A rapid non-destructive assay to quantify soybean nodule gas permeability

The low gas permeability of a diffusion barrier in the cortex of soybean nodules plays a significant role in the protection of nitrogenase from oxygen inactivation. It may also set an upper limit on nodule respiration and nitrogen fixation rates. Two methods which have been used to quantify the gas permeability of leguminous nodules are reviewed and found to be unreliable. A new assay technique for determining both the nodule activity and gas permeability is developed and tested. This ‘lag-phase’ assay is based on the time nodules require to reach steady-state ethylene production after being exposed to acetylene. The technique is rapid, insensitive to errors in biochemical parameters associated with nitrogenase, and is non-destructive. The method was tested with intact aeroponically grown soybean plants for which the mean nodule gas permeability was found to be 13.3×10⁻³ mms⁻¹. This corresponds to a layer of cells approximately 35 um thick and is consistent with previously reported values.     

Heterotrophic nitrogen fixation (acetylene reduction) associated to flooded rice: A modified measurement technique in the field

A modifiedin situ technique for measuring heterotrophic nitrogen fixing (acetylene reducing) activity associated to rice is proposed. Ethylene evolution rates measured in opaque cylinders covering the stems of rice plants which have been cut 10 cm over the water level were found independent of the diurnal cycle. Cutting of the leaves resulted in decreased variation between plants and suppression of the acceleration of ethylene evolution rate after 12 h incubation as compared to intact plants. In both systems ethylene evolved was swept by a current of methane and the molar ratio between methane and ethylene was stabilized after 12 h. Methane evolution rates remained stable during 12 h and more than 24 h in whole plants and cut plants respectively. It is suggested that alteration in the active gas transport system after 12 h incubation under 10% acetylene may lead to erroneous evaluation of the actual ethylene production in the root's environment. The average values of ethylene evolution rates by cut plants between 12 and 24 h of incubation may be used for comparative studies of nitrogen fixing activity associated to flooded rice.     

Effect of plant genotype and nitrogen fertilizer on symbiotic nitrogen fixation by soybean cultivars

Summary Isotopic as well as non-isotopic methods were used to assess symbiotic nitrogen fixation within eight soybean [Glycine max (L.) Merr.] cultivars grown at 20 and 100 kg N/ha levels of nitrogen fertilizer under field conditions.The¹⁵N methodology revealed large differences between soybean cultivars in their abilities to support nitrogen fixation. In almost all cases, the application of 100 kg N/ha resulted in lower N₂ fixed in soybean than at 20 kg N/ha in the first year of the study. However, N₂ fixed in one cultivar, Dunadja, was not significantly affected by the higher rate of N fertilizer application. These results were confirmed by measurements of acetylene reduction activity, nodule dry weight and N₂ fixed as measured by the difference method. Further proof of differences in N₂ fixed within soybean cultivars and the ability of Dunadja to fix similar amounts of N₂ at 20 and 100 kg N/ha was obtained during a second year experiment. Dunadja yield was affected by N fertilizer and produced larger yield at 100 kg N/ha than at 20 kg N/ha. This type of cultivar could be particularly useful in situations where soil N levels are high or where there is need to apply high amounts of N fertilizer.The present study reveals the great variability between legume germplasms in the ability to fix N₂ at different inorganic N levels, and also the potential that exists in breeding for nitrogen fixation associative traits. The¹⁵N methodology offers a unique tool to evaluate germplasms directly in the field for their N₂ fixation abilities at different N fertilizer levels.     

Absence of nitrogen fixation (acetylene reduction) by procaryotes in nectar of Banksias

Summary An earlier hypothesis that blue-green algae in the nectar ofBanksia telmatiaea contribute to the nitrogen economy of the host by fixing N₂ was tested. Field and laboratory experiments failed to demonstrate C₂H₄ production in C₂H₂-treated containers over extended periods. Soil N was not higher at the end of the flowering season and plants in which flower heads were removed prior to nectar production did not contain less N than the controls.     

A comparison between the acetylene reduction method,the isotope dilution method and the total nitrogen difference method for measuring nitrogen fixation in lucerne (Medicago sativa L.)

