Preincubation of Bradyrhizobium japonicum with Genistein Accelerates Nodule Development of Soybean at Suboptimal Root Zone Temperatures

In the soybean (Glycine max [L.] Merr.) N2-fixing symbiosis, suboptimal root zone temperatures (RZTs) slow nodule development, especially at temperatures below 17[deg]C. A step in the infection process that occurs within the first 24 h is particularly sensitive to suboptimal RZT. The first phase in the establishment of the soybean-Bradyrhizobium japonicum symbiosis is the exchange of recognition molecules. The most effective plant-to-bacterium signal is genistein. Binding of genistein to B. japonicum activates many of the B. japonicum nod genes. To our knowledge, the potential of sub-optimal RZT to disrupt this interorganismal signaling has not previously been investigated. Controlled environment experiments were conducted to determine whether the preincubation of B. japonicum with genistein increases soybean nodulation and N2 fixation at suboptimal RZT and whether the time between inoculation and root-hair curling is shortened by genistein application. The results of these experiments indicated that (a) genistein application increased soybean nodulation at suboptimal RZTs (17.5 and 15[deg]C) but not at the optimal RZT (25[deg]C); (b) the period between inoculation and root-hair curling was shortened by inoculation with bradyrhizobia preincubated with genistein; (c) at 17.5 and 15[deg]C RZT, the onset of N2 fixation occurred earlier in plants that received genistein-treated bradyrhizobia than in plants inoculated with untreated bradyrhizobia; (d) over the tested concentration range, genistein application at 15 to 20 [mu]M was the most effective in stimulating nodulation; and (e) between 25 and 15[deg]C, as RZT decreased, there was an increase in the nodulation-stimulating potential of genistein.     

Effects of low root zone temperatures on the early stages of symbiosis establishment between soybean [Glycine max (L.) Merr.] and Bradyrhizobium japonicum

It is known that low root zone temperatures (RZT) have moreeffect on infection and early nodule development than on nitrogenfixation by soybean [Glycine max (L.) Merr.]. However, therehave been no studies regarding how the low RZT inhibit the infectionstages of soybean. Two controlled environment experiments wereconducted to examine the effect of low RZT on bacterial attachmentto, and infection thread penetration of, soybean root hairs.The experimental designs were (1) plants maintained at 25, 17.5or 15C RZT, or transferred from 25 or 17.5 to 15C RZT at either0.5, 1, 2, or 7d after inoculation (DAI), (2) early symbioticestablishment between soybean and Bradyrhizobium japonicum wasexamined microscopically under three RZT (15, 17.5 and 25C).These results indicated that (1) keeping plants at 25C only0.5 DAI prior to transfer to a 15C RZT accelerates the onsetof N₂ fixation at 15C RZT by 6 d, (2) at RZT between 25 and17.5C the infection processes were progressively delayed astemperature declined, (3) RZT less than 17C strongly inhibitedinfection steps, such that when RZT dropped 8.5C from 25 to17.5C infection initiation was delayed 1 d, while when RZTdropped only 2.5C from 17.5 to 15C, infection initiation wasdelayed another 2 d. Key words: Bradyrhizobium japonicum, low temperature, nodulation, soybean     

Application of genistein to inocula and soil to overcome low spring soil temperature inhibition of soybean nodulation and nitrogen fixation

In the soybean (Glycine max. (L.) Merr)– Bradyrhizobium japonicum symbiosis, suboptimal root zone temperatures (RZTs) slow nodule development by disruption of the interorganismal signal exchange between the host plant and bradyrhizobia. Two field experiments were conducted on two adjacent sites in 1994 to determine whether the incubation of B. japonicum with genistein prior to application as an inoculant, or genistein, without B. japonicum, applied onto seeds in the furrow at the time of planting, increased soybean nodulation, N fixation, and total N yield. The results of these experiments indicated that genistein application increased nodule number and nodule dry matter per plant and hastened the onset of N fixation during the early portion of the soybean growing season, when the soils were still cool. Because these variables were improved, total fixed. N, fixed N as a percentage of total plant N, and N yield increased due to genistein application. The interaction between genistein application and soybean cultivars indicated that genistein application was more effective on N-stressed plants.     

