investigate the effects of soil phosphorus and genotypes of the host plant on symbiotic nitrogen fixation. Application of phosphorus (0–80 mg P kg^-1 soil) increased specific nodulation (g nodule dry weight g^-1 plant dry weight) of provenance Ma11 by two-fold and the percentage of nodulated root respiration allocated to nitrogenase by 50%, but had no effect on specific activity of nitrogenase or specific respiration coupled with nitrogenase activity. Improved phosphorus nutrition increased the specific nitrogenase activity of provenance Ma9 by 2-fold, the percentage of nodulated root respiration allocated to nitrogenase, and specific nitrogenase-linked respiration by 50%, respectively, but had no effect on the specific nodulation. The percentage of respiration coupled with nitrogenase activity in nodulated root respiration by provenance Ma9 was 60–70% higher than that in provenance Ma11, regardless of phosphorus levels applied. At the optimal level of phosphorus addition (10 mg P kg^-1 soil), provenance Ma9 had a lower dry mass than provenance Ma11. This was accompanied by a lower nodulated root respiration and a higher percentage of nodulated root respiration allocated to nitrogenase activity in provenance Ma9.     

Oxygen limitation of N2 fixation in stem-girdled and nitrate-treated soybean

The effects of increasing rhizosphere pO₂on nitrogenase activity and nodule resistance to O₂diffusion were investigated in soybean plants [Glycine max (L.) Merr. cv. Harosoy 63] in which nitrogenase (EC 1.7.99.2) activities were inhibited by (a) removal of the phloem tissue at the base of the stem (stem girdling), (b) exposure of roots to 10 mM NO₃over 5 days (NO₃-treated), or (c) partial inactivation of nitrogenase activity by an exposure of nodulated roots to 100 kPa O₂(O₂-inhibitcd). In control plants and in plants which had been treated with 100 kPa O₂, increasing rhizosphere O₂concentrations in 10 kPa increments from 20 to 70 kPa did not alter the steady-state nitrogenase activity. In contrast, in plants in which nitrogenase activities were depressed by stem girdling or by exposure to NO₃, increasing rhizosphere pO₂resulted in a recovery of 57 or 67%, respectively, of the initial, depressed rates of nitrogenase activity. This suggests that the nitrogenase activity of stem-girdled and NO₃-treated soybeans was O₂-limited. For each treatment, theoretical resistance values for O₂diffusion into nodules were estimated from measured rates of CO₂exchange, assuming a respiratory quotient of 1.1 and 0 kPa of O₂in the infected cells. At an external partial pressure of 20 kPa O₂, the stem-girdled and NO₃^--treated plants displayed resistance values which were 4 to 8.6 times higher than those in the nodules of the control plants. In control and O₂-inhibited plants, increases in pO₂from 20 to 70 kPa in 10 kPa increments resulted in a 2.5- to 3.9-fold increase in diffusion resistance to O₂, and had little effect on either respiration or nitrogenase activity. In contrast, in stem-girdled and NO₃^--treated plants, increases in external pO₂had little effect on diffusion resistance to O₂, but resulted in a 2.3- to 3.2-fold increase in nodule respiration and nitrogenase activity. These results are consistent with stem-girdling and NO₃^--inhibition treatments limiting phloem supply to nodules causing an increase in diffusion resistance to O₂at 20 kPa and an apparent insensitivity of diffusion resistance to increases in external pO₂.     

Symbiotic dinitrogen fixation as affected by short-term application of nitrate to nodulatedPisum sativum L.

Effect of nitrate on the nitrogenase (C₂H₂-reduction) activity, growth of nodule tissue accumulation of nitrate and nitrate reductase activity in 4-weeks-old nodulated peas (Pisum sativum l.) was investigated. A relatively slow decrease of the total nitrogenase activity (μmol C₂H₄ per root per h), as compared with plants cultivated without nitrate, was due to both retardation of further growth of the nodule tissue and to a decrease of their specific nitrogenase activity (μmol C₂H₄ per g_f.wt. per h). However, an absolute and pronounced decrease of both nitrogenase activities occurred only 4 or 7 d after the application of nitrate. The addition of nitrate led to its rapid accumulation in the nodule and leaf tissue with a simultaneous induction of the nitrate reductase activity. The nitrogenase activity was not completely inhibited even after a 7-d cultivation with 280 ppm NO₃ ^?-N in the nutrient medium and after accumulation of up to 180 ppm NO₃ ^?-N_f.wt. in the nodule tissue. The results obtained indicate that the “photosynthate deprivation” reflects competition between assimilation of nitrate and fixation of dinitrogen.     

