Identification of the rhizospheric microbe and metabolites that led by the continuous cropping of ramie (Boehmeria nivea L. Gaud).

Continuous cropping lowers the production and quality of ramie (Boehmeria nivea L. Gaud). This study aimed to reveal the metagenomic and metabolomic changes between the healthy- and obstacle-plant after a long period of continuous cropping. After 10 years of continuous cropping, ramie planted in some portions of the land exhibited weak growth and low yield (Obstacle-group), whereas, ramie planted in the other portion of the land grew healthy (Health-group). We collected rhizosphere soil and root samples from which measurements of soil chemical and plant physiochemical properties were taken. All samples were subjected to non-targeted gas chromatograph-mass spectrometer (GS/MS) metabolome analysis. Further, metagenomics was performed to analyze the functional genes in rhizospheric soil organisms. Based on the findings, ramie in Obstacle-group were characterized by shorter plant height, smaller stem diameter, and lower fiber production than that in Health-group. Besides, the Obstacle-group showed a lower relative abundance of Rhizobiaceae, Lysobacter antibioticus, and Bradyrhizobium japonicum, but a higher relative abundance of Azospirillum lipoferum and A. brasilense compared to the Health-group. Metabolomic analysis results implicated cysteinylglycine (Cys-Gly), uracil, malonate, and glycerol as the key differential metabolites between the Health- and Obstacle-group. Notably, this work revealed that bacteria such as Rhizobia potentially synthesize IAA and are likely to reduce the biotic stress of ramie. L. antibioticus also exerts a positive effect on plants in the fight against biotic stress and is mediated by metabolites including orthophosphate, uracil, and Cys-Gly, which may serve as markers for disease risk. These bacterial effects can play a key role in plant resistance to biotic stress via metabolic and methionine metabolism pathways.

Impact of pesticides in properties of Bradyrhizobium spp. and in the symbiotic performance with soybean.

Soybean [Glycine max (L.) Merr.] has great economic and nutritional importance mainly due to its high protein content. All plant's N needs can be met by the symbiosis with elite Bradyrhizobium strains applied as inoculants to the seeds at sowing time; however, the increasing use of pesticides in seed treatments can impair the contribution of the biological nitrogen fixation. In this study, we report decreases in cell survival of two strains, B. japonicum SEMIA 5079 and B. elkanii SEMIA 587 in seeds inoculated and treated with StandakTop™, composed of the fungicides pyraclostrobin and thiophanate-methyl and the insecticide fipronil, the pesticides most used in soybean seed treatment in several countries. Cell death was enhanced with the time of exposure to the pesticides, and B. elkanii was less tolerant, with almost no detectable viable cells after 15 days. Change in colony morphology with smaller colonies was observed in the presence of the pesticides, being more drastic with the time of exposure, and attributed to an adaptive response towards survival in the presence of the abiotic stress. However, morphological changes were reversible after elimination of the stressing agent and symbiotic performance under controlled greenhouse conditions was similar between strains that had been or not exposed to the pesticides. In addition, no changes in DNA profiles (BOX-PCR) of both strains were observed after the contact with the pesticides. In two field experiments, impacting effects of the pesticides were observed mainly on the total N accumulated in grains of plants relying on both N2-fixation and N-fertilizer. Our data indicate that StandakTop® affects parameters never reported before, including colony morphology of Bradyrhizobium spp. and N metabolism and/or N remobilization to soybean grains.

Bradyrhizobium nanningense sp. nov., Bradyrhizobium guangzhouense sp. nov. and Bradyrhizobium zhanjiangense sp. nov., isolated from effective nodules of peanut in Southeast China.

