Effects of Irradiance-Sulphur Interactions on Enzymes of Carbon,Nitrogen, and Sulphur Metabolism in Maize Plants

The effect of sulphur deprivation and irradiance (180 and 750 µmol m^–2 s^–1) on plant growth and enzyme activities of carbon, nitrogen, and sulphur metabolism were studied in maize (Zea mays L. Pioneer cv. Latina) plants over a 15-d-period of growth. Increase in irradiance resulted in an enhancement of several enzyme activities and generally accelerated the development of S deficiency. ATP sulphurylase (ATPs; EC 2.7.7.4) and o-acetylserine sulphydrylase (OASs; EC 4.2.99.8) showed a particular and different pattern as both enzymes exhibited maximum activity after 10 d from the beginning of deprivation period. Hence in maize leaves the enzymes of C, N, and S metabolism were differently regulated during the leaf development by irradiance and sulphur starvation.     

Genetic Variability in Carbon Fixation, Sucrose-P-Synthase and ADP Glucose Pyrophosphorylase in Maize Plants of Differing Growth Rate

The net photosynthetic rate and the activities of ribulose 1,5 bisphosphate carboxylase (RubisCo), phosphoenolpyruvate carboxylase, sucrose-P-synthase, and ADP glucose-pyrophosphorylase, key enzymes of the leaf carbohydrate metabolism were compared in eight maize (Zea mays L.) genotypes presenting large differences in growth rate. The sucrose-P-synthase activity varied in the ratio 1 to 3 from the less active to the more active genotype and this variation was highly correlated with those in growth rate. ADP glucose pyrophosphorylase activity was not significantly different from one genotype to another whatever the basis for expression, leaf area, or soluble protein. The photosynthetic rate varied with similar amplitude (1:1) to the RubisCo activity or RubisCo quantity but the correlation with growth rate was highly significant for photosynthesis and nonsignificant for RubisCo or phosphoenolpyruvate carboxylase. So, in our series of genotypes the sucrose synthesis capacities as expressed by sucrose phosphate synthase activity seem to have a good predicting value for mean growth rate at a young stage.     

不同缺氮营养水平对金色奥杜藻生长及光合生理的影响

采用了Φ6 cm柱状光生物反应器,在不同氮素营养条件(17.6 mmol/L N、8.8 mmol/L N、5.87 mmol/L N、0 mmol/L N)下通气培养硅藻金色奥杜藻[Odontella aurita(Bacillariophyceae;Centricae)],分析探讨藻细胞的光合生理及生长状况与氮素营养水平的关系。结果表明,不同氮素实验组藻细胞达到最大生长的时间明显差异,与对照组(17.6 mmol/L)相比,氮限制(5.87mmol/L N、8.8 mmol/L N)在培养的前期对金色奥杜藻的生长具有促进作用,氮饥饿(0 mmol/L)显著抑制藻细胞生长(P<0.05)。氮限制实验组藻细胞总碳水化合物的含量显著增加(P<0.05),而总蛋白含量明显下降(P<0.05)。藻细胞叶绿素a、c及总类胡萝卜素含量与培养液的氮素营养水平呈正相关。藻细胞最大光合放氧速率Pm随氮浓度下降而降低,呼吸速率Rd呈现相反趋势,PSⅡ最大光能转化效率(Fv/Fm)、实际光能转化效率(Yield)、潜在活性(Fv/Fo)以及相对电子传递效率(ETR)均随氮素限制而显著下降(P<0.05),说明藻细胞的表观光合生理状况与氮素营养水平直接相关。     

Nitrogen Fixation in the Phyllosphere of Tropical Plants: Occurrence of Phyllosphere Nitrogen-Fixing Micro-organisms in Eastern India and their Utility for the Growth and Nitrogen Nutrition of Host Plants

