Sodium stimulation of uptake hydrogenase activity in symbiotic Rhizobium

Initial observations showed a 100% increase in H₂-uptake (Hup) activity of Rhizobium leguminosarum strain 3855 in pea root nodules (Pisum sativum L. cv Alaska) on plants growing in a baked clay substrate relative to those growing in vermiculite, and an investigation of nutrient factors responsible for the phenomenon was initiated. Significantly greater Hup activity was first measured in the clay-grown plants 24 days after germination, and higher activity was maintained relative to the vermiculite treatment until experiments were terminated at day 32. The increase in Hup activity was associated with a decrease in H₂ evolution for plants with comparable rates of acetylene reduction. Analyses of the clay showed that it contained more Na⁺ (29 versus 9 milligrams per kilogram) and less K⁺ (6 versus 74 milligrams per kilogram) than the vermiculite. Analyses of plants, however, showed a large increase in Na⁺ concentration of clay-grown plants with a much smaller reduction in K⁺ concentration. In tests with the same organisms in a hydroponic system with controlled pH, 40 millimolar NaCl increased Hup activity more than 100% over plants grown in solutions lacking NaCl. Plants with increased Hup activity, however, did not have greater net carbon or total nitrogen assimilation. KCl treatments from 5 to 80 millimolar produced slight increased in Hup activity at 10 millimolar KCl, and tests with other salts in the hydroponic system indicated that only Na⁺ strongly promoted Hup activity. Treating vermiculite with 50 millimolar NaCl increased Na⁺ concentration in pea plant tissue and greatly promoted Hup activity of root nodules in a manner analogous to the original observation with the clay rooting medium. A wider generality of the phenomenon was suggested by demonstrating that exogenous Na⁺ increased Hup activity of other R. leguminosarum strains and promoted Hup activity of R. meliloti strain B300 in alfalfa (Medicago sativa L.).     

Screening method for the detection of uptake hydrogenase activity of Rhizobium leguminosarum bacteroids

Abstract A method has been developed for screening Rhizobium leguminosarum wild-type strains and mutants for uptake hydrogenase (Hup) activity, using H₂-dependent methylene blue reduction. For this purpose, a simple device has been constructed which allows the simultaneous screening of 6 strains and 6 controls. Bacteroids of R. leguminosarum isolated from pea root nodules were suspended in buffer containing methylene blue and inhibitors of dehydrogenases. The suspensions were first sparged with argon (to remove oxygen) and then with hydrogen.     

Recycling efficiency in hydrogenase uptake positive strains of Rhizobium leguminosarum

Essentially chlorophyll-free preparations of mitochondria from different tissues of the same plant can be obtained by a combined three step preparation procedure involving differential centrifugation, partition in aqueous polymeric two-phase system and centrifugation in a Percoll gradient. The polypeptide patterns of mitochondria from photosynthetic (leaves) and non-photosynthetic (petioles and roots) tissue from spinach were compared by use of SDS-electrophoresis.
About 35 polypeptides were found in leaf mitochondria with molecular weights from 14 to 103 kdalton. The polypeptide patterns of the membrane fractions and matrix fractions showed great differences. The membrane fractions contained significantly more polypeptide bands than the matrix fractions. The polypeptide patterns of mitochondria from photosynthetic and non-photosynthetic tissues showed some striking differences. The 15.9, 41.7, 50.7 and 101 kdalton polypeptides were clearly detected in leaf mitochondria but these polypeptides were not found or found in only small amounts in petiole and root mitochondria. The differences were mainly associated with the matrix fractions. Staining with 3,3',5,5'-tetramethylbenzidine and hydrogen peroxide for heme containing polypeptides showed that the polypeptides which differ do not contain heme.     

