Carbon and nitrogen partitioning in young nodulated pea (wild type and nitrate reductase-deficient mutant) plants exposed to NH4NO3

Carbon and nitrogen partitioning was examined in a wild-type and a nitrate reductase-deficient mutant (A317) of Pisum sativum L. (ev. Juneau), effectively inoculated with two strains of Rhizobium leguminosarum (128C23 and 128C54) and grown hydroponically in medium without nitrogen for 21 days, followed by a further 7 days in medium without and with 5 mM NH₄NO₃. In wild-type symbioses the application of NH₄NO₃ significantly reduced nodule growth, nitrogenase (EC 1.7.99.2) activity, nodule carbohydrates (soluble sugars and starch) and allocation of [¹⁴C]-labelled (NO₃⁻, NH₄⁺, amino acids) in roots. In nodules, there was a decline in amino acids together with an increase in inorganic nitrogen concentration. In contrast, symbioses involving A317 exhibited no change in nitrogenase activity or nodule carbohydrates, and the concentrations of all nitrogenous solutes measured (including asparagine) in roots and nodules were enhanced. Photosynthate allocation to the nodule was reduced in the 128C23 symbiosis. Nitrite accumulation was not detected in any case. These data cannot be wholly explained by either the carbohydrate deprivation hypothesis or the nitrite hypothesis for the inhibition of symbiotic nitrogen fixation by combined nitrogen. Our result with A317 also provided evidence against the hypothesis that NO₃⁻ and NH₄⁺ or its assimilation products exert a direct effect on nitrogenase activity. It is concluded that more than one legume host and Rhizobium strain must be studied before generalizations about Rhizobium /legume interactions are made.     

Trehalose and trehalase in root nodules from various legumes

Nitrogen-fixing (effective) nodules from various legume- Rhizobium combinations were analyzed for trehalose and other soluble carbohydrates using gas chromatography and for trehalase activity using biochemical assays. Whereas the bacterial disaccharide trehalose was present only in the minority of the nodules, trehalase activity was found in all of them. Extracts from determinate nodules had a higher trehalase activity than extracts from indeterminate nodules. More detailed studies were done on soybean nodules formed in interactions with two effective and 5 ineffective Bradyrhizobium japonicum strains. Only in effective soybean nodules colonized by the strain 61-A-101 was trehalose a major soluble carbohydrate. Irrespective of the wildtype strains used. effective soybean nodules contained about 10 nkat trehalase g⁻¹ fresh weight, whereas the ineffective nodules colonized by mutant strains derived from these wildtype strains contained 2 to 30 times less trehalase. However, a clear correlation between trehalose content and trehalase activity could not be established.     

Correlations between the ascorbate-glutathione pathway and effectiveness in legume root nodules

Legume root nodules use the ascorbate-glutathione pathway to remove harmful H₂O₂. In the present study. effective and ineffective nodules from soybean and alfalfa were compared with regard to this pathway. Effective nodules had higher activity of all 4 enzymes (ascorbate peroxidase, EC 1. 11. 1. 11: monodehydroascorbate reductase, EC 1. 6. 5. 4: dehydroascorbate reductase, EC 1. 8. 5. 1: and glutathione reductase, EC 1. 6. 4. 2). The concentration of thiol tripeptides (primarily homoglutathione) was about 1 m M in effective nodules – a level 3–4-fold higher than in ineffective nodules. Effective nodules contained higher levels of NAD⁺. NADP⁺ and NADPH. but not of NADH or ascorbate. The increased capacity for peroxide scavenging in effective nodules as compared to ineffective nodules emphasizes the important protective role that this pathway may play in processes related to nitrogen fixation.     

Metabolism of [13C]-labelled photosynthate in plant cytosol and bacteroids of root nodules of Glycine max

