Reaction of faba bean plants to soil and foliar N application and K nutrition

The effect of different rates and methods of fertilizer nitrogen application and potassium nutrition on the root nodule formation of faba bean plants var. Nadwiślański and on their nitrogenase activity was studied. It was found that fertilizer N depressed the nodule formation and nitrogenase activity, but inhibitory effect of N was smaller when it was supplied to the leaves instead to the soil. Plants growing at higher K level were in a position allowing on better development of nodules and consequently higher N₂- fixation.     

Breding common bean for improved biological nitrogen fixation

Common bean (Phaseolus vulgaris L.), which is an important food crop in the Americas, Africa and Asia, usually is thought to fix only small amounts of atmospheric nitrogen. However, field data indicate considerable genetic variability for total N₂ fixation and traits associated with fixation. Studies have shown that selection to increase N₂ fixation will be successful if: (1) discriminating traits (selection criteria) are measured precisely, (2) variability in germplasm is heritable, (3) selected parents are also agronomically suitable, (4) units of selection facilitate quantification of selection criteria, and (5) a breeding procedure that allows maximum genetic gain for N₂ fixation and recombination with essential agronomic traits is chosen. Breeding lines capable of fixing enough atmospheric N₂ to support seed yields of 1000–2000 kg ha^–1 have been identified and new cultivars with high N₂ fixation potential are being released.     

Enhancement of nitrogen fixation in lentil,faba bean,and soybean by dual inoculation with Rhizobia and mycorrhizae

The combined effect of Vesicular Arbuscular Mycorrhizae (VAM) and Rhizobium on the cold season legumes, lentil and faba bean, as well as on summer legume, soybean, were studied in soils with low indeginous VA mycorrhizal spores. Inoculation of the plant with VA mycorrhizal fungi increased the level of mycorrhizal root infection of lentil, faba bean and soybean. The inoculation with Rhizobium had no significant effect on VA mycorrhizal infection percent, but VA mycorrhizal inoculation increased nodulation of the three legumes. The inoculation with Rhizobium alone significantly increased plant dry weight and N content of lentil and faba bean as well as seed yield of soybean. VA mycorrhizal inoculation also significantly increased plant dry weight and phosphorus content of the plants as did fertilization with superphosphate. Rock phosphate fertilization, however, had no significant effect on plant growth or phosphorus uptake. The addition of rock phosphate in combination with VA mycorrhizal inoculation significantly increased plant dry weight and P uptake of the plants. The dual inoculation with both rhizobia and mycorrhizae induced more significant increases in plant dry weight, N and P content of lentil and faba bean as well as seed yield of soybean than inoculation with either VA mycorrhizae or Rhizobium alone.     

Time course of N2 fixation in common bean (Phaseolus vulgaris L.)

Field and greenhouse experiments were conducted to assess the nitrogen fixation rates of four cultivars of common bean (Phaseolus vulgaris L.) at different growth stages. The ¹⁵N isotope dilution technique was used to quantify biological nitrogen fixation. In the greenhouse, cultivars M4403 and Kallmet accumulated 301 and 189 mg N plant^–1, respectively, up to 63 days after planting (DAP) of which 57 and 43% was derived from atmosphere. Under field conditions, cultivars Bayocel and Flor de Mayo RMC accumulated in 77 DAP, 147 and 135 kg N ha^–1, respectively, of which approximately one-half was derived from the atmosphere. The rates of N₂ fixation determined at different growth stages increased as the plants developed, and reached a maximum during the reproductive stage both under field and greenhouse conditions. Differences in translocation of N were observed between the cultivars tested, particularly under field conditions. Thus, the fixed N harvest index was 93 and 60 for cultivars Flor de Mayo and Bayocel, respectively. In early stages of growth, the total content of ureides in the plants correlated with the N fixation rates. The findings reported in the present paper can be used to build a strategy for enhancing biological N₂ fixation in common bean.     

