Response of Leucaena/Rhizobium symbiosis to mineral nutrients in Southwestern Nigeria

Pot and field experiments carried out at the International Institute of Tropical Agriculture (IITA) and at Fashola, Southwestern Nigeria, examined the effect of inoculation and N, P and micronutrients on nodulation and growth ofLeucaena leucocephala (Lam.) de Wit. In pot studies all parameters measured, except the percentage of nitrogen in shoots, were improved by inoculation, nitrogen and phosphorus. Micronutrients increased only nitrogen and allantoin contents. Interactions between inoculation and P, N and micronutrients on nodulation and growth of leucaena were observed. The effect of inoculation and fertilization with phosphorus or micronutrients was further investigated in field experiments. Establishment of uninoculated and unfertilized leucaena was poor at both locations due to low soil fertility and the presence of only a few native leucaena rhizobia. At one site, only inoculated plants were nodulated, while at the other, all plants produced nodules. Shoot dry weight, total nitrogen and phosphorus of inoculated plants were statistically equal to nitrogen-fertilized plants. Uninoculated plants were stunted. Generally, micronutrients did not influence nodulation, total nitrogen or growth of leucaena. They had only a positive effect on nitrogenase activity. Phosphorus increased total nitrogen and phosphorus uptake and plant growth. A 75% increase in shoot dry weight was obtained when 80 kg P ha^–1 was applied to inoculated leucaena with Rhizobium strain IRc 1045. Inoculated plants contained more allantoins than uninoculated ones but no significant correlation was found between these compounds and other parameters of N fixation.     

Selection of salt-tolerant Rhizobium isolates of Acacia nilotica

Among 35 Rhizobium isolates of Acacia nilotica, from different agro-climatic zones, two, ANG4 and ANG5, tolerated up to 850 mm NaCl and one, ANG3, was sensitive to NaCl above 250 mm. Nodulation and nitrogenase activity of the three isolates decreased with increasing concentration of salt up to 150 mm. Nodulation by ANG3 was 15% at 75 mm NaCl and nil at 100 mm. With ANG4 and ANG5, nodulation was only slightly decreased at 150 mm NaCl. Nitrogenase activity associated with plants inoculated with ANG3 was halved at 25 mm NaCl compared with salt-free controls, whereas isolates ANG4 and ANG5 retained 25% and 15% activity, respectively, even at 100 mm NaCl. Salt-tolerant Rhizobium isolates can therefore nodulate and fix N₂ in saline soils.     

Persistence and recovery of introduced Rhizobium ten years after inoculation on Leucaena leucocephala grown on an Alfisol in southwestern Nigeria

Establishment of Leucaena leucocephala was poor at Ibadan (Transition forest-savanna zone) and Fashola (savanna zone, 70 km north of Ibadan) in southwestern Nigeria as a result of low soil fertility and the presence of only a few native rhizobia capable of nodulating it. Inoculation with L. leucocephala at these two locations in 1982 resulted in striking responses with Rhizobium strains IRc 1045 and IRc 1050 isolated from L. leucocephala grown in Nigeria. The persistence of inoculated effective Rhizobium strains after inoculation is desirable since it removes the need for reinoculation. Because of the perennial nature of L. leucocephala and its use in long-term alley farming experiments, we examined the persistence of inoculated rhizobial strains after inoculation, and their ability to sustain N₂-fixation and biomass production at Ibadan. In 1992, ten years after Rhizobium introduction, uninoculated, L. leucocephala fixed about 150 kg N ha^-1 yr^-1 or about 41% of total plant N compared to 180 kg N ha^-1 yr^-1 or 43% measured in 1982. Serological typing of the nodules using the Enzyme-Linked-Immunosorbent Assay (ELISA) and intrinsic resistance to the streptomycin test revealed that most of the nodules (96%) formed on L. leucocephala in 1992 were by Rhizobium strains IRc 1045 and IRc 1050, which were inoculated in 1982. Nodules were absent on uninoculated L. leucocephala grown on the adjacent field with no history of L. leucocephala cultivation. We conclude that the N₂ fixed by Rhizobium strains IRc 1045 and IRc 1050 persisted for many years in the absence of L. leucocephala and sustained effectively fixed N₂ which growth and yield of L. leucocephala after several years, thus encouraging a possible low-input alley farming system by smallholder farmers in Nigeria.     

