Relationship between N(2)-Fixing Efficiency and Natural N Enrichment of Soybean Nodules

Non-nodular tissue of soybean (Glycine max L. Merrill) plants grown hydroponically in the absence of added N have a ¹⁵N abundance close to that of atmospheric N₂. In contrast, nodules are usually enriched in ¹⁵N. In this paper, we report measurements of the ¹⁵N abundance of foliar tissue and nodules of soybeans inoculated with 11 variably efficient strains of Rhizobum japonicum and grown hydroponically with no added N. The efficiency of the 11 symbioses varied over a wide range as judged by a 16-fold difference in N content. The degree of ¹⁵N enrichment of nodules was closely correlated with N₂-fixing efficiency (milligrams N fixed per milligram N in the nodules).

These results confirm prior preliminary data based on six variably efficient R. japonicum strains. The strong correlation between ^NN enrichment of soybean nodules and N₂-fixing efficiency is consistent with the hypothesis that new nodule tissue is synthesized from a pool of recently fixed N within the same nodule.

     

Distribution of N within Pea, Lupin, and Soybean Nodules

The ¹⁵N abundance of some, but not all, legume root nodules is significantly elevated compared to that of the whole plant. It seems probable that differences in ¹⁵N enrichment reflect differences in the assimilatory pathway of fixed N. In that context, we have determined the distribution of naturally occurring ¹⁵N in structural fractions of nodules from soybean (Glycine max L. Merr.), yellow lupin (Lupinus luteus), and pea (Pisum sativum) nodules and in chemical components from soybean nodules and to a lesser extent, pea and lupin nodules. None of the fractions of pea nodules (cortex, bacteriod, or host plant cytoplasm) was enriched in ¹⁵N. The differences among bacteriods, cortex, and plant cytoplasm were smaller in lupin than in soybean nodules, but in both, bacteriods had the highest ¹⁵N enrichment. In soybean nodules, the ¹⁵N abundance of bacteriods and cortex was higher than plant cytoplasm, but all three fractions were more enriched in ¹⁵N than the entire plant. Plant cytoplasm from soybean nodules was fractionated into protein-rich material, nonprotein alcohol precipitable material (NA), and a low molecular weight fraction. The N of the latter was further separated into N of ureides, nucleotides and free amino acids. Most of these components were either similar to or lower in ¹⁵N abundance than the plant cytoplasm as a whole, but the NA fraction showed unusual ¹⁵N enrichment. However, the percentage of nodule N in this fraction was small. NA fractions from yellow lupin and pea nodules and from soybean leaves were not enriched in ¹⁵N. Nor was the NA fraction in ruptured bacteriods and cortical tissue of soybean nodules. Variation among soybean nodule fractions in the preponderance in protein of different amino acids was not large enough to explain the differences in ¹⁵N abundances among them. A hypothesis, consistent with all known data, concerning the mechanism leading to the observed excess ¹⁵N of lupin and soybean bacteriods is offered.     

Site of natural N enrichment of soybean nodules

Soybean (Glycine max L. Merrill) nodules are usually more enriched in ¹⁵N than other tissues. We show that both bacteroids and nodule cortex are considerably more enriched in ¹⁵N than nodule cytosol, with bacteroids being slightly more enriched than the cortex. Hence, ¹⁵N enrichment occurs in cells of both plant and bacterial origin.     

Pathways of Nitrogen Assimilation in Cowpea Nodules Studied using N(2) and Allopurinol

In the presence of 0.5 millimolar allopurinol (4-hydroxypyrazolo [3,4-d]pyrimidine), an inhibitor of NAD:xanthine oxidoreductase (EC 1.2.3.2), intact attached nodules of cowpea (Vigna unguiculata L. Walp. cv Vita 3) formed [¹⁵N]xanthine from ¹⁵N₂ at rates equivalent to those of ureide synthesis, confirming the direct assimilation of fixed nitrogen into purines. Xanthine accumulated in nodules and was exported in increasing amounts in xylem of allopurinol-treated plants. Other intermediates of purine oxidation, de novo purine synthesis, and ammonia assimilation did not increase and, over the time course of experiments (4 hours), allopurinol had no effect on nitrogenase (EC 1.7.99.2) activity. Negligible ¹⁵N-labeling of asparagine from ¹⁵N₂ was observed, suggesting that the significant pool (up to 14 micromoles per gram of nodule fresh weight) of this amide in cowpea nodules was not formed directly from fixation but may have accumulated as a consequence of phloem delivery.     