Plant Growth-promoting Rhizobacteria and Soybean [ Glycine max (L.) Merr.] Growth and Physiology at Suboptimal Root Zone Temperatures

Application of plant growth-promoting rhizobacteria (PGPR) hasbeen shown to increase legume growth and development under optimaltemperature conditions, and specifically to increase nodulationand nitrogen fixation of soybean [Glycine max (L.) Merr.] overa range of root zone temperatures (RZTs). Nine rhizobacteriaapplied into soybean rooting media were tested for their abilityto reduce the negative effects of low RZT on soybean growthand development by improving the physiological status of theplant. Three RZTs were tested: 25, 17.5, and 15 °C. At eachtemperature some PGPR strains increased plant growth and development,but the stimulatory strains varied with temperature. The strainsthat were most stimulatory at each temperatures were as follows:15 °C—Serratia proteamaculans 1–102; 17.5 °C—Aeromonashydrophila P73, and 25 °C—Serratia liquefaciens 2–68.Because enhancement of plant physiological activities were detectedbefore the onset of nitrogen fixation, these stimulatory effectscan be attributed to direct stimulation of the plant by thePGPR rather than stimulation of plant growth via improvementof the nitrogen fixation symbiosis. Legume; nitrogen fixation; nodulation; root zone temperature; PGPR     

Soybean (Glycine max) modulation and N2-fixation as affected by exposure to a low root-zone temperature

Low root-zone temperatures (RZTs) are known to reduce soybean N₂-fixation. However, the relative sensitivity of the various stages of symbiosis establishment and function (N₂-fixation) to suboptimal RZTs is unresolved. We conducted experiments to examine the effect of exposure to a RZT of 15°C on nodulation. The control RZT was 25°C. Root temperatures were controlled by circulating cooled water around pots on a growth bench. Soybean seedlings [ Glycine max (L.) Merr. cv. Maple Arrow] were inoculated with 1 ml of a log-phase culture (approximately 10⁻⁸ cells) of Bradyhizobium japonicum strain 532C. They were then (1) maintained continuously at RZTs of 15 or 25°C, transferred to 15 or 25°C from the alternate temperature 7 days after inoculation (DAI), or transferred to 15 or 25°C at 14 DAI, and (2) maintained at 15 or 25°C, or transferred at either 1, 4 or 7 DAI. When seedlings were maintained at a RZT of 25°C nodule primordia (<1 mm) were visible at 7 DAI and N₂-fixation commenced at 14 DAI. Nodule function (N₂-fixation) appeared to be relatively insensitive to low RZTs since exposure of plants to 15°C following the onset of N₂-fixation (14 DAI) resulted in 68% of the N fixed and 78% of the dry weight of the 25°C RZT, although N partitioning to shoot tissues was reduced. In contrast, exposure to the low RZT shortly after inoculation declayed the onset of N₂-fixation for 4 to 6 weeks, primarily by inhibiting the early stages of nodulation. This resulted in fixed N and dry weight levels of 9% and 22% of controls, respectively.     

Plant Growth Promoting Rhizobacteria and Soybean [ Glycine max (L.) Merr.] Nodulation and Nitrogen Fixation at Suboptimal Root Zone Temperatures

Co-inoculation of plant growth promoting rhizobacteria (PGPR)withBradyrhizobium has been shown to increase legume nodulationand nitrogen fixation at optimal soil temperatures. Nine rhizobacteriaco-inoculated withBradyrhizobium japonicum532C were tested fortheir ability to reduce the negative effects of low root zonetemperature (RZT) on soybean [Glycine max(L.) Merr.] nodulationand nitrogen fixation. Three RZTs were tested: 25 (optimal),17.5 (somewhat inhibitory), and 15°C (very inhibitory).At each temperature some PGPR strains increased the number ofnodules formed and the amount of fixed nitrogen when co-inoculatedwithB. japonicum,but the stimulatory strains varied with temperatures.The strains that were most stimulatory varied among temperaturesand were as follows: 15°C,Serratia proteamaculans 1-102;17.5°C,S. proteamaculans 1-102andAeromonas hydrophilaP73;25°C,Serratia liquefaciens2-68. Bradyrhizobium japonicum ; Glycine max; plant growth promoting rhizobacteria; suboptimal root zone temperatures     