Summary In view of the increasing need for the exact estimation of the input of nitrogen in agroecosystems, an application of the acetylene-reduction technique was developed. The technique, consisting of a plastic bag incubation system, using propane as an internal standard of the apparent volume, made it possible to carry out repeated incubations on the same plant system. The evaluated technique included studies of the diffusion of ethylene and propane in a soil column, as well as studies of the optimal substrate concentration and grade of purity of the substrate. In addition, the conversion factor between amounts of reduced acetylene as compared wtih reduced dinitrogen was determined by¹⁵N₂ incubations to be 4.41. The developedin situ acetylene-reduction technique was compared with an isotope dilution method and a total nitrogen difference method. By comparing the derived total nitrogen fixation values from each with the value derived from the acetylene-reduction method; it was shown that the values differed significantly. The acetylene-reduction method gave the highest nitrogen fixation values, the isotope dilution the lowest values and the total nitrogen difference method was intermediate. No statistical significant difference existed between the two different reference crops used in the isotope dilution method.     

A pellet method to demonstrate nitrogen fixation by free-living rhizobia

Summary A method is described to demonstrate nitrogen fixation by free-living Rhizobium cells. After aerobic growth in a nutrient solution, the bacteria are centrifuged. Acetylene reduction by the rhizobial cells in the pellet can be measured within a few days. Hydrogen gas frequently stimulates acetylene reduction.     

Potential for increasing biological nitrogen fixation in soybean

The importance of soybean as a source of oil and protein, and its ability to grow symbiotically on low-N soils, point to its continued status as the most valuable grain legume in the world. With limited new land on which to expand, and emphasis on sustainable systems, increases in soybean production will come mostly from increased yield per unit area. Improvements in biological nitrogen fixation can help achieve increased soybean production, and this chapter discusses research and production strategies for such improvement.The soybean-Bradyrhizobium symbiosis can fix about 300 kg N ha^-1 under good conditions. The factors which control the amount of N fixed include available soil N, genetic determinants of compatibility in both symbiotic partners and lack of other yield-limiting factors. Response to inoculation is controlled by the level of indigenous, competing bradyrhizobia, the N demand and yield potential of the host, and N availability in the soil.Research efforts to improve BNF are being applied to both microbe and soybean. While selection continues for effective, naturally occurring bradyrhizobia for inoculants and the use of improved inoculation techniques, genetic research on bradyrhizobia to improve effectiveness and competitiveness is advancing. Selection, mutagenesis and breeding of the host have focused on supernodulation, restricted nodulation of indigenous B. japonicum, and promiscuous nodulation with strains of bradyrhizobia from the cowpea cross-inoculation group. The research from the host side appears closer to being ready for practical use in the field.Existing knowledge and technology still has much to offer in improving biological nitrogen fixation in soybean. The use of high-quality inoculants, and education about their benefits and use can still make a significant contribution in many countries. The importance of using the best adapted soybean genotype with a fully compatible inoculant cannot be overlooked, and we need to address other crop management factors which influence yield potential and N demand, indirectly influencing nitrogen fixation. The implementation of proven approaches for improving nitrogen fixation in existing soybean production demands equal attention as received by research endeavours to make future improvements.     

Non-destructive semi-quantitative determination of acetylene reduction in the field

Summary Direct injection of acetylene into soil around plant roots, followed by determination of ethylene/acetylene ratios in the soil atmosphere has been tested as a rapid, non-destructive method of estimating acetylene reducing activity. In pots of artificial media as well as in field soil, the ratios determined within 10 min. after injection were significantly correlated with the rates of acetylenedependent ethylene production in detached roots. The method may be useful in preliminary screening of large numbers of plant-bacteria combinations.     

Field measurement of symbiotic nitrogen fixation in an established lucerne ley using15N and an acetylene reduction method

Summary Lucerne is an important forage legume in the south and south-east of Sweden on well-drained soils. However, data is lacking on the apparent amount of nitrogen derived through N₂ fixation by field-grown lucerne. This report provides basic information on the subject. The experiment was performed in a lucerne ley grown 40 km north of Uppsala. The input of nitrogen through fixation to the above-ground plant material of an established lucerne (Medicago sativa L.) ley was estimate by¹⁵N methodology during two successive years. The amount of fixed N was 242 kg N ha^–1 in 1982 and 319 kg N ha^–1 in 1983. The proportion of N derived from the atmosphere (%Ndfa) was 70% and 80% for the two years respectively. The first harvest in both years contained a lower proportion fixed N. Both N₂ fixation and dry matter production were enhanced during the second year, particularly in the first harvest. The Ndfa was 61% in the first harvest in 1982, compared to 72% Ndfa during the same period in 1983. This demonstrates the strong influence of environment on both dry matter production and N₂ fixation capacity of the lucerne.In addition anin situ acetylene reduction assay was used in 1982 to measure the seasonal distribution of the N₂ fixation and in 1983 to study the effect of soil moisture on the N₂ fixation process. The seasonal pattern showed great dependence on physiological development and harvest pattern of the lucerne ley. The maximum rate of N₂ fixation occurred at the bud or early flower stage of growth and was followed by a rapid decline as flowering proceeded. After harvest the nitrogenase activity markedly decreased and remained low during at least two weeks until regrowth of new shoots began. Irrigation doubled the nitrogenase activity of the lucerne in late summer 1983, when soil moisture content in the top soil was near wilting point. No changes in nitrogenase activity did occur in response to watering earlier during the summer, when the soil matric potential was around –0.30 MPa.     