The influence of nitrate supply on nitrogen fixation during growth of the field bean Vicia faba in sand

Field bean (Vicia faba L.) cv. Maris Bead seeds were inoculated with Rhizobium Catalogue No. 1001, supplied by Rothamsted Experimental Station and grown in sand culture supplied with ¹⁵N-labelled nitrate at two concentrations. Plants were sampled at intervals throughout their growth for ¹⁵N and total N analysis. The rate of nitrate uptake was almost uniform up to pod-fill and was proportional to the nitrate concentration. Nodule weight was slightly depressed by the larger nitrate concentration at all samplings, and there was a corresponding reduction in the amount of atmospheric nitrogen fixed. However, at harvest the bean seeds from plants given most nitrate contained slightly more total N, as the enhanced nitrate uptake outweighed the reduction in fixation.     

Quantitative assessment of symbiotic nitrogen fixation in diverse mutant lines of field bean (Vicia faba minor)

Summary Homozygous mutant lines of field bean selected for (a) improved yielding potential and (b) altered plant architecture and/or physiological response were tested for symbiotic nitrogen fixing ability under field conditions in comparison with their parent cultivar.¹⁵N-tracer techniques were applied to determine %N derived from atmosphere. Data were collected on assimilate and nitrogen accumulation and distribution among various plant parts during two stages of reproductive growth.Symbiotic nitrogen fixation was closely correlated with total plant top biomass and nitrogen yield. A similar close association was found between crop yield and nitrogen harvest index. Both harvest indices tended to be negatively correlated with stage of maturity and with the amount of N derived from air per unit of area. The generally high %N derived from symbiotic N₂ fixation and its comparatively small variability implies that this parameter may be difficult to improve inVicia faba under field conditions.It is concluded, that the main genetic potential for improving the amount of biological nitrogen fixation in this crop depends upon factors that promote high photosynthetic productivity and efficient N-use under appropriate agronomic conditions and with effective rhizobial associations. The establishment of rational ideotypes with a possitive impact on yield appears to be of practical significance for increasing the amount of symbiotically fixed nitrogen.     

Control of the expression of bacterial genes involved in symbiotic nitrogen fixation

Several genera of N₂-fixing bacteria establish symbiotic associations with plants. Among these, the genus Rhizobium has the most significant contribution, in terms of yield, in many important crop plants. The establishment of the Rhizobium-legume symbiosis is a very complex process involving many genes which need to be co-ordinately regulated. In the first instance, plant signal molecules, known to be flavonoids, trigger the expression of host-specific genes in the bacterial partner through the action of the regulatory NodD protein. In response to these signals, Rhizobium bacteria synthesize lipo-oligosaccharide molecules which in turn cause cell differentiation and nodule development. Once the nodule has formed, Rhizobium cells differentiate into bacteroids and another set of genes is activated. These genes, designated nif and fix, are responsible for N₂ fixation. In this system, several regulatory proteins are involved in a complex manner, the most important being NifA and a two component (FixK and FixL) regulatory system. Our knowledge about the establishment of these symbioses has advanced recently, although there are many questions yet to be solved.     

Proteolysis and nitrogen fixation in faba-bean (Vicia faba) nodules under water stress

Nodulated faba-beans ( Vicia faba L. var. minor) exhibiting high rates of N₂ fixation (133 μmol C₂H₄ g⁻¹ dry weight h⁻¹), were subjected to water restriction. A loss of C₂H₂ reduction due to water stress was always associated with a decline of the leghemoglobin content for each of the 4 decreasing values of Ψ_mod. Electron micrographs showed ultrastructural alterations of the fixing tissue, which affected both partners and increased with the severity of water stress. In the nodule cytosol, the alkaline proteolysis approximately doubled when Ψ_mod decreased from −0.55 MPa to −1.55 MPa. Concomitantly, an increase of the nodule intracellular pH from 6.3 to 7.0 was observed. Proteolysis was due to serine proteases, exhibiting a pH-optimum of 8 and which actively degraded purified leghemoglobin in vitro (K_m=100 μ M ). The degradation of leghemoglobin during water stress may contribute to the loss of C₂H₂ reduction and may affect the pattern of recovery upon rewatering.     

