Nitrate Effects on Nodule Oxygen Permeability and Leghemoglobin (Nodule Oximetry and Computer Modeling)

Two current hypotheses to explain nitrate inhibition of nodule function both involve decreased O2 supply for respiration in support of N2 fixation. This decrease could result from either (a) decreased O2 permeability (PO) of the nodule cortex, or (b) conversion of leghemoglobin (Lb) to an inactive, nitrosyl form. These hypotheses were tested using alfalfa (Medicago sativa L. cv Weevlchek) and birdsfoot trefoil (Lotus corniculatus L. cv Fergus) plants grown in growth pouches under controlled conditions. Nodulated roots were exposed to 10 mM KNO3 or KCI. Fractional oxygenation of Lb under air (FOLair), relative concentration of functional Lb, apparent PO, and O2-saturated central zone respiration rate were all monitored by nodule oximetry. Apparent PO and FOLair in nitrate-treated nodules decreased to <50% of values for KCI controls within 24 h, but there was no decrease in functional Lb concentration during the first 72 h. In nitrate-treated alfalfa, but not in birdsfoot trefoil, FOLair, apparent PO, and O2-saturated central zone respiration rate decreased during each light period and recovered somewhat during the subsequent dark period. This species difference could be explained by greater reliance on photoreduction of nitrate in alfalfa than in birdsfoot trefoil. Computer simulations extended the experimental results, showing that previously reported decreases in apparent PO of Glycine max nodules with nitrate exposure cannot be explained by hypothetical decreases in the concentration or O2 affinity of Lb.     

Elicitor-Inducible Caffeoyl-Coenzyme A 3-O-Methyltransferase from Petroselinum crispum Cell Suspensions : Purification, Partial Sequence, and Antigenicity

Physiological regulation of nodule gas permeability has a central role in the response of legumes to such diverse factors as drought, defoliation, and soil nitrate. A new method for quantifying nodule respiration and O₂ permeability, based on noninvasive spectrophotometry of leghemoglobin, was evaluated using intact, attached nodules of Lotus corniculatus. First, the relationship between nodule respiration (O₂ consumption) rate and internal O₂ concentration was determined from the rate of decrease in fractional oxygenation of leghemoglobin (FOL) under N₂. The rate of increase of FOL under 100% O₂ was then used to calculate nodule O₂ permeability, after correcting for respiration. Inactivation of nitrogenase by exposure to 100% O₂ for 15 minutes led to decreases in both permeability and O₂-saturated respiration (V_max), but the brief (<15 seconds) exposures to 100% O₂ required by the assay itself had little effect on either parameter. A gradual increase in external O₂ concentration from 20 to 40% resulted in a reversible decrease in permeability, but no change in V_max. The new method is likely to be useful for research on nodule physiology and might also be applicable to agronomic research and crop improvement programs.     

Reversible o(2) inhibition of nitrogenase activity in attached soybean nodules

Various forms of stress result in decreased O₂ permeability or decreased capacity to consume O₂ in legume root nodules. These changes alter the nodule interior O₂ concentration (O_i). To determine the relationship between O_i and nitrogenase activity in attached soybean (Glycine max) nodules, we controlled O_i by varying external pO₂ while monitoring internal H₂ concentration (H_i) with microelectrodes. O_i was monitored by noninvasive leghemoglobin spectrophotometry (nodule oximetry). After each step-change in O_i, H_i approached a new steady state, with a time constant averaging 23 s. The rate of H₂ production by nitrogenase was calculated as the product of H_i, nodule surface area, and nodule H₂ permeability. H₂ permeability was estimated from O₂ permeability (measured by nodule oximetry) by assuming diffusion through air-filled pores; support for this assumption is presented. O_i was nearly optimal for nitrogenase activity (H₂ production) between 15 and 150 nm. A 1- to 2-min exposure to elevated external pO₂ (40-100 kPa) reduced H_i to zero, but nitrogenase activity recovered quickly under air, often in <20 min. This rapid recovery contrasts with previous reports of much slower recovery with longer exposures to elevated pO₂. The mechanism of nitrogenase inhibition may differ between brief and prolonged O₂ exposures.     

