The Respiratory Costs of Nitrogen Fixation in Soyabean, Cowpea, and White Clover: II. COMPARISONS OF THE COST OF NITROGEN FIXATION AND THE UTILIZATION OF COMBINED NITROGEN

Plants of soyabean, cowpea, and white clover were grown singlyin pots in Saxcil growth cabinets at 23/18 °C, 30/24 °C,and 20/15 °C, respectively, until seed maturation or for85 d (white clover). Two populations were produced within eachspecies: one population effectively nodulated and wholly dependentfor nitrogen on fixation in the root nodules, and a second populationcompletely lacking nodules but receiving abundant nitrate nitrogen.In each species, the two populations were compared in termsof rate of gross photosynthesis, rate of shoot respiration,and rate of root respiration. Source of nitrogen had littleor no effect on rate of photosynthesis or shoot respiration.In contrast, the rate of respiration of the nodulated rootsof plants fixing their own nitrogen was greater, sometimes two-foldgreater, than that of equivalent plants lacking nodules andutilizing nitrate nitrogen. This superiority in terms of rateof root respiration was generally confined to the period ofintense nitrogen fixation. An analysis of the magnitude of thisrespiratory burden in terms of daily photosynthesis indicatesthat, in all three legumes, plants fixing their own nitrogenrespire 11–13% more of their fixed carbon each day thanequivalent plants lacking nodules and utilizing nitrate nitrogen.     

THE MUTUAL EFFECT OF RYEGRASS AND CLOVER WHEN GROWN TOGETHER

Italian ryegrass and a late-flowering red clover were grown together, with abundance of water and nutrients for both. It was found that even a small number of ryegrass plants reduced the growth of clover by 30%. This effect varied very little with increasing density of the clover crop.
The presence of clover reduced the ryegrass crop by an amount diminishing as the density of the ryegrass was increased. In a sparse crop of ryegrass, clover reduced the growth of the grass considerably more than did barley under comparable conditions.
There is no evidence of any specific effect of the roots of one plant on the other. When ample nitrogen is available the clover tends to take some that would otherwise be available for the grass and does not provide the grass with additional nitrogen.     

The effect of mixtures of rhizobium strains on the dry matter production of white clover grown in agar

The effects of mixtures of rhizobium strains on the dry matter production of S. 100 white clover were investigated by growing plants in tubes of agar with four pure strains known to give contrasts in yield effectiveness, and comparing the results with those produced by plants grown with mixtures of these strains, and with those of uninoculated plants receiving mineral nitrogen. It was found that some components of the mixtures influenced yield much more than others and these strains therefore appeared to be strong competitors. Ability to infect and capacities to fix nitrogen were shown to be mechanisms under separate genetic control; thus competitiveness and effectiveness were not necessarily linked. Variation within groups of plants inoculated with the same rhizobium strain was generally greater than within the uninoculated control receiving mineral nitrogen. The amount of variation differed from strain to strain and was largest with the intermediately effective one. The plant genotype could modify the relative competitiveness of rhizobium strains and effective association of plant and rhizobium with a high affinity for each other under competitive situations could be built up by coincidental selection of plant and bacterium.     

Studies on symbiotic nitrogen fixation by a new strain of tetraploid red clover (UO36)

Summary Some characteristics of the symbiotic nitrogen fixation by tetraploid red clover (UO36) have been studied in laboratory experiments. Cross-inoculations were made on tetraploid and diploid clover plants usingRhizobium isolates from both types of clover. Nodulation activity and nitrogen fixation were determined. No sign of specific strains necessary for optimal fixation of nitrogen by theUO36-symbiosis was observed in comparison to the diploid clover strain.Rhizobium cultures effective in connection with cultivation of diploid clover will probably also be effective when cultivating tetraploid clover strains.     