Of the 560 leaf samples belonging to 259 species of green plantsexamined more than 50 per cent of the Angiosperms and 25 percent of the Pteridophytes and Gymnosperms revealed the presenceof N₂-fixing micro-organisms in their phyllosphere. Plants particularlyremarkable in this respect are orchids and several other epiphytes,Scindapsus officinalis, Ficus and cucurbits. Most of the isolatesappear to be biotypes of Klebsiella pneumoniae. The more activestrains fixed more than 5 mg N g^–1 glucose utilized andreduced more than 100 nmol C₂H₂ mg^–1 cell d. w h^–1. The efficacy of the phyllosphere N₂-fixing isolates for N-nutritionof host plants was studied by spraying suspensions of the culturesgrown on N-free media on rice and wheat seedlings. In IR-26rice or Sonalika and Janak wheat grown on soil in wooden flatsor earthenware pots, 22 per cent of the 161 cultures studiedcaused increased height and about three-quarters of the culturesenhanced dry weight by more than 50 per cent; chlorophyll andN-contents were enhanced more than 50 per cent by about halfand two-thirds of the cultures respectively. In N-free sandculture 26 of the 50 promising strains doubled N-content, and30 doubled dry weight of the tested plants. In some cases dryweight, number of grains per panicle, and 1000 grain weightwere increased by 300, 70–83 and 126–158 per centrespectively; N-content of straw and seed was increased three-or fourfold. In several cases the beneficial effects were foundto match closely the performance of plants receiving ammoniumsulphate. Nitrogen-fixing micro-organisms, nitrogen nutrition, phyllosphere, rice, tropical plants, wheat     

Growth, Nitrogen Uptake and Flow in Maize Plants Affected by Root Growth Restriction

The objective of the present study was to investigate the influence of a reduced maize root-system size on root growth and nitrogen (N) uptake and flow within plants. Restriction of shoot-borne root growth caused a strong decrease in the absorption of root: shoot dry weight ratio and a reduction in shoot growth. On the other hand, compensatory growth and an increased N uptake rate in the remaining roots were observed. Despite the limited long-distance transport pathway in the mesocotyl with restriction of shoot-borne root growth, N cycling within these plants was higher than those in control plants, implying that xylem and phloem flow velocities via the mesocotyl were considerably higher than in plants with an intact root system. The removal of the seminal roots in addition to restricting shoot-borne root development did not affect whole plant growth and N uptake, except for the stronger compensatory growth of the primary roots. Our results suggest that an adequate N supply to maize plant is maintained by compensatory growth of the remaining roots, increased N uptake rate and flow velocities within the xylem and phloem via the mesocotyl, and reduction in the shoot growth rate.     

Growth,Nitrogen Uptake and Flow in Maize Plants Affected by Root Growth Restriction

The objective of the present study was to investigate the influence of a reduced maize root-system size on root growth and nitrogen （N） uptake and flow within plants. Restriction of shoot-borne root growth caused a strong decrease in the absorption of root ： shoot dry weight ratio and a reduction in shoot growth. On the other hand, compensatory growth and an increased N uptake rate in the remaining roots were observed. Despite the limited long-distance transport pathway in the mesocotyl with restriction of shoot-borne root growth, N cycling within these plants was higher than those in control plants, implying that xylem and phloem flow velocities via the mesocotyl were considerably higher than in plants with an intact root system. The removal of the seminal roots in addition to restricting shoot-borne root development did not affect whole plant growth and N uptake, except for the stronger compensatory growth of the primary roots. Our results suggest that an adequate N supply to maize plant is maintained by compensatory growth of the remaining roots, increased N uptake rate and flow velocities within the xylem and phloem via the mesocotyl, and reduction in the shoot growth rate.     

Effects of Nitrogen Nutrition on Photosynthesis in Cd-treated Sunflower Plants

Increased nitrogen supply stimulates plant growth and photosynthesis.Since it was shown that heavy metals may cause deficienciesof essential nutrients in plants the potential reversal of cadmiumtoxicity by increased N nutrition was investigated. The effectson photosynthesis of low Cd (0, 0.5, 2 or 5 mmol m^-3) combinedwith three N treatments (2, 7.5 or 10 mol m^-3) were examinedin young sunflower plants. Chlorophyll fluorescence quenchingparameters were determined at ambient CO₂and at 100 or 800 µmolquanta m^-2 s^-1. The vitality index (R_fd) decreased approx. three-timesin response to 5 mmol m^-3Cd, at 2 and 10 mol m^-3N. The maximumphotochemical efficiency of PSII reaction centres (F_v/ F_m) wasnot influenced by Cd or N treatment. The highest Cd concentrationdecreased quantum efficiency of PSII electron transport (_II)by 30%, at 2 and 10 mol m^-3N, mostly due to increased closureof PSII reaction centres (q_P). Photosynthetic oxygen evolutionrates at saturating CO₂were decreased in plants treated with5 mmol m^-3Cd, at all N concentrations. The results indicatethat Cd treatment affected the ribulose-1,5-bisphosphate (RuBP)regeneration capacity of the Calvin cycle more than other processes.At the same time, the amounts of soluble and ribulose-1,5-bisphosphatecarboxylase/oxygenase (Rubisco) protein increased with Cd treatment.Decreased photosynthesis, but substantially increased Rubiscocontent, in sunflower leaves under Cd stress indicate that asignificant amount of Rubisco protein is not active in photosynthesisand could have another function. It is shown that optimal nitrogennutrition decreases the inhibitory effects of Cd in young sunflowerplants. Copyright 2000 Annals of Botany Company Helianthus annuus L., cadmium, nitrogen, photosynthesis, Rubisco, sunflower     

