Viability of Bradyrhizobium japonicum bacteriods

Homogenates from soybean nodules, formed by 12 strains of Bradyrhizobium japonicum, were plated into yeast-extract mannitol agar containing 3 or 37 g mannitol 1^-1. Viable counts ranged from 8.298 to 11.265 log₁₀ cells-gram nodule^-1. When monitored over the life cycle of the symbiosis, the viability of strains USDA 110 and USDA 123 increased with days after planting (DAP), and at 70 DAP was 95% and 81%, respectively. By contrast, the viability of USDA 38 bacteroids decreased with time, and at 70 DAP was only 1.9%. At 49 DAP, nodules induced by USDA 38 had significantly fewer bacteroids per peribacteroid membrane than those formed by USDA 110 or USDA 123, and at 70 DAP, 27% of the USDA 38 bacteroids showed some degree of degeneration. Viable counts of USDA 123 and USDA 110 bacteroids, isolated from the nodules of 12 different cultivars, ranged from 10.963 to 11.463 and from 10.683 to 11.117 log₁₀ viable cells-gram nodule^-1, respectively. Varying the osmolarity of the medium had no predictable effect on bacteroid viability. When surface-sterilized nodules of IPAGO 587 (high bacteroid viability) and USDA 38 (low bacteroid viability) were inoculated into a nonsterile silt loam soil, at rates equivalent to 5.0×10⁸ and 5.0×10⁶ viable bacteroids g^-1 soil, respectively, and then incubated at 28° C for 60 days, 4.3×10⁴ and 1.5×10⁴ surviving cells g^-1 soil, respectively, were recovered. Thus, despite differences due to host and strain variation, bacteroid viability appears to be unrelated to persistence of individual strains following an annual legume crop cycle.Journal paper No. 14930, Agricultural Experiment Station University of Minnesota, St. Paul, MN 55108, USA     

用平截末端使大豆根瘤菌苹果酸脱氨酶基因插入失活及电激法转化

本实验用平截末端连接法把卡那霉素抗性基因插入到大豆根瘤菌（Ｂｒａｈｙｒｈ;ｚｏｂｉｕｍｊａｐｏｎｉｃｕｍ）１１０的苹果酸脱氢酶（ｍｄｈ）基因中,致使ｍｄｈ基因失活,再通过电激法把这一重组基因转入大豆根瘤菌（Ｂｒａｈｙｒｈｉｚｏｂｉｕｍｊａｐｏｎｉｃｕｍ）２１４３中,进而探讨ｍｄｈ基因失活对大豆固氮作用的影响。     

Siderophore Utilization by Bradyrhizobium japonicum

Bradyrhizobium japonicum USDA 110 and 61A152 can utilize the hydroxamate-type siderophores ferrichrome and rhodotorulate, in addition to ferric citrate, to overcome iron starvation. These strains can also utilize the pyoverdin-type siderophore pseudobactin St3. The ability to utilize another organism's siderophores may confer a selective advantage in the rhizosphere.     

Cytokinin Production by Bradyrhizobium japonicum

Although there is considerable circumstantial evidence for the involvement of cytokinins in legume nodulation, the cytokinins produced by rhizobia have not been well characterized. Bradyrhizobium japonicum 61A68, a bacterium which nodulates soybean (Glycine max [L.] Merr.), was grown in defined medium. Cytokinins were purified from the culture medium by Amberlite XAD-2 chromatography and fractionated by column chromatography on Sephadex LH-20 in 35% ethanol. Pooled fractions from the Sephadex column were analyzed for cytokinin activity with the tobacco callus bioassay. Cytokinin activity was observed in fractions corresponding to the elution volumes of zeatin, ribosylzeatin, and methylthiozeatin. No activity corresponding to the elution volumes of isopentenyladenine or its riboside was found. Total cytokinin activity in the B. japonicum culture filtrate was equivalent to approximately 1 microgram of kinetin per liter. Transfer RNA was isolated from B. japonicum cells by phenol extraction, followed by potassium acetate extraction, cetyltrimethylammonium bromide precipitation, and DEAE cellulose chromatography. Transfer RNA was enzymically hydrolyzed to nucleosides. High performance liquid chromatographic analysis of cytokinin nucleosides showed peaks corresponding to the retention times of trans-ribosylzeatin, methylthioribosylzeatin, isopentenyladenosine, and methylthioisopentenyladenosine. Analysis of the tRNA hydrolysate by Sephadex LH-20 chromatography and tobacco bioassay showed cytokinin activity in fractions corresponding to ribosylzeatin, methylthioribosylzeatin, and isopentenyladenosine. The presence of the trans isomer of ribosylzeatin was also determined by enzyme immunoassay.     