Nine slow-growing rhizobia isolated from effective nodules on peanut (Arachis hypogaea) were characterized to clarify the taxonomic status using a polyphasic approach. They were assigned to the genus Bradyrhizobium on the basis of 16S rRNA sequences. MLSA of concatenated glnII-recA-dnaK genes classified them into three species represented by CCBAU 53390T, CCBAU 51670T and CCBAU 51778T, which presented the closest similarity to B. guangxiense CCBAU 53363T, B. guangdongense CCBAU 51649T and B. manausense BR 3351T, B. vignae 7-2T and B. forestalis INPA 54BT, respectively. The dDDH (digital DNA-DNA hybridization) and ANI (Average Nucleotide Identity) between the genomes of the three representative strains and type strains for the closest Bradyrhizobium species were less than 42.1% and 91.98%, respectively, below the threshold of species circumscription. Effective nodules could be induced on peanut and Lablab purpureus by all representative strains, while Vigna radiata formed effective nodules only with CCBAU 53390T and CCBAU 51778T. Phenotypic characteristics including sole carbon sources and growth features supported the phylogenetic results. Based on the genotypic and phenotypic features, strains CCBAU 53390T, CCBAU 51670T and CCBAU 51778T are designated the type strains of three novel species, for which the names Bradyrhizobium nanningense sp. nov., Bradyrhizobium guangzhouense sp. nov. and Bradyrhizobium zhanjiangense sp. nov. are proposed, respectively.

Inoculação de diferentes doses de Bradyrhizobium por cobertura e seu efeito na cultura da soja / Inoculation by different doses of Bradyrhizobium by side dressing and its effect on Soybean / Inoculación de diferentes dosis de Bradyrhizobium por cubierta y su efecto en la Cultura de la soja

A soja é a cultura que mais cresceu no Brasil, com grande destaque para o agronegócio. Sendo o nutriente mais requerido, o nitrogênio, torna se necessário muitas vezes a utilização de fertilizantes nitrogenados e como uma alternativa sustentável, recomenda-se a inoculação com Bradyrhizobium realizando desse modo a fixação biológica de nitrogênio. O objetivo deste estudo foi avaliar os benefícios da inoculação de Bradyrhizobium na cultura da soja, pela pulverização em cobertura, na nodulação, no desenvolvimento das plantas e na produtividade. Foram conduzidos quatro tratamentos com design inteiramente casualizado e com quatro repetições, sendo tratamento 1 (controle) isento de pulverização, o segundo com pulverização de 500 mL ha­1, o terceiro de 1000 mL ha­1 e o quarto de 1500 mL ha­1 do inoculante com Bradyrhizobium. O número de sacas ha­1 com a inoculação de Bradyrhizobium por pulverização de 1500 mL ha­1 foi de 59 sacas. Reificouse ainda, aumentos significativos (p ≤ 0,05), sendo de 180,65 para número de nódulos, 4,44 g planta­1 para massa seca dos nódulos, 17,30 g planta­1 para massa seca das raízes e de 64,33 g planta­1 para massa seca da parte aérea em comparação com o tratamento controle, evidenciando o maior rendimento de soja para este tratamento. Conclui-se, portanto que a inoculação da soja com 1500 mL ha­1 de Bradyrhizobium em pulverização por cobertura, é a mais eficiente diante dos parâmetros testados no desenvolvimento e produção da soja.(AU)

The cultivation of soybean has presented the greatest increase in Brazil, with strong emphasis on agribusiness. Since nitrogen is the most required nutrient, nitrogen fertilizers are sometimes necessary. As a sustainable alternative, the inoculation of Bradyrhizobium is recommended, which can perform the biological fixation of nitrogen. The objective of this study was to evaluate the benefits of Bradyrhizobium inoculation in soybean crop, by spraying on its side dressing, nodulation, plant development and on productivity. Four treatments were carried out with a completely randomized design with four replications. The first treatment was left spray-free, the second was sprayed with 500 mL ha­1, the third with 1000 mL ha­1, and the fourth with 1500 mL ha­1 of the Bradyrhizobium inoculant. A total of 59 bags ha­1 were harvested with the application of the inoculation of Bradyrhizobium by spraying 1500 mL ha­1, and significant increases (p ≤ 0.05) were observed, namely 180.65 nodules, 4.44 g plant­1 for nodule dry matter, 17.30 g plant­1 for root dry matter, and 64.33 g plant­1 for shoot dry matter when compared to the control treatment, evidencing the higher soybean yield for this treatment. It can be concluded that the inoculation of soybean with 1500 mL ha­1 Bradyrhizobium in spray by side dressing is the most efficient in the tested parameters for the development and production of soybean.(AU)