The feedback mechanism of nitrate inhibition of nitrogenase activity in soybean may involve asparagine and/or products of its metabolism

A feedback mechanism which involves sensing of change in phloem N concentration has been proposed to control nodulation and dinitrogen fixation in the presence of external combined N. Whether this control is in response to a change in total N or in some specific signal compound(s) is not known. In the present study we reevaluated the hypothesis that control of nodulation and N₂ fixation involves sensing of change in tissue N composition and attempted to identify potential signal molecule(s) involved. Two soybean (Glycine max [L.] Merr.) genotypes (Williams 82 and NOD1-3) differing in nodule number and tolerance to nitrate were germinated in sand trays. Seven-day-old seedlings were inoculated with a solution of Bradyrhizobium japonicum and grown for 28 days in growth chambers, using a hydroponic system with limited N supply to promote nodulation. Half of 28-day-old plants were treated with 15 mM NO₃^?, then control and treated plants were sampled at the onset of nitrogenase inhibition (24 h following NO₃^?, treatment) for evaluation of nitrogenase activity and tissue concentration of total N and of each individual free amino acid. Phenylisothiocyanate-(PITC) amino acid derivatives were separated and quantified using HPLC. The decline in nitrogenase activity following the short-term nitrate treatment was associated with a dramatic asparagine concentration increase in the shoot and an increase in nodule aspartate and glutamate in both genotypes. Asparagine concentration in the shoot increased 35 times from a barely detectable level of 95 to 3 327 nmol g^?1 fresh weight in Williams 82, and more than tripled from 509 to 1 753 nmol g^?1 fresh weight in NOD1-3. Increase in levels of free Asn and in total free amino acids in the shoot following the short-term nitrate treatment was more pronounced in Williams 82 than in its partially nitrate-tolerant mutant NOD1-3. These results indicate that the feedback control of nodule activity may involve sensing changes in shoot asparagine levels and/or products of its metabolism (aspartate and glutamate) in the nodule. These results also indicate that partial-nitrate tolerance of nodulation in the hypernodulated NOD1-3 mutant is associated with a lesser change in tissue N following nitrate treatment.     

The effect of excision on O2 diffusion and metabolism in soybean nodules

Nitrogen-fixing nodules of soybean [Glycine max (L.) Merr. cv. Maple Arrow inoculated with Bradyrhizobium japonicum USDA 16] were studied before and after excision from the root to determine the role the O₂ regulation plays in the inhibition of nodule activity and the potential for using excised nodules nodules in studies of nodule metabolism. Relative nitrogenase (EC 1.7.99.2) activity (H₂ evolution in N₂:O₂) and nodule respiration (CO₂ evolution) were monitored first in intact nodulated roots and then in freshly excised nodules of the same plant to determine the time course of the decline in nodule metabolism. Folowing excision, nitrogenase activity and respiration declined rapidly in the first minute and then more gradually. After 40 min the rate of H₂ evolution was only 14–28% of that in the intact plant. In some nodules activity declined steadily, and in others there was a partial recovery in activity ca 10 min after detachment. Infected cell O₂ concentration (O_i), measured by a spectro-photometric technique, also declined after nodule detachment with a time course similar to the declines in nitrogenase activity and respiration. Following excision, O_i levels declined rapidly from ca 21 nM in attached nodules to 8–12 nM at 4–10 min after excision and then more gradually to 2–3 nM O₂ at 30–40 min after excision. These results show that the nodules' permeability to gas diffusion continued to be regulated for up to 40 min after detachement. At 40 min after detachment, when excised nodules displayed steady-state rates of gas exchange, linear increases in pO₂ from 20 to 100% at 4% min^?1 resulted in recoveries of H² and CO² evolution, indicating that O_i limited nitrogenase activity durig this period, and that energy reserves were greatly in excess of the O₂ available for respiration. When detached nodules were equilibrated for 12 h at 20, 30 and 50% O₂, O_i values measured at supra-ambient pO₂ were greater than those at 20% O₂ and were linked with a more rapid decline in nitrogenase activity. Also, increases in external pO₂ (O_c) failed to stimulate nodule metabolism, suggesting that the nodules' energy reserves were no longer greatly in excess of their respiratory demands. It was concluded that soybean nodules could provide useful material for steady-state studies of nodule metabolism between 40 and 240 min after detachment, but to attain metabolic rates equivalent to in vivo rates the nodules must be exposed to above-ambient pO₂.     