Pre-incubation of Bradyrhizobium japonicum with jasmonates accelerates nodulation and nitrogen fixation in soybean (Glycine max) at optimal and suboptimal root zone temperatures

Jasmonic acid (JA) and methyl jasmonate, collectively known as jasmonates, are naturally occurring in plants; they are important signal molecules involved in induced disease resistance and mediate many physiological activities in plants. We studied the effect of JA and its methyl ester, methyl jasmonate (MeJA), on the induction of nod genes in Bradyrhizobium japonicum GG4 (USDA3) carrying a plasmid with a translational fusion between B. japonicum nodY and lacZ of Escherichia coli, and the expression activity was measured by β-galactosidase activity. Both JA and MeJA strongly induced the expression of nod genes. They have little or no deleterious effects on the growth of B. japonicum cells, while genistein (Gen) showed inhibitory effects. We further studied the effect of JA- and MeJA-induced B. japonicum on soybean nodulation and nitrogen fixation under optimal (25°C) and suboptimal (17°C) root zone temperature (RZT) conditions. B. japonicum cells were grown in liquid yeast extract mannitol media and induced with a range of Gen, JA, and MeJA concentrations, including a treatment control with no inducer added. Soybean seedlings were grown at 25 or 17°C RZT with a constant air temperature (25°C) and inoculated, at the vegetative cotyledonary stage, with various B. japonicum induction treatments. Addition of Gen or jasmonates to B. japonicum, prior to inoculation, enhanced nodulation, nitrogen fixation, and plant growth at suboptimal RZT conditions. A higher concentration of Gen was inhibitory at 25°C, while this same concentration was stimulatory at 17°C. Interestingly, pre-incubation of B. japonicum with JA and MeJA enhanced soybean nodulation and nitrogen fixation under both optimal and suboptimal RZTs. We show that jasmonates are thus a new class of signaling molecules in the B. japonicum-soybean symbiosis and that pre-induction of B. japonicum with jasmonates can be used to enhance soybean nodulation, nitrogen fixation, and early plant growth.     

溴甲烷土壤灭菌对大豆苗期根系生长的影响

利用溴甲烷田间土壤灭菌,研究灭菌对正茬、重茬大豆苗期根系生长和产量的影响.试验结果表明,灭菌处理后重茬(连续种植3a)地大豆根系生长良好,根系形态明显改善,总根长、主根长、植株鲜重和根瘤数增加、孢囊线虫孢囊数为0.而灭菌处理后,正茬地大豆根系前期生长受到一定抑制,主根长、总根长、植株鲜重和侧根数有降低的趋势,但随时间推移,抑制幅度降低.溴甲烷处理促进大豆结瘤.灭菌后,重茬大豆与正茬大豆根系生长差异减少.溴甲烷灭菌处理可作为克服大豆连作障碍问题措施之一.     

Using signal molecule genistein to alleviate the stress of suboptimal root zone temperature on soybean-Bradyrhizobium symbiosis under different soil textures

Abstract

Suboptimal root zone temperatures (RZTs) (below 25°C) in Canada until July may adversely affect the secretion of interorganismal signal molecules such as genistein by soybean and hence, the soybean-Bradyrhizobium symbiosis. We also proposed for the first time that soil texture might play a role in these biochemical communications. Soybean plants, planted in undisturbed soil samples (with sandy, loamy and clay textures), collected from the field, were subjected to three different soil temperatures (14, 19 and 24°C). Bradyrhizobium japonicum (strain 532C) inocula, preincubated with four levels of genistein (0, 5, 10 and 20 µM), were used to inoculate the plants. The experiment was conducted at the research greenhouse of Macdonald Campus, McGill University, Canada. The effects of genistein 5 and 20 µM on soybean nodulation and growth were significant at 14°C. As genistein was more effective in loamy and clay soils, soil texture may also be a determining factor in the biochemical communications between B. japonicum and soybean.     