The effect of VA mycorrhizal fungi,phosphorus and drought stress on the growth of Acacia nilotica and Leucaena leucocephala seedlings

The effect of vesicular-arbuscular mycorrhizal (VAM) fungi on growth and drought resistance of Acacia nilotica and Leucaena leucocephala seedlings was studied in a glasshouse experiment. The experimental design was a 2·2·2 factorial: ± mycorrhizal inoculation, ± application of phosphorus fertilizer and ± repeated drought treatment. The growth promoting effect of VAM fungi equalled the effect of phosphorus fertilization after 12 weeks. The drought treatment reduced seedling biomass and nodulation. Differences between the plant species were found with respect to growth improvements due to VAM inoculation and/or phosphorus fertilization under drought stress conditions. The results are discussed in relation to plant drought resistance and reforestation in the subhumid to arid tropics.     

Growth of three legume trees inoculated with VA mycorrhizal fungi and Rhizobium

Effectiveness among four VA mycorrhizal fungi and Rhizobium (R) in promoting growth of three legume trees in a P-deficient soil was studied.Glomus fasciculatus + R andGigaspora margarita + R were most effective forAcacia mangium andAlbizia falcataria (syn.:Paraserianthes falcataria). Scutellospora persica + R,Gigaspora margarita + R andGlomus fasciculatus + R were most effective forAcacia auriculifornis. Consistently poor growth was attained by seedlings inoculated withSclerocystis clavispora + R,Rhizobium alone, or by uninoculated seedlings.     

Nitrate effects on the nodulation of legumes inoculated with nitrate-reductase-deficient mutants of Rhizobium

The effect of nitrate on the symbiotic properties of nitrate-reductase-deficient mutants of a strain of cowpea rhizobia (32H1), and of a strain of Rhizobium trifolii (TA1), were examined; the host species were Macroptilium atropurpureum (DC.) Urb. and Trifolium subterraneum L. Nitrate retarded initial nodulation by the mutant strains to an extent similar to that found with the parent strains. It is therefore unlikely that nitrite produced from nitrate by the rhizobia, plays a significant role in the inhibition of nodulation by nitrate. Nitrite is an inhibitor of nitrogenase, and its possible production in the nodule tissue by the action of nitrate reductase could be responsible for the observed inhibition of nitrogen fixation when nodulated plants are exposed to nitrate. However, the results of this investigation show that nitrogen fixation by the plants nodulated by parent or mutant strains was depressed by similar amounts in the presence of nitrate. No nitrite was detected in the nodules. Nodule growth, and to a lesser extent, the nitrogenase specific activity of the nodules (mol C₂H₄g^–1 nodule fr. wt. h^–1), were both affected by the added nitrate.     

Effect of Rhizobium inoculation methodologies on nodulation and growth of Leucaena leucocephala

The aim of this study was to evaluate the effect of five methods of Rhizobium inoculum application on nodulation and nitrogen fixation in Leucaena leucocephala seedlings cultivated for 6 months in the greenhouse. Plants inoculated with alginate beads were significantly more developed and more nodulated than plants inoculated with the other methodologies used.     