Symbiotic effectiveness of Bradyrhizobium strains isolated from Parasponia and tropical legumes on Parasponia host species

The symbiotic effectiveness of Bradyrhizobium strains isolated from three species of Parasponia and from legumes were compared on Parasponia grown in Leonard-jars. Effectiveness of each symbiotic association was estimated from dry weight and total nitrogen of shoots and nodules of plants grown on medium free of combined nitrogen. Twenty strains isolated from three species of Parasponia were found to vary in their effectiveness on P. andersonii, the least effective fixing one fifth of the nitrogen of the most effective strains. The outcome of the symbiosis was not associated with the host source of the test strain. P. andersonii, P. rugosa and P. rigida responded differently to a selection of seven strains of Parasponia Bradyrhizobium; some strains were either ineffective or fully effective on each host, while others varied in their symbiotic performance. P. andersonii fixed significantly (P < 0.001) larger quantities of nitrogen than either P. rugosa or P. rigida with p. rigida being the least effective. In contrast to Bradyrhizobium strains from Parasponia spp. which formed nodules rapidly (within 11–20 days), nine strains isolated from legumes required between 25 and 74 days to form partially effective nodules. The thre Parasponia species formed relatively large quantities of nodule tissue relative to the amount of nitrogen fixed and shoot dry matter produced. The Bradyrhizobium isolated from Parasponia plants growing in Papua New Guinea soils could be grouped together on the basis of their infection characteristics on Parasponia and legumes.     

The Respiratory Costs of Nitrogen Fixation in Soyabean, Cowpea, and White Clover: I. NITROGEN FIXATION AND THE RESPIRATION OF THE NODULATED ROOT

Soyabean, cowpea, and white clover, inoculated with effectiverhizobia, were grown singly with a standard mineral nutritionand light regime in controlled environments until seed maturation(in soyabean and cowpea) or late vegetative growth (white clover).Day/night temperature regimes were 23/18, 30/24, and 20/15 °Cin soyabean, cowpea, and white clover, respectively. The respiratorylosses of CO₂ from the nodulated root systems were studied inrelation to the concurrent rate of fixation of atmospheric nitrogen.Despite differences in development, the effectiveness of thesymbioses, and the temperature of growth, all three legumesexhibited similar respiratory losses from nodulated roots perunit of nitrogen fixed. During intense nitrogen fixation, theaverage respiratory losses for the three legumes varied between6·3 and 6·8 mg C mg^–1 N; within each species,the losses varied more widely at different stages of development.These respiratory burdens reflect the total cost to the plantof the nodule/nitrogen fixation syndrome including the subtendingroots. The results are discussed in relation to the respiratoryeffluxes from nodules and roots, and to biochemical investigationsof the costs of nitrogen fixation.     

THE COMPETITION BETWEEN BARLEY AND CERTAIN WEEDS UNDER CONTROLLED CONDITIONS

One of the commonest agricultural practices in Britain is the undersowing of barley and other corn crops with clover as a preparation for a clover ley after the corn crop has been reaped. The effect of the clover growing among the corn, where manuring (especially with nitrogen) is made as favourable as possible for the corn crop, is not clear. If nitrogen is deficient, it is well known that clover can furnish nitrogen for the corn, but where the supply is ample, the clover may act as a competitive crop.
When barley and clover were planted together, with abundance of water and nutrients for both, it was found that the presence of even a small number of barley plants reduced the growth of the clover by over 50%, but that an increase in the density of the barley did not increase the effect. The presence of the clover reduced the barley crop by an amount which tended to get less as the density of the barley was increased. In a sparse crop of barley, increase in clover density reduced the growth of barley very little, while that of the clover was again found to be little more than half what was obtained when this plant was grown alone.
There is no evidence of any specific effect of the roots of the one plant on the other. In the circumstances of these experiments it would seem that, far from the clover supplying nitrogen to the barley, it tends to steal some of that which would otherwise be available to the latter, when they are grown together.     