不同碳氮营养源和培养温度对大球盖菇菌丝生长的影响

研究了碳源、氮源和温度对大球盖菇菌丝生长的影响,结果表明碳源中蔗糖对大球盖菇的菌丝生长最有利,其次为可溶性淀粉. 氮源中尿素最好,其次为蛋白胨和酵母膏;经温度梯度试验得出大球盖菇菌丝生长温度在 5～35 ℃,适宜生长温度为 25～30 ℃.经生料栽培发现大球盖菇适于麦秸、稻草上生长.     

去叶对不同生长习性大豆固氮作用的影响

生殖生长期开始去叶后 ,(1)有限型、亚有限型和无限型 3种类型的大豆根瘤固氮酶活性都降低 ,而根瘤中酰脲含量则不同程度地增加 ;(2 )有限型大豆幼茎中酰脲含量明显增加 ,但亚有限型和无限型大豆变化不大 ;(3) 3种类型大豆幼茎中硝态氮含量增加明显     

Changes in Growth and Nitrogen Assimilation in Maize Plants Induced by NaCl and Growth Regulators

Experiments were conducted to determine the interactive effects of salinity and certain growth regulators on growth and nitrogen assimilation in maize (Zea mays L. cv. GS-2). 100 mM NaCl inhibited the biomass accumulation, chlorophyll and carotenoid contents in leaves, nitrate content and uptake and nitrate reductase activity. The application of kinetin, ascorbic acid and 10 and 50 μM abscisic acid in the first experiment and 50 and 100 μM abscisic acid in the second experiment induced a substantial increase in the above parameters, the effect was highest with abscisic acid in salinized as well as non-salinized plants. This revised version was published online in July 2006 with corrections to the Cover Date.     

Plant Growth-Promoting Rhizobacteria Inoculation to Enhance Vegetative Growth,Nitrogen Fixation and Nitrogen Remobilisation of Maize under Greenhouse Conditions

Plant growth-promoting rhizobacteria (PGPR) may provide a biological alternative to fix atmospheric N₂ and delay N remobilisation in maize plant to increase crop yield, based on an understanding that plant-N remobilisation is directly correlated to its plant senescence. Thus, four PGPR strains were selected from a series of bacterial strains isolated from maize roots at two locations in Malaysia. The PGPR strains were screened in vitro for their biochemical plant growth-promoting (PGP) abilities and plant growth promotion assays. These strains were identified as Klebsiella sp. Br1, Klebsiella pneumoniae Fr1, Bacillus pumilus S1r1 and Acinetobacter sp. S3r2 and a reference strain used was Bacillus subtilis UPMB10. All the PGPR strains were tested positive for N₂ fixation, phosphate solubilisation and auxin production by in vitro tests. In a greenhouse experiment with reduced fertiliser-N input (a third of recommended fertiliser-N rate), the N₂ fixation abilities of PGPR in association with maize were determined by ¹⁵N isotope dilution technique at two harvests, namely, prior to anthesis (D₅₀) and ear harvest (D₆₅). The results indicated that dry biomass of top, root and ear, total N content and bacterial colonisations in non-rhizosphere, rhizosphere and endosphere of maize roots were influenced by PGPR inoculation. In particular, the plants inoculated with B. pumilus S1r1 generally outperformed those with the other treatments. They produced the highest N₂ fixing capacity of 30.5% (262 mg N₂ fixed plant⁻¹) and 25.5% (304 mg N₂ fixed plant⁻¹) of the total N requirement of maize top at D₅₀ and D₆₅, respectively. N remobilisation and plant senescence in maize were delayed by PGPR inoculation, which is an indicative of greater grain production. This is indicated by significant interactions between PGPR strains and time of harvests for parameters on N uptake and at. % ¹⁵N_e of tassel. The phenomenon is also supported by the lower N content in tassels of maize treated with PGPR, namely, B. pumilus S1r1, K. pneumoniae Fr1, B. subtilis UPMB10 and Acinetobacter sp. S3r2 at D₆₅ harvest. This study provides evidence that PGPR inoculation, namely, B. pumilus S1r1 can biologically fix atmospheric N₂ and provide an alternative technique, besides plant breeding, to delay N remobilisation in maize plant for higher ear yield (up to 30.9%) with reduced fertiliser-N input.     

