Natural and dark-induced nodule senescence in chickpea: nodule functioning and H2O2 scavenging enzymes

An investigation was carried out on chickpea (Cicer arietinum L.) cv. C-235 inoculated withRhizobium sp.Cicer strain cv 4 Az^r. Nodule functioning was monitored at 15 d intervals starting from 45 days after sowing (DAS) and inoculation in order to study nodule development and senescence under natural and stress conditions (dark treatments of 18 and 66 h). Maximum rate of N₂-fixation was observed between 50 - 60 DAS. After this acetylene reducing activity (ARA) fell and it was negligible 75 DAS. This decline in ARA with ageing of plants and nodules was accompanied by a decline in leghemoglobin content and greening of the nodules. When 60 % of the nodule tissue had turned green 75 DAS, a sharp increase in nodule peroxidase activity (3.7 fold) was observed whereas the catalase activity was reduced by 50 % in comparison with the control. The glutathione-reductase and ascorbate-peroxidase activity followed a trend parallel to that in N₂-fixation, but the variation was much smaller. The changes in the total soluble carbohydrates, cytosolic proteins and nitrogen content per se were not expressive. Dark treatments induced premature senescence of the nodules as was evident from the marked decrease in ARA. However, the decline in leghemoglobin content was relatively small as compared to ARA. The changes in cytosolic proteins, total soluble carbohydrates, peroxidase activity, catalase activity, glutathione reductase activity and ascorbate peroxidase activity of nodules under dark-induced nodule senescence were almost parallel to those observed under natural senescence.     

Effect of Arbuscular Mycorrhizal Inoculation on Salt-induced Nodule Senescence in <Emphasis Type="Italic">Cajanus cajan</Emphasis> (Pigeonpea)

Many physiological and biochemical plant processes affected by salt stress trigger premature nodule senescence and decrease their ability to fix nitrogen. The objective of this study was to evaluate the role of arbuscular mycorrhiza (AM) in moderating salt-induced premature nodule senescence in Cajanus cajan (L.) Millsp. Greenhouse experiments were conducted in which the plants were exposed to salinity stress of 4, 6, and 8 dSm⁻¹. Various parameters linked to nodule senescence were assessed at 80 days after sowing. Nodulation, leghemoglobin content, and nitrogenase enzyme activity measured as acetylene-reducing activity (ARA) were evaluated. Two groups of antioxidant enzymes were studied: (1) enzymes involved in the detoxification of O₂⁻ radicals and H₂O₂, namely, superoxide dismutase (SOD), catalase (CAT) and peroxidase (POX), and (2) enzymes that are important components of the ascorbate glutathione pathway responsible for the removal of H₂O₂, namely, glutathione reductase (GR) and ascorbate peroxidase (APOX). Exposure of plants to salinity stress enhanced nodule formation; however, nodule growth suffered remarkably and a marked decline in nodule biomass, relative permeability, and lipid peroxidation was observed. Leghemoglobin content and ARA were reduced under saline conditions. AM significantly improved nodulation, leghemoglobin content, and nitrogenase activity under salt stress. Activities of SOD, CAT, APOX, POX, and GR increased markedly in mycorrhizal-stressed plants. A synthesis of the evidence obtained in this study suggests a correlation between enhanced levels of antioxidant enzyme activities, reduced membrane permeability, reduced lipid peroxidation, and improved nitrogen-fixing efficiency of AM plants under stressed and unstressed conditions. These factors could be responsible for the protective effects of mycorrhiza against stress-induced premature nodule senescence.     

La Dendrologia di Ulisse Aldrovandi

Abstract

Legume-Rhizobium symbiotic nitrogen (N₂) fixation plays a critical role in sustainable nitrogen management in agriculture. The nitrogen fixed by the root nodules not only affects the nitrogen cycle of nature, but is also of great economic importance. A number of physiological and biochemical processes in the nodules are affected by salt stress. The objective of this study was to evaluate the role of arbuscular mycorrhiza (AM) in moderating toxic effects of salt stress on nodular metabolism in Cajanus cajan (L.) Millspaugh (pigeonpea) cv. Manak. Exposure of plants to salinity stress (4, 6 and 8 dSm^?1) caused ionic imbalance, which resulted in increased Na⁺ and reduced K⁺ and Ca²⁺ contents in the nodules. Salinity induced increased synthesis and accumulation of proline and glycine betaine. Salt stress significantly increased the antioxidant enzyme activities in the nodules of all plants. Nodular growth suffered remarkably and a marked decline in nodule biomass was observed under salt stress. Leghemoglobin content and acetylene reduction activity (ARA) also declined under saline conditions. AM could significantly improve nodule dry mass, leghemoglobin content and nitrogenase activity, and phosphorus content under salt stress. Activities of antioxidant enzymes increased markedly in nodules of mycorrhizal-stressed plants. This study suggested a correlation between improved functional efficiency of nodules and higher osmolyte accumulation and enhanced antioxidant enzyme activities of AM plants under stressed conditions relative to the nodules of uninoculated plants.     