Tracing the Path of Oxygen into Birdsfoot Trefoil and Alfalfa Nodules using Iodine Vapor

Although physiological control of nodule 0₂ permeability is an active area of research, the gas diffusion pathway between the atmosphere and the infected zone has not been firmly established. Previous studies have used infiltration of ink or dyes to identify points of entry, but such water-soluble tracers could give a misleading picture of gas diffusion pathways. We therefore used iodine vapor (and its reaction with starch) to trace gas-phase pathways into the infected zone of determinate birdsfoot trefoil (Lotus corniculatus) and indeterminate alfalfa (Medicago sativa) nodules. We also used histochemical methods to identify suberized or lignified layers that could act as barriers to gas diffusion. Birdsfoot trefoil nodules were surrounded by a suberized periderm, but nonsuberized cells and intercellular spaces were observed in the periderm between lenticels and their associated vascular bundles. Iodine entered birdsfoot trefoil nodules only through lenticels. The periderm appears to provide a significant barrier to gas diffusion. Although airspaces were rare in the nodule parenchyma (also referred to as the “inner cortex”), we found some evidence that a few air-filled pathways cross this secondary barrier, also in the vicinity of vascular bundles. Alfalfa nodules were cylindrically surrounded by a suberized endodermis which ended near the meristematic tip; iodine entered principally at the end of the endodermis near the meristem. Future research on physiological control of nodule O₂ permeability should concentrate on strategic “choke points”, associated with lenticels in determinate nodules, or in the zone proximal to the meristem in indeterminate nodules.     

Nonphotosynthetic CO(2) Fixation by Alfalfa (Medicago sativa L.) Roots and Nodules

The dependence of alfalfa (Medicago sativa L.) root and nodule nonphotosynthetic CO₂ fixation on the supply of currently produced photosynthate and nodule nitrogenase activity was examined at various times after phloem-girdling and exposure of nodules to Ar:O₂. Phloemgirdling was effected 20 hours and exposure to Ar:O₂ was effected 2 to 3 hours before initiation of experiments. Nodule and root CO₂ fixation rates of phloem-girdled plants were reduced to 38 and 50%, respectively, of those of control plants. Exposure to Ar:O₂ decreased nodule CO₂ fixation rates to 45%, respiration rates to 55%, and nitrogenase activities to 51% of those of the controls. The products of nodule CO₂ fixation were exported through the xylem to the shoot mainly as amino acids within 30 to 60 minutes after exposure to ¹⁴CO₂. In contrast to nodules, roots exported very little radioactivity, and most of the ¹⁴C was exported as organic acids. The nonphotosynthetic CO₂ fixation rate of roots and nodules averaged 26% of the gross respiration rate, i.e. the sum of net respiration and nonphotosynthetic CO₂ assimilation. Nodules fixed CO₂ at a rate 5.6 times that of roots, but since nodules comprised a small portion of root system mass, roots accounted for 76% of the nodulated root system CO₂ fixation. The results of this study showed that exposure of nodules to Ar:O₂ reduced nodule-specific respiration and nitrogenase activity by similar amounts, and that phloem-girdling significantly reduced nodule CO₂ fixation, nitrogenase activity, nodule-specific respiration, and transport of ¹⁴C photoassimilate to nodules. These results indicate that nodule CO₂ fixation in alfalfa is associated with N assimilation.     

Species variation in the fixation and transfer of nitrogen from legumes to associated grasses

Summary Three legume species (alfalfa, red clover, and birdsfoot trefoil) in combination with five grass species (timothy, bromegrass, red fescue, tall fescue, and orchardgrass) were used to study N transfer in mixtures, using the 15_N dilution technique. The advantage of grass-legume mixtures was apparent. Total herbage and protein yields of grasses in mixtures were higher than those alone, especially at the later cuts. This benefit of mixed cropping is mainly due to N transfer from legumes to associated grasses. N₂-fixation and N transfer by alfalfa rated highest, red clover intermediate, and birdsfoot trefoil lowest. The importance of each pathway of N transfer from legumes appeared to differ between species. Alfalfa and red clover excreted more N than trefoil, while the latter contributed more N from decomposition of dead nodule and root tissue. The greatest advantage from a grass-legume mixture, with respect to the utilization of N released from the legume, varied with early maturing tall fescue (Kentucky 31), orchardgrass (Juno), and bromegrass (Tempo), to intermediate timothy (Climax), and least with late maturing red fescue (Carlawn). Contribution no. 817 of the Ottawa Research Station.     