Comparison of acetylene-reduction and nitrogen-15 techniques for the determination of nitrogen fixation by field bean (Vicia faba) nodules

Field bean (Vicia faba L.) cv. Maris Bead seeds were inoculated with Rhizobium Catalogue No. 1001, supplied by Rothamsted Experimental Station, and grown in sand culture supplied with a complete nutrient solution which included nitrate at either 1.5 or 6.0 mM. Nodules were detached from the roots at intervals during plant development and their rates of nitrogen fixation estimated by both acetylene reduction and ¹⁵N gas technique. There was a constant relationship, independent of nitrate supply, between the results obtained by these two methods at all samplings. The amounts of acetylene reduced divided by a factor of 5.75 gave the amount of true nitrogen fixation; this factor is about twice the theoretical value. It is suggested that this discrepancy arose because, with acetylene, all the electrons available to the nitrogenase were used to form ethylene, whereas during normal fixation only about half the electron supply was used to fix nitrogen, the remainder having been consumed in the production of hydrogen gas.     

Utilizing the potential for increased nitrogen fixation in common bean

Many variables affect the amount of N₂ fixation that occurs in field-grown common beans (Phaseolus vulgaris L.). When environmental conditions are optimized, genetically superior plants that are nodulated with efficient rhizobia are able to fix enough N₂ to support grain yields of up to 2000 kg ha^–1. All of the required components are available for common bean to fulfill its potential as a nitrogen-fixing food crop. However, these components must be assembled and presented to growers in a usable package that is economically attractive.     

Yield and biological nitrogen fixation of common bean (Phaseolus vulgaris L.) in Peru

Two field experiments were performed to evaluate the nitrogen fixation potential of twenty common bean cultivars and breeding lines during summer and winter seasons of 1986 and 1988, respectively. The ¹⁵N isotope dilution method was used to quantify N₂ fixation. The cultivars and breeding lines were variable in terms of their N₂ fixation. The cv. Caballero was very efficient, with more than 50% N derived from the atmosphere and 60–80 kg N ha^–1 fixed in both seasons. Other cultivars were less efficient, since the poorest ones derived less than 30% of their nitrogen from the atmosphere and fixed less than 20 kg N ha^–1. After additional testing the best cultivars may be used directly by the farmers for cultivation. The experiments have provided information about which genotypes may be used to breed for enhanced fixation in common bean.     

Proline accumulation inside symbiosomes of faba bean nodules under salt stress

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

Genotypic variation in biological nitrogen fixation by common bean

Field experiments were performed in Austria, Brazil, Chile, Colombia, Guatemala, Mexico and Peru as part of an FAO/IAEA Co-ordinated Research Programme to investigate the nitrogen fixing potential of cultivars and breeding lines of common bean (Phaseolus vulgaris L.). Each experiment included approximately 20 bean genotypes which were compared using the ¹⁵N isotope dilution method. Great differences in nitrogen fixation were observed between and within experiments, with average values of 35% N derived from atmosphere (% Ndfa) and highest values of 70% Ndfa being observed. These values which were larger than had been reported previously for common bean, were observed only when environmental factors were favorable. Therefore, common bean lines are available, which can support high biological nitrogen fixation. These can be used either directly as cultivars for production or in breeding programmes to enhance nitrogen fixation in other cultivars.     

几种生态因素对西北干旱地区豆科植物结瘤固氮的影响

通过对西北干旱地区栽培和野生豆科植物不同环境条件固氮状况的调查表明,栽培豆科植物一般能自然结瘤,野生豆科植物种的结瘤率极低。根瘤颜色栽培植物多为粉红色,而野生植物多为白色、黄色或棕色。通过对水分、光照强度和温度等不同条件下根瘤ARA测定,表明根瘤固氮活性与生态条件关系密切,而土壤水分是限制根瘤固氮活性表达的主要因素。     

Minimizing the effect of mineral nitrogen on biological nitrogen fixation in common bean by increasing nutrient levels

Although common bean (Phaseolus vulgaris L.) has good potential for N₂ fixation, some additional N provided through fertilizer usually is required for a maximum yield. In this study the suppressive effect of N on nodulation and N₂ fixation was evaluated in an unfertile soil under greenhouse conditions with different levels of soil fertility (low=no P, K and S additions; medium = 50, 63 and 10 mg kg^–1 soil and high = 200, 256 and 40 mg kg^–1 soil, respectively) and combined with 5, 15, 60 and 120 mg N kg^–1 soil of ¹⁵N-labelled urea. The overall average nodule number and weight increased under high fertility levels. At low N applications, nitrogen had a synergistic effect on N₂ fixation, by stimulating nodule formation, nitrogenase activity and plant growth. At high fertility and at the highest N rate (120 mg kg^–1 soil), the stimulatory effect of N fertilizer on N₂ fixation was still observed, increasing the amounts of N₂ fixed from 88 up to 375 mg N plant^–1. These results indicate that a suitable balance of soil nutrients is essential to obtain high N₂ fixation rates and yield in common beans.     