Constitutive and inducible aspects of nitrate-nitrogen uptake by Chlamydomonas reinhardtii

Similarly to higher plant root systems, Chlamydomonas reinhardtii Dangeard (UTEX 90) cells exhibited biphasic NO₃^? uptake kinetics. The uptake pattern was similar in cells cultured in 10 mM NO₃^? (NO₃^?-grown), 0.25 mM NO₃^? (N-limited) or 10 mM NO₃^? followed by an 18-h period of N-deprivation (N-starved). In all cell types there was an apparent phase transition in uptake at 1.1 mM NO₃^?, although there were variations in the uptake V_max of both isotherms. The rate of uptake via isotherm 0 ([NO₃^?]<1.1 mM) in N-limited cells was higher than that of either NO₃^?-grown or N-starved cells. In contrast, NO₃^?-grown and N-limited cells exhibited comparable V_max values when supplied with 1.1 to 1.8 mM NO₃^? (isotherm 1). When supplied with 1.6 mM NO₃^?, both N-limited and N-starved cells exhibited enhanced linear uptake after 60 min of incubation. We ascribed this to an induction phenomenon. This trend was not observed when NO₃^?-grown cells were supplied with 1.6 mM NO₃^?, or when N-limited and N-starved cells were supplied with 0.6 mM NO₃^?. The ‘inducible’ aspect of uptake by N-limited cells was blocked by cycloheximide (10 mg l^?1), but not by actinomycin D (5 mg l^?1), thus indicating the involvement of a translational or post-translational event. To investigate this phenomenon further, we analysed the cell proteins of N-limited cells supplied with either 0.6 or 1.6 mM NO₃^? for 90 min, using two-dimensional gel electrophoresis. Comparison of protein profiles enabled the identification of a single cell membrane-associated polypeptide (21 kDa, pI ca 5.5) and ten soluble fraction polypeptides (17–73 kDa, pI ca 5.0 to 7.1) unique to the high NO₃^? treatment. We propose that the ‘inducible’ portion of NO₃^? uptake may provide the means by which C. reinhardtii cells regulate uptake in accordance with assimilatory capacity.     

Correlation between nitrogenase and glutamine synthetase expression in the cyanobacterium Anabaena cylindrical

Distribution pattern and levels of nitrogenase (EC 1.7.99.2) and glutamine synthetase (GS, EC 6.3.1.2) were studied in N₂-, NO₃^? and NH₄⁺ grown Anabaena cylindrica (CCAP 1403/2a) using immunogold electron microscopy. In N₂- and NO₃^? grown cultures, heterocysts were formed and nitrogenase activity was present. The nitrogenase antigen appeared within the heterocysts only and showed an even distribution. The level of nitrogenase protein in the heterocysts was identical with both nitrogen sources. In NO₃^? grown cells the 30% reduction in the nitrogenase activity was due to a corresponding decrease in the heterocyst frequency and not to a repressed nitrogenase synthesis. In NH₄^? grown cells, the nitrogenase activity was almost zero and new heterocysts were formed to a very low extent. The heterocysts found showed practically no nitrogenase protein throughout the cytoplasm, although some label occurred at the periphery of the heterocyst. This demonstrates that heterocyst differentiation and nitrogenase expression are not necessarily correlated and that while NH₄⁺ caused repression of both heterocyst and nitrogenase synthesis, NO₃^? caused inhibition of heterocyst differentiation only. The glutamine synthetase protein label was found throughout the vegetative cells and the heterocysts of all three cultures. The relative level of the GS antigen varied in the heterocysts depending on the nitrogen source, whereas the GS level was similar in all vegetative cells. In N₂- and NO₃⁺ grown cells, where nitrogenase was expressed, the GS level was ca 100% higher in the heterocysts compared to vegetative cells. In NH₄⁺ grown cells, where nitrogenase was repressed, the GS level was similar in the two cell types. The enhanced level of GS expressed in heterocysts of N₂ and NO₃^? grown cultures apparently is related to nitrogenase expression and has a role in assimilation of N₂derived ammonia.     