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.     

Supply and partitioning of assimilates to roots of Medicago sativa L. and Lotus corniculatus L. under anoxia

Abstract A current explanation of the mechanism of flooding injury to roots suggests that oxygen deficiency depresses the supply of respirable carbohydrates sufficiently to inhibit fermentation. However, even though it has been shown that phloem transport of assimilate is sharply reduced to anaerobic roots, inhibition of assimilate metabolism has also been suggested to be an important factor. This study examines these hypotheses by relating assimilate supply and metabolic activity in anoxic roots of alfalfa (Medicago sativa L.), a flood-intolerant species, and birdsfoot trefoil (Lotus corniculatus L.), a flood-tolerant plant. Roots were made anoxic (severe O₂ deficiency) for 2, 4 or 6 d and shoots were labelled with ¹⁴CO₂. Assimilate transport to the roots and metabolism to structural components were significantly decreased in both species in response to anoxia. Trefoil exhibited significantly greater ¹⁴C incorporation into the residue fraction at 4 d anoxia than did alfalfa, and this was consistent with the greater flooding tolerance of trefoil. When assimilate supply to O₂-deficient roots was decreased by shoot shading, shoot fresh weight was reduced by both anoxia and light treatments. Root-soluble sugars were significantly decreased by shading but were greatly increased in response to anoxia. Root starch concentration also increased under anoxia. Root K⁺ concentration was reduced by anoxia only. The energy status (ATP/ADP) of roots was significantly decreased by shading; however, anoxia reduced the energy status only in unshaded plants. The data indicate that carbohydrate supply to anaerobic roots does not appear to be a limiting factor in the metabolic response of alfalfa roots. Alternatively, metabolism of assimilate in anoxic roots may be an important determinant of survival.     

Drought Stress,Permeability to O2 Diffusion,and the Respiratory Kinetics of Soybean Root Nodules

In legume nodules, treatments such as detopping or nitrate fertilization inhibit nodule metabolism and N2 fixation by decreasing the nodule's permeability to O2 diffusion, thereby decreasing the infected cell O2 concentration (Oi) and increasing the degree to which nodule metabolism is limited by O2 availability. In the present study we used nodule oximetry to assess and compare the role of O2 limitation in soybean (Glycine max L. Merr) nodules inhibited by either drought or detopping. Compared to detopping, drought caused only minor decreases in Oi, and when the external O2 concentration was increased to raise Oi, the infected cell respiration rate in the drought-stressed plants was not stimulated as much as it was in the nodules of the detopped plants. Unlike those in detopped plants, nodules exposed to moderate drought stress displayed an O2-sufficient respiration rate that was significantly lower than that in control nodules. Despite possible side effects of oximetry in altering nodule metabolism, these results provided direct evidence that, compared to detopping, O2 limitation plays a minor role in the inhibition of nodule metabolism during drought stress and changes in nodule permeability are the effect, not the cause, of a drought-induced inhibition of nodule metabolism and the O2-suffiecient rate of respiration.     

Photosynthetic down-regulation in N2-fixing alfalfa under elevated CO2 alters rubisco content and decreases nodule metabolism via nitrogenase and tricarboxylic acid cycle

Although responsiveness of N₂-fixing plants to elevated CO₂ conditions have been analyzed in previous studies, important uncertainties remain in relation to the effect enhanced CO₂ in nodule proteomic profile and its implication in leaf responsiveness. The aim of our study was to deepen our understanding of the relationship between leaf and nodule metabolism of N₂-fixing alfalfa plants after long-term exposure to elevated CO₂. After 30-day exposure to elevated CO₂, plants showed photosynthetic down-regulation with reductions in the light-saturated rate of CO₂ assimilation (A _sat) and the maximum rate of rubisco carboxylation (Vc_max). Under elevated CO₂ conditions, the rubisco availability limited potential photosynthesis by around 12 %, which represented the majority of the observed fall in Vc_max. Photosynthetic down-regulation has been associated with decreased N availability even if those plants are capable to assimilate N₂. Diminishment in shoot N demand (as reflected by the lower rubisco and leaf N content) suggests that the lower aboveground N requirements affected negatively nodule performance. In this condition, specific nodule activity was reduced due to an effect on nodule metabolism that manifested as a lower amount of nitrogenase reductase. Moreover, the nodule proteomic approach also revealed that nodule functioning was altered simultaneously in various enzyme quantity apart from nitrogenase. At elevated CO₂, the tricarboxylic acid cycle was also altered with a reduced amount of isocitrate synthase protein. The nodule proteome analysis also revealed the relaxation of the antioxidant system as shown by a decline in the amount of catalase and isoflavone reductase protein.     

