A non-destructive field assay for soybean nitrogen fixation by acetylene reduction

Summary A system for employing open-ended root chambers to measurein situ acetylene reduction rates under field conditions is described. Gas mixtures containing about 2 mbar acetylene were continuously flowed through the chambers providing a continuous record of acetylene reduction. These chambers have been used to measure acetylene reduction rates of soybeans during three growing seasons. The system has proved to be reliable with a high degree of precision. The large amount of plant-to-plant variability observed in N₂ fixation research has been confirmed by the data collected with this system. However, such variability in physiological studies can be reduced by using a non-destructive system to compare the response of an individual plant with its rates before treatment.     

Soybean nodule gas permeability,nitrogen fixation and dirunal cycles in soil temperature

While diurnal cycles in nitrogen fixation rates are sometimes assumed to result from diurnal variation in photosynthetically active radiation, contradicting evidence exists that indicate soil temperature is the primary environmental influence. These studies assessed the significance of temperature on soybean nitrogen fixation under field conditions. Two groups of intact field-grown soybean plants, one at ambient and the other exposed to a 10°C diurnal variation in soil temperature, were nondestructively assayed for acetylene reduction rates. Activity was closely associated with soil temperature (R²=0.85), even when temperature was 12 h out of phase with ambient. Data were also obtained to determine if the effects of rhizosphere temperature on nitrogen fixation are mediated through an effect on the nodule oxygen permeability. Nodule oxygen permeability of intact, aeroponically grown soybean was closely correlated with the diurnal changes in temperature (R²=0.90).     

Drought-avoidant soybean germplasm maintains nitrogen-fixation capacity under water stress

Inoculated soybeans (Glycine max L. (Merrill)) were grown in controlled environments to evaluate the relationship between genotype and plant water status on nodule function, nitrogen assimilation, growth rates, and seed yield. Plants were grown under well-watered (WW) and water-stressed (WS) conditions during the linear pod-filling growth stage in sand culture using N-free nutrient solution. Dry matter and N accumulation were greater for the drought-adapted Plant Introduction 416937 (PI) than for Forrest, a commercially adapted genotype of similar phenology. These differences are attributed to: (i) more favorable internal water balance throughout the pod-filling period (higher total leaf water potential), (ii) higher photosynthetic function (more total leaf area and higher net carbon exchange rates), and (iii) stronger nodule function (larger nodule mass, greater specific and total nodule activity, and thus more nitrogen assimilation) for the PI than for Forrest. While Forrest out yielded the PI under WW conditions, the percentage reduction in seed mass per plant was less for the PI than for Forrest when both genotypes were exposed to desiccating conditions. The inference is that soybean germplasm with the capacity to maintain tissue turgidity, and thus leaf and nodule function, during reproductively-imposed desiccation may reduce the extent to which yield is compromised during drought. These findings have implications for the role of symbiotic nitrogen fixation in conserving yield under dry weather conditions.Abbreviations DAE Days After Emergence - NCE Net CO₂ Exchange - PI PI 416937 - SNA Specific Nodule Activity - TNA Total Nodule Activity - WS Water Stressed - WW Well Watered     

Waterlogging effect on xylem sap glutamine of nodulated soybean

Waterlogging of soybean plants (Glycine max L.) led to impaired symbiotic N₂ fixation and a marked decline in glutamine (Gln) concentration in xylem bleeding sap. Xylem Gln concentration increased during the growth cycle of the plant and was correlated with nodule formation. Treatments known to impair N₂ fixation, such as exposing the root system to pure N₂ gas or a mixture of Ar and O₂ (80:20; v/v), led to specific declines in xylem sap Gln. The decrease in Gln observed during waterlogging was also seen on transfer of nodulated plants to aerated hydroponics, where the decline was highly correlated with ureide content in the xylem sap. Upon flooding the nodulated root system, the specific decline in xylem sap Gln could be detected within 10 min and reached a minimum within 60 min, indicating that waterlogging has an immediate effect on N₂ fixation. It is concluded that xylem Gln arises directly from N₂-fixation and is a useful indicator of N₂ fixation activity of symbiotic soybean plants.     