La soja es la cultura que más creció en Brasil, con gran destaque para el agronegocio. Con el nutriente más requerido el nitrógeno, se hace necesario a menudo la utilización de fertilizantes nitrogenados y como una alternativa sostenible, se recomienda la inoculación con Bradyrhizobium realizando de ese modo la fijación biológica de nitrógeno. El objetivo de este estudio fue evaluar los beneficios de la inoculación de Bradyrhizobium en el cultivo de la soja, la pulverización en cobertura, la nodulación, el desarrollo de las plantas y la productividad. Se realizaron cuatro tratamientos con diseño completamente casualizado y con cuatro repeticiones, siendo tratamiento 1 (control) exento de pulverización, el segundo con pulverización de 500 mL ha-1, el tercero de 1000 mL ha-1 y el cuarto de 1500 mL ha-1 del inoculante con Bradyrhizobium. El número de sacas ha-1 con la inoculación de Bradyrhizobium por pulverización de 1500 mL ha-1 fue de 59 sacas Se observaron también aumentos significativos (p ≤ 0,05), siendo de 180,65 para número de nódulos, 4,44 g planta-1 para masa seca de los nódulos, 17,30 g planta-1 para masa seca de las raíces y de 64,33 g planta-1 para masa seca de la parte aérea en comparación con el tratamiento control, evidenciando mayor rendimiento de soja para este tratamiento. Se concluye, por lo tanto, que la inoculación de la soja con 1500 mL ha-1 de Bradyrhizobium en pulverización por cubierta es la más eficiente, frente a los parámetros probados en el desarrollo y producción de la soja.(AU)

Synthetic Lethality of the bfr and mbfA Genes Reveals a Functional Relationship between Iron Storage and Iron Export in Managing Stress Responses in Bradyrhizobium japonicum.

An mbfA mutant of Bradyrhizobium japonicum defective in iron export is sensitive to short term exposure to high levels iron or H2O2. Here, we found that the mbfA strain grown in elevated iron media (100 µM) became resistant to those treatments, suggesting a stress response adaptation. The bfr gene encodes the iron storage protein bacterioferritin, and its expression is derepressed by iron. An mbfA bfr double mutant showed a loss of stress adaptation, and had a severe growth phenotype in high iron media. Moreover, a bfrup allele in which bfr is constitutively derepressed conferred stress tolerance on an mbfA mutant without elevating the iron content in the growth media. The intracellular iron content of the mbfA bfr double mutant was substantially higher than that found in the wild type, even when grown in relatively low iron media (5 µM). Under that condition, iron-responsive gene expression was aberrant in the mbfA bfr strain. Moreover, the double mutant was sensitive to the iron-activated antibiotic streptonigrin. We conclude that MbfA and Bfr work in concert to manage iron and oxidative stresses. In addition, the need for iron detoxification is not limited to extreme environments, but is also required for normal cellular function.

Interrogantes en la tecnología de la inoculación de semillas de soja con Bradyrhizobium spp / Queries related to the technology of soybean seed inoculation with Bradyrhizobium spp

With the aim of exploiting symbiotic nitrogen fixation, soybean crops are inoculated with selected strains of Bradyrhizobium japonicum, Bradyrhizobium diazoefficiens or Bradyrhizobium elkanii (collectively referred to as Bradyrhizobium spp.). The most common method of inoculation used is seed inoculation, whether performed immediately before sowing or using preinoculated seeds or pretreated seeds by the professional seed treatment. The methodology of inoculation should not only cover the seeds with living rhizobia, but must also optimize the chances of these rhizobia to infect the roots and nodulate. To this end, inoculated rhizobia must be in such an amount and condition that would allow them to overcome the competition exerted by the rhizobia of the allochthonous population of the soil, which are usually less effective for nitrogen fixation and thus dilute the effect of inoculation on yield. This optimization requires solving some queries related to the current knowledge of seed inoculation, which are addressed in this article. I conclude that the aspects that require further research are the adhesion and survival of rhizobia on seeds, the release of rhizobia once the seeds are deposited in the soil, and the movement of rhizobia from the vicinity of the seeds to the infection sites in the roots