Well-nodulated soybean ( Glycine max L. Merr. cv. Akisengoku) plants were allowed to assimilate ¹³CO₂. Plant cytosol and bacteroid fractions were isolated from nodules, and the kinetics of [¹³C]-labelling of soluble carbohydrates, organic acids and amino acids were investigated.
The concentrations of all metabolites, with the exception of trehalose and 3-hydroxy-butyrate, were 10- to 1000-fold higher in plant cell cytosol than in bacteroids. The major portion of trehalose was found in bacteroids and 3-hydroxybutyrate only in bacteroids. Sucrose was most highly labelled with ¹³C in nodules, and the levels and time-course of labelling of sucrose were in good agreement with those of respired CO₂ from the nodules. The levels and time-courses of labelling of sucrose were closely similar in cytosol and bacteroids. Glucose was less labelled than sucrose and the level of labelling was consistently higher in cytosol than in bacteroids. The levels of [¹³C]-labelling of organic acids and amino acids in nodules were lower than those of sucrose and of respired CO₂. Tricarboxylic acid cycle intermediates, particularly succinate, were considerably less labelled in bacteroids than in the cytosol. All amino acids detected were also much more rapidly labelled in the cytosol. The results are discussed in relation to the utilization and possible compartmentation of carbon substrates in nodule tissues.     

Effects of Salt Stress on Amino Acid, Organic Acid, and Carbohydrate Composition of Roots, Bacteroids, and Cytosol of Alfalfa (Medicago sativa L.)

Ethanol-soluble organic acid, carbohydrate, and amino acid constituents of alfalfa (Medicago sativa) roots and nodules (cytosol and bacteroids) have been identified by gas-liquid chromatography and high performance liquid chromatography. Among organic acids, citrate was the predominant compound in roots and cytosol, with malonate present in the highest concentration in bacteroids. These two organic acids together with malate and succinate accounted for more than 85% of the organic acid pool in nodules and for 97% in roots. The major carbohydrates in roots, nodule cytosol, and bacteroids were (descending order of concentration): sucrose, pinitol, glucose, and ononitol. Maltose and trehalose appeared to be present in very low concentrations. Asparagine, glutamate, alanine, γ-aminobutyrate, and proline were the major amino acids in cytosol and bacteroids. In addition to these solutes, serine and glutamine were well represented in roots. When alfalfa plants were subjected to 0.15 m sodium chloride stress for 2 weeks, total organic acid concentration in nodules and roots were depressed by more than 40%, whereas lactate concentration increased by 11, 27, and 94% in cytosol, roots, and bacteroids, respectively. In bacteroids, lactate became the most abundant organic acid and might contribute partly to the osmotic adjustment. On the other hand, salt stress induced a large increase in the amino acid and carbohydrate pools. Within the amino acids, proline showed the largest increase, 11.3-, 12.8-, and 8.0-fold in roots, cytosol, and bacteroids, respectively. Its accumulation reflected an osmoregulatory mechanism not only in roots but also in nodule tissue. In parallel, asparagine concentration was greatly enhanced; this amide remained the major nitrogen solute and, in bacteroids, played a significant role in osmoregulation. On the contrary, the salt treatment had a very limited effect on the concentration of other amino acids. Among carbohydrates, pinitol concentration was increased significantly, especially in cytosol and bacteroids (5.4- and 3.4-fold, respectively), in which this cyclitol accounted for more than 35% of the total carbohydrate pool; pinitol might contribute to the tolerance to salt stress. However, trehalose concentration remained low in both nodules and roots; its role in osmoregulation appeared unlikely in alfalfa.     

Succinate dehydrogenase mutant of Rhizobium meliloti.

A succinate dehydrogenase mutant strain of Rhizobium meliloti was isolated after nitrosoguanidine mutagenesis. It failed to grow on succinate, glutamate, acetate, pyruvate, or arabinose but grew on glucose, sucrose, fructose, and other carbohydrates. The mutant strain showed delayed nodulation of lucerne plants, and the nodules were white and ineffective. A spontaneous revertant strain of normal growth phenotype induced red and effective nodules.     

A comparison of the fluorescent ELISA and antibiotic resistance identification techniques for use in ecological experiments with Rhizobium trifolii

The fluorescent ELISA technique for the identification of bacteria was compared with antibiotic resistant mutants as marker systems for use with Rhizobium trifolii in root nodules and in soil. With an effective(CP3B) and an ineffective (R4) strain as a mixed 1:1 inoculum, there was a highly significant correlation ( P < 0.001) between the two techniques when the plants were grown at pH 5.5 when the majority of nodules were inhabited by the effective strain. At pH 6.5, where the ineffective strain predominated in the nodules, there was no correlation. The reason was that 85% of R4 nodules had volumes less than 0.1 mm₃ with bacterial numbers obviously below the necessary threshold for detection using the serological method. Both methods were efficient at enumerating rhizobia from soils although the recovery rate from a brown earth soil was significantly higher than from a peat soil. Fluorescent ELISA was able to detect rhizobia at 8.0 times 10₅ cells/ml soil suspension (1 g soil to 10 ml water) in the brown earth soil and at 2.0 times 10₅ cells/ml in the peat soil. The results are discussed in terms of the limitations of both techniques in ecological studies.     