Effects of water deficit on N2(C2H2) fixation in cowpea and groundnut

The effect of water deficit on nodulation, N₂ fixation, photosynthesis, and total soluble sugars and leghemoglobin in nodules was investigated in cowpea and groundnut. Nitrogenase activity completely ceased in cowpea with a decrease in leaf water potential ( _leaf) from –0.4 MPa to –0.9 MPa, while in groundnut it continued down to –1.7 MPa. With increasing water stress, the acetylene reduction activity (ARA) declined very sharply in cowpea, but ARA gradually decreased in groundnut. Even with mild water stress ( _leaf of 0.2 MPa), nodule fresh weight declined 50% in cowpea partly due to a severe nodule shedding whereas nodule fresh weight declined in groundnut only when _leaf decreased by 1.0 MPa. No nodule shedding was noticed even at a higher stress level in groundnut. Photosynthesis and stomatal conductance were also more stable in groundnut than in cowpea under water stress. There was a sharp increase in total soluble sugars and leghemoglobin in the nodules of groundut with water stress, but no definite trend could be found in cowpea.     

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.     

Nitrogen fixation and carbon metabolism by nodules and bacteroids of pea plants under sodium chloride stress

Acetylene reduction activity (ARA) and leghemoglobin (Lb) content in nodules were sigificantly reduced when pea ( Pisum sativum L. cv. Lincoln) plants were subjected to 50 m M sodium chloride stress for 3 weeks. C₂H₂ reduction activity by bacteriods isolated from pea nodules was drastically inhibited by saline stress, and malate appeared to be a more appropriate substrate than glucose or succinate in maintaining this activity. Salt added directly to the incubation mixture of bacteriods or to the culture medium of plants inhibited O₂ uptake by bacteroids. Nodule cytosolic phosphoenolpyruvate carboxylase (PEPC; EC 4.1.1.31) and bacteriod malate dehydrogenase (MDH; EC 1.1.1.37) activities were strongly enhanced by salt stress. Under these conditions, malate concentration was depressed in bacteroids and cytosol, whereas total soluble sugar (TSS)content slightly increased in both fractions. The effect of salt stress on TSS and malate content suggests that the utilization of carbohydrate within nodules could be inhibited during salt stress. The inhibitory effect of NaCl on N₂ fixation activity of bacteroids and to the decrease in bacteroid respiration. The stimulation of fermentative metabolism induced by salinity suggests some reduction in O₂ availability within the nodule. Salt stress was also responsible for a decrease of the cytosolic protein content, specifically of leghemoglobin, in the nodules.     

Effect of water stress on functioning and structure ofCicer arietinum L. nodules

Chickpea (Cicer arietinum L. cv. 235) plants were grown in sand culture at moisture equal to 45–50% of sand saturation capacity under greenhouse conditions. 60 d after sowing, pots were divided into four lots, leaving one as control and sand moisture content of others was brought to 25–30% (S₁), 12–15% (S₂) and 5–6% (S₃) of sand saturation capacity, by withholding the water supply and then maintaining the required levels gravimetrically till the harvest. Relative water content of leaves and nodule water content were measured as indices of water stress. With increase in the severity and duration of water stress nitrogenase activity and nitrogen and leghemoglobin content of the nodules decreased and the ratio of leghemoglobin components I and II were changed. Nodules developed under limited water availability showed decreased branching, breakdown of the endodermis, greater compactness and decreased vacuolation of cells in the central symbiotic tissue as compared to the control.     