Con el fin de aprovechar la fijación simbiótica de nitrógeno, el cultivo de soja se inocula con cepas seleccionadas de Bradyrhizobium japonicum, Bradyrhizobium diazoefficiens o Bradyrhizobium elkanii (conjuntamente referidas como Bradyrhizobium spp.). El método más común de hacerlo es la inoculación en semillas, ya sea que esta se realice en el momento previo a la siembra o que se utilicen semillas preinoculadas o pretratadas mediante el tratamiento profesional de semillas. La metodología de inoculación no debe limitarse a recubrir las semillas con rizobios vivos, sino que también debe optimizar las chances de esos rizobios para infectar las raíces y nodular. Para ello los rizobios inoculados deben estar en una cantidad y un estado tales que les permitan superar la competición ejercida por los rizobios de la población alóctona del suelo, los cuales usualmente son menos eficaces para la fijación de nitrógeno y así diluyen el efecto de la inoculación sobre el rendimiento. Esta optimización requiere resolver algunos interrogantes, que son abordados en el presente artículo. Concluyo que los aspectos que requieren más investigación son la adhesión y supervivencia de los rizobios en las semillas, la liberación de los rizobios una vez que las semillas se depositan en el suelo y el movimiento de los rizobios desde las inmediaciones de las semillas hasta los sitios de infección en las raíces

Physiological changes in rhizobia after growth in peat extract may be related to improved desiccation tolerance.

Improved survival of peat-cultured rhizobia compared to survival of liquid-cultured cells has been attributed to cellular adaptations during solid-state fermentation in moist peat. We have observed improved desiccation tolerance of Rhizobium leguminosarum bv. trifolii TA1 and Bradyrhizobium japonicum CB1809 after aerobic growth in water extracts of peat. Survival of TA1 grown in crude peat extract was 18-fold greater than that of cells grown in a defined liquid medium but was diminished when cells were grown in different-sized colloidal fractions of peat extract. Survival of CB1809 was generally better when grown in crude peat extract than in the control but was not statistically significant (P > 0.05) and was strongly dependent on peat extract concentration. Accumulation of intracellular trehalose by both TA1 and CB1809 was higher after growth in peat extract than in the defined medium control. Cells grown in water extracts of peat exhibit morphological changes similar to those observed after growth in moist peat. Electron microscopy revealed thickened plasma membranes, with an electron-dense material occupying the periplasmic space in both TA1 and CB1809. Growth in peat extract also resulted in changes to polypeptide expression in both strains, and peptide analysis by liquid chromatography-mass spectrometry indicated increased expression of stress response proteins. Our results suggest that increased capacity for desiccation tolerance in rhizobia is multifactorial, involving the accumulation of trehalose together with increased expression of proteins involved in protection of the cell envelope, repair of DNA damage, oxidative stress responses, and maintenance of stability and integrity of proteins.

Genetic diversity of Rhizobia isolates from Amazon soils using cowpea (Vigna unguiculata) as trap plant

The aim of this work was to characterize rhizobia isolated from the root nodules of cowpea (Vigna unguiculata) plants cultivated in Amazon soils samples by means of ARDRA (Amplified rDNA Restriction Analysis) and sequencing analysis, to know their phylogenetic relationships. The 16S rRNA gene of rhizobia was amplified by PCR (polymerase chain reaction) using universal primers Y1 and Y3. The amplification products were analyzed by the restriction enzymes HinfI, MspI and DdeI and also sequenced with Y1, Y3 and six intermediate primers. The clustering analysis based on ARDRA profiles separated the Amazon isolates in three subgroups, which formed a group apart from the reference isolates of Bradyrhizobium japonicum and Bradyrhizobium elkanii. The clustering analysis of 16S rRNA gene sequences showed that the fast-growing isolates had similarity with Enterobacter, Rhizobium, Klebsiella and Bradyrhizobium and all the slow-growing clustered close to Bradyrhizobium.