l-Ascorbic Acid Biosynthesis in Ochromonas danica

This paper expands upon previous reports of ¹⁵N elevation in nodules (compared to other tissues) of N₂-fixing plants. N₂-Fixing nodules of Glycine max (soybeans), Vigna unguiculata (cowpea), Phaseolus vulgaris (common bean), Phaseolus coccineus (scarlet runner bean), Prosopis glandulosa (mesquite), and Olneya tesota (desert ironwood) were enriched in ¹⁵N. Nodules of Vicia faba (fava beans), Arachis hypogaea (peanut), Trifolium pratense (red clover), Pisum sativum (pea), Lathyrus sativus (grass pea), Medicago sativa (alfalfa), and Lupinus mutabilis (South American lupine) were not; nor were the nodules of nine species of N₂-fixing nonlegumes. The nitrogen of ineffective nodules of soybeans and cowpeas was not enriched in ¹⁵N. Thus, ¹⁵N elevation in nodules of these plants depends on active N₂-fixation. Results obtained so far on the generality of ¹⁵N enrichment in N₂-fixing nodules suggest that only the nodules of plants which actively fix N₂ and which transport allantoin or allantoic acid exhibit ¹⁵N enrichment.     

The effect of ammonium nitrate on the synthesis of nitrogenase and the concentration of leghemoglobin in pea root nodules induced by Rhizobium leguminosarum

The effects of NH₄NO₃ on the development of root nodules of Pisum sativum after infection with Rhizobium leguminosarum (strain PRE) and on the nitrogenase activity of the bacteriods in the nodule tissue were studied. The addition of NH₄NO₃ decreased the nitrogenase activity measured on intact nodules. This reduction of nitrogen fixation did not result from a reduced number of bacteroids or a decreased amount of bacteroid proteins per gram of nodule. The synthesis of nitrogenase, measured as the relative amount of incorporation of [³⁵S]sulfate into the components I and II of nitrogenase was similarly not affected.The addition of NH₄NO₃ decreased the amount of leghemoglobin in the nodules and there was a quantitative correlation between the leghemoglobin content and the nitrogen-fixing capacity of the nodules. The conclusion is that the decrease of nitrogen-fixing capacity is caused by a decrease of the leghemoglobin content of the root nodules and not by repression of the nitrogenase synthesis.     

Allantoin and Allantoic Acid in the Nitrogen Economy of the Cowpea (Vigna unguiculata [L.] Walp.)

The ureides, allantoin and allantoic acid, represented major fractions of the soluble nitrogen pool of nodulated plants of cowpea (Vigna unguiculata [L.] Walp. cv. Caloona) throughout vegetative and reproductive growth. Stem and petioles were the principal sites of ureide accumulation, especially in early fruiting.

Labeling studies using ¹⁴CO₂ and ¹⁵N₂ and incubation periods of 25 to 245 minutes indicated that synthesis of allantoin and allantoic acid in root nodules involved currently delivered photosynthate and recently fixed N, and that the ureides were exported from nodule to shoot via the xylem. From 60 to 80% of xylem-borne N consisted of ureides; the remainder was glutamine, asparagine, and amino acids. Allantoin predominated in the soluble N fraction of nodules and fruits, allantoin and allantoic acid were present in approximately equal proportions in xylem exudate, stems, and petioles.

Extracts of the plant tissue fraction of nitrogen-fixing cowpea nodules contained glutamate synthase (EC 2.6.1.53) and glutamine synthetase (EC 6.3.1.2), but little activity of glutamate dehydrogenase (EC 1.4.1.3). High levels of uricase (EC 1.7.3.3) and allantoinase (EC 3.5.2.5) were also detected. Allantoinase but little uricase was found in extracts of leaflets, pods, and seeds.

Balance sheets were constructed for production, storage, and utilization of ureide N during growth. Virtually all (average 92%) of the ureides exported from roots was metabolized on entering the shoot, the compounds being presumably used as N sources for protein synthesis.