Effects of increasing inorganic carbon supply to roots on net nitrate uptake and assimilation in tomato seedlings

We investigated the influence of an increased inorganic carbon supply in the root medium on NO^?₃ uptake and assimilation in seedlings of Lycopersicon esculentum (L.) Mill. cv. F144. The seedlings were pre-grown for 4 to 7 days with 0 or 100 mM NaCl in hydroponic culture using 0.2 mM NO^?₃ (group A) or 0.2 mM NH⁺₄ (group B) as nitrogen source. The nutrient solution for group A plants was aerated with air or with air containing 4 800 μumol mol^?1 CO₂. Nitrate uptake rate and root and leaf malate contents in these plants were determined. The plants of group B were subdivided into two sets. Plants of one set were transferred either to N-free solution containing 0 or 5 mM NaHCO₃, or to a medium containing 2 mM NO^?₃ and 5 mM NaHCO₃. Both sets of group B plants were grown for 12 h in darkness prior to 2 h of illumination, and were assayed for malate content and NO^?₃ uptake rate (only for plants grown in N-free solution). The second set of group B plants was labeled with ¹⁴C by a 1-h pulse of H¹⁴CO^?₃ which was added to a 5 mM NaHCO₃ solution containing 0 or 100 mM NaCl and 0 or 2 mM NO^?₃, and ¹⁴C-assimilates were extracted and fractionated. The roots of group B plants growing in carbonated medium accumulated twice as much malate as did control plants. This malate was accumulated only when NO^?₃ was absent from the root medium. Both a high level of root malate and aeration with CO₂-enriched air stimulated NO^?₃ uptake. Analysis of ¹⁴C-assimilates indicated that with no NO^?₃ in the medium, the ¹⁴C was present mainly in organic acids, whereas with NO^?₃, a large proportion of ¹⁴C was incorporated into amino acids. Transport of root-incorporated ¹⁴C to the shoot was enhanced by NO^?₃, while the amino acid fraction was the major ¹⁴C-assimilates in the shoot. It is concluded that inorganic carbon fixed through phosphoenolpyruvate carboxylase (EC 4.1.1.31) in roots of tomato plants may have two fates: (a) as a carbon skeleton for amino acid synthesis; and (b) to accumulate, mainly as malate, in the roots, in the absence of a demand for the carbon skeleton. Inorganic carbon fixation in the root provides carbon skeletons for the assimilation of the NH⁺₄ resulting from NO₃ reduction, and the subsequent removal of amino acids through the xylem. This ‘removal’ of NO^?₃ from the cytoplasm of the root cells may in turn increase NO^?₃ uptake.     

Ammonium assimilation in root nodules of actinorhizal Discaria trinervis. Regulation of enzyme activities and protein levels by the availability of macronutrients (N,P and C)

Asparagine was found to be the main N compound exported from Discaria trinervis nodules. Aspartate (Asp), glutamate (Glu), alanine (Ala) and serine (Ser) were also detected in root xylem sap, but at lower concentrations. A comparable picture is found in nodulated alfalfa. We hypothesized that a similar set of enzymes for Asn synthesis was present in D. trinervis nodules. We demonstrate the expression of most of the enzymes involved in the synthesis of Asn from NH⁺ ₄ and oxoacids, in nodules – but not in roots – of fully symbiotic D. trinervis. By complementation of enzyme assays (^A) and immunodetection (^I) we detected glutamane-synthetase (GS^{A, I}), Asp-aminotransferase (AAT^A), malate-dehydrogenase (MDH^{A, I}, at least two isoforms), Glu-dehydrogenase (GDH^A), Glu-synthase (GOGAT^I) and Asn-synthetase (AS^I). PEP-carboxylase (PEPC) activity was not detected. We previously shown that N acts as a negative regulator of nodulation and nodule growth, while P is a strong stimulator for nodule growth. We present data on the regulation of nodule N metabolism by altering, during 4 weeks, the availability of N, P and light in symbiotic D. trinervis. NH₄NO₃ (2 mM) induced inactivation and degradation of nodule GS, MDH and AS, but activation of GDH and AAT; the amount of nitrogenase components was not affected. A 10-fold increase in P supply did not greatly affect activity and amount of enzymes, suggesting that N metabolism is not P-limited in nodules. On the other hand, suppression of P supply induced an important reduction of nodule GS, GOGAT, MDH and AS protein levels, although nitrogenase was not affected. GDH was the only measured activity that was stimulated by limiting P supply. Shading plants did result in complete degradation of nitrogenase and partial degradation of GS, AS and nodule-specific MDH isoform, but GDH and AAT were activated. These results are discussed in connection with the regulation of nodulation and nodule growth in D. trinervis.     