Triple inoculation with Bradyrhizobium, Glomus and Paenibacillus on cowpea (Vigna unguiculata) [L. ] walp. )development. (au)

The use of microorganisms to improve the availability of nutrients to plants is of great importance to agriculture. This study aimed to evaluate the effect of triple inoculation of cowpea with arbuscular mycorrhizal fungi (AMF), plant growth-promoting bacteria (PGPB) and rhizobia to maximize biological nitrogen fixation (BNF) and promote plant growth. The experiment was conducted in a greenhouse using cowpea plants (Vigna unguiculata L. Walp cv. IPA 206). The treatments included inoculation with strains of Bradyrhizobium sp. (BR 3267 and EI - 6) individually and as a mixture, an absolute control (AC) and mineral nitrogen control (NC), all combined with the presence or absence of native AMF (Glomus etunicatum) and PGPB (Paenibacillus brasilensis - 24) in a 5x2x2 factorial design. All treatments were replicated three times. Contrasts were performed to study the treatment of variables. Inoculation with Bradyrhizobium sp. (BR 3267 and EI - 6) and G. etunicatum favored nitrogen acquisition and phosphorus availability for the cowpea plants. Inoculation with P. brasilensis - 24 increased colonization by Bradyrhizobium sp. and G. etunicatum and promoted cowpea growth, while the nitrogen from symbiosis was sufficient to supply the plants nutritional needs.

Expression and functional roles of Bradyrhizobium japonicum genes involved in the utilization of inorganic and organic sulfur compounds in free-living and symbiotic conditions.

Strains of Bradyrhizobium spp. form nitrogen-fixing symbioses with many legumes, including soybean. Although inorganic sulfur is preferred by bacteria in laboratory conditions, sulfur in agricultural soil is mainly present as sulfonates and sulfur esters. Here, we show that Bradyrhizobium japonicum and B. elkanii strains were able to utilize sulfate, cysteine, sulfonates, and sulfur-ester compounds as sole sulfur sources for growth. Expression and functional analysis revealed that two sets of gene clusters (bll6449 to bll6455 or bll7007 to bll7011) are important for utilization of sulfonates sulfur source. The bll6451 or bll7010 genes are also expressed in the symbiotic nodules. However, B. japonicum mutants defective in either of the sulfonate utilization operons were not affected for symbiosis with soybean, indicating the functional redundancy or availability of other sulfur sources in planta. In accordance, B. japonicum bacteroids possessed significant sulfatase activity. These results indicate that strains of Bradyrhizobium spp. likely use organosulfur compounds for growth and survival in soils, as well as for legume nodulation and nitrogen fixation.

Importance of glutathione in the nodulation process of peanut (Arachis hypogaea).

GSH appears to be essential for proper development of the root nodules during the symbiotic association of legume-rhizobia in which the entry of rhizobia involves the formation of infection threads. In the particular case of peanut-rhizobia symbiosis, the entry of rhizobia occurs by the mechanism of infection called 'crack entry', i.e. entry at the point of emergence of lateral roots. We have previously shown the role of GSH content of Bradyrhizobium sp. SEMIA 6144 during the symbiotic association with peanut using a GSH-deficient mutant obtained by disruption of the gshA gene, encoding gamma-glutamylcysteine synthetase (gamma-GCS), which was able to induce nodules in peanut roots without alterations in the symbiotic phenotype. To investigate the role of the peanut GSH content in the symbiosis, the compound L-buthionine-sulfoximine (BSO), a specific inhibitor of gamma-GCS in plants, was used. There were no differences in the plant growth and the typical anatomic structure of the peanut roots when the plants grew in the Fahraeus medium either in presence or in absence of 0.1 mM BSO. However, the GSH content was reduced by 51% after treatment with BSO. The BSO-treated plants inoculated with wild-type or mutant strains of Bradyrhizobium sp. showed a significant reduction in the number and dry weight of nodules, suggesting that GSH content could play an important role in the nodulation process of root peanut with Bradyrhizobium sp.

Growth of Bradyrhizobium sp. SEMIA 6144 in response to methylglyoxal: role of glutathione.