     

Nitrogen fixation efficiency,natural15N abundance,and morphology of mesquite (Prosopis glandulosa) root nodules

Summary The relative nitrogen fixation efficiencies (RE 1-[H₂ evolved÷C₂H₂ reduced]·100) of four mesquite (Prosopis glandulosa var.torreyana) rhizobia (Strains WR 1001, WR 1002, L5, L9) and a cowpea rhizobia (Strain 176A32) on mesquite were evaluated in a glasshouse experiment. Plant yield, shoot N accumulation, and the natural¹⁵N abundance (¹⁵N) of nodule tissue were determined. Strain WR 1002 failed to nodulate mesquite and strain L5 produced ineffective nodules. Among the three effective strains (WR 1001, L9, 176A32) the cowpea strain (176A32) and strain L9 had significantly higher RE than strain WR 1001. Differences in RE, however, were not accompanied by significantly higher plant yield and shoot N accumulation. The difference in¹⁵N abundance between foliar tissue and nodules (nodules minus leaves) was 0.47 ¹⁵N for the ineffective L5 nodules, while for the effective WR 1001, L9, and 176A32 nodules, respectively, this difference was 8.35, 7.81, and 8.35 ¹⁵N. This indicates a similar relationship between N₂-fixing effectiveness and natural¹⁵N enrichment of nodules that was previously observed in soybeans (Glycine max, L. Merr.). Strains WR 1001 and L9 produced elongate, indeterminate nodules typical for mesquite. The ineffective L5 nodules had few infected cells and an abundance of cortical amyloplasts. Mesquite nodules produced by the cowpea strain were spherical and were somewhat more similar in internal morphology to determinate nodules typical of cowpea than indeterminate nodules normally associated with mesquite.     

Natural abundance of 15N in actinorhizal plants and nodules

Substantial enrichment of some plant parts in ¹⁵N relative to the rest of the plant is unusual, but is found in the nitrogen-fixing nodules of many legumes. A range of actinorhizal plants was surveyed to determine whether the nodules of any of them are also substantially enriched in ¹⁵N. The nonlegume Parasponia, nodulated by a rhizobium, was also included. Four of the actinorhizal genera and Parasponia were grown in N-free culture, and three actinorhizal genera were collected from the field. Nodules of Parasponia, Casuarina and Alnus were¹⁵N enriched relative to other plant parts, but only Parasponia approached the degree of enrichment found in some legume nodules. The nodules of Datisca, Myrica, Elaeagnus, Shepherdia, and Coriaria were depleted in ¹⁵N. Thus many actinorhizal nodules are depleted in ¹⁵N compared to other plant parts and enrichment is modest when it does occur. Whole plant ¹⁵N content (¹⁵N) in four actinorhizal plants and Parasponia showed a relatively narrow range of –1.41 to –1.90. Hence regardless of the degree of nodule enrichment or depletion, whole plant ¹⁵N content appears to vary little in plants grown in N-free culture.     

Effect of form and level of applied nitrogen on nitrogenase and nitrate reductase activities in faba beans

The effects of nitrogen applied at increasing levels of 0, 4, 8, 16 and 32 mM N (KNO₃ or NH₄Cl) were studied in faba bean (Vicia faba) nodulated byRhizobium leguminosarum bv.viceae RCR lool. Nitrogenase activity was higher at 4 and 8 mM N than the zero N treatment (control), but 16 and 32 mM N significantly reduced the efficiency of nodule functions. Nitrate reductase activities (NRA) of leaves, stems, roots, nodules and nodule fractions (bacteroid and cytosol) were increased with rising the NO₃ ^? or NH₄ ⁺ levels. NRA decreased in the order of nodules>leaves>stems>roots. Cytosolic NR was markedly higher than that recorded in the bacteroid fractions. Nitrate levels were linearly correlated to NRA of nodules. Accumulation of NO₂ ^? within nodules suggests that NO₂ ^? inhibits nodule’s activity after feeding plants with NO₃ ^? or NH₄ ⁺.     

Discrimination against 15N among recombinant inbred lines of Phaseolus vulgaris L. contrasting in phosphorus use efficiency for nitrogen fixation