Metabolite effectors for short-term nitrogen-dependent enhancement of phosphoenolpyruvate carboxylase activity and decrease of net sucrose synthesis in wheat leaves

It has been demonstrated previously that field pea (Pisum sativum L. cv. Express) grown in hydroponic culture on a complete nutrient solution with low NH₄⁺ concentrations (<0.5 mM) will produce a larger than normal proliferation of nodules. Peas grown in the absence of mineral N in hydroponic culture have been shown to rapidly autoregulate nodulation, forming a static nodule number by 14 to 21 days after planting. The present study further characterizes the effect of NH₄⁺ concentration in hydroponic culture on nodulation and nodule growth. Peas were grown continually for 4 weeks at NH₄⁺ concentrations that were autoregulatory (0.0 mM), stimulatory (0.2 mM) or inhibitory (1.0 mM), or peas were transferred between autoregulatory or NH₄⁺ inhibited and stimulatory solutions after 2 weeks. The peas nodulated as expected when grown under constant autoregulatory, stimulatory or inhibitory concentrations of NH₄⁺. When peas were transferred from the inhibitory (1.0 mM) to the stimulatory solution (0.2 mM) a massive proliferation of nodule primordia over the entire root system was observed within 3 days of the transfer. When they were transferred from the autoregulatory (0.0 mM) to the stimulatory (0.2 mM) solution a 10-day delay occurred before a proliferation in nodule primordia occurred at distal regions of the root system. These findings support our hypothesis that low concentrations (<1.0 mM) of NH₄⁺ in hydroponic culture cause a suppression of autoregulation in pea. In addition, the temporal and spatial differences in nodule proliferation between transfer treatments demonstrate at a whole plant level that autoregulation and NH₄⁺ inhibition suppress early nodule development via different mechanisms.     

Does oxygen limit nitrogenase activity in soybean exposed to elevated CO2?

Soybean (Glycine max L. Merr) plants grown under control (360 µmol mol^?1) or elevated CO₂ concentration (800 µmol mol^?1) from 33 to 42 d after sowing were assayed for various components of in vivo nitrogenase activity to test the hypothesis that increasing carbohydrate supply to nodules would increase the potential (i.e. O₂ saturated) nitrogenase activity and impose a more severe O₂ limitation on both nodule metabolism and total nitrogenase activity. Within 51 h of elevated CO₂ treatment, significant increases relative to control plants were seen in total nitrogenase activity expressed per plant. After 6 d of elevated CO₂, the total nitrogenase activity per plant was 18% higher than that in control. This was attributed to an initial increase in nodule size, and a subsequent increase in nodule number following plant exposure to elevated CO₂. However, after 9 d of elevated CO₂, the potential and total nitrogenase activities per gram nodule dry weight were lower, not higher than corresponding values in plants in the control treatment. These results did not support the hypothesis. It was concluded that the metabolic capacity of the control nodules were not limited by carbohydrate supply, at least at the assay temperatures employed here.     

O2 regulation and O2‐limitation of nitrogenase activity in root nodules of pea and lupin