Effects of Light and Nitrogen Nutrition on the Organization of the Photosynthetic Apparatus in Spinach

Nitrogen budgets of fully expanded young leaves of Spinaciaoleracea L. grown under three growth irradiances at four nitrateconcentrations, were compared in relation to photosynthesis.The proportion of nitrogen allocated to thylakoid membraneswas 24% of total leaf nitrogen irrespective of the growth conditions.The composition of the photosynthetic components in thylakoidmembranes was affected by growth irradiance but unaffected bynitrogen levels. The proportion of total leaf nitrogen allocatedto soluble protein and RuBP carboxylase (RuBPCase) increasedwith the increases in nitrogen and in irradiance levels. Someultrastructural properties of chloroplasts and their intra-leafgradients were also compared. The results suggest that nitrogennutrition affects the amount of thyalkoids per unit leaf areabut neither the properties of thyalkoids nor their intra-leafgradient. Growth irradiance, however, controls both the propertiesand the amount of thylakoids. The ratio of in vitro RuBPCase activity to electron transport/photophosphorylationactivity increased with the increase in nitrogen level, butdecreased with the increase in growth irradiance. The changein the ratio of in vitro activities may serve to balance thein vivo activities, given that the in vivo efficiency of RuBPCasedeclines with the increase in volume of a chloroplast due tothe increased liquid phase resistance to CO₂ diffusion. ³Present address: Plant Environmental Biology Group, ResearchSchool of Biological Sciences, The Australian National University,P.O. Box 475, Canberra, A.C.T. 2601, Australia. (Received July 29, 1987; Accepted November 2, 1987)     

Effects of Shading the First Leaf of Barley Plants on Growth and Carbon Nutrition of the Stem Apex

Effects of shading the first leaf on development of the apicalregion were investigated by examining the growth of leaf primordiaand the apical dome in the early seedling stages. Shade treatment affects the size of the dome; it was shown thatvalues for height, width, and volume of the dome of 12-day controlplants were always higher than for shaded plants. Primordialgrowth, in terms of length and dry weight, was reduced by shadeand growth in dry weight of the second, third, and fourth leaveswas shown to be dependent on photosynthetic production by thefirst leaf. Incorporation of ¹⁴C in the apical region was detected by autoradiographyon day 6 and increased with age. Transfer of assimilated carbonfrom the first leaf to the apex occurred during the first 3h after exposure to ¹⁴CO₂. On a unit dry-weight basis it isshown that the third and fourth leaves and apex incorporatedproportionately more labelled carbon than the larger older organssuch as the, second leaf. Shade treatment reduced incorporationinto the apical region and this is associated with the failureof the apex to grow over the period up to day 15. Evidence isprovided to show that in control plants the second leaf suppliescarbon to the apex from about day 12. The crucial importanceof the contribution of the first leaf to plant development isdiscussed.     

Effects of Salt Stress on Growth, Nodulation and Nitrogen Fixation in Cowpea and Mung Beans

The effects of salt stress on growth, nodulation, and nitrogen accumulation in cowpea (Vigna sinensis) and mung beans (Vigna aureus) were studied in sand culture. Salinity (NaCl) retarded the growth of leaves, stem and roots of both the crops. Root growth of mung beans was more sensitive to the increase in salt stress than that of cowpea. The relative growth rates of stressed plant parts declined initially but were subsequently higher than those of control for a period, suggesting that the plants tended to adapt to unfavourable environment even while being stressed. The total nodule number, weight and nitrogen content per plant decreased due to salt treatment, which interfered with the initiation of nodules but not with their further development. There was a considerable fall in the nitrogen fixation efficiency of mung beans under saline environment; it was not so in cowpea.     

