The Physiology and Nitrogen-fixing Capability of Aquatically and Terrestrially Grown Neptunia plena: The Importance of Nodule Oxygen Supply

The aquatic legume Neptunia plena (L.) Benth. was grown in non-aeratedwater culture or vermiculite. Growth, nodulation, nitrogen fixationand nodule physiology were investigated. Over an 80-d period,plants grew and fixed nitrogen and carbon equally well in bothrooting media, although distribution of growth between plantparts varied. Total nodule dry weights and volumes were similarbut vermiculite-grown plants had three times as many (smaller)nodules than those grown in water. Oxygen diffusion resistanceof nodules exposed to 21% oxygen and 10% acetylene did not differsignificantly. Both treatments showed similar declines in rootrespiration and acetylene reduction activity (approx. 10%) whenroot systems were exposed to stepped decreases and increasesin rhizosphere oxygen concentration. However, nitrogenase activityof aquatically grown plants was irreversibly inhibited by rapidexposure of nodules to ambient air, whereas vermiculite-grownplants were unaffected. Aeration of water-cultured N. plenareduced stem length (but not mass) and number of nodules perplant. The concentration of nitrogen fixation by 163%. PossibleO₂ transport pathways from the shoot atmosphere to roots andnodules are discussed. Aquatic legume, diffusion resistance, Neptunia plena, nitrogen fixation, oxygen, root nodules     

Nitrogen Fixation by Subterranean Clover at Varying Stages of Nodule Dehydration: I. CARBOHYDRATE STATUS AND SHORT-TERM RECOVERY OF NODULATED ROOT RESPIRATION

The nodule water potential (_nod) of subterranean clover (Trifoliumsubterraneum L.) cv. Seaton Park incubated in a flow-throughgas-exchange system was induced to decline independently ofleaf water potential (₁) by passing a continuous dry airstreamover the nodulated roots of intact well-watered plants. Reducedtranspiration by plants whose nodules had become dehydratedwas hypothesized to be related to the decline in nitrogen fixation.Whole-plant and nodule soluble carbohydrates increased as _noddeclined. Throughout an 8 d period of continual nodule dehydration,the gaseous diffusion resistance of nodules increased and theoptimum pO₂ for nitrogenase activity declined from 52 to 28kPa. Following rehydration of the nodulated roots between days4 and 5 and between days 7 and 8, nodulated root respirationincreased to or above pre-stress levels whereas nitrogenaseactivity did not recover. Re-establishment of initial ratesof nodulated root respiration was due to the stimulation ofgrowth and maintenance respiration, not to the respiration coupledto nitrogenase activity. Although no recovery of nitrogenaseactivity occurred, the elapsed time from the introduction ofacetylene into the gas stream flowing past the nodules untilmeasurement of the acetylene-induced decline in nitrogenaseactivity, decreased substantially. This was characteristic ofan increase in the permeability of the nodules to gaseous diffusionupon rehydration. However, calculated values of nodule diffusionresistance after the 24 h periods of rehydration did not indicateany recovery of gaseous diffusion resistance based on measurementsof the respiration coupled to nitrogenase activity. Hence, useof a diffusion analogue (i.e. Fick's Law) in conjunction withnodule respiratory CO₂ efflux was unable to predict changesin permeability of the variable barrier of legume nodules followingnodule dehydration and recovery. Key words: Subterranean clover, gaseous diffusion, respiration, carbohydrates, drought     

Effect of Water Stress on Nodule Physiology and Biochemistry of a Drought Tolerant Cultivar of Common Bean (Phaseolus vulgarisL.)

