Gas exchange in the filamentous cyanobacterium Nostoc punctiforme strain ATCC 29133 and Its hydrogenase-deficient mutant strain NHM5

Nostoc punctiforme ATCC 29133 is a nitrogen-fixing, heterocystous cyanobacterium of symbiotic origin. During nitrogen fixation, it produces molecular hydrogen (H(2)), which is recaptured by an uptake hydrogenase. Gas exchange in cultures of N. punctiforme ATCC 29133 and its hydrogenase-free mutant strain NHM5 was studied. Exchange of O(2), CO(2), N(2), and H(2) was followed simultaneously with a mass spectrometer in cultures grown under nitrogen-fixing conditions. Isotopic tracing was used to separate evolution and uptake of CO(2) and O(2). The amount of H(2) produced per molecule of N(2) fixed was found to vary with light conditions, high light giving a greater increase in H(2) production than N(2) fixation. The ratio under low light and high light was approximately 1.4 and 6.1 molecules of H(2) produced per molecule of N(2) fixed, respectively. Incubation under high light for a longer time, until the culture was depleted of CO(2), caused a decrease in the nitrogen fixation rate. At the same time, hydrogen production in the hydrogenase-deficient strain was increased from an initial rate of approximately 6 micro mol (mg of chlorophyll a)(-1) h(-1) to 9 micro mol (mg of chlorophyll a)(-1) h(-1) after about 50 min. A light-stimulated hydrogen-deuterium exchange activity stemming from the nitrogenase was observed in the two strains. The present findings are important for understanding this nitrogenase-based system, aiming at photobiological hydrogen production, as we have identified the conditions under which the energy flow through the nitrogenase can be directed towards hydrogen production rather than nitrogen fixation.     

Aerobic Hydrogen Production via Nitrogenase in Azotobacter vinelandii CA6

The diazotroph Azotobacter vinelandii possesses three distinct nitrogenase isoenzymes, all of which produce molecular hydrogen as a by-product. In batch cultures, A. vinelandii strain CA6, a mutant of strain CA, displays multiple phenotypes distinct from its parent: tolerance to tungstate, impaired growth and molybdate transport, and increased hydrogen evolution. Determining and comparing the genomic sequences of strains CA and CA6 revealed a large deletion in CA6''s genome, encompassing genes related to molybdate and iron transport and hydrogen reoxidation. A series of iron uptake analyses and chemostat culture experiments confirmed iron transport impairment and showed that the addition of fixed nitrogen (ammonia) resulted in cessation of hydrogen production. Additional chemostat experiments compared the hydrogen-producing parameters of different strains: in iron-sufficient, tungstate-free conditions, strain CA6''s yields were identical to those of a strain lacking only a single hydrogenase gene. However, in the presence of tungstate, CA6 produced several times more hydrogen. A. vinelandii may hold promise for developing a novel strategy for production of hydrogen as an energy compound.     

Photoevolution of hydrogen during oxygenic photosynthesis of cyanobacteriumNostoc muscorum

Summary Nitrogen fixing cultures of the cyanobacteriumNostoc muscorum lacked hydrogen evolution but cultures infected with cyanophage N-1 showed significant hydrogen evolution and inactive nitrogenase, suggesting that nitrogenase activity is not responsible for the observed oxygen-resistant photoproduction of hydrogen. Significant oxygen-resistant hydrogen production by nitrate or ammonium assimilating cultures deficient in both nitrogenase and uptake hydrogenase activity supports this conclusion. These findings suggest a role of uptake hydrogenase in blocking the production of hydrogen during aerobic photosynthetic conditions.     

Hydrogen metabolism of three unicellular nitrogen-fixing cyanobacteria

Abstract The enzyme activities responsible for the evolution and consumption of hydrogen in three unicellular cyanobacteria were investigated. Gloeothece sp. 6909 and Cyanothece sp. 7822 performed an oxygen-tolerant nitrogen fixation, whereas the nitrogenase activity of Synechococcus sp. 7425 was much more sensitive to oxygen. While in Gloeothece the net hydrogen production during nitrogen fixation was relatively low due to recycling by an uptake hydrogenase, little hydrogen consumption was detected in Cyanothece and Synechococcu . On the other hand a reversible hydrogenase was demonstrated in the latter strains. However, only Cyanothece shows hydrogenase-catalysed hydrogen production in vivo under anaerobic conditions in the dark. It is suggested that hydrogen is a fermentation product, and that the physiological function of this reversible hydrogenase is the removal of excess reduction equivalents under such conditions.     