The Flavin Content of Clovers Relative to Symbiosis with a Riboflavin-requiring Mutant of Rhizobium trifoli

A riboflavin-requiring auxotroph of Rhizobium trifolii (T1/D-his(r)-15) formed ineffective root nodules on red clover and on two cultivars of subterranean clover, but produced almost fully effective nodules on several other cultivars of subterranean clover. Fluorescence and bioassay measurements of the flavin content of the roots and shoots of these cultivars revealed no differences between cultivars which could be correlated with the differences in symbiotic response. The concentration of flavin in nodules formed by the auxotroph (in the absence of riboflavin), by the effective parent strain (T1), or by a partly effective mutant (penicillin-resistant) of T1 was roughly proportional to the effectiveness of the nodules. Effective nodules contained 20 times as much flavin, and ineffective nodules 3 to 4 times as much flavin as non-nodulated root tissue. Approximately 20 to 30% of the flavins in both root and nodule tissue was flavin adenine dinucleotide and 70 to 80% was riboflavin + flavin mononucleotide. Most of the flavin adenine dinucleotide in macerated nodules was associated with host cell fragments, and none was detected in a cell-free fraction. Bacteroids accounted for approximately 20% of flavins in effective nodules and also contained more riboflavin + flavin mononucleotide than cultured rhizobial cells. The total flavin content of noninoculated roots increased from about 1.2 nmoles to 1.7 nmoles flavin/g of tissue after 3 days' exposure to 80 mum riboflavin. Exposure of only the upper or lower portion of preinoculated roots indicated negligible translocation, as effective nodulation occurred only on parts of the root in direct contact with riboflavin. Plants grown in a medium containing combined nitrogen (100 or 300 mum nitrogen added as (NH(4))(2)SO(4)), but no added riboflavin showed an increased root flavin content (about 2.1 nmoles flavin/g tissue) and a partly effective response when inoculated with the mutant. Nitrogen also promoted some upward translocation of exogenous riboflavin in the roots.     

Regulation of cytosol acidity in plants under conditions of drought

In plants under water stress, the activity of photosynthesis declines most. Stimulation of the oxidative respiration and fermentation results in an increase in the amount of related organic acids: citrate, malate and lactate. In spite of some decline in photo-respiratory activity, dehydration may enhance the concentration of related organic acids, glycerate and glycolate. The resulting amount of H⁺ should stimulate NAD(P)H reduction of organic acids by dehydrogenases. Accumulation of proline could be the consequence of such reactions. In the oxidation of glycine, regeneration of NAD(P)H does not liberate H⁺ but NH₄⁺.
Assimilation of NH₄⁺ by cytosolic glutamine synthetase (EC 6.3.1.2) results in positively charged glutamine. It is also conceivable that the charge is essential in the final asparagine synthesis by cytosolic asparagine synthetase (EC 6.3.1.1).
At low pH the activity of the oxidative respiration declines. In water-stressed plants, maintenance of oxidative respiration will depend on the availability of sufficient amounts of carbohydrates and on adequate removal of excess H⁺ by accumulation of proline and asparagine.     

Symbiotic properties of Lotus pedunculitis root nodules induced by Rhizobium loti and Bradyrhizobium sp. (Lotus)

Vance, C. P., Reibach, P. H. and Pankhurst, C. E. 1987. Symbiotic properties of Lotus pedunculatus root nodules induced by Rhizobium loti and Bradyrhizobium sp. ( Lotus ).
Symbiotic properties of root nodules were evaluated in glasshouse-grown Lotus pedunculatus Cav. cv. Maku inoculated with either a fast-growing Rhizobium loti strain NZP2037 or a slow-growing Bradyrhizobium sp. ( Lotus ) strain CC814s. Although the nodule mass of plants inoculated with NZP2037 was twice that of plants inoculated with CC814s, the yield of NZP2037 shoots and roots was 50% that of CC814s shoots and roots. Nodules induced by Bradyrhizobium fixed substantially more N than nodules induced by R. loti. Glucose requirements [mol glucose (mol N₂ fixed)^-1] of nodules induced by CC814s and NZP2037 were 7.1 and 16.6, respectively. Nodule enzymes of carbon and nitrogen assimilation reflected the disparity of the two sym-bioses. Xylem sap of the symbiosis with the higher yield contained a higher concentration of asparagine [9.86 μmol (ml xylem sap)'] than did the lower yielding symbiosis [5.80 umol (ml xylem sap)"']. Nodule CO₂ fixation was directly linked to nodule N assimilation in both symbioses. The results indicate that the difference between the two symbioses extend to nodule N and C assimilation and whole plant N transport. The data support a role for host plant modulation of bacterial efficiency and assimilation of fixed N.     