Although isotopic discrimination processes during nitrogen (N) transformations influence the outcome of ¹⁵N based quantification of N₂ fixation in legumes, little attention has been given to the effects of genotypic variability and environmental constraints such as phosphorus (P) deficiency, on discrimination against ¹⁵N during N₂ fixation. In this study, six Phaseolus vulgaris recombinant inbred lines (RILs), i.e. RILs 115, 104, 34 (P deficiency tolerant) and 147, 83, 70 (P deficiency sensitive), were inoculated with Rhizobium tropici CIAT899, and hydroaeroponically grown with P-sufficient (250 μmol P plant⁻¹ week⁻¹) versus P-deficient (75 μmol P plant⁻¹ week⁻¹) supply. Two harvests were done at 15 (before nodule functioning) and 42 (flowering stage) days after transplanting. Nodulation, plant biomass, P and N contents, and the ratios of ¹⁵N over total N content (¹⁵N/Nt) for shoots, roots and nodules were determined. The results showed lower ¹⁵N/Nt in shoots than in roots, both being much lower than in nodules. P deficiency caused a larger decrease in ¹⁵N/Nt in shoots (−0.18%) than in nodules (−0.11%) for all of the genotypes, and the decrease in shoots was greatest for RILs 34 (−0.33%) and 104 (−0.25%). Nodule ¹⁵N/Nt was significantly related to both the quantity of N₂ fixed (R² = 0.96***) and the P content of nodules (R² = 0.66*). We conclude that the discrimination against ¹⁵N in the legume N₂-fixing symbiosis of common bean with R. tropici CIAT899 is affected by P nutrition and plant genotype, and that the ¹⁵N/Nt in nodules may be used to screen for genotypic variation in P use efficiency for N₂ fixation.     

Economy of Photosynthate Use in Nitrogen-fixing Legume Nodules: Observations on Two Contrasting Symbioses

The economy of C use by root nodules was examined in two symbioses, Vigna unguiculata (L.) Walp. (cv. Caloona):Rhizobium CB756 and Lupinus albus L. (cv. Ultra):Rhizobium WU425 over a 2-week period in early vegetative growth. Plants were grown in minus N water culture with cuvettes attached to the nodulated zone of their primary roots for collection of evolved CO₂ and H₂. Increments in total plant N and in C and N of nodules, and C:N weight ratios of xylem and phloem exudates were studied by periodic sampling from the plant populations. Itemized budgets were constructed for the partitioning and utilization of C in the two species. For each milligram N fixed and assimilated by the cowpea association, 1.54 ± 0.26 (standard error) milligrams C as CO₂ and negligible H₂ were evolved and 3.11 milligrams of translocated C utilized by the nodules. Comparable values for nodules of the lupin association were 3.64 ± 0.28 milligrams C as CO₂, 0.22 ± 0.05 milligrams H₂, and 6.58 milligrams C. More efficient use of C by cowpea nodules was due to a lesser requirement of C for synthesis of exported N compounds, a smaller allocation of C to nodule dry matter, and a lower evolution of CO₂. The activity of phosphoenolpyruvate carboxylase in nodule extracts and the rate of ¹⁴CO₂ fixation by detached nodules were greater for the cowpea symbiosis (0.56 ± 0.06 and 0.22 milligrams C as CO₂ fixed per gram fresh weight per hour, respectively) than for the lupin 0.06 ± 0.02 and 0.01 milligrams C as CO₂ fixed per gram fresh weight per hour. The significance of the data was discussed in relation to current information on theoretical costs of nitrogenase functioning and associated nodule processes.     

Symbiotic functioning,structural adaptation,and subcellular organization of root nodules from <Emphasis Type="Italic">Psoralea pinnata</Emphasis> (L.) plants grown naturally under wetland and upland conditions in the Cape Fynbos of South Africa

In the Cape Fynbos of South Africa, Psoralea pinnata (L.) plants occur naturally in both wetland and well-drained soils and yet effectively fix N₂ under the two contrasting conditions. In this study, nodule structure and functioning in P. pinnata plants from the two habitats were evaluated using light and transmission electron microscopy (TEM), as well as the ¹⁵N natural abundance technique. The results showed that, structurally, fully developed P. pinnata nodules were spherical in shape with six components (namely, lenticels, periderm, outer cortex, middle cortex, inner cortex, and a central bacteria-infected medulla region). Morphometric analysis revealed 44 and 84 % increase in cell area and volume of wetland nodules compared to those from upland. The percentage area of nodules occupied by the middle cortex in wetland nodules was twice that of upland nodules. As a result, the size of the medulla region in wetland nodules was significantly reduced compared to upland nodules. Additionally, the average area of medulla occupied by intercellular air spaces in wetland nodules was about five times that of upland nodules (about 431 % increase in wetland over upland nodules). TEM data also showed more bacteroids in symbiosomes of upland nodules when compared to wetland nodules. However, isotopic analysis of above-ground plant parts revealed no differences in symbiotic parameters such as N concentration, ?¹⁵N and %Ndfa between wetland and upland P. pinnata plants. These results suggest that, under limiting O₂ conditions especially in wetlands, nodules make structural and functional adjustments to meet the O₂ demands of N₂-fixing bacteroids.     

