Bernard Dreyfus

Bio: Bernard Dreyfus is an academic researcher from Centre national de la recherche scientifique. The author has contributed to research in topics: Sesbania rostrata & Nitrogen fixation. The author has an hindex of 4, co-authored 4 publications receiving 379 citations.

Nitrogen-fixing nodules induced by Rhizobium on the stem of the tropical legume Sesbania rostrata

Abstract: The only recorded instances of legume, species with aerial nodules are for Neptunia oleracea [ 11 and Aeschynomene indica [2,3 J . This latter, which grows in flooded soils, has two types of nodules: root nodules like other legumes, and stem nodules. Stem , nodules of A. indica usually are distributed sparsely along the lower stem and look more like small swellings than conventional Rhizobium nodules. We report here on a tropical legume, Sesbania 2.1. Techniques for structural studies

Sesbania rostrata green manure and the nitrogen content of rice crop and soil

Abstract: The effects of four treatments upon the N content of rice crop and soil in 1m2 irrigated microplots were compared: (1) PK fertilization + Sesbania rostrata (inoculated stems) ploughed in as green manure when it was 52 days old. (2) PK fertilization + S. rostrata (non-inoculated stems) ploughed in as green manure. (3) PK fertilization + ammonium sulphate (60kg N ha−1). (4) PK fertilization alone (control). The application of chemical N fertilizer (treatment 3) increased the grain yield by 169 g m−2 (1.69t ha−1). whereas incorporating S. rostrata as green manure resulted in a grain yield increase of 372 g m−2 (3.72t ha−1). N2 fixed by S. rostrata was estimated to be at least 26.7 g m−2 (267kg N ha−1), one third being transferred to the crop and two thirds to the soil.

Observations on the use of Sesbania rostrata as green manure in paddy fields

Abstract: Sesbania rostrata is a wild annual legume that grows in West Africa in waterlogged soils during the rainy season. This plant can bear N2-fixing nodules on roots and stems at the same time. Stem nodules result from the infection of predetermined sites (dormant root primordia distributed on the stems) by a specific strain ofRhizobium. The mode of infection ofS. rostrata is unique among the legumes, as it involves both an intercellular invasion by rhizobia and the development of infection threads. Inoculation of the stems is achieved by spraying a liquid culture of the specificRhizobium on the shoots. Properly inoculatedS. rostrata can fix up to 200 kg N2/ha in 50 days. A unique property ofS. rostrata is to nodulate and fix nitrogen even when the amount of combined nitrogen in the soil is high. Based on 1 m2 microplot trials conducted in Senegal during the summer the use ofS. rostrata as green manure doubled rice yields. These results were later confirmed in trials conducted on 25 m2 plots. In winter, when the day length is shorter,S. rostrata grows poorly but flowers readily.Sesbania rostrata trials should be conducted in two successive stages: (1) assessment ofS. rostrata behaviour in a given geographic region; (2) assessment of the effect ofS. rostrata green manure on rice yields.

Organic agriculture and the global food supply

Abstract: The principal objections to the proposition that organic agriculture can contribute significantly to the global food supply are low yields and insufficient quantities of organically acceptable fertilizers. We evaluated the universality of both claims. For the first claim, we compared yields of organic versus conventional or low-intensive food production for a global dataset of 293 examples and estimated the average yield ratio (organic:non-organic) of different food categories for the developed and the developing world. For most food categories, the average yield ratio was slightly 1.0 for studies in the developing world. With the average yield ratios, we modeled the global food supply that could be grown organically on the current agricultural land base. Model estimates indicate that organic methods could produce enough food on a global per capita basis to sustain the current human population, and potentially an even larger population, without increasing the agricultural land base. We also evaluated the amount of nitrogen potentially available from fixation by leguminous cover crops used as fertilizer. Data from temperate and tropical agroecosystems suggest that leguminous cover crops could fix enough nitrogen to replace the amount of synthetic fertilizer currently in use. These results indicate that organic agriculture has the potential to contribute quite substantially to the global food supply, while reducing the detrimental environmental impacts of conventional agriculture. Evaluation and review of this paper have raised important issues about crop rotations under organic versus conventional agriculture and the reliability of grey-literature sources. An ongoing dialogue on these subjects can be found in the Forum editorial of this issue.