The influence of supra-optimal root-zone temperatures on growth and stomatal conductance in Capsicum annuum L

Pepper (Capsicum annuum L.) plants were grown aeroponically in a Singapore greenhouse under natural diurnally fluctuating ambient shoot temperatures, but at two different root-zone temperatures (RZTs): a constant 20 +/- 2 degrees C RZT and a diurnally fluctuating ambient (A) (25-40 degrees C) RZT. Plants grown at 20-RZT had more leaves, greater leaf area and dry weight than A-RZT plants. Reciprocal transfer experiments were conducted between RZTs to investigate the effect on plant growth, stomatal conductance (gs) and water relations. Transfer of plants from A-RZT to 20-RZT increased plant dry weight, leaf area, number of leaves, shoot water potential (psi shoot), and gs; while transfer of plants from 20-RZT to A-RZT decreased these parameters. Root hydraulic conductivity was measured in the latter transfer and decreased by 80% after 23 d at A-RZT. Transfer of plants from 20-RZT to A-RZT had no effect on xylem ABA concentration or xylem nitrate concentration, but reduced xylem sap pH by 0.2 units. At both RZTs, gs measured in the youngest fully expanded leaves increased with plant development. In plants with the same number of leaves, A-RZT plants had a higher gs than 20-RZT plants, but only under high atmospheric vapour pressure deficit. The roles of chemical signals and hydraulic factors in controlling gs of aeroponically grown Capsicum plants at different RZTs are discussed.     

Effect of Root and Shoot Meristem Temperature on Shoot to Root Dry Matter Partitioning and the Internal Concentrations of Nitrogen and Carbohydrates in Maize and Wheat

Maize (Zea mays L.) and spring wheat (Triticum aestivum L.)were grown in nutrient solution at uniformly high air temperature(20 °C), but different root zone temperatures (RZT 20, 16,12 °C). To manipulate the ratio of shoot activity to rootactivity, the plants were grown with their shoot base includingthe apical meristem either above (i.e. at 20 °C) or withinthe nutrient solution (i.e. at 20, 16 or 12 °C). In wheat, the ratio of shoot:root dry matter partitioning decreasedat low RZT, whereas the opposite was true for maize. In bothspecies, dry matter partitioning to the shoot was one-sidedlyincreased when the shoot base temperature, and thus shoot activity,were increased at low RZT. The concentrations of non-structuralcarbohydrates (NSC) in the shoots and roots were higher at lowin comparison to high RZT in both species, irrespective of theshoot base temperature. The concentrations of nitrogen (N) inthe shoot and root fresh matter also increased at low RZT withthe exception of maize grown at 12 °C RZT and 20 °Cshoot base temperature. The ratio of NSC:N was increased inboth species at low RZT. However this ratio was negatively correlatedwith the ratio of shoot:root dry matter partitioning in wheat,but positively correlated in maize. It is suggested that dry matter partitioning between shoot androots at low RZT is not causally related to the internal nitrogenor carbohydrate status of the plants. Furthermore, balancedactivity between shoot and roots is maintained by adaptationsin specific shoot and root activity, rather than by an alteredratio of biomass allocation between shoot and roots.Copyright1994, 1999 Academic Press Wheat, Triticum aestivum, maize, Zea mays, root temperature, shoot meristem temperature, biomass allocation, shoot:root ratio, carbohydrate status, nitrogen status, functional equilibrium     

Effects of suboptimal root zone temperatures and shoot demand on net translocation of micronutrients from the roots to the shoot of maize

