Proline Accumulation, Nitrogenase (C2H2 reducing) Activity and Activities of Enzymes related to Proline Metabolism in Drought-Stressed Soybean Nodules

We examined the effect of drought stress on proline accumulation,nitrogenase activity and activities of enzymes related to prolinemetabolism in soybean (Glycine max [L.] Merr.) nodules. Nitrogenase(C₂H₂ reducing) activity was inhibited 90% or more as a resultof drought stress. This inhibition was substantially reversedafter a 4 h recovery period. Pyrroline-5-carboxylate reductaseactivity in extracts of drought-stressed nodules from 25-d-oldplants was 55% higher than in unstressed nodules, but the sameactivity in preparations from 55-d-old plants was similar tothat of control plants. Extracts of recovering nodules on plantsof both ages had activities near those of controls. Droughtstress increased the activity of the pentose phosphate pathwayby about 65% in extracts of nodules from 55-d-old plants, butthere was no effect in extracts of nodules from younger plants(25-d-old). Proline dehydrogenase activity was 3.7 and 1.6 timeshigher in bacteroids isolated from nodules taken from 25- and55-d-old stressed plants, respectively, than in comparable controlbacteroids. This activity remained high in bacteroids from bothsets of recovering nodules. The amount of proline in extractsfrom stressed nodules was 3- to 4-fold higher than in unstressednodules, despite increased proline dehydrogenase activity andremained high in nodules collected 4 h after rewatering. Thisincrease was observed in both cytoplasmic and bacteroid fractions.The possible physiological significance of these results isdiscussed. Key words: Proline metabolism, pentose phosphate pathway, drought stress, soybean nodules     

Proline accumulation inside symbiosomes of faba bean nodules under salt stress

A two‐week salt treatment (NaCl, 100 m M ) induced a 50% inhibition of acetylene reduction activity (ARA) of faba bean ( Vicia faba L. var. minor cv. Soravi) nodules, associated with a large increase in the nodule pool of amino acids. The concentration of proline in the different nodule compartments was determined after calculating their respective volumes from their areas on electron micrographs. The proline concentration exhibited a large increase, especially in the cytosol where its amount was 8‐fold enhanced under salt stress, whereas the low proline content of bacteroids was less affected. Increase of proline concentration in faba bean nodules subjected to salt stress was correlated with an enhancement of the cytosolic Δ¹‐pyrroline‐5‐carboxylate synthetase (EC 2.7.2.11 + EC 1.2.1.41; P5CS) activity. Experiments with purified symbiosome preparations showed that the greatest proline content occurred in the peribacteroid space (PBS), where proline was the most abundant amino acid, with a concentration reaching 15.3 m M under salt stress. Proline accumulation in the PBS resulted both from a diffusive transport from the host cell to the symbiosomes through the peribacteroid membrane (PBM) and from the very low rate of uptake by faba bean bacteroids. This accumulation could be partly responsible for the 1.7‐fold enlargement of the symbiosome volume observed in salt‐stressed nodules. In incubations of bacteroids, isolated from salt‐stressed or unstressed plants and supplied with O₂ by purified oxyleghemoglobin, addition of proline stimulated neither O₂ consumption nor ARA. These results were consistent with proline playing a role as osmoticum, rather than energy source for bacteroid N₂ fixation in amide‐exporting legumes such as faba bean.     

Metabolite transport across the peribacteroid membrane during broad bean development