Cyanobacterial H<Subscript>2</Subscript> production — a comparative analysis

Several unicellular and filamentous, nitrogen-fixing and non-nitrogen-fixing cyanobacterial strains have been investigated on the molecular and the physiological level in order to find the most efficient organisms for photobiological hydrogen production. These strains were screened for the presence or absence of hup and hox genes, and it was shown that they have different sets of genes involved in H₂ evolution. The uptake hydrogenase was identified in all N₂-fixing cyanobacteria, and some of these strains also contained the bidirectional hydrogenase, whereas the non-nitrogen fixing strains only possessed the bidirectional enzyme. In N₂-fixing strains, hydrogen was mainly produced by the nitrogenase as a by-product during the reduction of atmospheric nitrogen to ammonia. Therefore, hydrogen production was investigated both under non-nitrogen-fixing conditions and under nitrogen limitation. It was shown that the hydrogen uptake activity is linked to the nitrogenase activity, whereas the hydrogen evolution activity of the bidirectional hydrogenase is not dependent or even related to diazotrophic growth conditions. With regard to large-scale hydrogen evolution by N₂-fixing cyanobacteria, hydrogen uptake-deficient mutants have to be used because of their inability to re-oxidize the hydrogen produced by the nitrogenase. On the other hand, fermentative H₂ production by the bidirectional hydrogenase should also be taken into account in further investigations of biological hydrogen production.Abbreviations Chl chlorophyll - MV methyl viologen     

Gas Exchange in the Filamentous Cyanobacterium Nostoc punctiforme Strain ATCC 29133 and Its Hydrogenase-Deficient Mutant Strain NHM5

Nostoc punctiforme ATCC 29133 is a nitrogen-fixing, heterocystous cyanobacterium of symbiotic origin. During nitrogen fixation, it produces molecular hydrogen (H₂), which is recaptured by an uptake hydrogenase. Gas exchange in cultures of N. punctiforme ATCC 29133 and its hydrogenase-free mutant strain NHM5 was studied. Exchange of O₂, CO₂, N₂, and H₂ was followed simultaneously with a mass spectrometer in cultures grown under nitrogen-fixing conditions. Isotopic tracing was used to separate evolution and uptake of CO₂ and O₂. The amount of H₂ produced per molecule of N₂ fixed was found to vary with light conditions, high light giving a greater increase in H₂ production than N₂ fixation. The ratio under low light and high light was approximately 1.4 and 6.1 molecules of H₂ produced per molecule of N₂ fixed, respectively. Incubation under high light for a longer time, until the culture was depleted of CO₂, caused a decrease in the nitrogen fixation rate. At the same time, hydrogen production in the hydrogenase-deficient strain was increased from an initial rate of approximately 6 μmol (mg of chlorophyll a)⁻¹ h⁻¹ to 9 μmol (mg of chlorophyll a)⁻¹ h⁻¹ after about 50 min. A light-stimulated hydrogen-deuterium exchange activity stemming from the nitrogenase was observed in the two strains. The present findings are important for understanding this nitrogenase-based system, aiming at photobiological hydrogen production, as we have identified the conditions under which the energy flow through the nitrogenase can be directed towards hydrogen production rather than nitrogen fixation.     

Hydrogen oxidation and nitrogen fixation in rhizobia,with special attention focused on strain ORS 571

In this survey we describe the influence of hydrogen oxidation on the physiology ofRhizobium ORS 571. The presence of hydrogen is required for the synthesis of hydrogenase. Carbon substrates do not repress the synthesis of hydrogenase. The respiratory system contains cytrochromes of theb- andc-type. Cytochromea ₆₀₀ is present after growth at high oxygen tensions. The nature of the terminal oxidases functioning at low oxygen tensions has not been established yet. → H⁺/O values with endogenous substrates are between 6 and 7. The results show the presence of two phosphorylation sites: site 1 (ATP/2e=1.0) and site 2(ATP/2e=1.33). By measuring molar growth yields it has been demonstrated that carbon-limited, nitrogen-fixing cultures obtain additional ATP from hydrogen oxidation, and that site 2 of oxidative phosphorylation is passed during hydrogen oxidation. A method is described to calculate ATP/N₂ values (the total amount of ATP used by nitrogenase during the fixation of 1 mol N₂) and H₂/N₂ ratios (mol hydrogen formed per mol N₂ fixed) in aerobic organisms. ForRhizobium ORS 571 the ATP/N₂ value is about 40 and the H₂/N₂ ratio is between 5 and 7.5. Cells obtained from oxygen-limited nitrogen-fixing cultures contain 30–40% poly-β-hydroxybutyrate, which explains the high molar growth yields found. Hydrogen has not been detected in the effluent gas of these cultures, which may point to reoxidation of the hydrogen formed at nitrogen fixation. Calculations show that the effect of hydrogen reoxidation on the efficiency of nitrogen fixation (g N fixed × mol⁻¹ substrate converted) is not very large and that the actual H₂/N₂ ratio is of much more importance. After addition of hydrogen to succinate-limited, ammonia-assimilating cultures, an initial increase of the Y_succinate value (g dry wt × mol⁻¹ succinate) is followed by a gradual decrease. This is accompanied by a large decrease of the value, and an increased permeability of the cytoplasmic membrane to protons. The results may be explained by a transition of the culture from an energy-limited state to a carbon-limited state.     