Rhizobium strains expressing uptake hydrogenase in different host species of cowpea miscellany

Uptake hydrogenase activity in nodules of green gram (Vigna radiata (L.) (Wilczek)), black gram (Vigna mungo (L.) (Hepper)), cowpea (Vigna unguiculata (L.) and cluster bean (Cyamopsis tetragonoloba (L.) (Taub.)), formed with two Hup⁺ (S24 and CT2014) and one Hup⁻ (M11)Rhizobium strains, was determined at different levels of external H2 in air atmosphere. Nodules of all the 4 host species formed by inoculation with strains S24 and CT2014, showed H2 uptake but not those formed with strain M11. H₂ uptake rates were higher in 1 and 2% H₂ in air atmosphere (v/v) than at 5 or 10% levels in all the host species. Variations in the relative rates of H₂ uptake were observed both, due to host species as well as due toRhizobium strains. However, no host dependent complete repression of the expression of H₂ uptake activity was observed in nodules of any of the host species formed with Hup⁺ strains.     

Role of uptake hydrogenase in providing reductant for nitrogenase in Rhizobium leguminosarum bacteroids

The role of uptake hydrogenase in providing reducing power to nitrogenase was investigated in Rhizobium leguminosarum bacteroids from nodules of Pisum sativum L. (cv. Homesteader). H₂ increased the rate of C₂H₂ reduction in the absence of added substrates. Malate also increased nitrogenase (C₂H₂) activity while decreasing the effect of H₂. At exogenous malate concentrations above 0.05 mM no effect of H₂ was seen. Malate appeared to be more important as a source of reductant than of ATP. When iodoacetate was used to minimize the contribution of endogenous substrates to nitrogenase activity in an isolate in which H₂ uptake was not coupled to ATP formation, H₂ increased the rate of C₂H₂ reduction by 77%. In the presence of iodoacetate, an ATP-generating system did not enhance C₂H₂ reduction, but when H₂ was also included, the rate of C₂H₂ reduction was increased by 280% over that with the ATP-generating system alone. The data suggest that, under conditions of substrate starvation, the uptake hydrogenase in R. leguminosarum could provide reductant as well as ATP in an isolate in which the H₂ uptake is coupled to ATP formation, to the nitrogenase complex.     

Uptake hydrogenase activity and ATP formation in Rhizobium leguminosarum bacteroids.

The role of uptake hydrogenase was studied in Rhizobium leguminosarum bacteroids from the nodules of Pisum sativum L. cv. Homesteader. Uptake hydrogenase activity, measured by the 3H2 uptake method, was dependent on O-consumption and was similar to H2 uptake measured by gas chromatography. Km for O2 of 0.0007 atm (0.0709 kPa) and a Km for H2 of 0.0074 atm (0.7498, kPa) were determined. H2 increased the rate of endogenous respiration by isolates with uptake hydrogenase (Hup+) but had no effect on an isolate lacking uptake hydrogenase (Hup-). A survey of 14 Hup+ isolates indicated a wide range of H2 uptake activities. Four of the isolates tested had activities similar to or higher than those found in two Hup+ Rhizobium japonicum strains. H2 uptake was strongly coupled to ATP formation in only 5 of the 14 isolates. H2 increased the optimal O2 level of C2H2 reduction by 0.01 atm and permitted enhanced C2H2 reduction at O2 levels above the optimum in both a coupled and an uncoupled isolate. At suboptimal O2 concentrations a small enhancement of C2H2 reduction by H2 was seen in two out of three isolates in which H2 oxidation was coupled to ATP formation. Thus, the main function of uptake hydrogenase in R. leguminosarum appears to be in the protection of nitrogenase from O2 damage.     

Nitrate reductase activity in nodules of pea inoculated with hydrogenase positive and hydrogenase negative strains of Rhizobium leguminosarum

The nitrate reductase (NR, EC 1.6.6.1) activity in root nodules formed by hydrogenase positive (Hup⁺) and hydrogenase negative (Hup⁻) Rhizobium leguminosarum strains was examined in symbioses with the pea cultivar Alaska ( Pisum sativum L.), Rates of activity were determined by the in vivo assay in nodules from plants that were only N₂-dependent or grown in the presence of 2 m M KNO₃. The rates varied widely among strains, regardless of the Hup phenotype of the R. leguminosarum strain used for inoculation, but the overall results indicated that nodules formed by Hup⁻ strains accumulated more nitrite in the incubation medium than did those with Hup⁻ phenotypes. Total plant dry weight and reduced nitrogen content of pea plants grown in the presence of 2 m M KNO₃ and inoculated with single Hup⁺ and Hup⁻ R. leguminosarum strains were statistically different among some strains. These observations suggest that the possible advantages derived from the presence of the Hup system on whole plant growth may be counteracted by the higher rates of NR activity in the Hup⁻ strains in the R. leguminosarum -pea symbiosis.     