A temporal pattern of the peribacteroid membrane (PBM) transport function was studied. Spectrophotometric recording was used for establishing the effect of carbon-and nitrogen-containing substrates (malate, succinate, and glutamate) on the acidification of the peribacteroid space and the intensity of light scattering in the symbiosome suspension from broad bean (Vicia faba L.) root nodules of different age. At the early stages of nodule formation and functioning, PBM is permeable not only for malate and succinate, but also for glutamate, and this permeability fully provides for the active bacteroid division and the nitrogenase complex synthesis in the bacteroids at the expense of the carbon-and nitrogen-containing substrates. Mature nodules are characterized by the greatest nitrogen-fixing activity. In these nodules, PBM is selectively permeable for malate and succinate, but constitutes a barrier for glutamate. Thereby, mutually beneficial relations between the symbiotic partners are achieved. In senescent nodules, a rearrangement of symbiotic interactions is directed toward a minimization of both carbon and nitrogen metabolite consumption by the bacteroids. It is concluded that, in the course of the development of the legume-rhizobia symbiosis, the PBM transport function is changed. This function determines a qualitatively different pattern of symbiotic partner interactions in the following sequence: parasitism-mutualism-commensalism.     

Uptake of glycine betaine and its analogues by bacteroids of Rhizobium meliloti

Bacteroids isolated from alfalfa nodules induced by Rhizobium meliloti 102F34 transported glycine betaine at a constant rate for up to 30 min. Addition of sodium salts greatly increased the uptake activity, whereas other salts or non-electrolytes had less effect. The apparent Km for glycine betaine uptake was 8.3 microM and V was about 0.84 nmol min-1 (mg protein)-1 in the presence of 200 mM-NaCl which gave maximum stimulation of the transport. Supplementing bacteroid suspensions with various energy-yielding substrates, or ATP, did not increase glycine betaine uptake rates. The uncoupler carbonyl cyanide m-chlorophenylhydrazone (CCCP), and the respiratory inhibitor potassium cyanide strongly inhibited glycine betaine uptake, but arsenate was totally inactive. Glycine betaine transport showed considerable structural specificity: choline, proline betaine, gamma-butyrobetaine and trigonelline did not competitively inhibit the system, although choline and proline betaine were transported by bacteroids. Both a high-affinity activity and a low-affinity activity were found for choline uptake. These osmoprotective compounds might have a significant role in the maintenance of nitrogenase activity in bacteroids subjected to salt stress.     

Respiration supported nitrogenase activity of isolated Rhizobium meliloti bacteroids

Bacteroids having a high level of respiration-supported nitrogenase activity were isolated from nitrogen-fixing alfalfa root nodules. Gentle maceration under anaerobic conditions in the presence of sodium succinate and a fatty acid scavenging agent were employed in this method. A large proportion of isolated bacteroids retained a triple membrane structure as shown by transmission electron microscopy. Dicarboxylic acids of the TCA cycle (malate, fumarate, succinate), but not glutamate or aspartate, supported sufficient respiratory activity to supply the nitrogenase system with ATP and reducing equivalents and to protect the nitrogenase system from inactivation by 4% oxygen over a period of 20-30 min. Sugars did not support nitrogenase activity in intact bacteroids. The properties of the isolated bacteroids were ascribed to minimal damage to the cytoplasmic membrane and peribacteroidal membrane during isolation. With succinate as substrate and oxygen as terminal electron acceptor, initial nitrogenase activity was determined at 4% oxygen in the gas phase of the assay system employed. At this oxygen concentration, the sustained rate of acetylene reduction by respiring bacteroids was linear up to 30 min. Bacteroid activity declined rapidly with time of exposure to oxygen above 4% in the gas phase. The optimum temperature range for this activity was 10-20 degrees C. Nitrogenase activity was measurable at incubation temperatures below 10 degrees C under 4% oxygen. Functionally intact bacteroids had little nitrogenase activity under anaerobic conditions in the presence of an external source of ATP and reductant. Treatment of the bacteroids with chlorpromazine eliminated respiration-supported activity and rendered the bacteroid cell membrane permeable to external ATP. Bacteroids treated with chlorpromazine had high acetylene reducing activity with external ATP and dithionite in the absence of oxygen.     