Plants of EMGOPA-201, a drought tolerant cultivar of commonbean(Phaseolus vulgaris), were maintained either at 90% soilfield capacity (SFC) or stressed by reducing SFC to 70, 50 or30% over a 10 d period. Plant dry weight was not affected byany of these treatments although the number and weight of noduleswas reduced at 50 and 30% SFC. Nitrogenase activity, determinedby the acetylene reduction assay (ARA), was also reduced, ona plant basis, at 50% SFC and was almost stopped at 30% SFC.The latter treatment caused a marked increase in nodule O₂diffusionresistance and induced nodule senescence. A time-course analysisof the 10 d 30% SFC treatment showed a decrease in leaf waterpotential from -0.5 to -0.87 MPa by 8 d, with a cessation ofdry weight increase after 3 d, when leaf water potential was-0.65 MPa. Proteins in the host plant fraction of nodules decreasedto 50% of control values by 10 d and leghaemoglobin (Lb) contentwas also lower at this stage. The activity of sucrose synthase(SS) showed a 76% reduction between 3 and 6 d, whilst glutamatesynthase (GOGAT) activity showed a 40% reduction. The activityof other key enzymes of carbon metabolism was also reduced after10 d. Nodule sucrose content increased to double that of controlnodules by 6 d, before declining back to control levels at 10d. Starch content fell by 3 d and continued to fall throughoutthe stress period. The results are discussed in terms of droughttolerance strategies in relation to growth and metabolism inwhole plants and nodules.Copyright 1999 Annals of Botany Company. Phaseolus vulgaris,common bean, water stress, nitrogen fixation, oxygen diffusion, acetylene reduction, enzyme activity, carbon metabolism.     

Effects of Water Stress on the Respiratory and Nitrogen-fixing Activity of Soybean Root Nodules

Seventy-five per cent of the N₂-fixing activity (measured asthe reduction of C₂H₂ to C₂H₄) and 50 per cent of the respiratoryactivity of detached soybean root nodules was lost when thewater potential () of the nodules was lowered from approximately–1 ? 105 Pa (turgid nodules) to –9 ? 105 Pa (moderatelystressed nodules). Severely stressed nodules ( = –1.8? 10⁶ Pa) showed almost total loss of N₂-fixing activity andup to 80 per cent loss of respiratory activity. Increasing theoxygen partial pressure (PO₂) from 10⁴ to 10⁵ Pa completelyrestored both N₂-fixation and respiration in moderately stressednodules, but only partial recovery was possible in severelystressed nodules. The activity of the stressed nodules was verylow at low PO₂ (5 ? 10³ and 10⁴ Pa). The C₂H₂-reducing activityof nodule slices, nodule breis, and bacteroids from turgid andmoderately stressed nodules was almost identical but some activitywas lost in the breis and bacteroids from severely stressednodules. Calculations showed that at low PO₂ (10⁴ and 2 ? 10⁴Pa), the rate of O₂ diffusion into severely stressed noduleswas ten times lower than that for turgid nodules, but only fourtimes lower at a higher PO₂ (4 ? 10⁴ Pa). Carbon monoxide inhibitionof C₂H₂ reduction was slower in stressed nodules than in turgidnodules. The results are discussed in view of the possible developmentof a physical barrier to gaseous diffusion and/or the possiblealtered affinity of the nodule leghaemoglobin for O₂ in thewater-stressed nodules.     

Characterization of the Resistance to Oxygen Diffusion in Legume Nodules

A method for characterizing the resistance to oxygen diffusionin legume nodules has been developed. This is based on the assumptionsthat diffusion can be described using a simple resistance analogueand that the respiratory response of the bacteriod-containingcells to external oxygen concentrations can be analysed as adiffusion-limited process. Applying this analysis to experimentaldata from infact white clover plants allowed the total diffusionresistance to be separated into (a) a minimum resistance and(b) the extent to which this resistance can be increased. Whenthe carbohydrate status of the nodules was reduced by dark treatments,the minimum diffusion resistance increased, and after 24–28h darkness equalled the maximum resistance. At the same timethe ability to control this resistance was lost. White clover, nitrogen fixation, oxygen diffusion, nodule respiration     

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.     