Amylase Activity in Taproots of Medicago sativa L. and Lotus corniculatus L. Following Defoliation

Although the patterns of starch metabolism in taproots of alfalfa(Medicago sativa L.) and birdsfoot trefoil (Lotus corniculatusL.) have been characterized, little is known regarding the activitiesof starch-degrading enzymes in taproots of these species. Ourobjective was to determine how defoliation influences starchdegradation and activities of amylases in taproots of alfalfaand birdsfoot trefoil. In Exp. 1, amylolytic activities andstarch concentrations in taproots of defoliated and undefoliatedplants were compared on days 0, 3, 7, 10, and 14 after defoliation.Taproot starch concentrations declined in defoliated plants,while increasing in taproots of undefoliated plants. Exoamylaseactivities in taproots of defoliated plants did not change withdefoliation, while endoamylase activities increased 2-fold indefoliated alfalfa and 50% in defoliated birdsfoot trefoil plantswhen compared to undefoliated plants. In Exp. 2, activity andisoform complement of amylases were monitored during seedlingdevelopment. High endoamylase activity was found in taprootsof both species at all samplings. In contrast, exoamylase accumulatedin taproots of alfalfa, but not birdsfoot trefoil, in a patternsimilar to starch accumulation. As in Exp. 1, defoliation increasedendoamylase, but not exoamylase activity in taproots of bothspecies. Taproots of both species contained one major and twominor endoamylase isoforms, but the electrophoretic mobilityof these isoforms differed between species. Activities of allisoforms, as indicated on starch-gel blots, increased in responseto defoliation. These results indicate that defoliation increasesactivity of taproot endoamylases, whose activity is associatedwith taproot starch degradation. Key words: Starch degradation, alfalfa, birdsfoot trefoil, enzymes     

Nitrogen fixation and vegetative regrowth of alfalfa and birdsfoot trefoil after successive harvests or floral debudding

Nitrogenase-dependent acetylene reduction, leaf, herbage, and root growth, and total nonstructural carbohydrate accumulation of alfalfa (Medicago sativa L.) and birdsfoot trefoil (Lotus corniculatus L.) were compared to learn how nitrogen fixation capacity and vegetative growth respond to partial (75-85%) or total shoot and leaf removal, and floral debudding. Treatments were imposed on greenhouse-grown plants during two successive harvest cycles.     

Effect of Increases in Oxygen Concentration during the Argon-Induced Decline in Nitrogenase Activity in Root Nodules of Soybean

When intact nodulated roots of soybean (Glycine max L. Merr. nodulated with Bradyrhizobium japonicum strain USDA 16) were exposed to an atmosphere lacking N₂ gas (Ar:O₂ 80:20), total nitrogenase activity (measured as H₂ evolution) and respiration (CO₂ evolution) declined with time of exposure. In Ar-inhibited nodules, when the O₂ concentration in the rhizosphere was increased in a linear `ramp' of 2.7% per minute, 93% of the original H₂ evolution and 99% of the CO₂ evolution could be recovered. The internal nodule O₂ concentration (estimated from leghemoglobin oxygenation) declined to 56% of its initial value after 60 minutes of Ar:O₂ exposure and could be partially recovered by the linear increases in O₂ concentration. Nodule gas permeability, as estimated from the lag in ethylene production following exposure of nodules to acetylene, decreased to 26% of its initial value during the Ar-induced decline. Collectively, the results provide direct evidence that the Ar-induced decline results from decreased nodule gas permeability and indicate that the decline in permeability, rather than being immediate, occurs gradually over the period of Ar:O₂ exposure.     