Carbon metabolism and bacteroid respiration in nodules of chick-pea (Cicer arietinum L.) plants grown under saline conditions

ABSTRACT

The present work investigates the relationships between nitrogen fixation, carbon metabolism and oxygen consumption by bacteroids of Mesorhizobium ciceri in root nodules of chick-pea plants. Its aim was to establish whether some of the compounds which accumulate under salt stress may be used as respiratory substrates by bacteroids to fuel their own metabolism and nitrogenase activity. Plants were grown in a growth chamber, and salt stress was induced by adding 50 mM NaCl to the nutrient solution at sowing. The data presented here show a rise in fermentative metabolism in nodules of chick-pea plants exposed to high salinity, and suggest that proline, lactate or ethanol, may play an important role as energy-yielding substrates for bacteroids in this plant species. The bacteroids could utilize glucose as a respiratory substrate both under control and saline conditions, while malate did not appear to be the preferred substrate in the presence of salt.     

The role of formate metabolism in nitrogen fixation in Rhizobium Spp.

Formate metabolism supported nitrogen-fixation activity in free-living cultures of Rhizobium japonicum. However, formate0dependent nitrogense activity was observed only in the presence of carbon sources such as glutamate, ribose or aspartate which by themselves were unable to support nitrogenase activity. Formate-dependent nitrogenase activity was not detected in the presence of carbon sources such as malate, gluconate or glycerol which by themselves supported nitrogenase activity. A mutant strain of R. japonicum was isolated that was unable to utilise formate and was shown to lack formate dehydrogenase activity. This mutant strain exhibited no formate-dependent nitrogenase activity. Both the wild-type and mutant strains nodulated soybean plants effectively and there were no significant differences in the plant dry weight or total nitrogen content of the respective plants. Furthermore pea bacteroids lacked formate dehydrogenase activity and exogenously added formate had no stimulatory effect on the endogenous oxygen uptake rate. The role of formate metabolism in symbiotic nitrogen fixation is discussed.Abbreviation FDH formate dehydrogenase     

Cadmium-induced senescence in nodules of soybean (Glycine max L.) plants

The relationship between cadmium-induced oxidative stress and nodule senescence in soybean was investigated at two different concentrations of cadmium ions (50 and 200 μM), in solution culture. High cadmium concentration (200 μM) resulted in oxidative stress, which was indicated by an increase in thiobarbituric acid reactive substances content and a decrease in leghemoglobin levels. Consequently, nitrogenase activity was decreased, and increases in iron and ferritin levels were obtained. Senescent parameters such as ethylene production, increased levels of ammonium and an increase in protease activity were simultaneously observed. Glutamate dehydrogenase activity was also increased. Peroxidase activity decreased at the higher cadmium concentration while the lower cadmium treatment produced changes in peroxidase isoforms, compared to control nodules. Ultrastructural investigation of the nodules showed alterations with a reduction of both bacteroids number per symbiosome and the effective area for N₂-fixation. These results strongly suggest that, at least at the higher concentration, cadmium induces nodule senescence in soybean plants.     

Effect of disabling bacteroid proline catabolism on the response of soybeans to repeated drought stress

The aim of this study is to evaluate the contribution of bacteroidproline catabolism as an adaptation to drought stress in soybeanplants. To accomplish this, soybeans (Glycine max L. Merr.)were inoculated with either a parental strain of Bradyrhizobiumjaponicum which was able to catabolize proline, or a mutantstrain unable to catabolize proline. A large strain-dependentdifference in nodule number and size was observed. In orderto separate inoculant-dependent effects on nodulation from effectson bacteroid proline catabolism, plants inoculated with eachstrain were only compared to other plants inoculated with thesame strain, thus removing the observed inoculant-dependentdifferences in nodulation as a bar to interpretation of theresults. This experimental design allowed a comparison of thedrought penalty on yield for plants with parental bacteroidsand for plants with mutant bacteroids. The two results werethen compared to each other in order to evaluate the impactof the ability of bacteroids to catabolize proline on the responseto drought stress. When water stress was mild, soybean plants inoculated with bacteriaunable to catabolize proline suffered twice the percentage decreasein seed yield as did plants inoculated with bacteria able tocatabolize proline. However, when stress was severe there wasno significant effect of the ability of bacteroids to catabolizeproline on drought imposed decrease in seed yield. These resultssuggest that increasing the oxidative flux of proline in bacteroidsmight provide an agronomically significant yield advantage whenstress is modest, but that severe drought stress would probablyoverwhelm this yield benefit. Key words: N₂-fixation, proline dehydrogenase, drought stress     