Reversible dark-induced senescence of soybean root nodules

Nodule senescence was induced in intact soybean [Glycine max. (L.) Merr., cv Woodworth] plants by an 8-day dark treatment. Dark-induced senescence resulted in the complete loss of acetylene reduction activity, a 67% loss of total soluble protein, and an almost complete loss in total leghemoglobin of nodule extracts. Isoelectric focusing gels demonstrated a preferential loss of certain proteins, which was correlated with an increase in endoprotease specific activity toward azocasein. Nodules were completely green after the 8-day dark treatment. If plants were returned to a normal photoperiod after 8 days in the dark, nodules recovered from the dark treatment in 12 to 16 days. Acetylene reduction activity returned to normal, and both total soluble protein and leghemoglobin were resynthesized while protease activity against azocasein decreased to the level of control nodules. The nodule population that had turned green after 8 days in the dark exhibited a progressive increase in red color starting nearest the exterior of the nodule, and after 16 days of recovery nodules were indistinguishable from control nodules maintained under a normal photoperiod.     

The Effect of Ageing on the Leghemoglobin of Cowpea Nodules

Experiments were conducted to study the effect of ageing of the host and senescence of the nodules on the content and composition of the proteins of leghemoglobin in nodules of cowpea (Vigna sinensis L.). Total and heme protein contents of leghemoglobin were the highest in the red nodules and dwindled with the onset of nodule senescence. In the fully senescent green nodules the total proteins decreased to a very low level, while the heme proteins were almost absent. Disc electrophoretograms of leghemoglobin obtained from red and brown nodules showed nine bands out of which only four gave positive test for heme. Greening of the nodules resulted in a considerable reduction in the intensity of the bands. Senescence of the host plant resulted in a reduction in the number of leghemo-globin proteins in all types of nodules and brought about a drastic change in their electrophoretic mobility.     

The effect of ammonium nitrate on the synthesis of nitrogenase and the concentration of leghemoglobin in pea root nodules induced by Rhizobium leguminosarum

The effects of NH₄NO₃ on the development of root nodules of Pisum sativum after infection with Rhizobium leguminosarum (strain PRE) and on the nitrogenase activity of the bacteriods in the nodule tissue were studied. The addition of NH₄NO₃ decreased the nitrogenase activity measured on intact nodules. This reduction of nitrogen fixation did not result from a reduced number of bacteroids or a decreased amount of bacteroid proteins per gram of nodule. The synthesis of nitrogenase, measured as the relative amount of incorporation of [³⁵S]sulfate into the components I and II of nitrogenase was similarly not affected.The addition of NH₄NO₃ decreased the amount of leghemoglobin in the nodules and there was a quantitative correlation between the leghemoglobin content and the nitrogen-fixing capacity of the nodules. The conclusion is that the decrease of nitrogen-fixing capacity is caused by a decrease of the leghemoglobin content of the root nodules and not by repression of the nitrogenase synthesis.     

Water relations and nitrogen fixation in potassium fedVigna radiata nodules

Drought created by withholding the irrigation at 30 and 45 d after sowing significantly decreased relative water content (RWC) and osmotic potential (ψ_s) ofVigna radiata (L.) Wilczek cv. MH-83-30 nodules. Potassium fed plants showed higher RWC, whereas ψ_s was further declined irrespective of soil moisture levels. The nitrogenase activity and leghemoglobin content of nodules markedly decreased under drought and nodules of potassium fed plants showed better recovery after rehydration. The proline content significantly increased under drought but declined upon reirrigation. Also, the C, N and K contents of nodules significantly declined under drought.     

Nodule Functioning in Trifoliate and Pentafoliate Mungbean Genotypes as Influenced by Salinity

Two genotypes of mungbean differing in the leaf shape, K-851 (trifoliate) and a mutant (pentafoliate), were exposed to salinity (0, 2.5, 5, 10 dS m^–1) for 3, 6 and 9 d at flowering stage (40 – 45 d after sowing) to see the effect of salinity on nodule functioning. In both the genotypes, osmotic potential (_s) and relative water content (RWC) of nodules decreased significantly, and proline content increased with increasing the salinity. The _s of nodules was more decreased in the mutant than in genotype K-851, while reverse was true for RWC and proline accumulation. A remarkable increase in ethylene evolution was noticed from nodulated roots with the increasing level and duration of salinity and was much higher in K-851. A sharp decline in leghemoglobin content and acetylene reduction assay (ARA) of the nodules was observed with the salinity and this decrease was more marked in K-851 than the mutant. N content declined while Na⁺/K⁺ ratio and Cl^– content increased significantly. The mutant maintained better N status but lower Na⁺/K⁺ ratio and Cl^– content in nodules than K-851. Nodule dry matter also declined with salinity and the decrease was more expressed in K-851. Thus the functioning of nodules in the mutant was better than in the genotype K-851 under stress conditions.     