THE EFFECT OF VARIATIONS IN CALCIUM SUPPLY, PH VALUE AND NITROGEN CONTENT OF NUTRIENT SOLUTIONS ON THE RESPONSE OF LETTUCE AND RED CLOVER TO MOLYBDENUM

Lettuce and red clover were grown in nutrient solutions with varied calcium supply, pH value, and nitrogen content, and the response to molybdenum compared under each set of conditions.
The calcium requirement was greater in solutions at pH 4-4 than at 6-3, but the quantity of calcium supplied did not affect the response of the plant to molybdenum. Growth was best in the more acid of a range of solutions from pH 4-2 to 8-2 in spite of a rapid levelling up to a pH between 6 and 7, but with the possible exception of the solution at pH 8-3, the need for molybdenum was unaffected by the reaction of the medium. When the calcium supply and/or the initial pH value of the solution was varied, the effect of molybdenum was most pronounced in the largest plants.
When the nitrogen supply was deficient, lettuce showed a slower response to molybdenum than when it was plentiful. With both inoculated or uninoculated clover the reverse was true. This difference in behaviour is explained on the assumption that lettuce has a smaller requirement for molybdenum than clover.
In both lettuce and clover the percentage nitrate-nitrogen in the dry matter of the shoot was higher when molybdenum was not supplied, but the total nitrogen content was increased in the case of lettuce only. At any level of nitrogen supplied, 5 or 10 p.p.m. molybdenum was of no more benefit than o-i p.p.m. though the liability to damage from toxicity was possibly greater when nitrogen was plentiful.     

Improving nitrogen fixation in legumes by plant breeding; the relevance of host selection experiments in red clover (Trifolium pratense L.) and subterranean clover (T. subterraneum L.)

Summary This paper reviews (i) basic studies on the genetics of symbiosis in red clover (a self-sterile species) and subterranean clover (cleistogamous) and (ii) work on selection and plant breeding to increase nitrogen fixation in these hosts.Symbiotic effectiveness in red clover is influenced by many major and minor genes. The highly effective phenotype is inherited in a complex manner associated with early nodulation and the formation of large amounts of persistent bacteroid-containing tissue. Lines bred to fix more nitrogen with one strain ofRhizobium trifolii do so with most but not all other strains examined. They also show slightly increased vigour when grown on nitrate. The highly effective response is correlated with abundant nodulation and an early flowering habit, the evidence from breeding studies indicating that this correlation is not absolute. Normally effective and highly effective nodules have the same specific nitrogenase activities. The expression of the highly effective response is relatively little affected by environmental factors (temperature, light intensity, day length, supplementary carbon-di-oxide). Inbreeding substantially degrades the symbiotic response.Heterosis is shown in crosses between cultivars of subterranean clover but otherwise selection to increase effectiveness in this host was unsuccessful.The relevance of these results (and their physiological aspects) for the improvement of grain legumes is discussed.     

Variation within and between white clover varieties in their preference for strains of Rhizobium trifolii

Variation within as well as between varieties of white clover (Trifolium repens L.) in their selection or preference for rhizobial strains in nodulation was studied using antibiotic-resistant mutant strains of Rhizobium trifolii. Significant differences between varieties were found. Cv. S100 was nodulated almost exclusively by 75 str but there was more variation within S184 and, in particular, Pajbjerg smalbladet. In this experiment 93% of the total variance was genotypic, of which 68% was due to the difference between varieties and 25% due to variance between genotypes within varieties. Significant correlations were found between the preference for rhizobial strains of plants grown from seeds and of stolon lines vegetatively propagated from the former plants, indicating that the preference for rhizobial strains is genetically controlled by the host. A considerable drift in preference towards selection of more compatible rhizobial strains by the clonally propagated stolons compared with the original white clover plants was observed. The results are discussed from the point of view of improving symbiotic nitrogen fixation by combining highly effective and competitive Rhizobium strains with a host variety with uniform preference for those strains.     

Sitona weevils (Coleoptera: Curculionidae) as agents for rapid transfer of nitrogen from white clover (Trifolium repens L.) to perennial ryegrass (Lolium perenne L.)