The soybean NRAMP homologue,GmDMT1, is a symbiotic divalent metal transporter capable of ferrous iron transport

Iron is an important nutrient in N2-fixing legume root nodules. Iron supplied to the nodule is used by the plant for the synthesis of leghemoglobin, while in the bacteroid fraction, it is used as an essential cofactor for the bacterial N2-fixing enzyme, nitrogenase, and iron-containing proteins of the electron transport chain. The supply of iron to the bacteroids requires initial transport across the plant-derived peribacteroid membrane, which physically separates bacteroids from the infected plant cell cytosol. In this study, we have identified Glycine max divalent metal transporter 1 (GmDmt1), a soybean homologue of the NRAMP/Dmt1 family of divalent metal ion transporters. GmDmt1 shows enhanced expression in soybean root nodules and is most highly expressed at the onset of nitrogen fixation in developing nodules. Antibodies raised against a partial fragment of GmDmt1 confirmed its presence on the peribacteroid membrane (PBM) of soybean root nodules. GmDmt1 was able to both rescue growth and enhance 55Fe(II) uptake in the ferrous iron transport deficient yeast strain (fet3fet4). The results indicate that GmDmt1 is a nodule-enhanced transporter capable of ferrous iron transport across the PBM of soybean root nodules. Its role in nodule iron homeostasis to support bacterial nitrogen fixation is discussed.     

Immuno-Gold Localization of Nitrogenase in Root Nodules of Elaeagnus pungens Thunb

The molybdenum-iron component of nitrogenase (Mo-Fe component)was purified from soybean nodule bacteroids and antibody wasraised against it in rabbits. Antibody raised against the 53kDa polypeptide which was the major protein in the Mo-Fe componentfraction of soybean nitrogenase was confirmed to be specificto the nitrogenase by immunodiffusion and immunotitration. Thenitrogenase from root nodules of Elaeagnus pungens cross-reactedwith the antibody and appeared from the results of the immunodiffusionto be partially identical to soybean nitrogenase. Using the antibody, we examined intracellular localization ofnitrogenase in root nodules of Elaeagnus pungens, in which Frankiais present as a symbiont, by immuno-gold labelling. Thin sectionsof nodules of Elaeagnus pungens were first treated with anti-nitrogenasespecific antibody and then with colloidal gold-protein A asa marker. The gold particles were observed to be concentratedin the vesicles of the endophyte Frankia. This provides strongsupport for the existence E of nitrogenase in the vesicles.Furthermore, our results suggested that nitrogenase localizesin the hyphae of the endophyte Frankia in Elaeagnus pungensnodules. ¹Present address: Iwata Experiment Station, Japan Tobacco Inc.,Iwata-gun, Shizuoka 438, Japan. (Received March 9, 1988; Accepted July 28, 1988)     

Bacteroids Isolated from Ineffective Nodules of Pisum sativum Mutant E135 (syml3) Lack Nitrogenase Activity but Contain the Two Protein Components of Nitrogenase

Pea mutant E135 (sym15) forms ineffective (Fix^–) nodulesthat lack nitrogen fixing activity. To determine the developmentalstep blocked in E135 nodules we studied the nitrogenase activitiesin isolated bacteroids and in cell-free extracts of bacteroids,and measured the two components of nitrogenase protein in bacteroids.Bacteroids prepared anaerobically from E135 nodules showed noacetylene reduction activity in the presence and absence ofmyoglobin. Furthermore, no acetylene reduction activity by cell-freeextracts of E135 bacteroids was detected in the presence ofATP-generating system and dithionite. However, immuno-blottinganalyses revealed the presence of nitrogenase components I andII in E135 nodule bacteroids. These results suggest that a hostplant gene is involved in the expression of nitrogenase activityin symbiotic bacteria. (Received May 11, 1998; Accepted August 7, 1998)     