Regulation of hydrogenase in Rhizobium japonicum.

Factors that regulate the expression of an H2 uptake system in free-living cultures of Rhizobium japonicum have been investigated. Rapid rates of H2 uptake by R. japonicum were obtained by incubation of cell suspensions in a Mg-phosphate buffer under a gas phase of 86.7% N2, 8.3% H2, 4.2% CO2, and 0.8% O2. Cultures incubated under conditions comparable with those above, with the exception that Ar replaced H2, showed no hydrogenase activity. When H2 was removed after initiation of hydrogenase derepression, further increase in hydrogenase activity ceased. Nitrogenase activity was not essential for expression of hydrogenase activity. All usable carbon substrates tested repressed hydrogenase formation, but none of them inhibited hydrogenase activity. No effect on hydrogenase formation was observed from the addition of KNO3 or NH4Cl at 10 mM. Oxygen repressed hydrogenase formation, but did not inhibit activity of the enzyme in whole cells. The addition of rifampin or chloramphenicol to derepressed cultures resulted in inhibition of enzyme formation similar to that observed by O2 repression. The removal of CO2 during derepression caused a decrease in the rate of hydrogenase formation. No direct effect of CO2 on hydrogenase activity was observed.     

Rhythmic activity of uptake hydrogenase in the prokaryote Rhodospirillum rubrum

Growth of Rhodospirillum rubrum was followed in cultures kept under anoxic conditions at constant temperature in either continuous light (LL, 32 degrees C) or continuous darkness (DD, 32 degrees C and 16 degrees C). In DD, only small modifications of the turbidity were detected; linear regression analysis nevertheless gives a very significant slope (t(34) = 13.07, p < 10(-14), with R2 of 0.834). Mean generation times reflected these differences of growth with 11.9+/-0.5 h in LL and 43.2+/-1.1 h in DD at 32 degrees C and 37.4+/-1.0 h at 16 degrees C cultures. The uptake hydrogenase (Hup) activity has been followed in situ in whole cells of R. rubrum grown in the same conditions, and a clear ultradian rhythm of activity has been observed. Indeed, after about 12 h in the new media, a rapid rise of hydrogenase activity was observed in both LL and DD cultures after which it decreased again to very low values. The activity of Hup continued to show such fluctuations during the rest of the experiment, both in DD and in LL, during the growth and stationary phases. The Lomb-Scargle power periodogram method demonstrates the presence of a clear rhythmic Hup activity both in LL and DD. In the LL-grown cultures, the oscillating activity is faster and continues throughout the growth and the stationary phases, with an ultradian period of 12.1+/-0.5 h. In DD, the slow-growing bacteria showed an ultradian oscillatory pattern of Hup activity with periods of 15.2+/-0.5 h at 32 degrees C and 23.4+/-2.0 h at 16 degrees C. The different periods obtained for LL- and DD-grown bacteria are significantly different.     

Engineering the Rhizobium leguminosarum bv. viciae hydrogenase system for expression in free-living microaerobic cells and increased symbiotic hydrogenase activity