Isolation of an Asm− mutant of Rhizobium japonicum defective in symbiotic N2-fixation

Abstract A mutant strain of Rhizobium japonicum (CJ9) unable to assimilate ammonium (Asm⁻) was isolated following mutagenesis with N -methyl N -nitro-nitrosoguanidine (NTG). Glutamate synthase activity was not detectable in cell-free extracts of the mutant strain in contrast to the wild type and revertant strains. Although mutant CJ9 induced nitrogenase activity in an 'in vitro' assay system under microaerobic conditions, it failed to fix nitrogen (acetylene reduction) in soybean root nodules. These properties of mutant CJ9 constitute a new Asm⁻ mutant class in Rhizobium spp.     

Products of Dark CO(2) Fixation in Pea Root Nodules Support Bacteroid Metabolism

Products of the nodule cytosol in vivo dark [¹⁴C]CO₂ fixation were detected in the plant cytosol as well as in the bacteroids of pea (Pisum sativum L. cv “Bodil”) nodules. The distribution of the metabolites of the dark CO₂ fixation products was compared in effective (fix⁺) nodules infected by a wild-type Rhizobium leguminosarum (MNF 300), and ineffective (fix⁻) nodules of the R. leguminosarum mutant MNF 3080. The latter has a defect in the dicarboxylic acid transport system of the bacterial membrane. The ¹⁴C incorporation from [¹⁴C]CO₂ was about threefold greater in the wild-type nodules than in the mutant nodules. Similarly, in wild-type nodules the in vitro phosphoenolpyruvate carboxylase activity was substantially greater than that of the mutant. Almost 90% of the ¹⁴C label in the cytosol was found in organic acids in both symbioses. Malate comprised about half of the total cytosol organic acid content on a molar basis, and more than 70% of the cytosol radioactivity in the organic acid fraction was detected in malate in both symbioses. Most of the remaining ¹⁴C was contained in the amino acid fraction of the cytosol in both symbioses. More than 70% of the ¹⁴C label found in the amino acids of the cytosol was incorporated in aspartate, which on a molar basis comprised only about 1% of the total amino acid pool in the cytosol. The extensive ¹⁴C labeling of malate and aspartate from nodule dark [¹⁴C]CO₂ fixation is consistent with the role of phosphoenolpyruvate carboxlase in nodule dark CO₂ fixation. Bacteroids from the effective wild-type symbiosis accumulated sevenfold more ¹⁴C than did the dicarboxylic acid transport defective bacteroids. The bacteroids of the effective MNF 300 symbiosis contained the largest proportion of the incorporated ¹⁴C in the organic acids, whereas ineffective MNF 3080 bacteroids mainly contained ¹⁴C in the amino acid fraction. In both symbioses a larger proportion of the bacteroid ¹⁴C label was detected in malate and aspartate than their corresponding proportions of the organic acids and amino acids on a molar basis. The proportion of ¹⁴C label in succinate, 2-oxogultarate, citrate, and fumarate in the bacteroids of the wild type greatly exceeded that of the dicarboxylate uptake mutant. The results indicate a central role for nodule cytosol dark CO₂ fixation in the supply of the bacteroids with dicarboxylic acids.     

Distribution of nitrate reductase activity in Vicia faba: Effect of nitrate and plant genotype

The short term effect of NO₃⁻ (12 mM) on nitrate reductase (NR. EC 1.6.6.1) activity has been studied in the roots, nodules and leaves of different genotypes of Vicia faba L. at the end of vegetative growth. Root and leaf NR activity responded positively to NO₃⁻ while nodule activity, where detected, proved to he strongly inhibited. The withdraw of this NO₃⁻ from the solution consistently reduced activity in the roots and leaves but surprising, promoted a significant increase in nodule activity, which matched or surpassed that of control plants On the other hand, nodules developed in the presence of 8 mM NO₃⁻ expressed an on average 141% higher level of NR activity than did controls. This effect was observed even in nodules with negligible control activity. In any case, a naturally occurring mutant (VF17) lacking root and nodule NR activity is described. The results indicate that in V. faba. the effects of NO₃⁻ and plant genotype on NR activity depended on plant organ and time of NO₃⁻ application, hut the distribution of NO₃⁻ reduction through the plain was mainly dependent on plant genotype, and to a lesser extent on NO: supply and plant age.     