Nodule gas exchange and water potential response to rapid imposition of water deficit

The permeability (P) of the gaseous diffusion barrier in the nodules of soybean [Glycine max (L.) Merr.] decreases when water deficits are extended over a 7 to 10 d period. The mechanism controlling P changes is unclear, but may result from the release of water to intercellular pathways, and an associated change in the nodule water potential. The purpose of these experiments was to impose water deficit treatments rapidly in order to determine the early sequence of the responses of nodule water potential and nodule gas exchange without the complications that arise from long-term water deficit treatments. A vertical, split-root system was used to separate nodule drying effects from plant water deficits by replacing humidified air that was passed over upper root nodules in well-watered plants with dry air, or by replacing the nutrient solution that surrounded lower roots with -1.0 MPa polyethylene glycol (PEG) solution, or by a combination of the dry air and PEG treatments. The PEG treatment caused large decreases in both the components of nodule water potential and nodule relative water content, but there was no indication that these factors had immediate, direct effects on either nitrogenase activity or P. After 7 h of the PEG treatment a significant decrease in nitrogenase activity was found but no decrease in P was detected. These results indicate that changes in nitrogenase activity in response to water deficits precede decreases in P. Exposure of nodules to dry air in well-watered plants had no significant effect on either nitrogenase activity or P during the 7 h treatment.     

Exclusion of inefficient Bradyrhizobium japonicum serogroups by soybean genotypes

Soybean [Glycine max (L.) Merr.] forms a symbiosis with serogroups of Bradyrhizobium japonicum that differ in their dinitrogen fixing abilities. The objectives of this study were to identify soybean genotypes that would restrict nodulation by relatively inefficient serogroups indigenous to a large portion of the southeastern USA, and then characterize the nodulation responses of selected genotypes with specific bradyrhizobial strains under controlled conditions. From field screening trials followed by controlled single and competitive inoculations of serogroups USDA 31, 76 and 110, twelve soybean genotypes out of 382 tested were identified with varying levels of exclusion abilities. Soybean nodule occupancies and nodulation characteristics were influenced by plant genotype, environment (i.e. field or greenhouse), bradyrhizobial serogroup, and location of nodules (i.e. tap or lateral root). The cultivar Centennial sustains high seed yields even though it nodulates to a high degree with the inefficient serogroup USDA 31. In contrast, data from the released cultivars Braxton, Centennial and Coker 368 indicate that they may have been selected to exclude the inefficient serogroup USDA 76 from their tap root nodules, possibly contributing to high seed yield.     

Vascular transport and soybean nodule function: II. A role for phloem supply in product export*

Abstract The ureide content of soybean (Glycine max (L.) Merr.) nodules was unaffected by variations in the transpirational rate, while whole plant manipulations designed to decrease phloem supply to nodules resulted in lower rates of nitrogenase activity and an increase in the ureide content of the nodules. The rate of ureide export from the nodule was estimated from the exponential rate of decrease in the pool size of ureides in nodules, following exposure to an N₂-free atmosphere (Ar:O₂). Export was greatly reduced under treatments which reduced phloem supply to the nodule. A water budget for nodules suggested that the delivery of water to the nodule via mass flow in the phloem was comparable to that required for export of ureides from the nodule in the xylem from the nodule. Therefore, we suggest that xylem export from nodules is related to the phloem supply to the nodule rather than to the transpirational flux in the parent root. This suggestion is related to the reported decreases in nodule permeability to gases under conditions of phloem deprivation.     

A block in the endocytosis of Rhizobium allows cellular differentiation in nodules but affects the expression of some peribacteroid membrane nodulins