Rhizobium leguminosarum bv. viciae UPM791 induces hydrogenase activity in pea (Pisum sativum L.) bacteroids but not in free-living cells. The symbiotic induction of hydrogenase structural genes (hupSL) is mediated by NifA, the general regulator of the nitrogen fixation process. So far, no culture conditions have been found to induce NifA-dependent promoters in vegetative cells of this bacterium. This hampers the study of the R. leguminosarum hydrogenase system. We have replaced the native NifA-dependent hupSL promoter with the FnrN-dependent fixN promoter, generating strain SPF25, which expresses the hup system in microaerobic free-living cells. SPF25 reaches levels of hydrogenase activity in microaerobiosis similar to those induced in UPM791 bacteroids. A sixfold increase in hydrogenase activity was detected in merodiploid strain SPF25(pALPF1). A time course induction of hydrogenase activity in microaerobic free-living cells of SPF25(pALPF1) shows that hydrogenase activity is detected after 3 h of microaerobic incubation. Maximal hydrogen uptake activity was observed after 10 h of microaerobiosis. Immunoblot analysis of microaerobically induced SPF25(pALPF1) cell fractions indicated that the HupL active form is located in the membrane, whereas the unprocessed protein remains in the soluble fraction. Symbiotic hydrogenase activity of strain SPF25 was not impaired by the promoter replacement. Moreover, bacteroids from pea plants grown in low-nickel concentrations induced higher levels of hydrogenase activity than the wild-type strain and were able to recycle all hydrogen evolved by nodules. This constitutes a new strategy to improve hydrogenase activity in symbiosis.     

Heterotrophic metabolism and regulation of uptake hydrogenase activity in symbiotic cyanobacteria

The H₂ uptake activity of three cyanobionts isolated fromCycas revoluta, C. circinalis andazolla filiculoides was shown to be related primarily to the growth rate and independent of the main mode of carbon nutrition. Significant H₂ uptake was found in the coralloid roots ofCycas revoluta andZamia furfuracea (3 and 22 times higher than the respective C₂H₂ reduction activities). The results attained allow us to conclude that in cyanobacteria, in contrast to most nitrogen-fixing heterotrophs, uptake hydrogenase activity is not repressed by carbon substrates and that cyanobacteria in association seem to be endowed with sufficient H₂ uptake capacity to recover all of the H₂ released during the process of N₂-fixation.     

Nickel is a component of hydrogenase in Rhizobium japonicum

The derepression of H2-oxidizing activity in free-living Rhizobium japonicum does not require the addition of exogenous metal to the derepression media. However, the addition of EDTA (6 microM) inhibited derepression of H2 uptake activity by 80%. The addition of 5 microM nickel to the derepression medium overcame the EDTA inhibition. The addition of 5 microM Cu or Zn also relieved EDTA inhibition, but to a much lesser extent; 5 microM Fe, Co, Mg, or Mn did not. The kinetics of induction and magnitude of H2 uptake activity in the presence of EDTA plus Ni were similar to those of normally derepressed cells. Nickel also relieved EDTA inhibition of methylene blue-dependent Hup activity, suggesting that nickel is involved directly with the H2-activating hydrogenase enzyme. Adding nickel or EDTA to either whole cells or crude extracts after derepression did not affect the hydrogenase activity. Cells were grown in 63Ni and the hydrogenase was subsequently purified by gel electrophoresis. 63Ni comigrated with the H2-dependent methylene blue reducing activity on native polyacrylamide gels and native isoelectric focusing gels. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the nickel-containing hydrogenase band revealed a single polypeptide with a molecular weight of ca. 67,000. We conclude that the hydrogenase enzyme in R. japonicum is a nickel-containing metalloprotein.     

Properties of the hydrogenase system in Rhizobium japonicum bacteroids

The hydrogenase system which catalyzes the oxyhydrogen reaction in soybean nodules produced by strains of $\text{Rhizobium japonicum}$ is located in the bacteroids. The hydrogenase complex in intact bacteroids has an apparent K_m for H₂ of 2.8 μM and an apparent K_m for O₂ of 1.3 μM. The addition of hydrogen to bacteroids increases oxygen uptake but decreases respiratory CO₂ production, indicating a conservation of endogenous substrates. After correction for the effect of hydrogen on endogenous respiration a ratio of 1.9 ± 0.1 for H₂ to O₂ uptake was determined. Bacteroids from greenhouse or field-grown soybeans that evolved hydrogen showed no measurable oxyhydrogen reaction activity whereas consistent activity was demonstrated by bacteroids from soybean nodules that evolved little or no H₂.     