Acetate-Activating Enzymes of Bradyrhizobium japonicum Bacteroids

Acetyl coenzyme A (acetyl-CoA) synthetase and acetate kinase were localized within the soluble portion of Bradyrhizobium japonicum bacteroids, and no appreciable activity was found elsewhere in the nodule. The presence of each acetate-activating enzyme was confirmed by separation of the two enzyme activities on a hydroxylapatite column, by substrate dependence of each enzyme in both the forward and reverse directions, by substrate specificity, by inhibition patterns, and also by identification of the reaction products by C₁₈ reverse-phase high-pressure liquid chromatography. Phosphotransacetylase activity, found in the soluble portion of the bacteroid, was dependent on the presence of potassium and was inhibited by added sodium. The greatest acetyl-CoA hydrolase activity was found in the root nodule cytosol, although appreciable activity also was found within the bacteroids. The combined specific activities of acetyl-CoA synthetase and acetate kinase-phosphotransacetylase were approximate to that of the pyruvate dehydrogenase complex, thus providing B. japonicum with sufficient capacity to generate acetyl-CoA.     

Degradation of catechin by Bradyrhizobium japonicum

Rhizobia utilize phenolic substances as sole carbonsource. Bradyrhizobium japonicum utilizescatechin, a unit of condensed tannin as carbonsource. To establish the degradative pathway ofcatechin, the products of catechin degradation wereisolated by paper chromatography and TLC andidentified by HPLC, UV, IR and NMR spectra. B.japonicum cleaves catechin through catechinoxygenase. Phloroglucinolcarboxylic acid andprotocatechuic acid were identified as the initialproducts of degradation. Phloroglucinolcarboxylicacid is further decarboxylated to phloroglucinolwhich is dehydroxylated to resorcinol. Resorcinolis hydroxylated to hydroxyquinol. Protocatechuicacid and hydroxyquinol undergo intradiol cleavagethrough protocatechuate 3,4-dioxygenase andhydroxyquinol 1,2-dioxygenase to form-carboxy cis, cis-muconic acidand maleylacetate respectively. The enzymes ofcatechin degradative pathway are inducible. Estimation of all the enzymes involved in thecatabolism of catechin reveals the existence of acatechin degradative pathway in B. japonicum.     

Carbon metabolism in Bradyrhizobium japonicum bacteroids

Abstract Carbon metabolism in Bradyrhizobium japonicum bacteroids is reviewed. Additionally, the bacteroid tricarboxylic acid (TCA) cycle and its regulation under oxygen-limited conditions is considered, with emphasis on possible sites of TCA cycle rate-limiting reactions. Furthermore, we consider other adaptive pathways that may be employed by these organisms while in symbiosis. These pathways include: (1) a poly-β-hydroxy-butyrate shunt, (2) a malate-aspartate shuttle, (3) an α-ketoglutarate-glutamate shunt, (4) a modified dicarboxylic acid cycle, and (5) fermentation pathways leading to lactate, acetaldehyde and ethanol. The effects of oxygen limitation on host carbon metabolism are also considered briefly.     

Nickel uptake in Bradyrhizobium japonicum.

Free-living Bradyrhizobium japonicum grown heterotrophically with 1 microM 63Ni2+ accumulated label. Strain SR470, a Hupc mutant, accumulated almost 10-fold more 63Ni2+ on a per-cell basis than did strain SR, the wild type. Nongrowing cells were also able to accumulate nickel over a 2-h period, with the Hupc mutant strain SR470 again accumulating significantly more 63Ni2+ than strain SR. These results suggest that this mutant is constitutive for nickel uptake as well as for hydrogenase expression. The apparent Kms for nickel uptake in strain SR and strain SR470 were found to be similar, approximately 26 and 50 microM, respectively. The Vmax values, however, were significantly different, 0.29 nmol of Ni/min per 10(8) cells for SR and 1.40 nmol of Ni/min per 10(8) cells for SR470. The uptake process was relatively specific for nickel; only Cu2+ and Zn2+ (10 microM) were found to appreciably inhibit the uptake of 1 microM Ni, while a 10-fold excess of Mg2+, Co2+, Fe3+, or Mn2+ did not affect Ni2+ uptake. The lack of inhibition by Mg2+ indicates that nickel is not transported by a magnesium uptake system. Nickel uptake was also inhibited by cold (53% inhibition at 4 degrees C) and slightly by the ionophores nigericin and carbonyl cyanide m-chlorophenylhydrazone. Other ionophores did not appreciably affect nickel uptake, even though they significantly stimulated O2 uptake. The cytochrome c oxidase inhibitors azide, cyanide, and hydroxylamine did not inhibit Ni2+ uptake, even at concentrations (of cyanide and hydroxylamine) that inhibited O2 uptake. The addition of oxidizable substrates such as succinate or gluconate did not increase nickel uptake, even though they increased respiratory activity. Nickel update showed a pH dependence with an optimum at 6.0. Most (approximately 85%) of the 63Ni2+ taken up in 1 min by strain SR470 was not exchangeable with cold nickel.     