Effects of carbohydrate on the internal oxygen concentration, oxygen uptake, and nitrogenase activity in detached pea nodules

The interaction between carbon substrates and O₂ and their effects on nitrogenase activity (C₂H₂) were examined in detached nodules of pea (Pisum sativum L. cv “Sparkle”). The internal O₂ concentration was estimated from the fractional oxygenation of leghemoglobin measured by reflectance spectroscopy. Lowering the endogenous carbohydrate content of nodules by excising the shoots 16 hours before nodule harvest or by incubating detached nodules at 100 kPa O₂ for 2 hours resulted in a 2- to 10-fold increase in internal O₂, and a decline in nitrogenase activity. Conversely, when detached nodules were supplied with 100 millimolar succinate, the internal O₂ was lowered. Nitrogenase activity was stimulated by succinate but only at high external O₂. Oxygen uptake increased linearly with external O₂ but was affected only slightly by the carbon treatments. The apparent diffusion resistance in the nodule cortex was similar in all of the treatments. Carbon substrates can thus affect nitrogenase activity indirectly by affecting the O₂ concentration within detached nodules.     

An ELISA Procedure for Quantification of Relative Amounts of Intercellular Glycoprotein in Legume Nodules

An enzyme-linked immunosorbant assay (ELISA) method based ona monoclonal antibody (MAC236) is described in which relativeamounts of an intercellular glycoprotein were quantified inextracts of whole legume nodules. This glycoprotein has recentlybeen shown to be an important component of the cortical oxygendiffusion barrier. The ELISA method is demonstrated on threeexamples of soybean (Glycine max L. Merr.) nodule systems whichhave been the subject of previously published investigations:(a), cv. Clarke inoculated with Bradyrhizobium japonicum RCR3442,nodulated root systems of which were subject to 10, 21 or 40%oxygen continuously for 28 d; (b), cv. Bragg and its supernodulatingmutant derivative (nts382) inoculated with Bradyrhizobium japonicumUSDA110; (c), cv. Clarke inoculated with Bradyrhizobium japonicumRCR3442 or RCR3407. ELISA results are related to oxygen diffusioncharacteristics defined in previous publications and show thatincreases in the amount of glycoprotein present correlated withincreases in supra-ambient (40%) levels of rhizosphere pO₂,in minimum gas diffusion resistance and in speed of diffusionbarrier response. Area data of component parts of nodule inner cortices suggestthat diffusion resistance control under sub-ambient (10%) oxygenlevels also involves cell expansion. The amount of MAC236 antigen in nodules is affected by bothhost plant genotype and rhizobial strain and the latter alsoappears to be involved in determining the morphological developmentof the nodule inner cortex.Copyright 1993, 1999 Academic Press Oxygen diffusion resistance, glycoprotein, nodules, Glycine max, ELISA     

Wavelength options for monitoring leghaemoglobin oxygenation gradients in intact legume root nodules

Nodule oximetry, based on spectrophotometric measurements ofleghaemoglobin (Lb) oxygenation in intact nodules, has providednumerous insights into legume nodule physiology. Fractionaloxygenation of Lb (FOL) has been monitored at various wavelengths,but comparisons among wavelengths have not been published previously.Changes in transmittance were monitored simultaneously at 660nm and either 560 or 580 nm as FOL was manipulated by changingthe O₂ concentration around nodules of Medicago sativa L. orLotus comiculatus L. Video microscopy at 580 nm was used togenerate two-dimensional maps of FOL gradients in intact nodules.In general, all three wavelengths gave similar results. Smalldiscrepancies between 660 and 580 nm, sometimes seen in noduleswith high O₂ permeability, may indicate interference by theferric Lb peak at 625 nm. A slightly longer wavelength, forexample 670 nm, might be preferable. No significant discrepanciesamong wavelengths were seen in nodules whose O₂ permeabilityhad been reduced by a 48 h exposure to 10 mM nitrate. Minorgradients in FOL were seen in nodules of M. sativa and Trifoliumrepens L. under air and steeper gradients could be induced byvarious treatments. The existence of these gradients indicatesat least some restriction of longrange O₂ diffusion within theinfected zone. The FOL maps do not have enough spatial resolutionto measure gradients within infected cells. Key words: Leghaernoglobin oxygenation, nodules, spectrophotometry, nodule oximetry     