Assessment of genetic variability for N2 fixation between and within provenances of Leucaena leucocephala and Acacia albida estimated by 15N labelling techniques

Nitrogen fixed in 13 provenances of Acacia albida and 11 isolines of Leucaena leucocephala inoculated with effective Rhizobium strains was measured by ¹⁵N techniques and the total N difference method. In the test soil, on the average, L. leucocephala derived about 65% of its total N from atmospheric N₂ fixation compared to about 20% by A. albida. Significant differences in the percentage of N derived from atmospheric N₂ (% Ndfa) occurred, between provenances or isolines within species. The % Ndfa ranged from 37 to 74% within L. leucocephala and from 6 to 37 within A. albida; (equivalent to 20–50 mg N plant^–1 and 4–37 mg N plant^–1 for the two species over three months, respectively) and was correlated with the nodule mass (r=0.91). The time course of N₂ fixation of three selected provenances (low, intermediate and good fixers) was followed at 12 weekly intervals over a 36 week period. The % Ndfa of all provenances and isolines increased with time; and except for one of the L. leucocephala provenances, % Ndfa was similar within species at the 36 weeks harvest. There was a significant correlation between % Ndfa and the amount of N₂ fixed (r=0.96). Significant interactions occurred between provenances and N treatments and often growth of uninoculated but N fertilized plants was less variable than for inoculated unfertilized plants.     

Changes in nodule and root biomass of Sesbania sesban and Leucaena leucocephala following coppicing

A pot study was conducted to measure the extent of and determine the factors controlling fine root and nodule shedding following coppicing of Sesbania sesban and Leucaena leucocephala. Fine (<2 mm) root biomass decreased below pre-cutting values, but the decreases were not statistically significant in either species. Living (white) nodule biomass decreased and dead (brown) nodule biomass increased significantly two weeks after cutting in both species. These changes were relatively greater in Sesbania than in Leucaena. In the uncut treatments of both species, fine root and nodule biomass were correlated with leaf biomass, and in the cut treatments, root and nodule biomass returned to near this apparent equilibrium by two weeks after cutting. Stem growth rate per unit leaf area was not different between cut and uncut treatments, nor was it correlated with root:leaf ratios in either species. Leucaena allocated a greater fraction of its total biomass below-ground, and a greater fraction of its below-ground biomass to coarse (>2 mm) roots than Sesbania. These results are consistent with the hypothesis that relatively lower allocation to below-ground storage tissue is the cause for Sesbania's relatively greater sensitivity to cutting.     

Nodulation and growth ofLeucaena leucocephala (Lam.) de Wit as affected by inoculation and N fertilizer

Leonard jar, pot and field experiments examined the effects of inoculation and the influence of nitrogen fertilizer on nodulation, nitrogen fixation and growth ofLeucaena leucocephala (Lam.) de Wit at IITA, Ibadan, Nigeria. Leucaena responded to both inoculation and/or nitrogen application. Shoot growth and total N and P of inoculated plants were comparable to those of the highest N treatment, and the values were about 55% greater than those of uninoculated ones. Field data indicated that toal N yields of inoculated leucaena were increased by 50% with 40 or 80 kg ha^–1 of N fertilizer. However, N fertilizer depressed N fixation by 56% as was expected from nodule mass data. N-fixation was delayed for about 8 weeks in the plots without N. Application of small amounts of N starter (20 ppm) proved to be beneficial to satisfy the plant need during the early stage of leucaena growth. The rhizobial strains IRc 1045 and IRc 1050 were effective, competitive and survived well in the field one year after their establishment.     

Genes encoding a fructose-1,6-bisphosphate aldolase and a fructose-1,6-bisphosphatase are present within the gene cluster for mimosine degradation in Rhizobium sp. strain TAL1145

Rhizobium sp. strain TAL1145 can catabolize mimosine, a toxic amino acid produced by the tree-legume leucaena. The mid and pyd genes involved in mimosine degradation in TAL1145 are located in two clusters within a 25-kb region in the chromosome, which was cloned in plasmid pUHR263. A 5.5-kb EcoRI fragment, located between the mid and pyd genes in pUHR263, was characterized by sequencing and transposon-insertion mutagenesis and six open reading frames (ORF) were identified. Based on high homologies with other known proteins and conserved signature domains, ORF1 and ORF2 were identified as fba and fbp genes, encoding fructose-1,6-bisphosphate aldolase (FBA) and fructose-1,6-bisphosphatase (FBP), respectively. The fba mutant showed a slightly reduced growth rate compared to TAL1145 while the fbp mutant did not show any growth defects. Both mutants could catabolize mimosine and formed normal nitrogen-fixing nodules on leucaena, suggesting that these genes are not involved in mimosine degradation and symbiosis.     