We previously showed the important role of glutathione (GSH) in the protection mechanism against different stresses, such as acid pH, saline, and oxidative stress, using a GSH-deficient mutant of Bradyrhizobium sp. (peanut microsymbiont). In this work, we studied the role of GSH in the protection mechanism against methylglyoxal (MG) toxicity. MG is a naturally occurring toxic electrophilic compound, and it has been shown that GSH is involved in the detoxification of MG in Escherichia coli. One recognized component of this detoxification process is the formation of a GSH adduct, which in turn transports potassium (K(+)) out of bacterial cells. Our results showed that growth of wild-type strain Bradyrhizobium sp. SEMIA 6144 was not affected at a MG concentration of 0.5 mM in the yeast extract-mannitol culture medium. However, a reduction of growth, at concentrations of 1.5 and 2.5 mM MG and reaching complete growth inhibition at 3.0 mM MG, was observed. In wild-type strain, intracellular GSH content decreased, and intracellular K(+ )content was unchanged, whereas GSH-deficient mutant SEMIA 6144-S7Z was unable to grow at 1.5 mM MG. The addition of external GSH to the incubation medium did not restore the growth rate either in wild-type or mutant strains. Our findings showed that GSH has not proven to be protective against the cell-growth inhibiting activity of MG. Therefore, the response of Bradyrhizobium sp. growth to MG is different from that reported in E. coli and other Gram-negative bacteria.

Iron-dependent cytochrome c1 expression is mediated by the status of heme in Bradyrhizobium japonicum.

The heme prosthetic group of heme proteins contains iron, which can be a limiting nutrient. Here, we show that cytochrome c1 protein from Bradyrhizobium japonicum was strongly affected by the iron status, with low expression in cells grown under iron limitation. This control was not affected in mutants encoding the iron regulator Irr or Fur. Furthermore, cytochrome c1 mRNA was not influenced by the iron status, suggesting control at a posttranscriptional step. Cytochrome c1 protein levels were very low in mutants defective in the genes encoding delta-aminolevulinic acid (ALA) synthase and ferrochelatase, enzymes that catalyze the first and final steps of the heme biosynthetic pathway, respectively. Iron-dependent cytochrome c1 expression was restored in the ALA synthase mutant by supplementation of the medium with the heme precursor ALA. Supplementation with heme resulted in high levels of cytochrome c1 protein in the wild type and in both mutants, but expression was no longer iron dependent. Cytochrome c1 is synthesized as a protein precursor fused with cytochrome b. A plasmid-borne construct encoding only cytochrome c1 was expressed in an iron- and heme-dependent manner similar to that of the wild-type gene, indicating that control by those effectors is not linked to posttranslational processing of the fusion protein. Mutation of the cytochrome c1 cysteines involved in covalent binding to heme nearly abolished immunodetectable protein. Thus, defects in heme synthesis or heme binding abrogate cytochrome c1 accumulation, apparently due to protein degradation. We suggest that iron-dependent cytochrome c1 expression is mediated by heme availability for heme protein formation.

New method of denitrification analysis of bradyrhizobium field isolates by gas chromatographic determination of (15)N-labeled N(2).

To evaluate the denitrification abilities of many Bradyrhizobium field isolates, we developed a new (15)N-labeled N(2) detection methodology, which is free from interference from atmospheric N(2) contamination. (30)N(2) ((15)N(15)N) and (29)N(2) ((15)N(14)N) were detected as an apparent peak by a gas chromatograph equipped with a thermal conductivity detector with N(2) gas having natural abundance of (15)N (0.366 atom%) as a carrier gas. The detection limit was 0.04% (30)N(2), and the linearity extended at least to 40% (30)N(2). When Bradyrhizobium japonicum USDA110 was grown in cultures anaerobically with (15)NO(3)(-), denitrification product ((30)N(2)) was detected stoichiometrically. A total of 65 isolates of soybean bradyrhizobia from two field sites in Japan were assayed by this method. The denitrification abilities were partly correlated with filed sites, Bradyrhizobium species, and the hup genotype.

Effect of thorium on the growth and capsule morphology of Bradyrhizobium.