An osmotic hypothesis for the regulation of oxygen permeability in soybean nodules

Nodule permeability (P) controls the amount of O₂ entering the nodule, and thereby the rates of both nodule respiration and N₂ fixation. P may be regulated by changes in the effective thickness of a water-filled diffusion barrier in the nodule cortex. Regulation of diffusion barrier thickness was hypothesized to result from changes in the water content of intercellular spaces. Modulation of intercellular water would be a response to osmotic potential gradients in the tissue. To test this hypothesis, preliminary experiments examined three classes of solutes (soluble sugars, free amino acids, and ureides) in nodules of intact plants exposed to 10 or 21 kPa O₂ for 24 h. Neither soluble sugars nor free amino acids in nodules were responsive to O₂ treatments. However, nodule ureides accumulated after exposure to 10kPa O₂ for 24 h. A symplastic increase in nodule ureides under the 10kPa O₂ treatment compared to the 21 kPa O₂ treatment may have removed water from intercellular spaces in the nodule cortex and increased P. In addition, the nodule cortex of intact plants was infiltrated with water, polyethylene glycol (PEG), KC1, or Na-succinate solutions to determine the effect of intercellular water and osmoticants on dinitrogenase activity and P. Results from infiltrating the apoplast of the nodule cortex with osmotic solutions indicated that both increases in intercellular water and decreases in the apoplastic water potential decrease dinitrogenase activity and P. Furthermore, the inability to recover dinitrogenase activity and P following the infiltration of the cortex with PEG compared to either KCl or Na-succinate treatments may indicate that recovery was dependent upon removal of the solute from the apoplast.     

Alterations in Apoplastic and Total Solute Concentrations in Soybean Nodules Resulting from Treatments Known to Affect Gas Diffusion

Ureide concentration in the cortical apoplast of soybean (Glycinemax(L.) Merr.) nodules increases rapidly in response to noduleexcision. The objective here was to determine if changes inapoplastic ureide may be related to the control of resistanceto gas diffusion which is thought to be localized in the nodulecortex. Following decapitation of shoots, nitrogenase activity(acetylene reduction) and ureide concentration in total noduleextracts declined over a period of several hours. Apoplasticureide concentration relative to total nodule ureide was elevatedunder these conditions, but the treatment effect was small comparedto non-decapitated controls. Decapitation also caused a significantdecline in the concentrations of sucrose, glucose, and D-pinitolin nodules. However, the decline in carbohydrates was similarin the nodule cortex and the nodule as a whole, suggesting thatthe carbohydrate changes are not related to a cortex-localizedmechanism. Non-invasive treatments involving increases or decreasesin oxygen concentration supplied to nodulated roots caused rapiddecreases in respiration of nodulated roots and in ureide concentrationin total nodule extracts, but did not cause major changes inapoplastic ureide concentrations. The combined results indicatethat apoplastic ureide is probably not involved in the regulationof resistance to gas diffusion. The rapid decline in noduleureide concentrations in response to changing oxygen supplydocuments the sensitivity of ureide synthesis and/or transportto alterations in nodule respiration and/or nitrogenase activity Key words: Glycine max, Pisum sativum, ureide, carbohydrates     