Hydrogen oxidation and efficiency of nitrogen fixation in succinate-limited chemostat cultures ofRhizobium ORS 571

Rhizobium ORS 571, isolated from stem nodules of the tropical legumeSesbania rostrata is able to grow in the chemostat with molecular nitrogen as sole nitrogen source at a specific growth rate of 0.1 h^-1. Samples from nitrogenfixing cultures showed high acetylene reduction activities: 1,500 nmol ethylene formed per milligram dry weight per hour. Under nitrogen-fixing conditions an uptake hydrogenase is induced. Ammonia-assimilating cultures, without additional hydrogen, did not induce hydrogenase. The addition of hydrogen to succinate-limited nitrogen-fixing cultures resulted in an increase in the molar growth yield on succinate (Y _succinate) from 27 to 35 and a slight decrease in the molar growth yield on oxygen ( ), showing that hydrogen oxidation is less energy-yielding than the oxidation of endogenous substrates. Respiration-driven proton translocation measured with starved cells indicated the functioning of site 1 and 2 of oxidative phosphorylation. Cytochrome spectra showed that cytochromea ₆₀₀, present at high dissolved oxygen tension (d.o.t.) almost completely disappeared at low d.o.t. In flash-photolysis spectra only thea-type cytochrome could be detected as an oxidase in cells both grown at high and low d.o.t. Growth yields in ammonia-assimilating cultures were higher than those measured in nitrogen-fixing cultures. Assuming two sites of oxidative phosphorylation, a molar growth yield on ATP (Y _ATP) of about 3 and 6 was calculated for respecticely nitrogen-fixing and ammonia-assimilating cultures. TheY _ATP under nitrogen-fixing conditions is dependent on the amount of H₂ formed per mol N₂ fixed (H₂/N₂ ratio). A method has been described to calculate the total amount of ATP use by nitrogenase during the fixation of 1 mol N₂ (ATP/N₂ ratio) and H₂/N₂ ratios in aerobic nitrogen fixing organisms. This calculation yielded that nitrogen fixation inRhizobium ORS 571 is a high ATP-consuming process. The calculated ATP/N₂ and H₂/N₂ ratios were respectively 42 and 7.5.Abbreviations d.o.t. dissolved oxygen tension A preliminary account of this work was presented at the 5th International Symposium on Nitrogen Fixation, September 1983, Noordwijkerhout, The Netherlands     

Pathways of hydrogen uptake in the cyanobacterium Nostoc muscorum

Two pathways of hydrogen uptake in Nostoc muscorum are apparent using either oxygen or nitrogen as electron acceptor. Hydrogen uptake (under argon with some oxygen as electron acceptor assayed in the dark; oxyhydrogen reaction) is found to be more active in dense, light-limited cultures than in thin cultures when light is not limiting. Addition of bicarbonate inhibits this hydrogen uptake, because photosynthesis is stimulated. In a cell-free hydrogenase assay, a 10-fold increase of the activity can be measured, after the cells having been kept under lightlimiting conditions. After incubation under light-saturating conditions, no hydrogen uptake is found, when filaments are assayed under argon plus some oxygen. Assaying these cells under a nitrogen atmosphere, a strong hydrogen uptake occurs. The corresponding cell-free hydrogenase assay exhibits low hydrogenase activity. Furthermore, the hydrogen uptake by intact filaments under nitrogen in the light apparently is correlated with nitrogenase activity. These studies give evidence that, under certain physiological conditions, hydrogen uptake of heterocysts proceeds directly via nitrogenase, with no hydrogenase involved.Abbreviations Chl chlorophyll - DCMU (diuron) 3-3,4-dichlorophenyl)-1,1-dimethylurea - pev packed cell volume     