动物的共生菌固氮

介绍了共生菌固氮涉及的动物和微生物类群、动物共生菌固氮的性质和机理。应用乙炔还原法和固氮酶基因检测等研究表明,所涉及的动物有7门13纲23目50科99属174种。动物肠道具有丰富的微生境,供不同生理需求的固氮菌生长发育,所蕴含的共生固氮菌类群也十分丰富,涵盖植物共生固氮菌、植物内生固氮菌、植物根际固氮菌、自生固氮菌等生态类型。一般认为动物共生固氮菌来源于环境,其性质属于联合共生固氮。动物共生固氮菌一般与其他共生生物形成复合体,以满足固氮过程中对电子和质子供体、能量供给、固氮酶活性保护以及氨阻遏解除等方面的需求。动物共生菌固氮产物氨的同化也需要多种共生物的协同作用,可能通过谷氨酰胺合成酶/谷氨酸合成酶等途径。总体上,食物氮、非蛋白氮和共生菌固氮相互协调,形成营养和解毒的代谢网络,共同维持动物体内氮素营养的动态平衡,并对未来研究提出展望。     

The effects of aluminium on nodulation and symbiotic nitrogen fixation in Casuarina cunninghamiana Miq.

In order to investigate the effects of Al on nodule formation and function in the Casuarina-Frankia symbiosis, inoculated plants were grown in sand culture at five nominal Al concentrations (0-880 M Al) at pH 4.0. There was an Al-free control at pH 6.0 to assess the effects of pH 4.0 treatments. Mean N concentration of nodules was significantly less at pH 4.0 (1.83%) than at pH 6.0 (2.01%). There were nodulated plants at all Al levels, though there were fewer nodulated plants at 440 and 880 M Al. Dry weights of nodules, shoots and roots were not reduced by Al concentrations at or below 220 M Al, but were decreased by Al concentrations at or above 440 M Al. Nodule weight expressed as a percentage of total weight did not differ significantly with respect to an Al-free control at pH 4. N concentrations of shoots and whole plants were significantly reduced at 440 M Al. Nodular specific acetylene reduction activity (ARA) did not differ significantly among Al treatments. However, N₂-fixation efficiency was decreased from 0.20 to 0.10 mg N fixed mg nodule dry weight^–1 at 880 M Al.     

Nitrogen fixation and plant growth of common bean (Phaseolus vulgaris L.) at different levels of phosphorus availability

The efficacy of the alumina system for differentiating between bean (Phaseolus vulgaris L.) genotypes for growth at different levels of phosphorus availability was determinated. In addition to response to P levels, comparisons were made between plants receiving N either from fertilizer or nitrogen fixation. When the cv. Carioca was provided with either 100 ppm of N or inoculated withRhizobium leguminosarum biovarphaseoli, differences in shoot dry weight and nodule number were related to P level. There was a greater proportion of green, ineffectivevs. red, active nodules at the low P concentration than at the higher P concentration. In a second experiment, two cvs., Puebla 152 and Carioca and the breeding line UW 24-21, either were inoculated with rhizobia or provided with 150ppm of N. Each genotype-nitrogen combination was grown at 8 levels of P. There was a positive effect of P level on shoot dry weight, nodule number and nodule mass. Root mass was affected less than nodule or shoot mass by the P level of the growth medium. Nodule mass, but not P concentration in the nodules, was affected by P level, whereas in the other plant tissues, P concentrations were lower at lower P levels in the media.     

马桑结瘤固氮与光合作用的关系

马桑(Coriaria sinica)植株的结瘤量、根瘤固氮活性和固氮能力均与植株叶面积和光合能力呈显著的直线相关关系,叶面积大、光合能力强的植株结瘤量大,根瘤固氮活性高,固氮能力强。马桑根瘤固氮活性呈白天升高夜间降低的昼夜变化特点,昼夜变幅为10～20μmol C2H2/g.h,光合作用是引起固氮活性昼夜变化的主要因素,同时受土壤温湿度的影响,遮阴或光照不足将引起马桑结瘤固氮能力的大幅度降低。