Symbiotically defective histidine auxotrophs of Bradyrhizobium japonicum

Four histidine auxotrophs of Bradyrhizobium japonicum strain USDA 122 were isolated by random transposon Tn5 mutagenesis. These mutants arose from different, single transposition events as shown by the comparison of EcoRI and XhoI-generated Tn5 flanking sequences of genomic DNA. The mutants grew on minimal medium supplemented with l-histidine or l-histidinol but failed to grow with l-histidinol phosphate. While two of the muants were symbiotically defective and did not form nodules on Glycine max cvs. Lee and Peking and on Glycine soja, the other two mutants were symbiotically competent. Reversion to prototrophy occurred at a frequency of about 10^-7 on growth medium without added antibiotics, but prototrophs could not be isolated from growth medium containing 200 g/ml kanamycin and streptomycin. The prototrophic revertants formed nodules on all the soybean cultivars examined. When histidine was supplied to the plant growth medium, both nodulation deficient mutants formed effective symbioses. On histidine unamended plants, nodules were observed infrequently. Three classes of bacterial colonies were isolated from such infrequent nodules: class 1 were kanamycin resistant-auxotrophs; class 2 were kanamycin sensitive-prototrophs; and class 3 were kanamycin-sensitive auxotrophs. Our results suggest that two Tn5 insertion mutations in B. japonicum leading to histidine auxotrophy, affect nodulation in some way. These mutations are in regions that show no homology to the Rhizobium meliloti common nodulation genes.     

Autecology of Bradyrhizobium japonicum in soybean-rice rotations

The effect of rice culture on changes in the number of a strain of soybean root-nodule bacteria, (Bradyrhizobium japonicum CB1809), already established in the soil by growing inoculated soybean crops, was investigated in transitional red-brown earth soils at two sites in south-western New South Wales. At the first site, 5.5 years elapsed between the harvest of the last of four successive crops of soybean and the sowing of the next. In this period three crops of rice and one crop of triticale were sown and in the intervals between these crops, and after the crop of triticale, the land was fallowed. Before sowing the first rice crop, the number of Bradyrhizobium japonicum was 1.32×10⁵ g^–1 soil. The respective numbers of bradyrhizobia after the first, second and third rice crops were 4.52 ×10⁴, 1.26×10⁴ and 6.40×10² g^–1 soil. In the following two years the population remained constant. Thus sufficient bradyrhizobia survived in soil to nodulate and allow N₂-fixation by the succeeding soybean crop. At the second site, numbers of bradyrhizobia declined during a rice crop, but the decline was less than when the soil was fallowed (400-fold cf. 2200-fold). Multiplication of bradyrhizobia was rapid in the rhizosphere of soybean seedlings sown without inoculation in the rice bays. At 16 days after sowing, their numbers were not significantly different (p<0.05) from those in plots where rice had not been sown. Nodulation of soybeans was greatest in plots where rice had not been grown, but yield and grain nitrogen were not significantly different (p<0.05). Our results indicate that flooding soil has a deleterious effect on the survival of bradyrhizobia but, under the conditions of the experiments, sufficient B. japonicum strain CB 1809 survived to provide good nodulation after three crops of rice covering a total period of 5.5 years between crops of soybean.     

Molybdate transport by Bradyrhizobium japonicum bacteroids.

Bacteroid suspensions of Bradyrhizobium japonicum USDA 136 isolated from soybeans grown in Mo-deficient conditions were able to transport molybdate at a nearly constant rate for up to 1 min. The apparent Km for molybdate was 0.1 microM, and the Vmax was about 5 pmol/min per mg (dry weight) of bacteroid. Supplementation of bacteroid suspensions with oxidizable carbon sources did not markedly increase molybdate uptake rates. Anaerobically isolated bacteroids accumulated twice as much Mo in 1 h as aerobically isolated cells did, but the first 5 min of molybdate uptake was not dependent on the isolation condition with respect to O2. Respiratory inhibitors such as cyanide, azide, and hydroxylamine did not appreciably affect molybdate uptake, even at concentrations that inhibited O2 uptake. The uncouplers carbonyl cyanide m-chlorophenylhydrazone (CCCP) and carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) and the ionophores nigericin and monensin significantly inhibited molybdate uptake. The electrogenic ionophores valinomycin and gramicidin stimulated molybdate uptake. Rapid pH shift experiments indicated that molybdate transport depends on a transmembrane proton gradient (delta pH), and it is probably transported electroneutrally as H2MoO4. Most of the 99MoO4(2-) taken up was not exchangeable with a 100-fold excess of unlabeled MoO4(2-). Tungstate was a competitive inhibitor of molybdate uptake, with a Ki of 0.034 microM, and vanadate inhibited molybdate uptake slightly.     