水稻根际兼性厌氧催娩克氏杆菌和阴沟肠杆菌的固氮与氢代谢

兼性厌氧细菌Enterobacter cloacae菌株E-26和Klebsiella oxytoca菌株NG-13的氢酶与固氮酶同时形成。固氮的最佳碳源为蔗糖、葡萄糖和丙酮酸,此外延胡索酸和苹果酸也能支持固氮。支持固氮的碳源也支持放氢,两者动力学基本一致。40％乙炔预处理后,吸氢活性下跌,放氢量未增加;NH_4~ 抑制固氮酶,但未导致放氢量降低;可能E-26菌株的放氢主要依赖于氢酶。菌株E-26和NG-13的吸氢反应,既能以O_2为电子受体,也能以延胡索酸、硝酸、MB为电子受体。但仅延胡索酸为电子受体时,E-26菌的固氮活性被分子H_2促进,它的氢吸收利用与固氮相偶联;而在CO_2和NH_4~ 代谢与H_2利用之间并无明显相关性,吸氢活性不被CO_2和NH_4~ 促进。     

Hydrogenase activity in nitrogen-fixing methane-oxidizing bacteria

Hydrogenase activity in cells of the nitrogen-fixing methane-oxidizing bacterium strain 41 of the Methylosinus type increased markedly when growth was dependent upon the fixation of gaseous nitrogen. A direct relationship may exist between hydrogenase and nitrogenase in this bacterium. Acetylene reduction was supported by the presence of hydrogen gas.     

Hydrogenase does not confer significant benefits to Azotobacter vinelandii growing diazotrophically under conditions of glucose limitation.

The presumed beneficial effect of hydrogenase on growth of diazotrophic bacteria was reinvestigated with carbon-limited chemostat cultures of the hydrogenase-deficient mutant hoxKG of Azotobacter vinelandii and its parent. The results revealed that hydrogen recycling was too low to benefit the cellular energy metabolism or activities of nitrogenase and respiration.     

Hydrogenase in Frankia KB5: expression of and relation to nitrogenase

The localization and expression of the hydrogenase in free-living Frankia KB5 was investigated immunologically and by monitoring activity, focusing on its relationships with nitrogenase and H2. Immunological studies revealed that the large subunit of the hydrogenase in Frankia KB5 was modified post-translationally, and transferred into the membrane after processing. The large subunit was constitutively expressed and no correlation was found between hydrogenase activity and synthesis. Although H2 was not needed for induction of hydrogenase synthesis, exogenously added H2 triggered hydrogen uptake in medium containing nitrogen, i.e., in the hyphae. A correlation between nitrogenase activity and hydrogen uptake was found in cultures grown in media without nitrogen, but interestingly the two enzymes showed no co-regulation.     

Relative energy efficiency of nitrogen fixation by nodules of chickpeas (Cicer arietinum L.) produced by different strains ofRhizobium

Hydrogen evolution from a nitrogenase-catalyzed reaction in nodules has been proposed as one of the main causes of inefficiency in theRhizobium-legume symbiosis. We have evaluated the energy efficiency of the nitrogen fixation by chickpeas as affected by specific strains ofRhizobium. All seventeen strains tested produced nodules that evolved amounts of hydrogen ranging from 2.4 to 7.5 μmol/h×g fresh nodule weight. The equivalent energy losses represented from 31% to 58% of the nitrogenase activity estimated as acetylene reduction. No hydrogen uptake hydrogenase activity was detected in any of the bacteroid suspensions from nodules produced by the strains examined. The need to select strains of chickpea rhizobia with higher energy efficiency to improve productivity is emphasized.     

Hydrogen uptake by Robinia pseudoacacia nodules

Summary Hydrogen uptake is thought to increase the efficiency of nitrogen fixation by recycling H₂ produced by nitrogenase that would otherwise be lost by diffusion. Here we demonstrate the capacity of eight Rhizobium strains to take up molecular hydrogen. Uptake by nodule homogenates from Robinia pseudoacacia was measured amperometrically under nitrogenase repression. Markedly lower activities were found than in soybean nodules. In addition hydrogenase activity was detected by the ability of bacteroids to reduce methylene blue in the presence of hydrogen. It was demonstrated that hydrogenase structural genes are present in the black locust symbiont, Rhizobium sp. strain R1, using hybridization with a plasmid, which contained hydrogenase genes from R. leguminosarum bv. viceae.     