The cloned 1-aminocyclopropane-1-carboxylate (ACC) deaminase gene from Sinorhizobium sp. strain BL3 in Rhizobium sp. strain TAL1145 promotes nodulation and growth of Leucaena leucocephala

The objective of this study was to determine the role of 1-aminocyclopropane-1-carboxylate (ACC) deaminase of symbionts in nodulation and growth of Leucaena leucocephala. The acdS genes encoding ACC deaminase were cloned from Rhizobium sp. strain TAL1145 and Sinorhizobium sp. BL3 in multicopy plasmids, and transferred to TAL1145. The BL3-acdS gene greatly enhanced ACC deaminase activity in TAL1145 compared to the native acdS gene. The transconjugants of TAL1145 containing the native or BL3 acdS gene could grow in minimal media containing 1.5mM ACC, whereas BL3 could tolerate up to 3mM ACC. The TAL1145 acdS gene was inducible by mimosine and not by ACC, while the BL3 acdS gene was highly inducible by ACC and not by mimosine. The transconjugants of TAL1145 containing the native- and BL3-acdS genes formed nodules with greater number and sizes, and produced higher root mass on L. leucocephala than by TAL1145. This study shows that the introduction of multiple copies of the acdS gene increased ACC deaminase activities of TAL1145 and enhanced its symbiotic efficiency on L. leucocephala.     

Assessment of nodulation of Mucuna pruriens by promiscuous indigenous rhizobia in the moist savanna zone of Nigeria

Leucaena leucocephala failed to nodulate effectively with promiscuous indigenous rhizobia with which Mucuna pruriens nodulated effectively. Mucuna pruriens was adequately established and well nodulated due to the presence of favourable climatic and edaphic factors which enhanced its establishment in the humid/moist savanna zone of Nigeria. The microsymbiont for M. pruriens seems to thrive more in an alkaline rhizosphere. Introduction of M. pruriens into the farming system in Nigeria may serve as a low input agricultural system, which is not only sustainable but also economically viable.     

Effect of herbicide residues in a sandy loam on the growth,nodulation and nitrogenase activity (C2H2/C2H4) of Trifolium subterraneum

The herbicides 2,4-D, amitrole, atrazine, diclofop-methyl, diquat, paraquat and trifiluralin were applied at rates of 0, 2, 5 and 10 μg ai. g⁻¹ to a sandy loam soil and allowed to degrade for 120 days. After this period, subterranean clover seedlings were transplanted into treated soil and the effect of herbicide residues on plant growth, number of nodules formed and nitrogenase activity was investigated. At all rates of atrazine and chlorsulfuron, and at all rates of amitrole in excess of 2 mg ai g⁻¹ of soil, sufficient herbicide remained to be lethal to the seedlings. When amitrole was applied at the rate of 2 mg ai g⁻¹ of soil, plant growth, nodulation and nitrogenase activity of plants were reduced. Residues of diquat reduced all plant parameters studied while, residues of 2,4-D reduced plant growth and nodule formation, but plant nitrogenase activity was unaffected. Residues of trifluralin had no effect on plant growth parameters but the number of nodules formed per plant was reduced. Residues of paraquat and diclofop-methyl had no effect on any of the plant parameters studied.     