Nitrate entry and nitrite formation in the infected region of soybean nodules

The entry of nitrate into the infected region of soybean nodules and the possibility of a subsequent nitrite accumulation was studied. Nitrate was observed to gain access to the infected region in the short-term and significant amounts could be measured within 2 d of nitrate supply. The availability of nitrate in the bacteroid-containing region did not cause free-nitrite accumulation for at least 8d. However, to avoid the artefactual production of nitrite during extraction it was necessary to disrupt nodules in the presence of zinc acetate and ethanol, to prevent bacteroid nitrate reductase activity. Nitrite rapidly accumulated if nodules were extracted without prior enzyme-inactivation, or if bacteroids were allowed access to nitrate, or, more significantly, if nodules were not extracted immediately following detachment. Nitrate accumulation in detached nodules was mediated by oxygen concentration within the nodule; in the presence of pure N2 gas, nitrite accumulation was three times greater than in air and, conversely, it was prevented by exposure to pure O2. Furthermore, nitrite produced in detached nodules under atmospheric conditions was scavenged by transferring these nodules into 100% oxygen. However, measurements of apparent functional leghaemoglobin, using a nodule oximeter, suggested that after 8 d nitrate exposure up to 83% of Lb activity was lost, possibly due to interactions with nitrite produced in the nodule interior leading to the formation of nitrosylleghaemoglobin.Key words: Glycine max, cortex, infected region, leghaemoglobin, nitrate, nitrite, nodules, soybean      

The Influence of Water Stress on the Photosynthesis of a Simulated Sward of Perennial Ryegrass

The rate of canopy photosynthesis, single leaf photosynthesis,leaf resistance to gaseous exchange, and leaf water potentialof simulated swards of perennial ryegrass (Lolium perenne cv.S24) in a controlled environment, were determined during a periodof increasing water stress and recovery from that stress. Canopyphotosynthesis did not decline immediately water was withheldbut continued at an undiminished rate for several days; thereafterit fell rapidly, particularly at first. As water stress increasedsuccessive relationships between canopy photosynthesis and irradiancebecame more curved, indicating that the effect of water stressincreased with increasing irradiance. After the swards werere-watered canopy photosynthesis rose, most rapidly during thefirst 24 h. In general, the pattern of change of leaf waterpotential was similar to that of canopy photosynthesis, althougha more detailed examination of this relationship showed it tobe hysteresial; in particular, the fall in leaf water potentialpreceded that of canopy photosynthesis. Single leaf photosynthesisappeared to be the main agent through which water stress influencedcanopy photosynthesis although in the more severely stressedswards (leaf water potentials of about—15 bars) some leaftissue died and so limited the recovery of canopy photosynthesis.The leaf resistance to gaseous diffusion increased with increasingwater stress, as did the CO₂ compensation point, thereby influencingsingle-leaf photosynthesis and through it canopy photosynthesis.     

Effect of Cuticular Abrasion on Thermocouple Psychrometric In Situ Measurement of Leaf Water Potential

Cuticular resistance to water vapour diffusion between the substomatalcavity and the sensing psychrometer junction is a problem uniqueto leaf hygrometry. This resistance is not encountered in soilor solution hygrometry. The cuticular resistance may introduceerror in the measurement of leaf water potential. Using in situleaf hygrometers, we studied the effect of abrading the cuticleof Citrus jambhiri Lushington leaves, to reduce the diffusiveresistance. Field measurements of psychrometer water potentialwere compared with Scholander pressure chamber values for adjacentleaves. Different treatments were compared by sealing pairsof psychrometers on either side of the midrib. The time forwater vapour equilibration between the leaf and the psychrometerchamber was greater than 5 h for no abrasion. For abraded leaves,the true water potential value was obtained within an hour.After equilibration, psychrometer values compared favourablywith pressure chamber values for adjacent leaves (r > 0.97).Measured water potential for unabraded leaves did not correlatewell with corresponding pressure chamber measurements. Scanning electron micrographs indicated that the damage causedby abrading leaves for 60 s using carborundum powder (60 µmdiameter) was surface localized, with numerous scratchings ofthe leaf cuticle. The coarse abrasion treatment (aluminium oxide,75 µm diameter) resulted in fewer but larger cavitiesin the epidermis, which may explain the observed variabilityin the corresponding psychrometric measurements. Key words: Leaf water potential, Cuticular resistance, Leaf abrasion, Thermocouple psychrometer     