The gas exchange characteristics of intact attached nodulated roots of pea (Pisum sativum cv. Finale X) and lupin (Lupinus albus cv. Ultra) were studied under a number of environmental conditions to determine whether or not the nodules regulate resistance to oxygen diffusion. Nitrogenase activity (H₂ evolution) in both species was inhibited by an increase in rhizosphere pO₂ from 20% to 30%, but recovered within 30 min without a significant increase in nodulated root respiration (CO₂ evolution). These data suggest that the nodules possess a variable barrier to O₂ diffusion. Also, nitrogenase activity in both species declined when the roots were either exposed to an atmosphere of Ar:O₂ or when the shoots of the plants were excised. These declines could be reversed by elevating rhizosphere pO₂, indicating that the inhibition of nitrogenase activity resulted from an increase in gas diffusion resistance and consequent O₂-limitation of nitrogenase-linked respiration. These results indicate that nodules of pea and lupin regulate their internal O₂ concentration in a manner similar to nodules of soybean, despite the distinct morphological and biochemical differences that exist between the nodules of the 3 species. Experiments in which total nitrogenase activity (TNA = H₂ production in Ar:O₂) in pea and lupin nodules was monitored while rhizosphere pO₂ was increased gradually to 100%, showed that the resistance of the nodules to O₂ diffusion maintains nitrogenase activity at about 80% of its potential activity (PNA) under normal atmospheric conditions. The O₂-limitation coefficient of nitrogenase (OLC_N= TNA/PNA) declined significantly with prolonged exposure to Ar:O₂ or with shoot excision. Together, these results indicate a significant degree of O₂-limitation of nitrogenase activity in pea and lupin nodules, and that yields may be increased by realizing full potential activity.     

Involvement of cytokinin in the stimulation of nodulation by low concentrations of ammonium in Pisum sativum

Nodulation in pea (Pisum sativum L.) grown in hydroponic and sand culture systems is stimulated by low concentrations (<1.0 mM) of ammonium, but the physiological mechanisms underlying this stimulation are unknown. The current study involves a series of experiments, which investigate if the ammonium‐induced stimulation of nodulation involves changes in endogenous hormone (auxin and cytokinin) levels. P. sativum L. cv. Express was grown in growth pouches for 1 week with mineral N (0.5 and 2.0 mM NH₄⁺ or NO₃^–) or for 3 weeks exposed to exogenous indole‐3‐acetic acid (IAA) or 6‐benzylaminopurine (BAP) at a range of concentrations (10^‐9?10^‐5 M). Ammonium enhanced nodulation on the basis of both early whole plant (nodules plant^?1) and specific nodulation (nodules g^?1 root DW), especially in 0.5 mM treatment in which nodulation was approximately 4‐fold of the mineral‐N‐free control 1 week after inoculation. Correspondingly, the roots treated with ammonium contained much higher levels of t‐zeatin (Z) and lower t‐zeatin riboside (ZR) than that the control or nitrate‐treated plants. There was no significant difference in IAA levels between the control and ammonium treatments. Exogenous application of BAP for 3 weeks at concentrations of 10^‐7?10^‐5 M strongly inhibited nodulation. However, 10^?9 M BAP, but not IAA, significantly enhanced nodulation. These data support the theory that a relatively high ratio of cytokinin:auxin in roots is favourable for nodule initiation, but that an excessively high level of cytokinin inhibits nodulation. Based on these results we propose that stimulation of nodulation by low concentrations of ammonium may be mediated through increasing Z level in roots, which alters the balance of cytokinin and auxin, which in turn induces cortical cell divisions leading to nodule initiation.     

Changes in NO3− and K+ uptake by four species in flowing solution culture in response to increased irradiance

Net rates of NO₃^? and K⁺ uptake were compared for oilseed rape (Brassica napus L. cv. Jet neuf), perennial ryegrass (Lolium perenne L. cv. S23), Italian ryegrass (Lolium multiflorum Lam. cv. Augusta) and wheat (Triticum aestivum L. cv. Fen-man) in flowing solution culture during a 4-day sequence of low-low-high-high natural irradiance. Concentrations of NO₃^? (10 μM) and K⁺ (2.5 μM) in solutions were maintained automatically and hourly variation in net uptake of these ions was measured. During the 2 days of low irradiance (<1 MJ m^?2 day^?1) the uptake rates of both ions by all species were low at <1 mmol NO₃^?, m^?2 h^?1 and <0.4 mmol K⁺ m^?2 h^?1. Uptake increased in each species during the first day of high irradiance (7.90 MJ m^?2 day^?1) to >4 mmol NO₃^? m^?2 h^?1 and >1.4 mmol K⁺ m^?1 h^?1. These higher rates were maintained throughout the following night. The lag-time between maximum irradiance and the onset of the highest acceleration in uptake was greater for NO₃^? (5–8 h) than for K⁺ (≤1 h) in rape, wheat and Italian ryegrass. Uptake of NO₃^?, by perennial ryegrass showed an almost constant acceleration for 18 h following maximum irradiance. In all species the measured maximum inflows (uptake rate per unit root length) of both ions were greater than theoretical maximum potential inflows to a non-competing infinite-sink root in soil, by factors of 7 and 36, respectively, for NO₃^? and K⁺, averaged over all species.     