Carbon Dioxide Fixation by Lupin Root Nodules: I. Characterization, Association with Phosphoenolpyruvate Carboxylase, and Correlation with Nitrogen Fixation during Nodule Development

In vivo CO₂ fixation and in vitro phosphoenolpyruvate (PEP) carboxylase levels have been measured in lupin (Lupinus angustifolius L.) root nodules of various ages. Both activities were greater in nodule tissue than in either primary or secondary root tissue, and increased about 3-fold with the onset of N₂ fixation. PEP carboxylase activity was predominantly located in the bacteroid-containing zone of mature nodules, but purified bacteroids contained no activity. Partially purified PEP carboxylases from nodules, roots, and leaves were identical in a number of kinetic parameters. Both in vivo CO₂ fixation activity and in vitro PEP carboxylase activity were significantly correlated with nodule acetylene reduction activity during nodule development. The maximum rate of in vivo CO₂ fixation in mature nodules was 7.9 nmol hour⁻¹ mg fresh weight⁻¹, similar to rates of N₂ fixation and reported values for amino acid translocation.     

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.     

Probable site of allantoin formation in nodulating soybean plants

Nodulated soybean plants contain high concentration of allantoin in all parts. Excision of nodules from the roots brought about a marked decrease in allantoin. To examine the function of nodules in allantoin production, nodulated and nodule-detached soybeans were fed with ¹⁵NH₃ for 1 week. High abundance of ¹⁵N was found in the amino acid-N fraction of both plants. In the root and stem of the nodulated plants, ca 80% of the nitrogen in this fraction was derived from the NH₃ added in the medium. Excess ¹⁵N was detected also in allantoin-N fraction, but the ¹⁵N content was very low in contrast to that in amino acid-N fraction. The site involved in the allantoin formation and the possible significance of its synthesis are discussed in relation to symbiotic nitrogen fixation.     

THE EFFECT OF CO2 ENRICHMENT ON ROOT NODULE DEVELOPMENT AND SYMBIOTIC N2 REDUCTION IN PISUM SATIVUM L.

A very significant increase in N₂(C₂H₂) reduction by Visum sativum L. infected with Rhizobium leguminosarum occurred when plants were grown in the light with 6 hr of CO₂ enrichment (0.00120 atm). Plants grown for 4 wk under 0.00120 atm CO₂ showed significant increases over control plants at 0.00032 atm CO₂ in plant dry weight, N content, root nodule mass, number of nodules, and mean nodule dry weight. Acetylene-reduction assays, however, revealed no reproducible increase in nitrogenase activity/mg nodule in plants subjected to long-term CO₂ enrichment. Both control and CO₂-enriched plants optimized the sink/source ratio between the mass of nodules and the extranodular plant mass. The optimum ratio for N₂ reduction by 4-week-old peas was 0.05. Long-term CO₂ enrichment did not promote root nodule formation to a greater degree than total plant development, and increases in N content were directly proportional to increases in nodule mass. Morphological data revealed significantly greater deposits of starch in root nodules of plants grown under CO₂-enriched conditions. The results are interpreted as showing that short-term increases in CO₂ levels promote N₂ reduction by affecting root nodule functioning, whereas long-term CO₂ enrichment promotes N₂ reduction by increasing total plant and root nodule development.     

Temporal Relationships between Nitrogenase and Intercellular Glycoprotein in Developing White Lupin Nodules