The effects of suboptimal root zone temperatures (RZTs) on net translocation rates from the roots to the shoots and the concentrations of Fe, Mn, Zn, and Cu were examined in maize grown in nutrient solution or soil. Plants were grown at 12 °C, 18 °C and 24 °C RZT. At each RZT, the growth-related shoot demand for nutrients was varied by independently modifying the temperature of the shoot base (SBT) including the apical shoot meristem. The net translocation rates of Mn and Zn from the roots to the shoots were reduced at low RZTs, irrespective of the SBT and of the substrate (soil or nutrient solution). Obviously, the net translocation rates of Mn and Zn at low RZT were mainly regulated by temperature effects on the roots and not by the chemical nutrient availability in the rhizosphere or by shoot growth rate as controlled by SBTs. When both RZT and SBT were reduced, the decrease in net translocation rates of Mn and Zn was similar to the decline in the shoot growth rate and concentrations of Mn and Zn in the shoot fresh matter were not greatly affected or were even increased by low RZT. However, at high SBT and low RZT in nutrient solution, the depressed net translocation rates of Mn and Zn combined with the increased shoot growth resulted in significantly decreased concentrations of Mn and Zn in the shoot, indicating that Mn and Zn may become deficient even at high chemical availability. By contrast to Mn and Zn, the net translocation rates of Fe and Cu at all RZTs were markedly enhanced by increased SBTs. Accordingly, the concentrations of Fe and Cu in the shoot fresh matter were not greatly affected by RZTs, irrespective of the SBTs. These results indicate that the ability of roots to supply Fe and Cu to the shoot was internally regulated by the growth related shoot demand per unit of roots. Deceased 21 September 1996 Deceased 21 September 1996     

Preincubation of B. japonicum cells with genistein reduces the inhibitory effects of mineral nitrogen on soybean nodulation and nitrogen fixation under field conditions

Genistein is the major root produced isoflavonoid inducer of nod genes in the symbiosis between B. japonicum and soybean plants. Reduction in the isoflavonoid content of the host plants has recently been suggested as a possible explanation for the inhibition of mineral nitrogen (N) on the establishment of the symbiosis. In order to determine whether genistein addition could overcome this inhibition, we incubated B. japonicum cells (strain 532C) with genistein. Mineral N (in the form of NH₄NO₃) was applied at 0, 20 and 100 kg ha^-1. The experiments were conducted on both a sandy-loam soil and a clay-loam soil. Preincubation of B. japonicum cells with genistein increased soybean nodule number and nodule weight, especially in the low-N-containing sandy-loam soil and the low N fertilizer treatment. Plant growth and yield were less affected by genistein preincubation treatments than nitrogen assimilation. Total plant nitrogen content was increased by the two genistein preincubation treatments at the early flowering stage. At maturity, shoot and total plant nitrogen contents were increased by the 40 μM genistein preincubation treatment at the sandy-loam soil site. Total nitrogen contents were increased by the 20 μM genistein preincubation treatment only at the 0 and 20 kg ha^-1 nitrate levels in clay-loam soil. Forty μM genistein preincubation treatment increased soybean yield on the sandy-loam soil. There was no difference among treatments for 100-seed weight. The results suggest that preincubation of B. japonicum cells with genistein could improve soybean nodulation and nitrogen fixation, and at least partially overcome the inhibition of mineral nitrogen on soybean nodulation and nitrogen fixation. This revised version was published online in June 2006 with corrections to the Cover Date.     

The effects of low root-zone temperature stress on two soybean (Glycine max) genotypes when combined with Bradyrhizobium strains of varying geographic origin