Glycolytic Flux Is Adjusted to Nitrogenase Activity in Nodules of Detopped and Argon-Treated Alfalfa Plants

To investigate the short-term (30–240 min) interactions among nitrogenase activity, NH₄⁺ assimilation, and plant glycolysis, we measured the concentrations of selected C and N metabolites in alfalfa (Medicago sativa L.) root nodules after detopping and during continuous exposure of the nodulated roots to Ar:O₂ (80:20, v/v). Both treatments caused an increase in the ratios of glucose-6-phosphate to fructose-1,6-bisphosphate, fructose-6-phosphate to fructose-1,6-bisphosphate, phosphoenolpyruvate (PEP) to pyruvate, and PEP to malate. This suggested that glycolytic flux was inhibited at the steps catalyzed by phosphofructokinase, pyruvate kinase, and PEP carboxylase. In the Ar:O₂-treated plants the apparent inhibition of glycolytic flux was reversible, whereas in the detopped plants it was not. In both groups of plants the apparent inhibition of glycolytic flux was delayed relative to the decline in nitrogenase activity. The decline in nitrogenase activity was followed by a dramatic increase in the nodular glutamate to glutamine ratio. In the detopped plants this was coincident with the apparent inhibition of glycolytic flux, whereas in the Ar:O₂-treated plants it preceded the apparent inhibition of glycolytic flux. We propose that the increase in the nodular glutamate to glutamine ratio, which occurs as a result of the decline in nitrogenase activity, may act as a signal to decrease plant glycolytic flux in legume root nodules.     

Nitrogenase Activity and Nodule Gas Permeability Response to Rhizospheric NH(3) in Soybean

This study was conducted on soybean (Glycine max L. Merr.) nodules to determine if exogenous NH₃ exerts a controlling influence over nitrogenase activity through changes in nodule gas permeability (P), and if decreasing carbohydrate availability, as a result of low-light treatment, increases the sensitivity of root nodules to NH₃. Nodulated root systems of intact plants were exposed to one of several NH₃ concentrations ranging from 0 to 821 microliters per liter for an 8-hour period. Treatments were conducted under high-light (2300 micromoles per square meter per second) or low-light (800 micromoles per square meter per second) conditions. Increasing the NH₃ concentration and length of exposure of NH₃ caused a progressive decline in acetylene reduction activity (ARA). There was generally a greater reduction in ARA under the low-light treatment compared to the high-light treatment at a particular NH₃ concentration. The NH₃ concentration necessary to decrease P was greater than that needed to decrease ARA, and there was no evidence of a causal relationship between P and ARA in response to NH₃.     

Experimental determination of the respiration associated with soybean/rhizobium nitrogenase function, nodule maintenance, and total nodule nitrogen fixation

The total metabolic cost of soybean (Glycine max L. Mer Clark) nodule nitrogen fixation was empirically separated into respiration associated with electron flow through nitrogenase and respiration associated with maintenance of nodule function.

Rates of CO₂ evolution and H₂ evolution from intact, nodulated root systems under Ar:O₂ atmospheres decreased in parallel when plants were maintained in an extended dark period. While H₂ evolution approached zero after 36 hours of darkness at 22°C, CO₂ evolution rate remained at 38° of the rate measured in light. Of the remaining CO₂ evolution, 62% was estimated to originate from the nodules and represents a measure of nodule maintenance respiration. The nodule maintenance requirement was temperature dependent and was estimated at 79 and 137 micromoles CO₂ (per gram dry weight nodule) per hour at 22°C and 30°C, respectively.

The cost of N₂ fixation in terms of CO₂ evolved per electron pair utilized by nitrogenase was estimated from the slope of H₂ evolution rate versus CO₂ evolution rate. The cost was 2 moles CO₂ evolved per mole H₂ evolved and was independent of temperature.

In this symbiosis, nodule maintenance consumed 22% of total respiratory energy while the functioning of nitrogenase consumed a further 52%. The remaining respiratory energy was calculated to be associated with ammonia assimilation, transport of reduced N, and H₂ evolution.

     

Does oxygen limit nitrogenase activity in soybean exposed to elevated CO2?