Effetto della rimozione dei fiori sulla crescita delle piante e sul contenuto in leghemoglobina dei tubercoli radicali di pisello e fava

Abstract

Observations on vegetative growth and leghemoglobin contents of root nodules of pea and bean plants after flower bud removal. — These studies found their origin in the papers by MATTIROLO (1899) on the effect of the removal of flowers as they formed in bean plants; he observed that deflowering resulted in extraordinary plant growth, stem branching and flower buds formation as well as in a delayed root nodule senescence. In the light of modern knowledge of the leghemoglobin role in symbiotic nitrogen fixation, the aim of the present research was to ascertain any possible relation between flower bud removal and haeme pigment contents in the root nodules. The experiments were carried out during two growing seasons (1966 and 1970) using Vicia faba L. cv. Regina and Pisum sativum L. cv. Senatore during 1966 and cv. Vittoria in 1970. In both control and test plants the seasonal trends of average plant height, fresh and dry weight of vegetative portions, fresh and dry weight of root system, fresh weight of nodules, root nodule leghemoglobin concentration and total leghemoglobin content per plant, were determined. The data obtained are quoted in Table 2 and reported in Figures 1, 2, and 3. The removal of flower buds caused in both species: an increased plant growth, a marked stem branching, a longer blooming period, an increased flower number, an increased root nodule number and a certain delay in root nodule reabsorption. Deflowering did not significantly extend — at least in the species studied — life span (senescence was delayed only of one week). On the basis of these and of other Authors' results, we conclude that deflowering may actually delay senescence; the size of this delay, however, depends on the plant species considered and is fairly negligible both in pea and bean. The different effects of deflowering and of preventing floral induction on life span extension, are discussed, and these facts lead to consider floral induction as the onset of a chain of processes leading annual plants toward senescence in a more or less delayable, but definitive way. After having stressed the generally accepted importance of leghemoglobin concentration as an index of nodule nitrogen fixing ability, a correlation between biomass increase of test plants and number and total weight increase of root nodules, is put in evidence. No correlation between test plant biomass and the leghemoglobin concentration in root nodules, was however observed. Leghemoglobin concentration in root nodules is known to change in connection with various factors depending either on host plants and on Rhizobium strains and also in connection with several environmental conditions. Any prevented flower onset (ROPONEN and VIRTANEN, 1968) and deflowering (our data) however exerted no significant influence. The effects of flower bud removal were therefore the following: increased stem, leaf and root weights and increased root nodule number; no difference between control and test plants was however observed as regards size and leghemoglobin concentration of root nodules and hence probably no difference as regards their nitrogen fixing ability.     

Mathematical modeling of oxygen diffusion and respiration in legume root nodules

The O₂ permeability of legume root nodules is under physiological control; decreases in permeability are triggered by various forms of stress. Two linked mathematical models were used to explore several hypotheses concerning the physical nature of the variable diffusion barrier in nodules. Respiration and diffusion of dissolved O₂ and oxygenated leghemoglobin were simulated for the nodule cortex and the nodule interior. Measured nodule permeabilities were shown to be inconsistent with the hypothesis that large numbers of air-filled pores penetrate the diffusion barrier. Changes in the affinity of leghemoglobin for O₂ or in the rate of cytoplasmic streaming in diffusion barrier cells did not result in the large changes in O₂ permeability reported for real nodules. The presence or absence, but not the thickness, of aqueous plugs in radial pores through the cortex was found to have a large effect on permeability. Flooding of intercellular spaces, either between layers of cells in the cortex or in the nodule interior, also caused large changes in simulated permeability. The unsteady-state O₂ method for determining nodule permeability was tested using data generated by the model. The accuracy of the method was confirmed, provided that certain assumptions (full oxygenation of leghemoglobin under pure O₂ and uniform conditions in the nodule interior) are met.     

Sensitive fluorometric assay for leghemoglobin

A sensitive spectrofluorometric assay for leghemoglobin is based upon the action of hot saturated oxalic acid on heme proteins. The assay will detect 200 ng of leghemoglobin per milliliter and is specific enough to permit estimation in single nodules or extracts of whole roots. The leghemoglobin concentration measured fluorometrically shows a correlation with nitrogenase [C₂H₂] activity, even during nodule senescence, when standard colorimetric assays may overestimate leghemoglobin.     