Distribution of NO3− reduction between roots and shoots of peachtree seedlings as affected by NO3− uptake rate

The distribution of NO₃^? reduction between roots and shoots was studied in hydro-ponically-grown peach-tree seedlings (Prunus persica L.) during recovery from N starvation. Uptake, translocation and reduction of NO₃^?, together with transport through xylem and phloem of the newly reduced N were estimated, using ¹⁵N labellings, in intact plants supplied for 90 h with 0.5 mM NH₄⁺ and 0.5, 1.5 or 10 mM NO₃^?. Xylem transport of NO₃^? was further investigated by xylem sap analysis in a similar experiment. The roots were the main site of NO₃^? reduction at all 3 levels of NO₃^? nutrition. However, the contribution of the shoots to the whole plant NO₃^? reduction increased with increasing external NO₃^? availability. This contribution was estimated to be 20, 23 and 42% of the total assimilation at 0.5, 1.5 and 10 mM NO₃^?, respectively. Both ¹⁵N results and xylem sap analysis confirmed that this trend was due to an enhancement of NO₃^? translocation from roots to shoots. It is proposed that the lack of NO₃^? export to the shoots at low NO₃^? uptake rate resulted from a competition between NO₃^? reduction in the root epidermis/cortex and NO₃^? diffusion to the stele. On the other hand, net xylem transport of newly reduced N was very efficient since ca 70% of the amino acids synthesized in the roots were translocated to the shoots, regardless of the level of NO₃^? nutrition. This net xylem transport by far exceeded the net downward phloem transport of the reduced N assimilated in shoots. As a consequence, the reduced N resulting from NO₃^? assimilation, principally occurring in the roots, was mainly incorporated in the shoots.     

Nitrite and Nitrate Levels in Individual Molluscan Neurons: Single-Cell Capillary Electrophoresis Analysis

Abstract: Cell and tissue concentrations of NO₂^? and NO₃^? are important indicators of nitric oxide synthase activity and crucial in the regulation of many metabolic functions, as well as in nonenzymatic nitric oxide release. We adapted the capillary electrophoresis technique to quantify NO₂^? and NO₃^? levels in single identified buccal neurons and ganglia in the opisthobranch mollusc Pleurobranchaea californica, a model system for the study of the chemistry of neuron function. Neurons were injected into a 75-µm separation capillary and the NO₂^? and NO₃^? were separated electrophoretically from other anions and detected by direct ultraviolet absorbance. The limits of detection for NO₂^? and NO₃^? were <200 fmol (<4 µM in the neurons under study). The NO₂^? and NO₃^? levels in individual neurons varied from 2 mM (NO₂^?) and 12 mM (NO₃^?) in neurons histochemically positive for NADPH-diaphorase activity down to undetectable levels in many NADPH-diaphorase-negative cells. These results affirm the correspondence of histochemical NADPH-diaphorase activity and nitric oxide synthase in molluscan neurons. NO₂^? was not detected in whole ganglion homogenates or in hemolymph, whereas hemolymph NO₃^? averaged 1.8 ± 0.2 × 10^?3M. Hemolymph NO₃^? in Pleurobranchaea was appreciably higher than values measured for the freshwater pulmonate Lymnaea stagnalis (3.2 ± 0.2 × 10^?5M) and for another opisthobranch, Aplysia californica (3.6 ± 0.7 × 10^?4M). Capillary electrophoresis methods provide utility and convenience for monitoring NO₂^?/NO₃^? levels in single cells and small amounts of tissue.     