Soybean (Glycine max L. Merr) plants grown under control (360 µmol mol^?1) or elevated CO₂ concentration (800 µmol mol^?1) from 33 to 42 d after sowing were assayed for various components of in vivo nitrogenase activity to test the hypothesis that increasing carbohydrate supply to nodules would increase the potential (i.e. O₂ saturated) nitrogenase activity and impose a more severe O₂ limitation on both nodule metabolism and total nitrogenase activity. Within 51 h of elevated CO₂ treatment, significant increases relative to control plants were seen in total nitrogenase activity expressed per plant. After 6 d of elevated CO₂, the total nitrogenase activity per plant was 18% higher than that in control. This was attributed to an initial increase in nodule size, and a subsequent increase in nodule number following plant exposure to elevated CO₂. However, after 9 d of elevated CO₂, the potential and total nitrogenase activities per gram nodule dry weight were lower, not higher than corresponding values in plants in the control treatment. These results did not support the hypothesis. It was concluded that the metabolic capacity of the control nodules were not limited by carbohydrate supply, at least at the assay temperatures employed here.     

Mechanism of Nitrogenase Inhibition in Soybean Nodules : Pulse-Modulated Spectroscopy Indicates that Nitrogenase Activity Is Limited by O(2)

A novel, pulse-modulated spectroscopic system for measuring fractional leghemoglobin oxygenation and infected cell O₂ concentration (O_i) in intact attached nodules of soybean (Glycine max) is described. The system is noninvasive and uses a pulsed (1000 Hertz) light-emitting diode coupled to an optical fiber to illuminate the nodule with light at 660 nanometer. A second optical fiber receives a portion of the light reflected from the nodule and directs this to a photodiode. A lock-in amplifier measures only the signal from the photodiode which is in phase with the pulsed light from the light-emitting diode, and the voltage output from the amplifier, proportional to reflectance, is used to calculate fractional leghemoglobin oxygenation and the nanomolar concentration of free O₂ in the infected cells of the nodule (O_i). The system was used to show that inhibition of nitrogenase activity in soybean nodules by NO₃⁻ treatment, stem-girdling, continuous darkness, or nodule disturbance is caused by a reduction in O_i and limitation of respiration in support of nitrogenase activity. A plot of nitrogenase activity (measured as peak H₂ evolution in Ar:O₂) versus O_i for the various treatments was consistent with the concept that O_i limits in vivo nitrogenase activity in legume nodules under adverse conditions. The potential for using O_i to estimate nitrogenase activity in laboratory and field-grown legumes is discussed.     

Adaptation of Nitrogen Fixation by Intact Soybean Nodules to Altered Rhizosphere pO(2)

The N₂-fixing legume nodule requires O₂ for ATP production; however, the O₂ sensitivity of nitrogenase dictates a requirement for a low pO₂ inside the nodule. The effects of long term exposures to various pO₂s on N₂[C₂H₂] fixation were evaluated with intact soybean (Glycine max [L.] Merr., var. Wye) plants. Continuous exposure of their rhizosphere to a pO₂ of 0.06 atmospheres initially reduced nitrogenase activity by 37 to 45% with restoration of original activity in 4 to 24 hours and with no further change in tests up to 95 hours; continuous exposure to 0.02 atmosphere of O₂ initially reduced nitrogenase activity 72%, with only partial recovery by 95 hours. Similar exposures to a pO₂ of 0.32 atmospheres had little effect on N₂[C₂H₂] fixation; a pO₂ of 0.89 atmospheres initially reduced nitrogenase activity by 98% with restoration to only 14 to 24% of that of the ambient O₂ controls by 95 hours. Re-exposure to ambient pO₂ of plants adapted to nonambient pO₂s reduced N₂[C₂H₂] fixation to similar magnitudes as the reductions which occurred upon initial exposure to variant pO₂ conditions, and a time period was required to readapt to ambient O₂. It is concluded that the N₂[C₂H₂]-fixing system of intact soybean plants is able to adapt to a wide range of external pO₂s as probably occur in soil. We postulate that this occurs through an undefined mechanism which enables the nodule to maintain an internal pO₂ optimal for nitrogenase activity.