Nickel accumulation and storage in Bradyrhizobium japonicum

Hydrogenase-derepressed (chemolithotrophic growth conditions) and heterotrophically grown cultures of Bradyrhizobium japonicum accumulated nickel about equally over a 3-h period. Both types of cultures accumulated nickel primarily in a form that was not exchangeable with NiCl2, and they accumulated much more Ni than would be needed for the Ni-containing hydrogenase. The nickel accumulated by heterotrophically incubated cultures could later be mobilized to allow active hydrogenase synthesis during derepression in the absence of nickel, while cells both grown and derepressed without nickel had low hydrogenase activities. The level of activity in cells grown with Ni and then derepressed without nickel was about the same as that in cultures derepressed in the presence of nickel. The Ni accumulated by heterotrophically grown cultures was associated principally with soluble proteins rather than particulate material, and this Ni was not lost upon dialyzing an extract containing the soluble proteins against either Ni-containing or EDTA-containing buffer. However, this Ni was lost upon pronase or low pH treatments. The soluble Ni-binding proteins were partially purified by gel filtration and DEAE chromatography. They were not antigenically related to hydrogenase peptides. Much of the 63Ni eluted as a single peak of 48 kilodaltons. Experiments involving immunoprecipitation of 63Ni-containing hydrogenase suggested that the stored source of Ni in heterotrophic cultures that could later be mobilized into hydrogenase resided in the nonexchangeable Ni-containing fraction rather than in loosely bound or ionic forms.     

A dominant-negative fur mutation in Bradyrhizobium japonicum

In many bacteria, the ferric uptake regulator (Fur) protein plays a central role in the regulation of iron uptake genes. Because iron figures prominently in the agriculturally important symbiosis between soybean and its nitrogen-fixing endosymbiont Bradyrhizobium japonicum, we wanted to assess the role of Fur in the interaction. We identified a fur mutant by selecting for manganese resistance. Manganese interacts with the Fur protein and represses iron uptake genes. In the presence of high levels of manganese, bacteria with a wild-type copy of the fur gene repress iron uptake systems and starve for iron, whereas fur mutants fail to repress iron uptake systems and survive. The B. japonicum fur mutant, as expected, fails to repress iron-regulated outer membrane proteins in the presence of iron. Unexpectedly, a wild-type copy of the fur gene cannot complement the fur mutant. Expression of the fur mutant allele in wild-type cells leads to a fur phenotype. Unlike a B. japonicum fur-null mutant, the strain carrying the dominant-negative fur mutation is unable to form functional, nitrogen-fixing nodules on soybean, mung bean, or cowpea, suggesting a role for a Fur-regulated protein or proteins in the symbiosis.     

Bradyrhizobium japonicum isocitrate dehydrogenase exhibits calcium-dependent hysteresis

Bradyrhizobium japonicum NADP(+)-dependent isocitrate dehydrogenase was purified both from cultured cells and from the symbiotic form of the bacteria and was found to be identical in terms of N-terminal amino acid sequence, kinetics, and physicochemical properties. Magnesium and glycerol were absolute requirements for maintaining enzyme activity. The N-terminal amino acid sequence of the enzyme was more similar to the sequences from soybean and yeast than to other bacterial sequences. There was no immunological cross-reaction of antibodies from B. japonicum isocitrate dehydrogenase to extracts of soybean, pea, or Escherichia coli, but there was detectable, although weak, cross-reaction of antibodies from E. coli with the B. japonicum enzyme. B. japonicum isocitrate dehydrogenase displayed strong inhibition by NADH, indicating that during symbiotic nitrogen fixation the enzyme activity would be markedly reduced in planta. The enzyme displayed a calcium-dependent hysteresis, with a pronounced lag lasting as long as 2 min. Hysteresis was evident at concentrations of magnesium less than 0.5 mM and calcium greater than 1 microM. The hysteresis could be alleviated by excess magnesium or by 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid. The results suggest two roles for magnesium during catalysis; one magnesium may be needed to convert the enzyme into the steady-state form and the second needed for chelation of isocitrate for catalysis. The calcium-dependent hysteretic behavior of B. japonicum NADP(+)-isocitrate dehydrogenase suggested that this metal could serve as an intracellular regulator during symbiosis.     

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.