Denitrification and nitrogen fixation by Azospirillum

A model system is described where Azospirillum and germinated wheat seeds were grown in association for a week and then assayed for nitrogen fixation (C₂H₂-reduction) and denitrification (N₂O-formation) activities. The association performed C₂H₂-reduction and N₂O-formation under microaerobic conditions. Both activities were measurable after already 3–5 h of incubation with substantial rates and were strictly dependent on the presence of both plants and bacteria. During the week of the growth of the association, the bacteria had lived exclusively from the carbon compounds supplied by the roots of the plants. C₂H₂-reduction activity by the association was more or less the same with all the Azospirillum brasilense strains, but lower with A. lipoferum and with the A. amazonense strains tested. Two nitrogenase negative mutants of Azospirillum brasilense showed virtually no activity in the association. C₂H₂-reduction activity was strongly dependent on the growth temperature of the association. Denitrification (N₂O-formation) was high also at higher temperatures and at pH-values in the medium around 7.8 but not at neutrality and was strictly dependent on nitrate. The Azospirillum strain used strongly determined the rate of the N₂O-formation in the association. It is suggested that Azospirillum may be beneficial to crops particularly under tropical conditions.Dedicated to Professor Dr. Gerhart Drews, Freiburg, on the occasion of his 60th birthday     

Membrane lipid peroxidation, nitrogen fixation and leghemoglobin content in soybean root nodules

Membrane lipids in soybean nodules may undergo oxidative degradation resulting in the loss of membrane structural integrity and physiological activities. One of the final products of lipid peroxidation is malondialdehyde (MDA), which can react with thiobarbituric acid (TBA) in vitro to form a chromogenic adduct, a Schiff base product that can be measured spectrophotometrically. MDA formation was quantified in the nodules as well as in the adjacent root tissue. Lipid peroxidation was initially high in soybean nodules induced by Bradyrhizobium japonicum, but sharply declined following an increase in both leghemoglobin content and nitrogen fixation rate. Lipid peroxidation was 2 to 4 times higher in the nodules than in their corresponding adjoining root tissue. Malondialdehyde levels in ineffective nodules were 1.5 times higher than those in effective nodules. MDA formation was also shown to occur in the ‘leghemoglobin-free’ cytosolic fraction, the ‘leghemoglobin’ fraction, and the nodule tissue pellet. Antioxidants, such as reduced ascorbic acid, glutathione, and 8-hydroxyquinoline, caused a partial suppression of lipid peroxidation, whereas ferrous sulfate, hydrogen peroxide, iron EDTA, disodium-EDTA, and β-carotene induced MDA formation. In contrast, quenchers of oxygen free radicals such as HEPES, MES, MOPS, PIPES, phenylalanine, Tiron, thiourea, sodium azide, and sodium cyanide (uncouplers of oxidative phosphorylation) caused somewhere between a 12 to 70 percnt; reduction in MDA production. TBA-reactive products were formed despite the incorporation of superoxide dismutase, proxidase, and catalase into the reaction mixture.     