A plant arabinogalactan-like glycoprotein promotes a novel type of polar surface attachment by Rhizobium leguminosarum

Rhizobium leguminosarum bv. viciae can attach to the roots of legume and non-legume plants. We wanted to determine whether root exudates could affect in vitro surface attachment in a confocal microscopy assay. Root exudate from pea, other legumes, wheat, and Arabidopsis induced R. leguminosarum bv. viciae to attach end-on (in a polar manner) to glass in hexagonal close-packed arrays, rather than attaching along their long axis. This did not involve a reorientation but was probably due to altered growth. The polar attachment involves a novel bacterial component because it occurred in mutants lacking a symbiosis plasmid (and hence nodulation genes) and polar glucomannan. The major surface (acidic) exopolysaccharide was required, and mutations affecting exported proteins and flagella delayed but did not block polar attachment. The polar attachment activity was purified as a high molecular weight fraction from pea root exudate and is an arabinogalactan protein (AGP) based on its carbohydrate content, reactivity with AGP-specific monoclonal antibodies and Yariv reagent, and sensitivity to enzymes that degrade proteins and carbohydrates. We propose that this novel mode of AGP-induced attachment may be important for growth of these bacteria on the roots of both legumes and non-legumes.     

Localization of an uptake hydrogenase in anabaena

Occurrence and localization of an uptake hydrogenase were examined in three strains of the blue-green alga, Anabaena. In vivo H₂ uptake was detected (0.60-1.44 μmoles/[mg of chlorophyll a per hour]) in all three strains when grown with N₂ as the sole source of nitrogen. H₂ uptake (in vivo and in vitro) was severely suppressed in cultures grown on NH₄⁺ and lacking heterocysts. H₂ uptake in cell-free extracts could be readily measured with a methyl viologen-ferricyanide electron acceptor system. Solubilization kinetics during cavitation of aerobically grown Anabaena 7120 indicates that the uptake hydrogenase is localized solely in the heterocyst. When the same organism is grown on N₂/CO₂, vegetative cells may account for up to 21% of the total hydrogenase activity in the filaments. The results are discussed in terms of a proposed functional relationship between nitrogenase and hydrogenase.     

Further evidence that two unique subunits are essential for expression of hydrogenase activity in Rhizobium japonicum.

Eight strains of Rhizobium lacking hydrogenase uptake (Hup) activity and 17 transconjugant strains carrying the hup cosmids pHU1, pHU52, or pHU53 (G. R. Lambert, M. A. Cantrell, F. J. Hanus, S. A. Russell, K. R. Haddad, and H. J. Evans, Proc. Natl. Acad. Sci. USA, 82:3232-3236, 1985) were screened for Hup activity and the presence of immunologically detectable hydrogenase polypeptides. Crude extracts of these strains were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot analysis with affinity-purified antibodies against the two subunits of purified hydrogenase (Mr 60,000 and 30,000). Derepressed transconjugants carrying the cosmid pHU52 were Hup+ and contained detectable levels of both hydrogenase subunit polypeptides. Non-derepressed strains, Hup- parent strains, and strains carrying cosmids other than pHU52 did not express Hup activity and contained no immunologically detectable protein. These data provide further evidence for the essential involvement of the smaller (Mr 30,000) subunit in the expression of hydrogenase activity in Rhizobium japonicum and suggest that the determinants for hydrogenase subunit synthesis are present on pHU52.     

The induction of nitrogenase activity in Rhizobium by non-legume plant cells

Summary Nitrogen fixation was induced in a strain of cowpea rhizobia, 32Hl, when it was grown in association with cell cultures of the non-legume, tobacco (Nicotiana tabacum). Rhizobia grown alone on the various media examined did not show nitrogenase activity, indicating the involvement of particular plant metabolites in nitrogenase induction. Nitrogenase activity, as measured by C₂H₂ reduction, was maximized at an O₂ concentration of 20% and at an assay temperature of 30°C, the conditions under which the plant cell-rhizobia associations developed. Glutamine, as a nitrogen source, could be replaced by other organic nitrogen sources, but NH₄ ⁺ and NO₃ ^- repressed nitrogenase activity. Nitrogenase activity induced in rhizobia when cultured adjacent to, but not in contact with, the plant cells could be stimulated by providing succinate in the medium. At least 12 other strains of rhizobia also reduced C₂H₂ in association with tobacco cells; the highest levels of activity were found among cowpea strains.