In areas with short growing seasons, poor early vegetative growth of soybean (Glycine max [L.] Merr.) is often attributed to the restrictive effect of cool soil conditions on nodulation and N₂-fixation by this subtropical grain legume. However, there are few studies regarding potential genetic variability of soybean and Bradyrhizobium japonicum genotypes for nodulation at cool root-zone temperatures (RZT). Experiments were conducted to (1) test for a threshold temperature for low RZT inhibition of soybean nodulation and (2) ascertain whether this threshold temperature response depends mainly on the micro- or macrosymbiont. In experiment 1 soybean seedlings (Glycine max [L.] Merr. cv. Maple Arrow) were inoculated with 1 ml of a log phase culture of B. japonicum strain 532C, H8 or H15 (the latter two strains were isolated from cold soils of Hokkaido, northern Japan) and maintained at either 16, 17.5, 19 or 25°C RZT. In experiment 2 seedlings of cv. Maple Arrow and a cold-tolerant Evans isoline were combined with strain 532C and two Hokkaido strains (H5, H30) at both 19 and 25°C RZT. Results indicated that N₂-fixation at 44 days after inoculation was substantially reduced (30–40%) by RZT as high as 19°C, due to development of less nodule mass and to a delay in the onset of N₂-fixation and a small decrease in the number of nodules formed. However, the number of nodules formed was sharply reduced and the time required for the first appearance of nodules was significantly delayed below an RZT of 17.5°C. Differences between cultivars for nodulation and N accumulation were apparent at 25°C, but were abolished by growth at 19°C, indicating that, in spite of differences in growth potential between the cultivars under optimum RZT, both cultivars were equally limited by low RZT. Differences between B. japonicum strains were consistent across temperatures and were largely attributable to higher rates of specific nodule activity recorded for strain 532C, which seemed well adapted to low RZT. These results suggest that the host plant mediates the sensitivity of N₂-fixation under low RZT and that inoculation with B. japonicum strains from cold environments is unlikely to enhance soybean N₂-fixation under cool soil conditions.     

Efficacy of biological preparations of soybean root nodule bacteria modified with a homologous lectin

The effect of various biopreparations of the root nodule bacterium Bradyrhizobium japonicum, modified with a homologous lectin, on the virulence of Rhizobia, the nitrogen-fixing activity of root nodules, and the productivity of the soybean (Glycine max (L.) Merr.) was studied. It was shown that a homologous lectin, added to a bacterial suspension when manufacturing biopreparations on a liquid and solid support, increases the efficiency of the soybean symbiotic system and the productivity of the host plant. The potentialities of using bacterial preparations modified with a homologous lectin are discussed.     

Isolation of plant-growth-promoting Bacillus strains from soybean root nodules

Endophytic bacteria reside within plant tissues and have often been found to promote plant growth. Fourteen strains of putative endophytic bacteria, not including endosymbiotic Bradyrhizobium strains, were isolated from surface-sterilized soybean (Glycine max. (L.) Merr.) root nodules. These isolates were designated as non-Bradyrhizobium endophytic bacteria (NEB). Three isolates (NEB4, NEB5, and NEB17) were found to increase soybean weight when plants were co-inoculated with one of the isolates and Bradyrhizobium japonicum under nitrogen-free conditions, compared with plants inoculated with B. japonicum alone. In the absence of B. japonicum, these isolates neither nodulated soybean, nor did they affect soybean growth. All three isolates were Gram-positive spore-forming rods. While Biolog tests indicated that the three isolates belonged to the genus Bacillus, it was not possible to determine the species. Phylogenetic analysis of 16S rRNA gene hypervariant region sequences demonstrated that both NEB4 and NEB5 are Bacillus subtilis strains, and that NEB17 is a Bacillus thuringiensis strain.     

Sensing Iron--A Whole Plant Approach

Regulatory mechanisms leading to cellular Fe homeostasis wereinvestigated inPlantago (Plantago lanceolata L.) plants grownhydroponically at different temperature regimes either in thepresence or absence of iron. During the experimental periodof 6 d, growth was not affected by Fe availability, but wasdecreased by lowering the root zone temperature (RZT) from 24to 12°C. Cultivating plants at low RZT decreased the reductionactivity for ferric chelates in Fe-deficient plants. In thepresence of iron, the temperature regime did not affect Fe accumulationby root cells, but decreased translocation of Fe to the shoot,and chlorosis of young leaves was observed at suboptimal RZT.Under these conditions root-mediated reduction of ferric chelateswas increased. In cold-treated plants this effect was specificto Fe and could not be evoked by Mn²⁺and Zn ^{+ 2}additions. Supplementingthe medium with the ferrous scavenger ferrozine caused a furtherenhancement in reduction rates, probably due to mobilizationof apoplastic Fe. These results can be explained plausibly ifdifferent sites of Fe sensing are postulated and if it is assumedthat both the absence and presence of iron could be a signalincreasing root reduction activity. Copyright 2000 Annals ofBotany Company Adaptation, iron uptake regulation, ferric reduction, Plantago lanceolata, root zone temperature, whole plant signalling     