A transposon-induced mutant (T8-1) of Bradyrhizobium japonicum (61A76) was unable to develop into the nitrogen-fixing endosymbiotic form, the bacteroid. Comparison between this mutant and T5-95, an ineffective (non-nitrogen fixing, Fix^-) mutant, confirmed that the process of bacteroid development is a distinct phase of differentiation of the endosymbiont and is independent of nitrogen fixation activity. The T8-1 mutant was able to induce normal-size nodules which differentiated two plant cell types and contained numerous infection threads. However, the infected cells were devoid of bacteroids. Electron microscopy revealed that the ends of the infection threads were broken down in a normal manner once the thread had penetrated the cells, but the mutant was not internalized by endocytosis. The lack of peribacteroid membrane (PBM) in nodules induced by this mutant was correlated with a reduced level of expression of plant genes coding for PBM nodulins. These genes were expressed in the T5-95 mutant, showing that the low expression in T8-1 was not due to the lack of nitrogen fixation. One of the PBM nodulins, nodulin-26, was found at normal levels in the nodules which lack PBM, suggesting that there are at least two developmental stages in PBM biosynthesis. These data suggest that a coordination of plant and Rhizobium gene expression is required for the release and internalization of bacteria into the PBM compartments of infected cells of nodules.author for correspondence     

Vascular transport and soybean nodule function: nodule xylem is a blind alley, not a throughway

Abstract. The only published consideration of product removal from the soybean root nodule hypothesizes that the peripheral xylem circuit of this determinate nodule structure is flushed by the transpiration stream. However, dyes fed to the transpiration stream through a cut root distal to the nodule do not enter the nodule, and the observed movement of radio-tracers from the root into the nodule can be explained by simple diffusion, Also, there are few xylem elements in the nodule, and these elements are of a small diameter, such that this path can not act as a functional loop of the root system. Further, in this study, nodule vascular strands were never observed to be continuous about the nodule, but were observed to end at the nodule tip in a loop within an intact, closed endodermal sac. Nodule vascular tissue was invested in a pericycle of at least three cell layers. These cells are suggested to be active in the loading of the xylem apoplast with ureides, such that the xylem of the nodule always operates in an export role. Nodule water requirements may be supplied via the phloem or the root cortex apoplasm.     

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.     

Symbiotic interactions between soybean and competing strains ofBradyrhizobium japonicum

Selected symbiotic characteristics of fiveBradyrhizobium japonicum strains were assessed in association with ‘Ransom’ soybean plants (Glycine max [L.] Merr.). In the first of two greenhouse experiments, relative nodulation competitiveness of the strains was examined. Strains were grouped into pairs, and corresponding cells were applied to surface-disinfected seeds so as to provide seven ratios of cell numbers between the two strains. Tap root nodules were harvested 28 days after sowing and serotyped by means of an enzyme-linked immunosorbent assay. Strains differed considerably in nodulation competitiveness, and these differences were successfully quantified using relationships previously proposed in the literature. A second experiment involved assessment of the reproducibility of this technique and characterization of the symbiotic response to single- and double-strain inocula. Differences in relative nodulating abilities of strains were apparent between experiments and were possibly related to observed variations in greenhouse temperatures. Plant shoot weight and total N content were not significantly correlated with nodule number or weight when evaluated across inoculation treatments, but these correlations were often significant within inoculation treatments. Certain double-strain inocula produced either positive or negative effects on shoot weight, N content, and nodulation, when compared with values predicted from corresponding controls receiving single-strain inocula. Paper No. 11741 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, NC 27695-7643, USA.     

Mechanism of soybean nodule adaptation to different oxygen pressures

Abstract. Soybean nodules showed the ability to adapt to oxygen pressures above and below ambient levels and this adaptation involved a decrease in cortical intercellular air-spaces with increasing oxygen pressure. Nodules were grown in oxygen pressures from 4.7 to 75 kPa and the decrease in number and size of cortical intercellular spaces with increasing oxygen pressure was the result of a change in cell structure and the deposition of an electron dense material within intercellular spaces. Exposure to a saturating pressure of acetylene caused a similar inhibition of respiration and nitrogenase activity in nodules developed in oxygen pressures from 4.7 to 47 kPa, suggesting that putative acetylene-induced changes in oxygen diffusion resistance occur by a different mechanism than that involved in long-term adaptation to oxygen. However, in nodules grown at 75 kPa oxygen, the initial specific activities were lower and did not show an acetylene induced decline. The results are discussed in terms of the current theories of regulation of nitrogenase activity by oxygen availability.     