The influence of soybean planting density on dinitrogen fixation and yield

We investigated the effect of planting density on soybean (Glycine max (L.) Merr.) yield in glasshouse and field experiments. Because net canopy photosynthesis increases with increasing plant density, we hypothesized that increasing planting density would result in increasing rates of dinitrogen fixation in soybeans and higher yields per unit land area.In glasshouse studies, Wayne variety soybeans were planted in 10-cm diameter pots, 1 plant pot^-1 in matrices of 10-, 15-, 20-, 25-, or 30-cm equidistant intervals. Bradyrhizobium japonicum inoculum was added to half of the plants in each treatment. Replicate measurements of total stem height, internode lengths, leaf mass, stem mass, root mass, nodule number, nodule mass, and nitrogenase activity were obtained at 3, 6, and 9 weeks post-emergence. Fruits were harvested and counted at week 14. As planting density increased there were (1) altered morphology and growth rates, (2) increased apparent specific nodule activity (SNA), (3) decreased nodule number and mass, and (4) nearly constant fruit and seed production/plant. Expressed on a unit area basis, nitrogen influx and yield increased geometrically as planting density increased, with maximum values observed for 10-cm plantings.Field studies of Wayne, Stein, Williams, and Gold Harvest soybean varieties were made in 1985. Plots were established containing 100 plants spaced at 10-, 20-, and 30-cm distances. Measurements made during the growing season and at harvest established the same relative trends identified from the glasshouse studies. Increasing plant densities resulted in higher yields per unit land. Varietal differences were almost significant.     

Interactions ofRhizobium japonicum strains in soybean nodules and their contribution to nitrogen fixation

Summary Rhizobium japonicum strain 8-0 Str^R applied as inoculum to Clark 63 soybeans formed small ineffective nodules which had very low nitrogenase activity compared to nodules formed by two effective strains, 110 Tet^R and 138 Kan^R. Mean numbers of cells per milligram of nodule tissue for plants up to 34 days old were 7.7×10⁶ for 8-0 Str^R, 4.1×10⁸ for 110 Tet^R and 7.6×10⁸ for 138 Kan^R. Cell counts per unit mass of nodule were independent of plant age for strains 110 Tet^R and 138 Kan^R, however, for strain 8-0 Str^R, 25 and 34 days old plants had fewer viable cells per nodule mass than 18 day old plants. When a mixture of two effective strains was used, the nodules of individual plants were predominantly caused by either 110 Tet^R or 138 Kan^R. In one experiment the predominance was random, but in another, strain 110 Tet^R clearly dominated. Strain 138 Kan^R was absent in some nodules on 18 day old plants, and in others, less than 10² cells per nodule were found. When strains 8-0 Str^R and 138 Kan^R were used as mixed inoculum, most of the nodules had strain 8-0 Str^R but strain 138 Kan^R was detected in many nodules and was generally evident in the largest nodules. Nitrogenase activity by many individual nodules was low except for nodules which had cells of 138 Kan^R. Nitrogenase activity by whole root systems of these plants was relatively high and similar to plants that had only nodules of strain 138 Kan^R. Similar relationships were observed for a mixed inoculum of 8-0 Str^R and 110 Tet^R. In general, mixed inoculations resulted in nodules with a particular strain being dominant for each individual plant. Double infections within individual nodules were not uncommon and such nodules often had disproportionate numbers of cells of two competingR. japonicum strains.Contribution from the Laboratory of Soil Microbiology, Department of Agronomy, Missouri Agricultural Experiment Station. Missouri Journal Series Number 7967.     

Characterization of soybean vegetative storage proteins and genes

Summary Soybean vegetative storage proteins (VSPs) were purified and characterized. Anion exchange HPLC resolved partially purified VSPs into fractions containing 27-kD/27-kD and 29-kD/29-kD homodimers and 27-kD/29-kD heterodimers. Reversed-phase HPLC resolved partially purified VSPs into three fractions. One fraction contained only 27-kD VSP and the other two contained 29-kD VSP. The two 29-kD VSP fractions differed with respect to their cyanogen bromide cleavage patterns, an observation that indicated the 29-kD VSPs were heterogeneous. Genomic clones that contained 29-kD VSP genes were also isolated and characterized. One genomic clone contained a complete 29-kD VSP gene and was sequenced. The coding region in the clone contained two introns whose borders had regulatory sequences typical of other eukaryotic genes. Putative polyadenlyation signals were present in the 3-flanking region of the gene, while putative TATA, CAAT, and enhancer core sequences were found in the 5-flanking regions. A second genomic clone that was studied contained the 5 regions of two partial 29-kD VSP genes in an inverted linkage. Genomic DNA gel blots showed that the two genes were organized in the same arrangement in the soybean genome.Cooperative research between USDA/Agricultural Research Service and the Indiana Agricultural Experiment Station. Journal Paper No. 12,192 from the Indiana Agricultural Experiment Station     

Seasonal variation in rates of heterotrophic nitrogen fixation (acetylene reduction) in Zostera noltii meadows and uncolonised sediments of the Bassin d'Arcachon, south-west France