The thorium effect on Bradyrhizobium growth was assayed in liquid media. Th4+ inhibited the growth of Bradyrhizobium (Chamaecytisus) BGA-1, but this effect decreased in the presence of suspensions of live or dead bacterial cells. Th4+ induced the formation of a gel-like precipitate when added to a dense suspension of B. (Chamaecytisus) BGA-1 cells. Viable Bradyrhizobium cells remained in suspension after precipitate formation. Thorium was recovered in the precipitate, in which polysaccharide, lipopolysaccharide and proteins were also found. After Th4+ addition, the morphology of B. (Chamaecytisus) BGA-1 or Bradyrhizobium japonicum USDA 110 sedimented cells studied by scanning electron microscopy changed from an entangled network of capsulated bacteria to uncapsulated individual cells and an amorphous precipitate. Energy-dispersive X-ray spectroscopy showed that thorium was mainly in the amorphous fraction. Precipitate was also formed between B. (Chamaecytisus) BGA-1 and Al3+, which was also toxic to this bacterium. Precipitate induced by Th4+ or Al3+ was found in all Bradyrhizobium and Sinorhizobium strains tested, but not in Rhizobium, Salmonella typhimurium, Aerobacter aerogenes or Escherichia coli. These results suggest a specific defence mechanism based on metal precipitation by extracellular polymers.

Carbon monoxide dehydrogenase activity in Bradyrhizobium japonicum.

Bradyrhizobium japonicum strain 110spc4 was capable of chemolithoautotrophic growth with carbon monoxide (CO) as a sole energy and carbon source under aerobic conditions. The enzyme carbon monoxide dehydrogenase (CODH; EC 1.2.99.2) has been purified 21-fold, with a yield of 16% and a specific activity of 58 nmol of CO oxidized/min/mg of protein, by a procedure that involved differential ultracentrifugation, anion-exchange chromatography, hydrophobic interaction chromatography, and gel filtration. The purified enzyme gave a single protein and activity band on nondenaturing polyacrylamide gel electrophoresis and had a molecular mass of 230,000 Da. The 230-kDa enzyme was composed of large (L; 75-kDa), medium (M; 28.4-kDa), and small (S; 17.2-kDa) subunits occurring in heterohexameric (LMS)(2) subunit composition. The 75-kDa polypeptide exhibited immunological cross-reactivity with the large subunit of the CODH of Oligotropha carboxidovorans. The B. japonicum enzyme contained, per mole, 2.29 atoms of Mo, 7.96 atoms of Fe, 7.60 atoms of labile S, and 1.99 mol of flavin. Treatment of the enzyme with iodoacetamide yielded di(carboxamidomethyl)molybdopterin cytosine dinucleotide, identifying molybdopterin cytosine dinucleotide as the organic portion of the B. japonicum CODH molybdenum cofactor. The absorption spectrum of the purified enzyme was characteristic of a molybdenum-containing iron-sulfur flavoprotein.

Efetividade do inoculante com Bradyrhizobium sp em diferentes substratos / Effectivenees of Bradyrhizobium sp inoculants on different substrates

Resumo: Objetivando determinar as condiçöes ideais para a sobrevivência e efetividade do Bradyrhizobium sp em substratos alternativos com diferentes potenciais matriciais, foi conduzido u experimento utilizando-se como veículo de inoculaçäo os substratos: diatomia, vinhaça, seca, vermiculita e composto urbano em relaçäo à turfa. A inoculaçäo foi procedida com a estirpe UMKL-58, selecionada em trabalhos anteriores. Os substratos foram submetidos aos m de -0,33, -1,0 e -3,00 bar e incubados por 240dias. Para a qualificaçäo dos veiculos foram feitos testes de sobrevivência da estirpe nos materiais utilizando-se os métodos de diluiçäo em placas e de infecçäo em plantas coma leguminosa cunhä (Clitoria ternatea L.) nos intervalos de 0, 12, 30, 60, 90, 120, 150, 180 e 240dias após a inoculaçäo, como também, avaliaçäo da eficiência da fixaçäo biológica do N2 em funçäo do veículo de inoculaçäo. Os resultados demonstram que o Bradyrhizobium sobreviveu melhor na diatomita submetida a m -3,0 bar e nos demais potenciais foi comparável a turfa. Para todos os veículos, observou-se que altos valores de m reduzirama taxa de sobrevivência da bactéria como também afetaram a qualidade do inóculo diminuindo a efetividade da estirpe (au)