The effects of root feeding by larvae of Sitona hispidulus (F.) (a common weevil pest of white clover) on the rate of transfer of nitrogen between plants of white clover (Trifolium repens L.) and perennial ryegrass (Lolium perenne L.) were investigated using a nutrient slant board technique. Clover plants, labelled with ¹⁵N were grown adjacent to ryegrass plants and were either infested with Sitona larvae or not infested. Ryegrass plants associated with the infested clover plants had a significantly higher dry matter yield and nitrogen content (75% and 74% respectively) than the uninvested plants, after 33 days exposure to insect herbivory. It was concluded that root feeding insects could play an important role in the cycling of nitrogen in grass/clover swards.     

Grass species and their fungal symbionts affect subsequent forage growth

Persistence of forage grasses is enhanced through the deliberate and selective use of symbiotic fungal endophytes that confer benefits, particularly pest resistance. However, they have also been implicated in reduced plant community diversity as a result of directly or indirectly enhancing competitive ability. A relatively underexplored mechanism by which endophytes might influence pasture plant composition is by altering the biotic or abiotic soil conditions. To examine the soil conditioning effects of forage grass species and their fungal symbionts we tested the responses of three pasture plants, perennial ryegrass, prairie grass, and white clover in nine different soils that had been conditioned by monocultures of endophyte-containing (E+), or endophyte-free (E?), perennial ryegrass, tall fescue, or meadow fescue. Conditioning grass species had little effect on the responses of perennial ryegrass and prairie grass regardless of E+ or E? treatments. In contrast, conditioning species had a strong effect on the response of white clover, resulting in reduced biomass when grown in perennial ryegrass conditioned soils. The presence of endophyte also had significant growth consequences for white clover, but was either positive or negative depending on the conditioning grass species. In comparison to their respective E? treatments, E+ tall and meadow fescue conditioned soils resulted in reduced biomass of white clover, whereas E+ perennial ryegrass conditioned soils resulted in increased biomass of white clover. Among the conditioning strains (AR1, AR37, NEA2, WE) of E+ perennial ryegrass, white clover showed significantly different responses, but all responses were positive in comparison to the E? treatment. By examining the effects of several grass species and endophyte strains, we were able to determine the relative importance of grass species vs. fungal symbiont on soil conditioning. Overall, the conditioning effect of grass species was stronger than the effects associated with endophyte, particularly with regard to the response of white clover. We conclude that both grass species and their fungal endophytes can influence pasture plant community composition through plant–soil feedback.     

Molecular diversity and phylogeny of indigenous <Emphasis Type="Italic">Rhizobium leguminosarum</Emphasis> strains associated with <Emphasis Type="Italic">Trifolium repens</Emphasis> plants in Romania

The symbiotic nitrogen fixing legumes play an essential role in sustainable agriculture. White clover (Trifolium repens L.) is one of the most valuable perennial legumes in pastures and meadows of temperate regions. Despite its great agriculture and economic importance, there is no detailed available information on phylogenetic assignation and characterization of rhizobia associated with native white clover plants in South-Eastern Europe. In the present work, the diversity of indigenous white clover rhizobia originating in 11 different natural ecosystems in North-Eastern Romania were assessed by a polyphasic approach. Initial grouping showed that, 73 rhizobial isolates, representing seven distinct phenons were distributed into 12 genotypes, indicating a wide phenotypic and genotypic diversity among the isolates. To clarify their phylogeny, 44 representative strains were used in sequence analysis of 16S rRNA gene and IGS fragments, three housekeeping genes (atpD, glnII and recA) and two symbiosis-related genes (nodA and nifH). Multilocus sequence analysis (MLSA) phylogeny based on concatenated housekeeping genes delineated the clover isolates into five putative genospecies. Despite their diverse chromosomal backgrounds, test strains shared highly similar symbiotic genes closely related to Rhizobium leguminosarum biovar trifolii. Phylogenies inferred from housekeeping genes were incongruent with those of symbiotic genes, probably due to occurrence of lateral transfer events among native strains. This is the first polyphasic taxonomic study to report on the MLSA-based phylogenetic diversity of indigenous rhizobia nodulating white clover plants grown in various soil types in South-Eastern Europe. Our results provide valuable taxonomic data on native clover rhizobia and may increase the pool of genetic material to be used as biofertilizers.     