Nodule physiology of a supernodulating pea mutant

Physiological and biochemical parameters of the supernodulating pea (Pisum sativum L.) mutant nod₃ were compared to those of its wild-type parent cv. Rondo in a nil nitrate environment. Plants of cv. Rondo produced more biomass and accumulated more N than plants of nod₃. Accordingly, seed yield of the wild type was twice that of the supernodulating mutant. Although the nodule number of nod₃ was 10-fold that of cv. Rondo, the nodule mass of nod₃ was only twice that of cv. Rondo as individual nodules were smaller in nod₃ than in cv. Rondo. The maximum rate of acetylene reduction activity, determined in an open flow-through gas system, was higher in the wild type than in nod₃ when expressed on a nodule dry weight basis. However, when expressed on a whole plant basis, the nitrogenase activity (acetylene reduction) was similar in the two symbioses. The net carbon costs of nitrogenase activity was 25% lower in nod₃ than in cv. Rondo. An equal proportion of the net CO₂ efflux from the root system was for growth and maintenance of the tissue in the two symbioses. However, growth and maintenance respiration was higher in nod₃ than in cv. Rondo per gram dry weight of the nodulated root system. The nodules of nod₃ had a reduced soluble protein concentration as compared to those of the wild type. The specific activities of nodule glutamine synthetase (EC 6.3.1.2), glutamate synthase (EC 1.4.1.14) and asparagine synthetase (EC 6.3.5.4) were lower in nod₃ than in cv. Rondo. The root bleeding sap of nod₃ contained lower amounts of glutamine and higher amounts of asparagine than that of cv. Rondo. The results suggest that the use of carbon directly related to the dinitrogen fixation and nitrogen assimilation may be less in nod₃ than in cv. Rondo, and that there may be differences between the two symbioses in the pathway for assimilation of fixed nitrogen.     

The nitrogen balance of Raphanus sativus X raphanistrum plants. I. Daily nitrogen use under high nitrate supply

Abstract Growth-chamber cultivated Raphanus plants accumulate nitrate during their vegetative growth. After 25 days of growth at a constant supply to the roots of 1 mol m^?3 (NO^?₃) in a balanced nutrient solution, the oldest leaves (eight-leaf stage) accumulated 2.5% NO^?₃-nitrogen (NO₃-N) in their lamina, and almost 5% NO₃-N in their petioles on a dry weight basis. This is equivalent to approximately 190 and 400 mol^?3 m^?3 concentration of NO^?₃ in the lamina and the petiole, respectively, as calculated on a total tissue water content basis. Measurements were made of root NO^?₃ uptake, NO^?₃ fluxes in the xylem, nitrate uptake by the mesophyll cells, and nitrate reduction as measured by an in vivo test. NO^?₃ uptake by roots and mesophyll cells was greater in the light than in the dark. The NO^?₃ concentration in the xylem fluid was constant with leaf age, but showed a distinct daily variation as a result of the independent fluxes of root uptake, transpiration and mesophyll uptake. NO^?₃ was reduced in the leaf at a higher rate in the light than in the dark. The reduction was inhibited at the high concentrations calculated to exist in the mesophyll vacuoles, but reduction continued at a low rate, even when there was no supply from the incubation medium. Sixty-four per cent of the NO^?₃ influx was turned into organic nitrogen, with the remaining NO^?₃ accumulating in both the light and the dark.     

Stimulation of nitrogenase activity and photosynthesis in some cyanobacteria by glyoxylate

Abstract The effect og glyoxylate on nitrogenase activity (C₂H₂ reduction) and photosynthesis (H¹⁴CO₃ fixation and O₂ evolution) was in vestigated in the three heterocystous cyanobacteria Anabaena cylindrica, A. variabiltis and N. muscorum. Glyoxylate had virtually no effect on the rate of dark respiration and was unable to sustain photoheterotrophic growth, though some slight stimulation (= 30%) of photorophic growth was noted. A considerable stimulation of both nitrogenase and photosynthetic activities was observed in presence of glyoxylate. In the light the stimulation increased with time up to about 15-25 h after adding optimal concentrations of 4–6 mM glyoxylate. Placing glyoxylate treated samples in the dark or adding DCMU (30 μM) in the light, showed that glyoxylate initially supported significantly higher nitrogenase activity than did samples in absence of glyoxylate. However, after a prolonged incubation in the dark or in presence of DCMU glyoxylate is unable to relieve the adverse effects of such conditions. The stimulation of the nitrogenase activity was even more pronounced when the glyoxylate was added to cells preincubated in the dark (“carbon starved”) than for cells kept constantly in light. The results suggest that glyoxylate, or a metabolite, may act as an inhibitor of cyanobacterial photorespiration and this hypothesis is discussed.