The Effects of Salinity on Nitrogen Fixation and Trehalose Metabolism in Mycorrhizal Cajanus cajan (L.) Millsp. Plants

Arbuscular mycorrhizal (AM) fungi exist widely in natural ecosystems as well as in salt-affected soils and are considered suitable candidates for bio-amelioration of saline soils. Plants respond to salinity by accumulating sugars and other low-molecular-weight compatible solutes. One such compound is trehalose, which has been found to play an important role as a stress protectant. The aim of the present investigation was to study interactions between an AM fungus and salinity stress on growth, nitrogen fixation, and trehalose metabolism in Cajanus cajan (L.) Millsp. (pigeonpea). Two genotypes [Sel 85N (salt-tolerant) and ICP 13997 (salt-sensitive)] were subjected to saline treatments with and without mycorrhizal inoculations. Salinity reduced plant biomass (shoot and root) in both genotypes and resulted in a decline in shoot-to-root ratio (SRR); however, a smaller decline was observed in Sel 85N than in ICP 13997. AM colonization was reduced with increasing salinity levels but mycorrhizal responsiveness (MR) increased. Genotypic variability in nitrogen fixation and trehalose metabolism in response to salinity and mycorrhization was observed. An increment in nodule number was accompanied by a reduction in dry mass. Subsequently, nodular activity (leghemoglobin, acetylene-reduction activity [ARA], nitrogen content) was reduced under soil salinity, which was more profound in ICP 13997 than in Sel 85N. The symbiotic association with Glomus mosseae led to significant improvement in plant dry mass and nitrogen-fixing potential of nodules under salt stress. Salinity led to an increase in trehalose-6-P synthetase (TPS) and trehalose-6-P phosphatase (TPP) activities resulting in increased trehalose content in nodules, which was accompanied by inhibition of trehalose catabolism (trehalase activity). AM plants had lower trehalase activity under saline and nonsaline conditions. Thus, a symbiotic relationship between plant roots and G. mosseae might have resulted in salinity tolerance in a genotype-dependent manner.     

Nitrogen Fixation (C(2)H(2) Reduction) by Broad Bean (Vicia faba L.) Nodules and Bacteroids under Water-Restricted Conditions

Water potentials of leaves and nodules of broad bean (Vicia faba L.) cultivated on a sandy mixture were linearly and highly (r² = 0.99) correlated throughout a water deprivation of plants. A decrease of 0.2 megapascal of the nodule water potential (Ψ_nod) induced an immediate 25% inhibition of the highest level of acetylene reduction of broad bean nodules attached to roots. This activity continued to be depressed when water stress increased, but the effect was less pronounced. Partial recovery of optimal C₂H₂ reduction capacity of mildly water stressed nodules (Ψ_nod = −1.2 megapascals) was possible by increasing the external O₂ partial pressure up to 60 kilopascals. The dense packing of the cortical cells of nodules may be responsible for the limitation of O₂ diffusion to the central tissue. Bacteroids isolated from broad bean nodules exhibited higher N₂ fixation activity with glucose than with succinate as an energy-yielding substrate. Bacteroids from stressed nodules appeared more sensitive to O₂, and their optimal activity declined with increasing nodule water deprivation. This effect could be partly due to decreased bacteroid respiration capacity with water stress. Water stress was also responsible for a decrease of the cytosolic protein content of the nodule and more specifically of leghemoglobin. The alteration of the bacteroid environment appears to contribute to the decline in N₂ fixation under water restricted conditions.     

Temporal Relationships between Nitrogenase and Intercellular Glycoprotein in Developing White Lupin Nodules