Isolation of Rhizobium leguminosarum (biovar trifolii) Strains from Ethiopian Soils and Symbiotic Effectiveness on African Annual Clover Species

Strains of Rhizobium leguminosarum (biovar trifolii) isolated from two Ethiopian soils or obtained from a commercial source were evaluated for symbiotic effectiveness on five African annual clover species. Numerous Rhizobium trifolii strains that exhibited varying levels of symbiotic effectiveness were isolated from both soils (a nitosol and a vertisol), and it was possible to identify strains that were highly effective for each clover species. The soil isolates were, as a group, superior to the strains from the commercial source. Several R. trifolii strains were found to be effective on more than one clover species, and there appeared to be at least two and possibly three distinct cross-inoculation effectiveness groups.     

Improvement of biological nitrogen fixation in Egyptian winter legumes through better management of Rhizobium

The diversity of rhizobia nodulating common bean ( Phaseolus vulgaris), berseem clover (Trifolium alexanderinum) and lentil (Lens culinaris) was assessed using several characterization techniques, including nitrogen fixation efficiency, intrinsic antibiotic-resistance patterns (IAR), plasmid profiles, serological markers and rep-PCR fingerprinting. Wide diversity among indigenous rhizobial populations of the isolates from lentil, bean and clover was found. Strikingly, a large percentage of the indigenous rhizobial population was extremely poor at fixing nitrogen. This emphasizes the need to increase the balance of highly efficient strains within the rhizobial population. Use of high-quality inocula strains that survive and compete with other less-desired and less-efficient N2-fixing rhizobia represents the best approach to increase biological nitrogen fixation of the target legume. In field-grown lentils, the inoculant strains were not able to outcompete the indigenous rhizobia and the native lentil rhizobia occupied 76–88% of the total nodules formed on inoculated plants. Nitrogen fixation by lentils, estimated using the ¹⁵N isotope dilution technique, ranged between 127 to 139 kg ha-1 in both inoculated and un-inoculated plants. With berseem clover, the inoculant strains were highly competitive against indigenous rhizobia and occupied 52–79% of all nodules. Inoculation with selected inocula improved N2 fixation by clover from 162 to 205 kg ha-1 in the three cuts as compared with 118 kg ha-1 in the un-inoculated treatment. The results also indicated the potential for improvement of N2 fixation by beans through the application of efficient N2-fixing rhizobia.     

SOME EFFECTS OF HOST-PLANT NUTRITION ON THE MULTIPLICATION OF VIRUSES

The amounts of tobacco mosaic virus present in systemically infected tobacco plants varied greatly with the mineral nutrition of the plants and were related to the effects on plant growth. With plants in soil, supplements of phosphorus produced the greatest increases in plant size, in virus concentration of expressed sap, and in total virus per plant; nitrogen increased plant size only when phosphorus was also added, and only then increased virus concentration and total virus per plant. Combined supplements of phosphorus and nitrogen doubled the virus concentration of sap and increased the total virus per plant by factors up to forty. Potassium slightly reduced the virus concentration of sap, though it usually increased plant size and total virus per plant. From all plants, only about one-third of the virus contained in leaves was present in sap. Virus production seemed to occur at the expense of normal plant proteins, and the ratio of virus to other nitrogenous materials was highest in plants receiving a supplement of phosphorus but not of nitrogen.
The effects of host nutrition on the production of virus in inoculated leaves resembled those in systemically infected leaves, but were more variable.
No evidence was obtained, with plants grown in soil or sand, that host nutrition had any consistent effect on the intrinsic infectivity of tobacco mosaic virus.
The concentration of virus in sap from potato plants systemically infected with two strains of potato virus X was not consistently affected by fertilizers; the chief effect of host nutrition on virus production was indirect by altering plant size.     