Shoot versus Root Signal Involvement in Nodulation and Vegetative Growth in Wild-Type and Hypernodulating Soybean Genotypes

Grafting studies involving Williams 82 (normally nodulating) and NOD1-3 (hypernodulating) soybean (Glycine max [L.] Merr.) lines and Lablab purpureus were used to evaluate the effect of shoot and root on nodulation control and plant growth. A single- or double-wedge graft technique, with superimposed partial defoliation, was used to separate signal control from a photosynthate supply effect. Grafting of hypernodulated soybean shoots to roots of Williams 82 or L. purpureus resulted in increased nodule numbers. Grafting of two shoots to one root enhanced root growth in both soybean genotypes, whereas the nodule number was a function of shoot genotype but not of the photosynthetic area. In double-shoot, single-root-grafted plants, removing trifoliolate leaves from either Williams 82 or NOD1-3 shoots decreased root and shoot dry matter, attributable to decreased photosynthetic source. Concurrently, Williams 82 shoot defoliation increased the nodule number, whereas NOD1-3 shoot defoliation decreased the nodule number on both soybean and L. purpureus roots. It was concluded that (a) soybean leaves are the dominant site of autoregulatory signal production, which controls the nodule number; (b) soybean and L. purpureus have a common, translocatable, autoregulatory control signal; (c) seedling vegetative growth and nodule number are independently controlled; and (d) two signals, inhibitor and promoter, may be involved in controlling legume nodule numbers.     

Soybean root and nodule nitrate reductase

Nitrate reductase (NR) activity was followed in root and nodule from Glycine max (L.) Merr. (Cv. Tracy) inoculated with Rhizobium japonicum . Initially, a plus NO^3- in vivo assay was used. When chlorate-resistant mutants were used as inoculum, nodule NR activity was reduced by about 90%. indicating that the bacteroid accounts for much of the normal nodule's NR. With plants 3 to 15 weeks of age nodule NR activity (g fresh weight)^-1 was highest in young plants and root activity highest in old plants. Root and nodule total NR activity increased with plant age and were often not greatly different. Root NR activity correlated with plant NO^3- supply and increased from 0.8 to 11.4 μmol plant^-1 h^-1 as NO^3- was increased from 0 to 3 m M . In contrast, nodule NR activity was high in plants grown without NO^3- and did not appear to increase as nitrate supply to the plant was increased. Nodule activity was 6 to 14 μmol NO^2- plant^-1 h^-1. Use of a minus NO^3- in vivo assay had little affect on root NR activity, but greatly reduced nodule activity. Root tissue was found to have 5 to 38 times more NO^3- than nodule tissue. It is concluded that low nitrate levels within the nodule limit NR activity and that it is improbable that the nodule is a major site of plant nitrate reduction.     

Nitrate metabolism in soybean root nodules

The nitrate metabolism in nodules induced by Bradyrhizobium japonicum strain PJ17 on roots of soybean [ Glycine max (L.) Merr. cv. Hodgson] has been characterized by the nitrate reductase (NR; EC 1.6.6.1 and EC 1.6.6.3) activity of both partners of the symbiosis. NR activities of bacteroids and nodular cytosol were comparable and significantly higher than those of the roots. Nitrate reduction led to nitrite accumulation in root nodules, which was maximum after pod filling. The nodule had the capacity to metabolize nitrite via nitrite reductase (NiR; EC 1.6.6.4), at least in the cytosolic fraction. This activity was partly inhibited by the low content of free O₂ in the nodule. Indeed, nitrite accumulation decreased in the presence of an increased external pressure of O₂.