The development of the N₂-fixing symbiosis between white lupin (Lupinus albusL.) cv. Multolupa andBradyrhizobiumstrain ISLU16 was followed using the acetylene reduction assay (ARA), immunoblots of protein extracts, and microscopy/immunogold labelling at 0, 8, 12, 17 and 20 d after infection. There was no ARA at 0, 8 and 12 d, although macroscopically visible nodule primordia had formed on roots by 8 d. The lack of nitrogenase at these times was confirmed by a negative signal to immunogold labelling with nitrogenase-specific antibodies. At 17 d three out of six plants had ARA, and nodules from these gave a positive signal with the nitrogenase antibody. By contrast, ARA⁻(fix⁻) nodules at 17 d were smaller (mean radius of 0.49 mm compared to 1.01 mm with fix⁺nodules) and gave a negative signal with the nitrogenase antibody. Western blots of nodule protein extracts using the monoclonal antibodies MAC236 and MAC265 (which recognize two epitopes on a glycoprotein which is considered to be involved in both rhizobial infection and the regulation of nodule oxygen diffusion) gave a strong signal with nodules (fix⁺) from 20 d plants and with 17 d fix⁺plants. The signal with MAC236/MAC265 was substantially weaker with nodules from 17 d fix⁻plants, and there was no signal apparent from nodules/nodulated roots from the 0, 8 and 12 d harvests. However, further investigation using immunogold labelling revealed that not only were MAC236 and MAC265 expressed within cortical intercellular spaces in 20 d and 17 d fix⁺/fix⁻nodules, but they were also strongly expressed in the developing cortex surrounding the newly-infected tissue in 8 d nodules, as well as in intercellular spaces within the cortex and infected tissue of 12 d nodules. These data demonstrate that the glycoprotein recognized by MAC236 and MAC265 is present before the onset of nitrogenase expression and function, but expression of the epitopes appears to be enhanced from the onset of N₂fixation. Nodules at all harvests were investigated for the presence of infection threads, as the MAC236/MAC265-recognized glycoprotein is also a component of the infection thread matrix in nodules from other legumes. Infection threads were not seen in nodules from any of the harvests except for the 20 d nodules, and then only after serial sectioning. The latter revealed occasional short wide infection threads entering and releasing rhizobia into small pockets of uninfected cells, within the infected tissue, but not within the meristems. The matrix of these infection threads labelled weakly, or not at all, with MAC236 and MAC265, and it was concluded that the majority of the MAC236/MAC265 detected in lupin nodule extracts originated from glycoprotein within cortical intercellular spaces.     

Phosphoenolpynivate carboxylase, malate and alcohol dehydrogenase activities in alfalfa (Medicago sativa) nodules under water stress

The effect of drought upon phosphoenolpyruvate carboxylase (PEPC; EC 4.1.1.31), malate ddiydrogenase (MDH; EC 1.1.1.37), alcohol dehydrogenase (ADH; EC 1.1.1.1) and β -hydroxybulyrate dehydrogenase ( β -OH-BDH; EC 1.1.1.30) enzyme activities as well as the leghemoglobin (Lb), malate and ethanol contents of alfalfa nodules ( Medicago sativa L. cv. Aragon) were examined. Both the ieghemoglobin (Lb) content and the Lb/soluble protein ratio were significantly reduced at a nodule water potential (Ψ_nod) of—1.3 MPa. At lower Ψ_nod, Lb content decreased further, but the ratio remained unchanged. Slight stress (—1.3 MPa) drastically affected acetylene reduction activity (ARA; 60% reduction) whereas in vitro PEPC activity was main-tained at relatively constant values. As stress progressed (—2.0 MPa), a simultaneous reduction in both activities was observed. Severe stress (Ψ_nod lower than —2.0 MPa) stimulated in vitro PEPC. Bacteroid β -J-OH-BDH activity was stimulated by slight (—1.3 MPa) and moderate (—2.0 MPa) drought. MDH activity rose in slightly stressed nodules (Ψ_nod—1.3 MPa). Greater water deficits sharply decreased MDH activity to values significantly lower than those found in control nodules. Nodule malate content followed the same pattern as MDH. The plant fraction of the nodule showed constitutive ADH activity and contained ethanol. ADH was stimulated at slight (— 1.3 MPa) and moderate drought levels (—2.0 MPa). Ethanol content showed similar behavior to ADH activity. Inhibition of ARA, reduction of Lb content and stimulation of the fermentative metabolism induced by water stress suggest some reduction ira O₂ availability within the nodule.     

Proteolytic Activity in Soybean Root Nodules : Activity in Host Cell Cytosol and Bacteroids throughout Physiological Development and Senescence

Root nodules were harvested from chamber-grown soybean (Glycine max L. Merrill cv Woodworth) plants throughout development. Apparent nitrogenase activity (acetylene reduction) peaked before seeds began to develop, but a significant amount of activity remained as the seeds matured. Nodule senescence was defined as the period in which residual nitrogenase activity was lost. During this time, soluble protein and leghemoglobin levels in the host cell cytosol decreased, and proteolytic activity against azocasein increased. Degradative changes were not detected in bacteroids during nodule senescence. Total soluble bacteroid protein per gram of nodule remained constant, and an increase in proteolytic activity in bacteroid extracts was not observed. These results are consistent with the view that soybean nodule bacteroids are capable of redifferentiation into free-living bacteria upon deterioration of the legume-rhizobia symbiosis.