Nitrogen fixation (acetylene reduction) rates were measured over an annual cycle in meadows of the seagrass Z. noltii and uncolonised sediments of the Bassin d'Arcachon, south-west France, using both slurry and whole core techniques. Measured rates using the slurry technique in Z. noltii colonised sediments were consistently higher than those determined in isolated cores. This was probably due to the release of labile organic carbon sources during preparation of the slurries. Thus, in colonised sediments the whole core technique may provide a more accurate estimate of in situ activity. Acetylene reduction rates measured by the whole core technique in colonised sediments were 1.8 to 4-fold greater, dependent upon the season, in the light compared with those measured in the dark, indicating that organic carbon released by the plant roots during photosynthesis was an important factor regulating nitrogen fixation. In contrast acetylene reduction rates in uncolonised sediments were independent of light.Addition of sodium molybdate, a specific inhibitor of sulphate reduction inhibited acetylene reduction activity in Z. noltii colonised sediments by > 80% as measured by both slurry and whole core techniques irrespective of the light regime, throughout the year inferring that sulphate reducing bacteria (SRB) were the dominant component of the nitrogen fixing microflora. A mutualistic relationship between Z. noltii and nitrogen fixing SRB in the rhizosphere, based on the exchange of organic carbon and fixed nitrogen is proposed. In uncolonised sediments sodium molybdate initially severely inhibited acetylene reduction rates, but the level of this inhibition declined over the course of the year. These data indicate that the nitrogen fixing SRB associated with the Zostera roots and rhizomes were progressively replaced by an aerobic population of nitrogen fixers associated with the decomposition of this recalcitrant high C:N ratio organic matter.Acetylene and sulphate reduction rates in the seagrass beds showed distinct summer maxima which correlated with a reduced availability of NH ₄ ⁺ in the sediment and the growth cycle of Z. noltii in the Bassin. Overall, these data indicate that acetylene reduction (nitrogen fixation) activity in the rhizosphere of Z. noltii was regulated both by release of organic carbon from the plant roots and maintenance of low ammonium concentrations in the root zone due to efficient ammonium assimilation.Nitrogen fixation rates determined from acetylene reduction rates measured by the whole core technique ranged from 0.1 to 7.3 mg N m^–2 d^–1 in the Z. noltii beds and between 0.02 and 3.7 mg N m^–2 d^–1 in uncolonised sediments, dependent upon the season. Nitrogen fixation in the rhizosphere of Z. noltii was calculated to contribute between 0.4 and 1.1 g N m^–2 y^–1 or between 6.3 and 12% of the annual fixed nitrogen requirement of the plants. Heterotrophic nitrogen fixation therefore represents a substantial local input of fixed nitrogen to the sediments of this shallow coastal lagoon and contributes to the overall productivity of Z. noltii in this ecosystem.     

Oxidation of the enzymes involved in nitrogen assimilation plays an important role in the cadmium-induced toxicity in soybean plants

Cadmium causes oxidative damage and hence affects nitrogen assimilation. In the present work we tested the relationship between the inactivation of the enzymes involved in nitrogen assimilation pathway (glutamine synthetase (GS)/glutamate synthase (GOGAT)) and the protein oxidation in nodules of soybean (Glycine max L.) plants under Cd²⁺ stress. Therefore, the effect of Cd²⁺ and reduced gluthatione (GSH) on GS and GOGAT activities, and protein abundance and oxidation were analyzed. Under the metal treatment, amino acids oxidative modification occurred, evidenced by the accumulation of carbonylated proteins, especially those of high molecular weight. When Cd²⁺ was present in the nutrient solution, although a decrease in GS and GOGAT activities was observed (17 and 52%, respectively, compared to controls), the protein abundance of both enzymes remained similar to control nodules. When GSH was added together with Cd²⁺ in the nutrient medium, it protected the nodule against Cd²⁺ induced oxidative damage, maintaining GS and GOGAT activities close to control values. These results allow us to conclude that the inactivation of the nitrogen assimilation pathway by Cd²⁺ in soybean nodules is due to an increment in GS and GOGAT oxidation that can be prevented by the soluble antioxidant GSH. Section Editor: H. Schat     

Selection for improved nitrogen fixation inGlycine max (L.) Merr. andPhaseolus vulgaris L.