Features of the intrageneric Alnus-Frankia specificity

Host specificity between local Frankia strains and native alders [Alnus incana (L.) Moench and A. glutinosa (L.) Gaertn.] was evaluated in inoculation experiments. Pure cultures of Frankia , whether originating from A. incana or A. glutinosa , were infective and effective on both host species. These pure cultures were isolated from spore-negative (Sp⁻) nodules. From spore-positive (Sp⁺) nodules no Frankia isolates were obtained. This strain type resisted all our isolation attempts and therefore crushed nodules had to be used for Sp⁺ type inoculations.
The Sp⁺ type Frankia populations differed in their host specificity. Sp⁺ nodules from A. glutinosa were effective on both alder species, but Sp⁺ nodules from A. incana induced effective nodules only on the original host; on A. glutinosa only small (1-3mm) prenodule-like structures were found. Such A. glutinosa plants died on N-free medium, thus showing that these nodules were ineffective. In the effective nodules the middle cortex was dominated by infected cells filled with vesicle clusters. In the ineffective nodules only a few cortical cells were infected and sporangia predominated in these cells. Surprisingly enough they also contained vesicle-like structures as demonstrated in electron micrographs.     

Identification of Rhizobium leguminosarum and Rhizobium sp. (Cicer) strains using a custom Fatty Acid Methyl Ester (FAME) profile library

The potential of using fatty acid methyl ester (FAME) profiles of Rhizobium leguminosarum bv. viceae , phaseoli and trifolii , and Rhizobium sp. ( Cicer ) strains, for the identification of unknown isolates was assessed. This was achieved by developing a Rhizobium FAME library using 16 different Rhizobium strains of Rh. leguminosarum bv. viceae ( n  ₌ 5), Rh. leguminosarum bv. phaseoli ( n  ₌ 5), Rh. leguminosarum bv. trifolii ( n  ₌ 1) and Rhizobium sp. ( Cicer ) ( n  ₌ 5). Although there were considerable differences between Rh. leguminosarum biovars and strains and Rhizobium sp. ( Cicer ) strains, the variation within a particular biovar of Rh. leguminosarum was not high. Nevertheless, the feature FAME profiles of the various groups in the library allowed 75 putative rhizobia obtained from surface-sterilized nodules of field-grown lentil and pea plants to be identified.     

Regulation of nitrogenase activity in Bradyrhizobium japonicum/soybean symbiosis by plant N status as determined by shoot C:N ratio

Regulation of nitrogenase is not sufficiently understood to engineer symbioses that achieve a high N₂ fixation rate under high levels of soil N. In the present hydroponic growth chamber study we evaluated the hypothesis that nitrogenase activity and the extent of its inhibition by NO₃⁻ may be related to both N and carbohydrate levels in plant tissues. A wide range of C:N ratios in various plant tissues (8.5 to 41.0, 1.9 to 3.7, and 0.8 to 1.8, respectively, in shoots, roots, and nodules) was generated through a combination of light and CO₂ levels, using two soybean genotypes differing in C and N acquisition rates. For both genotypes, N concentration in shoots was negatively correlated to nitrogenase activity and positively correlated to the extent of nitrogenase inhibition by NO₃⁻. Furthermore, nitrogenase activity was positively correlated to total nonstructural carbohydrates (TNC) and C:N ratio in shoot and nodules for both genotypes. Nitrogenase inhibition by NO₃⁻ was negatively correlated to TNC and C:N ratio in shoots, but not in nodules for both genotypes. At the onset of nitrogenase inhibition by NO₃⁻, C:N ratio declined in shoots but not in nodules. These results indicate that both C and N levels in plant tissues are involved in regulation of nitrogenase activity. We suggest that the level of nitrogenase activity may be determined by (1) N needs (as determined by shoot C:N) and (2) availability of carbohydrates in nodules. Modulation of the nitrogenase activity may occur through sensing changes in plant N, i.e. changes in shoot C:N ratio, possibly through some phloem translocatable compound(s).     