Propagation of the tropical tree,Leucaena leucocephala K67, by in vitro bud culture

A tissue culture method is described for clonal multiplication of Leucaena leucocephala K67 using single lateral bud explants from 2–3 m tall greenhouse grown trees. N-6 benzyladenine (BA: 3.0 mg.1^-1) and napthaleneacetic acid (NAA: 0.05 mg.1^-1) in Murashige & Skoog's (MS) medium were found to be best suited for multiple shoot differentiation in 4–5 week old cultures. Analysis of variance of the main treatment effects of BA and NAA on shoot parameters showed that BA significantly (P=0.001) affected shoot development while NAA did not. A shoot multiplication rate of 22±3.63 shoots per bud explant was obtained in 150 days on 1/2 strength MS medium with 3.0 mg.1^-1 BA and 0.05 mg.1^-1 NAA. Shoots developed adventitious roots within 15 days in 1/2 strength MS medium containing indole-3-butyric acid (IBA: 3.0 mg.1^-1) and Kinetin (0.05 mg.1^-1). Eighty percent of the transplanted plantlets are being grown in greenhouse conditions.     

Nodulation,biomass and nitrogen content in Sesbania species

Sesbania rostrata developed nitrogen fixing nodules on the stem after spraying the plants with the bacterial culture TCSR 1. The number of stem nodules at 55 days after sowing was about 1200. Plants with stem nodules had a significantly reduced number of root nodules. The biomass of S. rostrata was comparable to the locally well adapted non-stem nodulating species S. aculeata. The %N and total nitrogen content were highest in S. rostrata compared to the other three species studied.     

Formation of nodular structures on the non-legumes Brassica napus,B. campestris,B. juncea and Arabidopsis thaliana with Bradyrhizobium and Rhizobium isolated from Parasponia spp. or legumes grown in tropical soils

Strains of Bradyrhizobium formed nodule-like structures on Arabidopsis and species of Brassica in pots with sandvermiculite and in glass tubes on a nitrogen-free mineral salts agar. Broad-host-range Rhizobium strains NGR234 from Lablab purpureus and NGR76 from Phaseolus vulgaris formed similar nodule-like structures on Brassica spp. The size of these structures on plants in pots were large, often reaching 10 mm in diameter.The frequency of inoculated Brassica plants in pots with nodule-like structures was 25–50%, depending on the inoculum strain. The inheritable nature of factors involved in the formation of the nodule-like structures was demonstrated when the structures occurred on 100% of inoculated B. napus seedlings derived from plants with the nodule-like structures.Nodule-like structures occurred without, but not with, the application of a cellulase-pectolyase-PEG treatment to the roots. Attempts to isolate Bradyrhizobium or Rhizobium from the nodule-like structures failed. Internal infection of these structures could not be detected using either the light or electron microscope. The inoculum strains of root-nodule bacteria were detected in high numbers in the rhizosphere of plants 5 months after inoculation. On agar plates bacterial colonies could be seen, with undiminished growth, over the surface of the agar extending to the root surface. However, ground root tissue of Brassica was toxic to Bradyrhizobium strains. This suggested that Bradyrhizobium strains would not survive after infecting the roots of Brassica spp. Nitrogen fixation was associated with high rhizosphere populations of Azospirillum and not with Bradyrhizobium induced nodule structures of Brassica spp.     

Litter decomposition and nitrogen mineralization of soils in subtropical plantation forests of southern China,with special attention to comparisons between legumes and non-legumes

Litter decomposition and nitrogen mineralization were investigated in subtropical plantation forests in southern China. The CO₂ –C release from incubated litter and the forest floor of Acacia mangium, Acacia auriculaeformis, Eucalyptus citriodora, Pinus elliotii and Schima superba stands were used to estimate relative rates of litter decomposition. Decomposition was not positively correlated with litter nitrogen. E. citridora litter decomposed most rapidly and A. mangium litter most slowly, both with and without the addition of exotic nitrogen. Aerobic incubation and intact soil core incubation at 30 °C over a period of 30 days were used to assess nitrogen mineralization of six forest soils. Although there were differences in results obtained using the two methods, patterns between legume and non-legume species were the same regardless of method. All soils had pH values below 4.5, but this did not prevent nitrification. The dominant form of mineral nitrogen was nitrate for legume species and ammonium for non-legume species. The nitrogen mineralization potential was highest for soils in which legumes were growing.     