Effects of defoliation on seed protein concentration in normal and high protein lines of soybean

Two high (NC106, NC111) and two normal (NC103, NC107) seed protein concentration lines, derived from two different recurrent selection populations of soybean (Glycine max L. Merr.) were subjected to partial defoliation at beginning seed fill (R5) under outdoor pot culture and field conditions. The aim of this study was to test the hypothesis that capacity to store N in vegetative organs and/or to mobilize that N to reproductive organs is associated with the high seed protein concentration trait. Symbiotic N₂ fixation was the sole source of N in the pot experiment and the major source of N (met > 50% of the N requirement) in the low N soil used in the field experiment. Seed protein concentration and seed yield at maturity in both experiments and N accumulation and mobilization between R5 and maturity in the pot experiment were measured. The four genotypes did not differ significantly with respect to the amount of N accumulated before beginning seed fill (R5). Removal of up to two leaflets per trifoliolate leaf at R5 significantly decreased the seed protein concentration of NC107/111 but had no effect on this trait in NC103/106. Defoliation treatments significantly decreased seed yield, whole plant N accumulation (N₂-fixation) during reproductive growth and vegetative N mobilization of all genotypes. Differences in harvest indices between the high and low protein lines accounted for approximately 35% of the differences in protein concentration. The two normal protein lines mobilized more vegetative N to the seed (average. 5.26 g plant^–1) than the two high protein lines (average. 4.28 g plant^–1). The two high seed protein lines (NC106, NC111) exhibited significantly different relative dependencies of reproductive N accumulation on vegetative N mobilization, 45% vs. 29%, in the control treatment. Whereas, NC103 with normal and NC106 with high seed protein concentration exhibited similar relative dependencies of reproductive N accumulation on vegetative N mobilization, (47% vs. 45%). Collectively, these results indicate that N stored in shoot organs before R5 and greater absolute and relative contribution of vegetative N mobilization to the reproductive N requirement are not responsible for the high seed protein concentration trait.Abbreviations DAT days after transplanting - R5 fifth reproductive stage according to Fehr and Caviness, 1977 Mention of trademark or proprietary product does not constitute a guarantee or warranty of the product by the United States Department of Agriculture and does not imply its approval to the exclusion of other products that may also be suitable.     

Vascular transport and soybean nodule function. III: Implications of a continual phloem supply of carbon and water

Abstract. In soybean, stores of carbon within the leaf have been demonstrated to support nodule metabolism under both photosynthetic and non-photosynthetic conditions. Indeed, a net depletion of nodule starch is observed only under conditions of suboptimal rates of nodule metabolism. Therefore, maximal rates of nodule metabolism are associated with a continual supply of phloem sap to the nodule, delivering water, carbon and other solutes. A restriction of phloem supply to the nodule may result in changes in turgor between the apoplast of the export pathway and the symplast of the nodule. This change may cause the observed decrease in the permeability to gases and to the rate of product export from nodules deprived of a phloem supply. It is suggested that nodule metabolism is homeostatically regulated in terms of internal O₂ levels by the delivery of phloem water and solutes.     

Regulation of soybean nodule phosphoenolpyruvate carboxylase in vivo

The sensitivity of soybean ( Glycine max L. Merr, cv. PS47) nodule phosphoenolpyruvate carboxylase (PEPC; EC 4.1.1.31) to inhibition by L-malate in vitro increased when well-nodulated plants were subjected to decapitation (shoot removal). There was no effect of decapitation on the apparent K_m of the enzyme for its substrate PEP but the I₅₀ (L-malate) decreased from 4.2 to 1.7 m M. The total amount of PEP doubled and that of malate decreased by half in the nodules of decapitated plants relative to the control plants. This observation was consistent with a decrease in the activity of PEPC in vivo as a result of the increased malate sensitivity of the enzyme observed in vitro. Sucrose levels in the nodules declined in response to decapitation but there were no effects on the levels of glucose, fructose, pyruvate, 2-oxoglutarate, glutamine or glutamate. The results are discussed in terms of the role of protein phosphorylation in the regulation of PEPC activity in legume nodules.     