Relative efficiency of nitrogen fixation and the occurrence of hydrogenase in pea root nodules

Summary The apparent K_m(hydrogen) for uptake of hydrogen by pea root nodules was determined. This enabled the concentration gradient necessary for the evolution of hydrogen to be calculated for nodules with no hydrogenase activity. This indicated that hydrogen inhibition of nitrogenase is not likely to be the cause of the low relative efficiency of legume root nodules. The factors that affect electron allocation between protons and nitrogen in nitrogenase are reviewed and it is concluded that there must be some as yet unknown factor that affects electron distribution inRhizobium nitrogenase. One possibility is put forward and considered. A strain ofRhizobium was used that was found to possess hydrogenase activity in combination with pea variety Feltham First but not with variety Meteor. The control of this enzyme is briefly discussed.     

Immunogold localization of hydrogenase in free-living Frankia CpI1

Abstract The free-living Frankia strain CpI1 cultured under nitrogen-fixing and non-nitrogen-fixing conditions was investigated for occurrence of hydrogenase protein by Western blots. Transmission electron microscopy and immunocytological labelling were used to study the distribution of hydrogenase in the Frankia strain.
Western immunoblots revealed that a 72-kDa protein in the Frankia strain CpI1 was immunologically related to the large subunit of a dimeric hydrogenase purified from Alcaligenes latus . Immunolocalization showed that the hydrogenase protein is located both in vesicles and hyphae in Frankia strain CpI1 grown in a nitrogen-free medium. Earlier reports that nitrogenase is localized in the vesicles [1,2], together with this finding, point out a possible role for hydrogenase in increasing relative efficiency of nitrogen fixation. In CpI1 grown in media containing nitrogen (lacking vesicles), the enzyme was evenly distributed in the hyphae. The impact of this result has to be further analysed.     

Inactivation of uptake hydrogenase leads to enhanced and sustained hydrogen production with high nitrogenase activity under high light exposure in the cyanobacterium <Emphasis Type="Italic">Anabaena siamensis</Emphasis> TISTR 8012

Background

Biohydrogen from cyanobacteria has attracted public interest due to its potential as a renewable energy carrier produced from solar energy and water. Anabaena siamensis TISTR 8012, a novel strain isolated from rice paddy field in Thailand, has been identified as a promising cyanobacterial strain for use as a high-yield hydrogen producer attributed to the activities of two enzymes, nitrogenase and bidirectional hydrogenase. One main obstacle for high hydrogen production by A. siamensis is a light-driven hydrogen consumption catalyzed by the uptake hydrogenase. To overcome this and in order to enhance the potential for nitrogenase based hydrogen production, we engineered a hydrogen uptake deficient strain by interrupting hupS encoding the small subunit of the uptake hydrogenase.

Results

An engineered strain lacking a functional uptake hydrogenase (?hupS) produced about 4-folds more hydrogen than the wild type strain. Moreover, the ?hupS strain showed long term, sustained hydrogen production under light exposure with 2–3 folds higher nitrogenase activity compared to the wild type. In addition, HupS inactivation had no major effects on cell growth and heterocyst differentiation. Gene expression analysis using RT-PCR indicates that electrons and ATP molecules required for hydrogen production in the ?hupS strain may be obtained from the electron transport chain associated with the photosynthetic oxidation of water in the vegetative cells. The ?hupS strain was found to compete well with the wild type up to 50 h in a mixed culture, thereafter the wild type started to grow on the relative expense of the ?hupS strain.

Conclusions

Inactivation of hupS is an effective strategy for improving biohydrogen production, in rates and specifically in total yield, in nitrogen-fixing cultures of the cyanobacterium Anabaena siamensis TISTR 8012.

     

微藻光合作用制氢——能源危机的最终出路?

微藻光合作用制氢是解决能源短缺问题的有效途径.本文介绍了微藻光合作用制氢的机理,包括蓝藻固氮酶和可逆氢酶产氢以及绿藻可逆氢酶产氢的机理.在分析光合制氢限制因素的基础上,指出筛选和构建高效放氢藻株是制氢的有效途径.然后介绍了“直接生物光解”、固氮酶放氢和“间接生物光解”等制氢方式.利用绿藻“间接生物光解”水制氢是一种最有发展潜力的制氢方式.本文最后展望了微藻光合制氢的前景.