Photosystem II Independent Carbon Dioxide Fixation in Plectonema boryanum During Photoautotrophic Growth Under Nitrogen Fixation Conditions

The non-heterocystous filamentous cyanobacterium Plectonema boryanum UTEX 594 grew rapidly microaerobically under nitrogen-starvation conditions in continuous high light intensity by conducting oxygenic photosynthesis and oxygen sensitive nitrogen-fixation in alternating cycles. During diazotrophic phase, the light harvesting pigment phycocyanin declined with a concomitant depression in light dependent oxygen evolution by the cyanobacterium. A substantial component of light dependent carbon dioxide fixation during diazotrophic phase was not inhibited by DCMU in spite of complete cessation of photosynthetic oxygen evolution. Endogenous-reductant dependent electron transfer to photosystem I during diazotrophic phase is postulated even during photoautotrophic growth.     

Nitrogen Fixation and Allantoin Formation in Soybean Plants

The activity of nitrogenase and the concentration of ammonia and allantoin (+ allantoic acid) in root nodules were measured throughout the growth period of soybean plants. Nitrogenase activity measured by acetylene reduction increased with plant growth and reached a maximum level at the flowering period. The level of ammonia and allantoin concentration in nodules was parallel with increased nitrogenase activity. At the late reproductive stage (pod-forming period), nitrogenase activity showed a marked decrease, but the ammonia and allantoin in the nodules remained at a constant level. Detached nodules from 56 day-old soybean plants were exposed to ¹⁵N₂ gas, and the distribution of ¹⁵N among nitrogen compounds was investigated. Enrichment of ¹⁵N in allantoin and allantoic acid reached a fairly high level after 90 min of nitrogen fixation; ca. 22% of ¹⁵N in acid-soluble nitrogen compounds was incorporated into allantoin + allantoic acid. In contrast, enrichment of ¹⁵N in amide nitrogen was relatively low. No significant ¹⁵N was detected in the RNA fraction. The data suggested that ureide formation in nitrogen-fixing root nodules did not take place through the breakdown of nucleic acids, but directly associated with the assimilating system of biologically fixed nitrogen.     

A Host-specific, Nitrogen Fixation Mutant of Bradyrhizobium: Physiology on Three Host Plants

NC92 #284 is a transposon mutant of Bradyrhizobium sp. (Arachis)strain NC92 and has a host-specific fixation phenotype. It appearsto be ineffective on the host pigeonpea (90% reduction in shootN compared to that of the wild type), but partially effectiveon two other host plants, groundnut and siratro (50% and 20%reduction in shoot N compared to the wild type, respectively).To understand this phenomenon of host-specific fixation, thephysiological basis of the phenotypes was investigated. Host-dependentdifferences in symbiotic effectiveness were largely explainedby the degree to which nitrogenase activity was impaired inthe various #284 symbioses. Nodulation and the onset of nitrogenfixation were found to be delayed on all three hosts, but tothe greatest degree on pigeonpea. The specific activity of nitrogenaseper gram nodule was also reduced on all three hosts, again tothe greatest extent on pigeonpea. By contrast, the carbon costsand relative efficiencies of each symbiosis were similar tothe wild type. The results indicate that the host-specific fixationphenotype of #284 is reflected in a quantitative reduction inthe amount of N₂ fixed. Thus the phenotypes reflect the differentability of the three host plants to tolerate or support the#284 mutation, rather than a defect in a specific interactionbetween #284 and a particular host plant. Key words: Bradyrhizobium, nodules, nitrogenase activity, relative efficiency, Arachis hypogaea, Cajanus cajan, Macroptilium atropurpureum     

Effects of Temperature on Growth and Nitrogen Fixation by Swards of Subterranean Clover