A comparison of the nodulation of diploid and tetraploid varieties of red clover inoculated with different Rhizobial strains

Summary The effectiveness of three different strains ofRhizobium trifolii on a diploid and a tetraploid variety of red clover (Trifolium pratense) grown in aseptic mineral-agar culture was compared. It was found that with two of the rhizobial strains tested, the tetraploid plants were slower to nodulate than the diploid plants, but that a hundred per cent nodulation was obtained in both cases. With the third strain, however, a sixty-six per cent nodulation of the diploid plants was reduced to an eight per cent nodulation of the tetraploids.In general, over a given period, fewer nodules were formed on the tetraploid plants, but these tended to be larger than on the diploids. The fresh weight of the tetraploid plants always exceeded that of the diploids, but less so in cases of poorly nodulated plants.     

A STUDY OF THE BACTERIA ASSOCIATED WITH THE ROOTS OF SUBTERRANEAN CLOVER AND WIMMERA RYE-GRASS

SUMMARY: A study of the bacteria from the surfaces of roots of subterranean clover ( T. subterraneum L.) and Wimmera rye-grass ( L. rigidum Gaud.) revealed that 21 genera were represented among the isolates from clover and 16 genera among those from rye-grass. Bacteria showing branched forms predominated and accounted for 63% of the 151 clover isolates and 78% of the 167 grass isolates. Most of these were identified as Arthrobacter , but from clover a significant proportion were Nocardia -like types. Members of the genera Mycoplana, Micromonospora, Mycobacterium , and Mycococcus were also identified among the branching forms.
Although the soil had been inoculated with effective rhizobia and the clover plants were effectively nodulated only one of the 318 isolates was capable of nodulating subterranean clover. The majority of the isolates were chromogenic and Gram-negative, produced acid from glucose and ammonia from peptone, were catalase-positive and grew best aerobically. Approximately half the isolates liquefied gelatin and produced hydrogen sulphide from peptone.     

鲁黄1号大豆与根瘤菌的共生匹配性

大豆可与中华根瘤菌属及慢生根瘤菌属的多种根瘤菌共生固氮.研究大豆品种与不同种根瘤菌之间的共生匹配性,对获得高效根瘤菌用于接种,提高大豆的产量及品质有重要的理论和实践意义.本研究使用黄淮海地区的优质高蛋白大豆品种鲁黄1号从当地土壤内捕捉并分离纯化到27株根瘤菌.经持家基因recA的序列分析,发现其中18株属于中华根瘤菌属,9株属于慢生根瘤菌属.选用两个属的代表菌株各一株(Sinorhizobium fredii S6和Bradyrhizobium sp. S10),分别在蛭石、土壤盆栽及大田试验条件下,研究这两株菌单独及混合接种对鲁黄1号大豆的生长、结瘤、固氮活力、产量、种子蛋白含量及含油量的影响.结果表明： 与S10菌株相比,S6菌株对大豆的促生能力更强,对提高产量和品质的效果更好,从而确定S6为与鲁黄1号大豆相匹配的高效根瘤菌,可作为黄淮海地区推广种植鲁黄1号大豆时接种高效根瘤菌的菌种资源.
     

Distribution of dry weight between root and shoot in white clover dependent on N2 fixation or utilizing abundant nitrate nitrogen

Summary Plants of white clover var. Blanca were grown singly in pots in controlled environments, or in small swards in a glasshouse, to determine how their distribution of dry weight between root and shoot was influenced when they were dependent on N₂ fixation in their root nodules or when they lacked nodules but utilized an abundant supply of nitrate nitrogen. In single plants and in swards, changes in root/shoot ratio with increasing age and plant development were not influenced by the source of nitrogen, but nodulated plants always displayed a higher root/shoot ratio. When nodulated plants were supplied with nitrate nitrogen, root/shoot ratio declined to values intermediate between those of nodulated and of nitrate plants. The results are discussed in relation to the persistence of white clover, and the general level of productivity, in grass-clover swards. The Grassland Research Institute is financed through the Agricultural Research Council.