Agronomic evaluation of tissue-culture-derived soybean plants

Summary Genetic alterations of regenerated plants based on the tissue culture process (somaclonal variation) have become common for many plant species including soybean [Glycine max (L.) Merr.]. The objective of this study was to test for the presence of tissue-culture-derived genetic variation in eight agronomic traits in homozygous progeny regenerated by organogenesis using the commercially important cultivar Asgrow A3127. A total of 86 lines derived by repeated self-pollination of nine regenerated plants was grown in two locations for 2 years. When compared to the unregenerated parent, statistically significant variation (P<0.05) was found for maturity, lodging, height, seed protein and oil, but not for seed quality, seed weight, or seed yield. All of the variation noted was beneficial and did not involve decreased yield. Since the differences were not large, the results indicate that the tissue culture process is not necessarily detrimental to plant performance, which is an important consideration since tissue culture techniques are used in many genetic engineering methods.     

A novel plasma membrane-bound thioredoxin from soybean

Two thioredoxin cDNAs from soybean were isolated by screening an expression library using an anti-(plasma membrane) serum. The nucleotide sequences of the two cDNAs were found to be 89% identical. The polypeptides encoded by the two cDNAs, designated TRX1 and TRX2, contain a disulfide active site, as found in other thioredoxins. TRX1 was expressed as a fusion protein in Escherichia coli and shown to possess thiol-disufide interchange activity. Unlike other eukaryotic thioredoxins, these two soybean thioredoxins contain a putative transmembrane domain in their N-terminal regions. To determine subcellular location, the TRX1 was fused with a reporter epitope at its C-terminus and expressed in transgenic tobacco plants. The fusion protein was co-purified with plasma membrane markers 1,3-glucan synthase and vanadate-sensitive ATPase, indicating the plasma membrane location of TRX1. When the reporter epitope was inserted between the start codon and the transmembrane domain in the N-terminus, the fusion protein was found in the soluble fraction, possibly due to disruption of the transmembrane domain by the highly hydrophilic epitope sequence. Taken together, our results demonstrate that soybean TRX1 is a plasma membrane-bound thioredoxin, which is most likely anchored to the membrane through the N-terminal transmembrane domain. It is known that plant plasma membranes contain various proteins with thiol-disulfide interchange activity. The soybean thioredoxins reported here are the first group of such proteins to be characterized at the molecular level. However, the biological function of the plasma membrane-bound thioredoxin remains to be determined.     

Iron-deficiency chlorosis evaluation of soybean with tissue culture

Summary The objectives of this study were: (i) to develop a tissue culture technique for the evaluation of Fe efficiency in soybean, and (ii) to compare the laboratory technique with field Fe chlorosis scores. Nineteen genotypes that had low and high levels of Fe efficiency were evaluated in the laboratory and at five field locations. Friable callus was induced from epicotyl sections, weighed, and placed on two different modified Murashige and Skoog media; one low in -naphthaleneacetic acid and the other low in Fe. Callus growth was rated as lack of growth compared to respective controls. As an example, Fe-inefficient cultivars (Asgrow A3205 and Pride B216) had significantly reduced growth compared to Fe-efficient germ plasm lines (All and A14). Correlation between the laboratory and field chlorosis rating was highest for the low auxin medium (r ² = 0.78), although correlation for the low Fe medium was also significant (r ² = 0.72). These results show that in vitro evaluation for Fe efficiency can be a useful tool for plant breeders.     

Ultrastructural specialization for ureide production in uninfected cells of soybean root nodules

Summary Ultrastructural studies were conducted on root nodules of soybean (Glycine max) inoculated as seeds withRhizobium japonicum. The development of the large peroxisomes and abundant tubular endoplasmic reticulum (ER) characteristic of the uninfected interstitial cells was followed during nodule growth and maturation. Quantitative data on differences between the uninfected and infected cells in volumes and numbers of peroxisomes, plastids and mitochondria were analyzed statistically. The peroxisomes are 60 times greater in volume per unit cytoplasm in the uninfected cells than the small presumptive peroxisomes in the infected cells. Plastids are about equal in volume in the two types of cells. Mitochondria have 4 × the volume and 3 × the number of profiles per unit cytoplasm in the infected cells than in the uninfected. The observations are discussed in relation to published evidence that several enzymes involved in ureide production are localized in organelles of the uninfected cells. The uninfected cells are viewed as essential components in the symbiotic relationship between host and bacterium.Abbreviations DAB 3,3-diaminobenzidine - ER endoplasmic reticulum