Lifecycle of the bruchid beetle Bruchidius uberatus and its predation of Acacia nilotica seeds in a tree savanna in Botswana

The life cycle of the bruchid beetle Bruchidius uberatus in seeds of Acacia nilotica has been investigated under field and laboratory condition. In contrast to the multivoltine populations in the Sudan, in Botswana most beetles of B. uberatus are univoltine. They emerge from the seed and pod in early spring (October to November). Only a small part of the population, which emerge in late summer (February to March) is multivoltine, as confirmed by rearing experiments. The reproductive activity of females is not stimulated by pollen, as found in feeding experiments. Minimum life-span of adult beetles varies between 4 and 40 days, but it did not differ between univoltine and multivoltine beetles. Other data on life-history are 22 days for hatching of the fist-instar larva at a temperature regime of 20/15 °C (day/night) and 15 days at a temperature regime of 32/15 °C and 3 to 11 months for development from larvae to beetle.During dry storage of seeds B. uberatus can destroy the total amount of stored seeds within a few years. In stored seed pool, host-specificity of larva is low.The life cycles of the Botswana population have been discussed in relation to that of the species in the Sudan.

---

Zusammenfassung Der Lebenszyklus des Samenkäfers Bruchidius uberatus in Samen von Acacia nilotica wurde unter Feld- und Laborbedingungen untersucht. Im Gegensatz zu multivoltinen Populationen im Sudan (Peake, 1982) sind die Populationen von B. uberatus in Botswana vor allem univoltin. Adulte Käfer verlassen die Samen von A. nilotica während des Süd-Frühlings (Oktober/November). Im Spätsommer (Februar/März) geschlüpfte Käfer entstammen multivoltinen Genotypen, wie Züchtungsexperimente gezeigt haben. Die reproduktive Aktivität der Weibchen wird nicht durch die Zufuhr von Pollen oder Zucker stimuliert.Die Entwicklungsdauer vom Ei bis zum 1. Larvenstadium beträgt 15 Tage bis 52 und 3 bis 11 Monate bis zum adulten Käfer, deren Lebenserwartung unter Laboratoriumbedingungen 4 bis 40 Tage beträgt. Hierbei besteht kein Unterschied zwischen uni- und multivoltinen Käfern. Der lange Lebenszyklus in Botswana steht im Gegensatz zu dem 40-tägigen Lebenszyklus von B. uberatus im Sudan, der offensichtlich durch die Jahrhunderte andauernde Sammlung von Früchten verursacht ist.Samenvorräte, die zu Forstzwecken längere Zeit aufbewahrt werden, können innerhalb von 5 bis 8 Jahren völlig zerstört werden. Dabei ist die Wirtsspezifität gering. Die Infektion betrifft auch andere Acacia-Arten, z.B. A. burkei, A. erioloba, A. hebeclada, A. mellifera, A. robusta und A. tortilis. Durch die rasche Zerstörung der Embryoachse haben die Käfer keinen positiven Einfluss auf die Keimung dieser hartschaligen Acacia-Samen.

     

Nitrogen-fixing potential of micropropagated clones of Acacia mangium inoculated with different Bradyrhizobium spp. strains

Five A. mangium seedlings of different shoot lengths were selected from a 600-seed screening experiment and micropropagated. Two-week-old rooted microcuttings of the 5 micropropagated clones were inoculated with 3 specific Bradyrhizobium spp. strains in 15 combinations. After 5 months of growth, nodule dry weight and shoot dry weight data showed significant effects of clone and Bradyrhizobium spp. strain. Clones RR-G₁ and IR-M₂ and Bradyrhizobium sp. Aust13c resulted in the highest dry-matter production and most efficient nodulation. No interaction was observed between clone and Bradyrhizobium spp. strain, which indicates that the Bradyrhizobium spp. strain and the host plant can be selected separately.