Regulation of nitrogenase activity in Bradyrhizobium japonicum/soybean symbiosis by plant N status as determined by shoot C:N ratio

Regulation of nitrogenase is not sufficiently understood to engineer symbioses that achieve a high N₂ fixation rate under high levels of soil N. In the present hydroponic growth chamber study we evaluated the hypothesis that nitrogenase activity and the extent of its inhibition by NO₃⁻ may be related to both N and carbohydrate levels in plant tissues. A wide range of C:N ratios in various plant tissues (8.5 to 41.0, 1.9 to 3.7, and 0.8 to 1.8, respectively, in shoots, roots, and nodules) was generated through a combination of light and CO₂ levels, using two soybean genotypes differing in C and N acquisition rates. For both genotypes, N concentration in shoots was negatively correlated to nitrogenase activity and positively correlated to the extent of nitrogenase inhibition by NO₃⁻. Furthermore, nitrogenase activity was positively correlated to total nonstructural carbohydrates (TNC) and C:N ratio in shoot and nodules for both genotypes. Nitrogenase inhibition by NO₃⁻ was negatively correlated to TNC and C:N ratio in shoots, but not in nodules for both genotypes. At the onset of nitrogenase inhibition by NO₃⁻, C:N ratio declined in shoots but not in nodules. These results indicate that both C and N levels in plant tissues are involved in regulation of nitrogenase activity. We suggest that the level of nitrogenase activity may be determined by (1) N needs (as determined by shoot C:N) and (2) availability of carbohydrates in nodules. Modulation of the nitrogenase activity may occur through sensing changes in plant N, i.e. changes in shoot C:N ratio, possibly through some phloem translocatable compound(s).     

Combined effect of organic acids and supercritical carbon dioxide treatments against nonpathogenic Escherichia coli, Listeria monocytogenes, Salmonella typhimurium and E. coli O157:H7 in fresh pork

Aims:  To evaluate the effectiveness of organic acids and supercritical carbon dioxide (SC-CO₂) treatments as well as their combined effect for the reduction of nonpathogenic Escherichia coli and three pathogenic bacteria in fresh pork.
Methods and Results:  The different treatment conditions were as follows: (i) treatment with acetic (1%, 2% or 3%) or lactic acid (1%, 2% or 3%) only, (ii) treatment with SC-CO₂ at 12 MPa and 35°C for 30 min only and (iii) treatment with 3% acetic or lactic acid followed by treatment with SC-CO₂. Within the same organic acid concentration, the lactic and acetic acid treatments had similar reductions. For the combined treatment of lactic acid and SC-CO₂, micro-organism levels were maximally reduced, ranging from 2·10 to 2·60 log CFU cm⁻² ( E. coli , 2·58 log CFU cm⁻²; Listeria monocytogenes , 2·60 log CFU cm⁻²; Salmonella typhimurium , 2·33 log CFU cm⁻²; E. coli O157:H7, 2·10 log CFU cm⁻²).
Conclusions:  The results of this study indicate that the combined treatments of SC-CO₂ and organic acids were more effective at destroying foodborne pathogens than the treatments of SC-CO₂ or organic acids alone.
Significance and Impact of the Study:  The combination treatment of SC-CO₂ and organic acids may be useful in the meat industry to help increase microbial safety.     

Acetylene reduction by effective and ineffective clover and soybean root nodules

Summary Acetylene was reduced to ethylene by effective white clover nodules and by fully and partially effective intact nodules, nodule homogenates, and bacteroids of soybeans. Succinate and several amino acids markedly stimulated the reduction by effective soybean bacteroids, but the stimulation was slight with partially effective bacteroids. Acetylene metabolism by effective soybean bacteroids was also enhanced by excretions of in vitro-grown Rhizobium japonicum, excretions of bacteria derived from effective and ineffective nodules, and the soluble fraction from these nodules. Inhibitors of nitrogen fixation were not found in ineffective nodules. Ineffective soybean and white clover nodules and homogenates or isolated bacteria from ineffective soybean nodules did not reduce acetylene. Additions of succinate, amino acids, the soluble fraction of effective nodules, or excretions of effective bacteroids or of in vitro-grown cells of an effective R. japonicum strain did not promote nitrogen fixation by bacterial cells obtained from ineffective soybean nodules.