Summary While symbiotic nitrogen (N₂) fixation byG. max andP. vulgaris reduces their need for combined N, N₂ fixation under field conditions is rarely maximized. This paper reviews constraints to N₂ fixation in these species, then examines the genetic variability recorded for traits affecting N₂ fixation and the further work needed in this area. It considers emerging programs for the improvement of N₂ fixation inG. max andP. vulgaris and pays particular attention to methodological considerations.Scientific Journal Series, Minnesota Agri. Exp. Station. No 14190.     

Relationship between porewater organic carbon content, sulphate reduction and nitrogen fixation (acetylene reduction) in the rhizosphere of Zostera noltii

Depth profiles of nitrogen fixation (acetylene reduction), sulphate reduction, NH ₄ ⁺ concentration and porewater volatile fatty acids concentrations were measured in Zostera noltii colonised sediments in the Bassin d'Arcachon, France in March 1994. Acetylene reduction activity (ARA) was detectable throughout sediment profiles. Addition of sodium molybdate (20 mmol l^–1) a specific inhibitor of sulphate reduction to slurries inhibited ARA by >75% inferring that sulphate-reducing bacteria (SRB) were the dominant component of the nitrogen fixing microflora. The peak of ARA was coincident with that of sulphate reduction and a relatively constant relationship of 40 mole sulphate reduced per mole acetylene reduced was recorded throughout the profiles. From this ratio it was calculated that at least 17% of the ATP yield from sulphate reduction would be required to support the measured rates of nitrogen fixation (acetylene reduction).Acetate was the dominant constituent of the porewater volatile fatty acids pool, accounting for >90% of the total pool as measured by HPLC. Concentrations of porewater acetate recorded by HPLC were compared with those measured using an enzymatic technique and these data indicate that approximately 10% of the total porewater acetate pool was not available to microbial metabolism. Profiles of porewater acetate concentrations measured by both techniques were similar to those recorded for both ARA and sulphate reduction and thus acetate oxidation may fuel these activities.     

Phosphorus fertilization and tillage effect on dinitrogen fixation in soybeans

Summary Tillage has been shown to affect the uptake of phosphorus (P) and yield of soybeans, [Glycine max (L.) Merr.], but there is little information concerning the effects of P fertilization on nitrogen (N₂) fixation in soybeans under no-tillage. Two field experiments were conducted in 1980 and 1981 to determine the effects of soil P on N₂ fixation under no-tillage and to study the interaction of P fertilization and tillage of N₂ fixation, nutrient uptake, and yield of soybeans. In Exp. I, P was applied in 1977 at five rates up to 384 kg P ha⁻¹ and the effects of residual soil P were evaluated in 1980 and 1981 under no-tillage management. Nitrogen fixation rates, as measured by acetylene reduction assay, were significantly affected by soil P in Exp. I, but the assay proved to be a poor technique for estimating total plant N in these tests. Acetylene reduction rates and plant P increased rapidly as soil P increased from 2 to 20 mg kg⁻¹, with little additional increase above 20 mg P kg⁻¹. In Exp. II, rates (0, 32, 64, and 128 kg P ha⁻¹) and time (fall, spring and fall plus spring) of P application were compared under conventional tillage and no tillage. However, plant P increased with increasing levels of applied P. Applied P had no affect on acetylene reduction rates but rates were greater for no-tillage than conventional tillage at the V9 and R5 stages of growth in 1981. Plant uptake of P was more efficient under no-tillage than under conventional tillage in 1980 and 1981. Application of 64 kg P ha⁻¹ under no-tillage resulted in equivalent plant P levels as the 128 kg P ha⁻¹ applied under conventional tillage.     

Grafting experiments on the nature of the decline in N2 fixation during fruit development in soybean

A decline in nitrogen fixation at the time of pod-filling is persistently seen in soybeans. This phenomenon was studied by grafting experiments. Young scions with 3 nodes were grafted near the base of fruiting stocks which had passed their peak of nitrogen fixation. These grafts produced a second peak of nitrogen fixation on the same root system, indicating that the decline is reversible. If the scions were grafted near the apex of the fruiting stocks then the second peak of nitrogen fixation was very small. Thus, the translocation system could have an important role in regulating the decline in nitrogen fixation. Grafting of a second shoot of the same age as the rootstock, after the decline in nitrogen fixation, did not reduce the rate of decline even when the fruits from the scion were removed. It appears that physiological changes in different components of the shoot jointly regulate the decline in the rate of nitrogen fixation in soybeans.