Subterranean clover (Trifolium subterraneum L.) cv. ‘Woogenellup’ swards were grown at 10, 15, 20 and 25 Cwith a 12 h photoperiod of 500 or 1000 µmol m^–2s^–1 [low and high photosynthetic photon flux density (PPFD)].Nitrogen-fixing swards received nutrient solution lacking combinednitrogen while control swards received a complete nutrient solution.Growth was measured by infra-red analysis of carbon dioxideexchange and by accumulation of dry matter. Swards were harvestedat intervals between 95 and 570 g d. wt m^–2 for estimationof nitrogenase activity by acetylene reduction and hydrogenevolution assays. Nitrogen fixation was also measured by increasein organic nitrogen. The growth rate was highest at 10 C at low PPFD, and at 10–15C at high PPFD. Nitrogen-fixing swards grew slower than thosereceiving combined nitrogen. Nitrogen fixation measured by increasein organic nitrogen responded similarly to the growth rate,as did acetylene reduction between 10 and 20 C. At 25 C therelationship between acetylene reduction and nitrogen fixationwas distrupted. The difference between the rates of acetylenereduction and hydrogen evolution, theoretically proportionalto nitrogen fixation, was not a reliable indicator of nitrogenfixation because hydrogen uptake developed. Trifolium subterraneum L, subterranean clover, growth, nitrogen fixation, temperature, acetylene reduction     

Photosynthetic CO2 Fixation in the Second Leaf of Wheat Seedlings Grown at Different Conditions of Nitrogen Nutrition

The rates of photosynthetic ₂ assimilation were determined in fully expanded second leaves of 21-day-old wheat (Triticum aestivum L.) seedlings grown on media supplied with nitrate or ammonia and on a nitrogen-free medium (NO₃ ^–- or NH₄ ⁺-treatments and N-deficit treatment, respectively). The maximal quantum efficiency of photosynthesis was independent on conditions of nitrogen nutrition. When leaves were exposed to 0.03% ₂ and high-intensity light, the lowest photosynthetic rate was noted for N-deficit treatment and the highest rate was characteristic of NH₄ ⁺ treatment. The elevation of the ₂ concentration in the gas phase to 0.1% stimulated photosynthesis at high-intensity light in all treatments. The rate of ₂ uptake by the leaf of N-deficient seedlings increased with ₂ concentration to a larger extent than in other treatments and approached the ₂ uptake rate characteristic of the NO₃ ^– treatment. In plants grown on a nitrogen-free medium, the leaf accumulated lesser amounts of reduced nitrogen and higher amounts of starch, but the content of chloroplast protein corresponded to that of NO₃ ^– treatment. In the leaf of NH₄ ⁺-treated seedlings, the rate of ₂ assimilation was higher than in the leaf of NO₃ ^– treated plants, regardless of the composition of the gas mixture. The ammonium-type nutrition, as compared to the nitrate-type nutrition, elevated the amount of reduced nitrogen in the leaf and promoted accumulation of chlorophyll and protein, the chloroplast protein in particular.     

Hydrogen Reactions of Nodulated Leguminous Plants: II. Effects on Dry Matter Accumulation and Nitrogen Fixation

The interaction between the ATP-dependent evolution of H₂ catalyzed by nitrogenase and the oxidation of H₂ via a hydrogenase has been postulated to influence the efficiency of the N₂-fixing process in nodulated legumes. A comparative study using soybean (Glycine max L. Merr.) cv. Anoka inoculated with either Rhizobium japonicum strain USDA 31 or USDA 110 and cowpea (Vigna unguiculata L. Walp.) cv. Whippoorwill inoculated with Rhizobium strain 176A27 or 176A28 cultured on a N-free medium was conducted to address this question. Nodules from the Anoka cultivar inoculated with USDA 31 evolved H₂ in air and the H₂ produced accounted for about 30% of the energy transferred to the nitrogenase system during the period of active N₂ fixation. In contrast the same soybean cultivar inoculated with USDA 110 produced nodules with an active hydrogenase and consequently did not evolve H₂ in air. A comparison of Anoka soybeans inoculated with the two different strains of R. japonicum showed that mean rates of C₂H₂ reduction and O₂ consumption and mean mass of nodules taken at four times during vegetative growth were not significantly different.

When compared to Anoka inoculated with USDA 31, the same cultivar inoculated with USDA 110 showed increases in total dry matter, per cent nitrogen, and total N₂ fixed of 24, 7, and 31%, respectively. Cowpeas in symbiosis with the hydrogenase-producing strain 176A28 in comparison with the same cultivar inoculated with the H₂-evolving strain 176A27 produced increases in plant dry weight and total N₂ fixed of 11 and 15%, respectively. This apparent increase in the efficiency of N₂ fixation for nodulated legumes capable of reutilizing the H₂ evolved from nitrogenase is considered and it is concluded that provision of conclusive evidence of the role of the H₂-recycling process in N₂-fixing efficiency of legumes will require comparison of Rhizobium strains that are genetically identical with the exception of the presence of hydrogenase.