Stress-Induced Legume Root Nodule Senescence. Physiological, Biochemical, and Structural Alterations

Nitrate-fed and dark-stressed bean (Phaseolus vulgaris) and pea (Pisum sativum) plants were used to study nodule senescence. In bean, 1 d of nitrate treatment caused a partially reversible decline in nitrogenase activity and an increase in O₂ diffusion resistance, but minimal changes in carbon metabolites, antioxidants, and other biochemical parameters, indicating that the initial decrease in nitrogenase activity was due to O₂ limitation. In pea, 1 d of dark treatment led to a 96% decline in nitrogenase activity and sucrose, indicating sugar deprivation as the primary cause of activity loss. In later stages of senescence (4 d of nitrate or 2–4 d of dark treatment), nodules showed accumulation of oxidized proteins and general ultrastructural deterioration. The major thiol tripeptides of untreated nodules were homoglutathione (72%) in bean and glutathione (89%) in pea. These predominant thiols declined by approximately 93% after 4 d of nitrate or dark treatment, but the loss of thiol content can be only ascribed in part to limited synthesis by γ-glutamylcysteinyl, homoglutathione, and glutathione synthetases. Ascorbate peroxidase was immunolocalized primarily in the infected and parenchyma (inner cortex) nodule cells, with large decreases in senescent tissue. Ferritin was almost undetectable in untreated bean nodules, but accumulated in the plastids and amyloplasts of uninfected interstitial and parenchyma cells following 2 or 4 d of nitrate treatment, probably as a response to oxidative stress.     

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.     

The Effect of Irradiance on the Recovery of Soybean Nodules from Sodium Chloride-Induced Senescence

Soybean (Glycine max L. Merr) cv. Clarke plants inoculated withBradyrhizobium japonicum strain RCR3407 were grown either ina greenhouse with a low irradiance (200–400)µmolm^–2 s^–1) or in a controlled-environment growth cabinetwith a higher irradiance (600 µimol m^–2 s^–1).At 42 d plants were given a nitrogen-free nutrient solutioncontaining 50 mol m^–3 sodium chloride for 2 weeks andthen allowed to recover from salt-stress for a further 2 weeks. Salt treatment reduced plant growth by at least half in bothgrowth regimes, however, the controlled environment-grown (CEG)plants were five times larger than the greenhouse-grown (GG)plants in terms of dry weight and number/weight of nodules perplant, regardless of treatment. The structure of nodules, from both growth regimes, harvestedat the end of the 2 week salt-stress was similar to unstressedcontrol nodules. However, nodules harvested 1 week later fromboth CEG and GG plants had structural changes including degradationof bacteria in vacuoles around host cell nuclei, particularlyin the outer cell layers of the infected tissue. In addition,meristematic activity was seen in the cortex of some nodulesfrom GG plants. Young cells here contained infection threadsand newly-released bacteria. Nodules harvested 2 weeks after removal of the salt-stress fromCEG plants showed an apparent recovery from the stress. However,there was a very marked increase in the amount of starch inthe cortex which was not seen in equivalent GG nodules. In contrast,nodules from GG plants contained many vacuolate infected cellsand, consequently, a lowered bacteroid population. Further,meristematic activity was seen in a zone concentric to the infectedzone, newly-formed cells contained many large infection threadsand were interspersed with intercellular bacteria. The meristematicactivity increased the relative volume of cortical to infectedcells in these nodules. Growth conditions did not affect control nodule specific nitrogenaseactivity or oxygen diffusion resistance (R) and these parameterswere also not altered in CEG nodules exposed to salt plus the14 d recovery period. However, nitrogenase activity was greatlyreduced, and R increased by more than eight times in equivalentGG nodules exposed to salt plus recovery. It is hypothesized that the gross morphological changes werean attempt to counter salt toxicity and/or oxygen damage underconditions of reduced photosynthate supply to the nodules dueto the poor light levels in the greenhouse. However, soybeannodules supplied with adequate photosynthate were able to withstandand recover from long-term salt-stress with little alterationto their structural integrity. Key words: Soybean, sodium chloride, nitrogen fixation, light intensity, oxygen diffusion resistance     