Effect of nitrate on the organic Acid and amino Acid composition of legume nodules

Nitrate supplied to legume plants inhibits the activity of nitrogenase in Rhizobium bacteroids in root nodules. The accumulation of amino N which is known to occur in Glycine max (L.) Merr. nodules as nitrogenase activity declines was studied in more detail by analysis of changes in free amino acid composition in response to high nitrate supply. A 6-fold increase in asparagine concentration in Bradyrhizobium japonicum bacteroids was found about the time of maximum nitrogenase inhibition. However, the accumulation of amino acids in soybean nodules lagged behind the inhibition of nitrogenase. Furthermore, in studies of a second legume, Phaseolus vulgaris (L.) inoculated with two different strains of Rhizobium phaseoli, a high nitrate treatment inhibited nitrogenase but had no significant effect on amino acid composition of nodules. The possibility that nitrate may interfere with the supply of carbon substrates to bacteroids was examined by the analysis of organic acids in legume nodules supplied with nitrate. Nitrate had a small (10-20%) negative effect on the concentration of tricarboxylic acid cycle acids in P. vulgaris nodules. However, in G. max nodules, high nitrate treatment resulted in significant increases in the concentration of malate, succinate, fumarate, and citrate. Thus, carbon deprivation of bacteroids also seems unlikely as a cause of the inhibition of nitrogenase by nitrate. There was a transient increase in ammonium concentration in P. vulgaris nodules in response to high nitrate treatment. This effect was rapid relative to other effects of nitrate on nodule composition and was roughly coincident with the rapid decline in acetylene reduction activity.     

Hydrogen Effect on Nitrogenase (C2H2 Reduction) Response to Oxygen in Bradyrhizobium japonicum-Phaseoleae Symbioses

The influence of hydrogenase in Bradyrizobum-Phaseoleae symbioseswas studied ex-planta and in-planra in soybean (Glycine max)and cowpea (Vigna unguiculata). The hydrogenase was activatedby the addition of hydrogen in the incubation gas phase whichmodified the response of nitrogenase activity of Hup⁺ (hydrogenuptake positive) symbiosis to the external oxygen partial pressure.For bacteroids the hydrogenase expression increased nitrogenaseactivity at supraoptimal pO₂, acting possibly as a respiratoryprotection of nitrogenase. However, at suboptimal pO₂, nitrogenaseactivity of Hup⁺ bacteroids decreased with hydrogen, a phenomenonattributed to the lower efficiency of ATP synthesis from hydrogenthan from carbon substrates oxidation. For undisturbed nodules,the hydrogenase expression in soybean increased the optimalpO₂ for ARA (COP), from 35.3 to 40.3 kPa O₂, and the ARA atsupraoptimal pO₂; at suboptimal PO₂ there was a negative effectof hydrogenase on ARA, although this inhibition was less thanon bacteroids and was not detected if plants were grown at 15°C rather than 20 °C root temperature. No H₂ effectwas detected on cowpea nodules. The results on soybean nodulesare consistent with the concept that symbiotic nitrogen fixationis oxygen-limited and that hydrogenase activity has no beneficialeffect on nitrogen fixation in O₂ limitation. Key words: Glycine max, hydrogenase, nitrogenase, nitrogen fixation, nodules, Vigna unguiculata     

delta-Aminolevulinate uptake by Rhizobium bacteroids and its limitation by the peribacteroid membrane in Legume nodules.

Heme is overproduced during Rhizobium-Legume symbiosis and delta-aminolevulinate (ALA) is a common precursor in both bacterial and plant synthesis pathways of this molecule. ALA uptake by bacteroids from French bean and soybean nodules was characterized. The action of several metabolic inhibitors and the competition effect of malate on this uptake were studied. ALA transport appeared to be mediated by the dicarboxylate carrier system. Purified symbiosomes--bacteroids surrounded by the peribacteroid membrane--failed to accumulate significant amount of ALA. These experiments rule out the possibility for the plant cytosol to provide the bacteroid with ALA and strengthen the restrictive role of the peribacteroid membrane for exchanges between the two symbiotic partners.     