The development of the N₂-fixing symbiosis between white lupin (Lupinus albusL.) cv. Multolupa andBradyrhizobiumstrain ISLU16 was followed using the acetylene reduction assay (ARA), immunoblots of protein extracts, and microscopy/immunogold labelling at 0, 8, 12, 17 and 20 d after infection. There was no ARA at 0, 8 and 12 d, although macroscopically visible nodule primordia had formed on roots by 8 d. The lack of nitrogenase at these times was confirmed by a negative signal to immunogold labelling with nitrogenase-specific antibodies. At 17 d three out of six plants had ARA, and nodules from these gave a positive signal with the nitrogenase antibody. By contrast, ARA⁻(fix⁻) nodules at 17 d were smaller (mean radius of 0.49 mm compared to 1.01 mm with fix⁺nodules) and gave a negative signal with the nitrogenase antibody. Western blots of nodule protein extracts using the monoclonal antibodies MAC236 and MAC265 (which recognize two epitopes on a glycoprotein which is considered to be involved in both rhizobial infection and the regulation of nodule oxygen diffusion) gave a strong signal with nodules (fix⁺) from 20 d plants and with 17 d fix⁺plants. The signal with MAC236/MAC265 was substantially weaker with nodules from 17 d fix⁻plants, and there was no signal apparent from nodules/nodulated roots from the 0, 8 and 12 d harvests. However, further investigation using immunogold labelling revealed that not only were MAC236 and MAC265 expressed within cortical intercellular spaces in 20 d and 17 d fix⁺/fix⁻nodules, but they were also strongly expressed in the developing cortex surrounding the newly-infected tissue in 8 d nodules, as well as in intercellular spaces within the cortex and infected tissue of 12 d nodules. These data demonstrate that the glycoprotein recognized by MAC236 and MAC265 is present before the onset of nitrogenase expression and function, but expression of the epitopes appears to be enhanced from the onset of N₂fixation. Nodules at all harvests were investigated for the presence of infection threads, as the MAC236/MAC265-recognized glycoprotein is also a component of the infection thread matrix in nodules from other legumes. Infection threads were not seen in nodules from any of the harvests except for the 20 d nodules, and then only after serial sectioning. The latter revealed occasional short wide infection threads entering and releasing rhizobia into small pockets of uninfected cells, within the infected tissue, but not within the meristems. The matrix of these infection threads labelled weakly, or not at all, with MAC236 and MAC265, and it was concluded that the majority of the MAC236/MAC265 detected in lupin nodule extracts originated from glycoprotein within cortical intercellular spaces.     

Nonphotosynthetic CO(2) Fixation by Alfalfa (Medicago sativa L.) Roots and Nodules

The dependence of alfalfa (Medicago sativa L.) root and nodule nonphotosynthetic CO₂ fixation on the supply of currently produced photosynthate and nodule nitrogenase activity was examined at various times after phloem-girdling and exposure of nodules to Ar:O₂. Phloemgirdling was effected 20 hours and exposure to Ar:O₂ was effected 2 to 3 hours before initiation of experiments. Nodule and root CO₂ fixation rates of phloem-girdled plants were reduced to 38 and 50%, respectively, of those of control plants. Exposure to Ar:O₂ decreased nodule CO₂ fixation rates to 45%, respiration rates to 55%, and nitrogenase activities to 51% of those of the controls. The products of nodule CO₂ fixation were exported through the xylem to the shoot mainly as amino acids within 30 to 60 minutes after exposure to ¹⁴CO₂. In contrast to nodules, roots exported very little radioactivity, and most of the ¹⁴C was exported as organic acids. The nonphotosynthetic CO₂ fixation rate of roots and nodules averaged 26% of the gross respiration rate, i.e. the sum of net respiration and nonphotosynthetic CO₂ assimilation. Nodules fixed CO₂ at a rate 5.6 times that of roots, but since nodules comprised a small portion of root system mass, roots accounted for 76% of the nodulated root system CO₂ fixation. The results of this study showed that exposure of nodules to Ar:O₂ reduced nodule-specific respiration and nitrogenase activity by similar amounts, and that phloem-girdling significantly reduced nodule CO₂ fixation, nitrogenase activity, nodule-specific respiration, and transport of ¹⁴C photoassimilate to nodules. These results indicate that nodule CO₂ fixation in alfalfa is associated with N assimilation.     

Spatial distribution and biomass of root nodules in a naturally regenerated stand of Alnus hirsuta (Turcz.) var. sibirica

To estimate nodule biomass of Alnus hirsuta var. sibirica, an N₂-fixing tree species, we examined the distribution pattern and size structure of nodules in a 17 to 18 year old stand naturally regenerated after disturbance by road construction in Japan. Nodules were harvested within 1 m from the outer edge of stems of plants with different sizes on four occasions from June to October. The diameter of the subtending root at the base of each nodule and nodule dry weight were measured in 20 cm increments outwards from the base of each stem. Horizontal distribution of nodules around each tree varied greatly among tree diameters at 1.3 m (dbh) within the even-aged stand. In particular, smaller individuals had a concentrated distribution of nodules close to the stem. Nodule abundance occurred further from the stems with increasing tree size. Nodule biomass within 1 m from the outer edge of individual stems increased with tree size ([nodule biomass] = 0.442 [dbh]^2.01, R ²?=?0.747, P?<?0.05). By using the relationship, nodule biomasses were estimated to be 84.1 kg ha^?1. These results suggest that it is necessary to take into account tree size and patterns of tree distribution in nodule biomass estimates.