Nodule growth and activity may be regulated by a feedback mechanism involving phloem nitrogen*

We present a mechanism of regulation of growth and activity of legume root nodules which is consistent with published experimental observations. The concentration of reduced nitrogen compounds, probably amino acids, flowing into the nodules from the phloem, is sensed by the nodules; growth and activity of the nodules is adjusted accordingly. In many legumes this response may involve changes in the oxygen diffusion resistance of the nodule cortex. A straightforward feedback mechanism in which nodule activity is lowered when reduced N in the phloem is high and increased when it is low is envisaged. Almost all import into nodules is via the phloem sap originating in the lower leaves. As a plant develops, these mature leaves no longer utilize nitrogen delivered in the xylem and so export it in the phloem. In plants with an adequate nitrogen supply (from nodules or combined nitrogen in soil), a high concentration of nitrogen containing compounds in the phloem from the lower leaves may inhibit nodule growth as well as activity. This suggestion is an alternative to the hypotheses of carbohydrate deprivation or nitrate inhibition which are commonly used to explain the effects of combined nitrogen on nodule growth and activity.     

Nodule Activity and Allocation of Photosynthate of Soybean during Recovery from Water Stress

Nodulated soybean plants (Glycine max [L.] Merr. cv Ransom) in a growth-chamber study were subjected to a leaf water potential (Ψ_w) of −2.0 megapascal during vegetative growth. Changes in nonstructural carbohydrate contents of leaves, stems, roots, and nodules, allocation of dry matter among plant parts, in situ specific nodule activity, and in situ canopy apparent photosynthetic rate were measured in stressed and nonstressed plants during a 7-day period following rewatering. Leaf and nodule Ψ_w also were determined. At the time of maximum stress, concentration of nonstructural carbohydrates had declined in leaves of stressed, relative to nonstressed, plants, and the concentration of nonstructural carbohydrates had increased in stems, roots, and nodules. Sucrose concentrations in roots and nodules of stressed plants were 1.5 and 3 times greater, respectively, than those of nonstressed plants. Within 12 hours after rewatering, leaf and nodule Ψ_w of stressed plants had returned to values of nonstressed plants. Canopy apparent photosynthesis and specific nodule activity of stressed plants recovered to levels for nonstressed plants within 2 days after rewatering. The elevated sucrose concentrations in roots and nodules of stressed plants also declined rapidly upon rehydration. The increase in sucrose concentration in nodules, as well as the increase of carbohydrates in roots and stems, during water stress and the rapid disappearance upon rewatering indicates that inhibition of carbohydrate utilization within the nodule may be associated with loss of nodule activity. Availability of carbohydrates within the nodules and from photosynthetic activity following rehydration of nodules may mediate the rate of recovery of N₂-fixation activity.     

The Effect of Different Water Regimes on Growth and Nodule Development of Greenhouse-Grown Vicia faba

Plants of Vicia faba cv. Maris Bead were germinated under uniformconditions; some were then transferred to conditions of waterexcess or stress for the vegetative growth phase. Those on theexcess water regime grew best, produced most root nodules, andfixed most nitrogen. Microscopic examination showed that controland water-stressed plants did not develop all those noduleswhich had previously been initiated. Average nodule weight andspecific activity were unaffected, but nodules showed a progressiveincrease in size and a more open structure as water supply wasincreased. Transfer between treatments resulted in adaptationto the new environment within a few days. It is concluded that established plants of V. faba are far morelikely to be adversely affected by water stress than by excesswater.