Specificity and regulation of the dicarboxylate carrier on the peribacteroid membrane of soybean nodules

Malate and succinate were taken up rapidly by isolated, intact peribacteroid units (PBUs) from soybean (Glycine max (L.) Merr.) root nodules and inhibited each other in a competitive manner. Malonate uptake was slower and was severely inhibited by equimolar malate in the reaction medium. The apparent K_m for malonate uptake was higher than that for malate and succinate uptake. Malate uptake by PBUs was inhibited by (in diminishing order of severity) oxaloacetate, fumarate, succinate, phthalonate and oxoglutarate. Malonate and butylmalonate inhibited only slightly and pyruvate,isocitrate and glutamate not at all. Of these compounds, only oxaloacetate, fumarate and succinate inhibited malate uptake by free bacteroids. Malate uptake by PBUs was inhibited severely by the uncoupler carbonylcyanidem-chlorophenyl hydrazone and the respiratory poison KCN, and was stimulated by ATP. We conclude that the peribacteroid membrane contains a dicarboxylate transport system which is distinct from that on the bacteroid membrane and other plant membranes. This system can catalyse the rapid uptake of a range of dicarboxylates into PBUs, with malate and succinate preferred substrates, and is likely to play an important role in symbiotic nitrogen fixation. Energization of both the bacteroid and peribacteroid membranes controls the rate of dicarboxylate transport into peribacteroid units.     

A Rhizobium leguminosarum lipopolysaccharide lipid-A mutant induces nitrogen-fixing nodules with delayed and defective bacteroid formation

Lipopolysaccharides from pea-nodulating strain Rhizobium leguminosarum by. viciae 3841, as all other members of the family Rhizobiaceae with the possible exception of Azorhizobium caulinodans, contains a very long chain fatty acid; 27-hydroxyoctacosanoic acid (27OHC28:0) in its lipid A region. The exact function and importance of this residue, however, is not known. In this work, a previously constructed mutant, Rhizobium leguminosarum by. viciae 22, deficient in the fatty acid residue, was analyzed for its symbiotic phenotype. While the mutant was able to form nitrogen-fixing nodules, a detailed study of the timing and efficiency of nodulation using light and electron microscopy showed that there was a delay in the onset of nodulation and nodule tissue invasion. Further, microscopy showed that the mutant was unable to differentiate normally forming numerous irregularly shaped bacteroids, that the resultant mature bacteroids were unusually large, and that several bacteroids were frequently enclosed in a single symbiosome membrane, a feature not observed with parent bacteroids. In addition, the mutant nodules were delayed in the onset of nitrogenase production and showed reduced nitrogenase throughout the testing period. These results imply that the lack of 27OHC28:0 in the lipid A in mutant bacteroids results in altered membrane properties that are essential for the development of normal bacteroids.     

Nitrogenase activity of pea bacteroids as affected by carbohydrates and ammonium chloride

Summary Regulation and efficiency of the nitrogen-fixing system of the rhizobium-pea symbiosis were investigated. Acetylene reduction of detached root nodules was measured with various substrates added. Succinate, fumarate and malate were most effective in stimulating nitrogenase activity; glucose, pyruvate and citrate were also active. Acetylene reducing activity of detached nodules was inhibited by the addition of NH₄Cl, irrespective of the substrate present. Nitrogenase activity of isolated bacteroids was not influenced by NH₄Cl.Respiration of detached nodules was not significantly stimulated by the addition of substrates. Ammonium chloride did not influence respiration. With detached nodules and isolated bacteroids a consumption of about 16 g of carbohydrate per g of nitrogen fixed could be calculated. Detached nodules produced more hydrogen relative to the acetylene reduced than did isolated bacteroids and intact plants.Results obtained indicate that the regulation of nitrogenase activity and the efficiency of substrate consumption depend on environmental conditions.