Characterization of Azorhizobium caulinodans gen. nov., sp. nov., a stem-nodulating nitrogen-fixing bacterium isolated from Sesbania rostrata

Abstract: Twenty stem- and root-nodulating bacterial strains isolated from stem nodules of Sesbania rostrata were compared by numerical analysis of 221 phenotypic features with nine strains which effectively nodulate only the roots of this plant and with representative strains from the genera Rhizobium and Bradyrhizobium. Representative organisms from the different clusters were investigated further, together with possibly related organisms, by performing comparative gel electrophoresis of whole-cell proteins and by performing deoxyribonucleic acid (DNA)-DNA and DNA-ribosomal ribonucleic acid (rRNA) hybridizations. 3H-labeled rRNA was prepared from Sesbania stem- and root-nodulating bacterial strain ORS 571T (T = type strain); [14C]rRNA from Bradyrhizobium japonicum NZP 5549T was also used. The following conclusions were drawn: (i) the Sesbania root-nodulating bacterial strains are genuine rhizobia; (ii) the Sesbania stem- and root-nodulating strains are quite different from Rhizobium and Bradyrhizobium, and thus they constitute a separate rRNA subbranch on the Rhodopseudomonas palustris rRNA branch in rRNA superfamily IV; and (iii) the closest relative of these organisms is Xanthobacter, but they are phenotypically and genotypically sufficiently different from the latter genus to deserve a separate generic rank. Because the feature of free-living nitrogen fixation is quite discriminative, a new genus, Azorhizobium, is proposed, with one species, Azorhizobium caulinodans. The type strain is strain ORS 571 (= LMG 6465).

Biological nitrogen fixation: investments, expectations and actual contributions to agriculture

Abstract: Inputs of biologically fixed N into agricultural systems may be derived from symbiotic relationships involving legumes and Rhizobium spp., partnerships between plants and Frankia spp. or cyanobacteria, or from non-symbiotic associations between free-living diazotrophs and plant roots. It is assumed that these N2-fixing systems will satisfy a large portion of their own N requirements from atmospheric N2, and that additional fixed N will be contributed to soil reserves for the benefit of other crops or forage species. This paper reviews the actual levels of N2 fixation attained by legume and non-legume associations and assesses their role as a source of N in tropical and sub-tropical agriculture. We discuss factors influencing N2 fixation and identify possible strategies for improving the amount of N2 fixed.

Biodiversity of endophytic bacteria which colonize red clover nodules, roots, stems and foliage and their influence on host growth

Abstract: The aim of this study was to identifiy the endophytic bacteria recovered from the foliage, tap roots and nodules of red clover plants (Trifolium pratense L.); and to assess the effects of the nodule bacteria, alone and in combination with Rhizobium spp., on the growth and development of red clover seedlings. Thirty-one bacteria species from 14 different genera were recovered from within the foliage, roots and nodules of red clover plants cv. AC Charlie. Genera diversity and species number were greatest in foliage tissues. Pantoea agglomerans (59.6%) was the most frequent species recovered in foliage tissues, Agrobacterium rhizogenes A in the tap root (49.2%) and Rhizobium leguminosarum BV phaseoli and R. loti B in the nodules (27.2% each). Recovery of Rhizobium species was not restricted to the nodules, and species of this genus were systemic throughout the plant. Clover root nodules were host to 12 bacteria species other than rhizobia, of which 8 were specific to this tissue. Using non-selective media, R. leguminosarum BV trifolii constituted only 8.8% of all the root nodule bacteria recovered. In root bacterization experiments, species of nodule bacteria promoted growth of red clover more often when applied in combination with R. leguminosarum BV trifolii than when applied singly. However, Bacillus megaterium, Bordetella avium and Curtobacterium luteum consistently promoted growth either individually or in combination with R. leguminosarum BV trifolii. Nodulation was promoted when R. leguminosarum BV trifolii was coinoculated with Bacillus insolitus, B. brevis or A. rhizogenes A. Single isolate applications of Rhizobium species to roots always led to the depression of clover growth, but mixtures of R. leguminosarum BV trifolii and R. leguminosarum BV phaseoli resulted in growth promotion. The latter is considered further evidence of the beneficial allelopathic side effect of strain competition for the same ecological niche.